itd standard - cleveland clinic

ITD STANDARD

SPECIFICATIONS FOR TECHNOLOGY FACILITIES, INFRASTRUCTURE, AND LOW VOLTAGE CABLING Release 2.5 (supersedes all previous releases) January 2016

Released by:

Cleveland Clinic Information Technology Division Facility Planning & Design 8002 Katherine Boulevard Brecksville, Ohio 44114 All information within this Document is CONFIDENTIAL and PROPRIETARY. By receipt and use of this Document, the recipient agrees not to divulge any of the information herein and attached hereto to persons other than those within the recipients’ organization that have specific need to know for the purposes of reviewing and referencing this information. Recipient also agrees not to use this information in any manner detrimental to the interests of Cleveland Clinic.

Specifications For Technology Facilities, Infrastructure, and Low Voltage Cabling Release 2.5 (January 2016)

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Cleveland Clinic Information Technology Division Standard

Specifications for Technology Facilities, Infrastructure, and Low Voltage Cabling Copyright © 2015

By the Cleveland Clinic

Reproduction of these documents, or parts thereof, in any form without the written permission of the Cleveland Clinic is prohibited.


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CONTENTS SUMMARY OF CHANGES – RELEASE 2.5 .............................................................................................. V

1.0 GENERAL SPECIFICATIONS ........................................................................................................ 1

1.1 PURPOSE ............................................................................................................... 1 1.2 SCOPE OF WORK .................................................................................................. 1 1.3 DEFINITIONS .......................................................................................................... 2 1.4 APPLICABLE STANDARDS .................................................................................... 3 1.5 CONTRACTOR QUALIFICATIONS ......................................................................... 4 1.6 ENVIRONMENTAL DUST PREVENTION ............................................................... 5 1.7 WORKMANSHIP ..................................................................................................... 5 1.8 VERIFICATION OF DETAILS .................................................................................. 6 1.9 PERMITS AND FEES .............................................................................................. 6 1.10 LABOR AND MATERIALS ....................................................................................... 6 1.11 SAFETY ................................................................................................................... 7 1.12 PROTECTION OF PERSONS AND PROPERTY .................................................... 7 1.13 CLEANING .............................................................................................................. 7 1.14 EXPLOSIVES .......................................................................................................... 8 1.15 STORAGE SPACE .................................................................................................. 8 1.16 BADGES AND PARKING PERMITS ........................................................................ 8 1.17 RESPONSIBILITY FOR TOOLS AND EQUIPMENT ............................................... 9 1.18 CHANGE ORDERS ................................................................................................. 9 1.19 WARRANTY ............................................................................................................ 9 1.20 SUBMITTALS ........................................................................................................ 10 1.21 PROJECT COMPLETION AND CLOSE OUT ........................................................ 11

2.0 PROJECT MANAGEMENT ........................................................................................................... 12

2.1 PROJECT MANAGER ........................................................................................... 12 2.2 PROJECT SCHEDULE .......................................................................................... 12 2.3 QUALITY CONTROL ............................................................................................. 12 2.4 MATERIALS MANAGEMENT ................................................................................ 13 2.5 SUBCONTRACTS MANAGEMENT ...................................................................... 13

3.0 OUTSIDE PLANT & ENTRANCE FACILITIES ............................................................................. 15

3.1 MAINTENANCE HOLES ........................................................................................ 15 3.2 HAND HOLES ........................................................................................................ 17 3.3 UNDERGROUND CONDUITS / DUCT-BANKS .................................................... 18 3.4 DIGGING AND TRENCHING ................................................................................. 20 3.5 AERIAL CABLE PLANT ......................................................................................... 23 3.6 BUILDING ENTRY POINTS ................................................................................... 26 3.7 DUAL ENTRANCE PATHWAYS ............................................................................ 26

4.0 TECHNOLOGY ROOMS ............................................................................................................... 27

4.1 GENERAL .............................................................................................................. 27 4.2 DESIGN ................................................................................................................. 27


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4.3 IT WORKROOM .................................................................................................... 33 5.0 BUILDING PATHWAYS ................................................................................................................ 34

5.1 GENERAL .............................................................................................................. 34 5.2 VERTICAL (RISER) INTERCONNECTING PATHWAYS ...................................... 35 5.3 HORIZONTAL DISTRIBUTION PATHWAYS ........................................................ 35 5.4 ROOF PENETRATIONS ........................................................................................ 36 5.5 EQUIPMENT AND MATERIALS ............................................................................ 37 5.6 INSTALLATION ..................................................................................................... 42

6.0 TECHNOLOGY GROUNDING SYSTEM ...................................................................................... 46

6.1 GENERAL .............................................................................................................. 46 6.2 EQUIPMENT GROUNDING .................................................................................. 46 6.3 EQUIPMENT AND MATERIALS ............................................................................ 47 6.4 INSTALLATION ..................................................................................................... 48

7.0 FIRESTOP ..................................................................................................................................... 52

7.1 GENERAL .............................................................................................................. 52 7.2 QUALITY ASSURANCE ........................................................................................ 52 7.3 EQUIPMENT AND MATERIALS ............................................................................ 53 7.4 INSTALLATION ..................................................................................................... 54

8.0 EQUIPMENT ENCLOSURES & RACKS ...................................................................................... 58

8.1 GENERAL .............................................................................................................. 58 8.2 EQUIPMENT AND MATERIALS ............................................................................ 58 8.3 INSTALLATION ..................................................................................................... 60

9.0 OUTSIDE PLANT & ENTRANCE FACILITIES ............................................................................. 61


10.0 BACKBONE COPPER CABLING (HIGH PAIR COUNT) ............................................................. 69


11.0 HORIZONTAL CABLING .............................................................................................................. 72


12.0 WORK AREA ................................................................................................................................. 78



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13.0 CABLING SYSTEM ADMINISTRATION ....................................................................................... 82


14.0 TESTING ........................................................................................................................................ 86

14.1 GENERAL .............................................................................................................. 86 14.2 FIBER OPTIC CABLE TESTS ............................................................................... 86 14.3 UTP CABLE TESTS ............................................................................................... 88 14.4 BACKBONE COPPER HIGH PAIR COUNT CABLE TESTS ................................. 90

15.0 AS-BUILT DOCUMENTATION ..................................................................................................... 91

15.1 GENERAL .............................................................................................................. 91 15.2 LOW VOLTAGE CABLING SYSTEM DOCUMENTATION .................................... 91 15.3 RECORD DRAWINGS ........................................................................................... 92 15.4 FIBER STRAND ID CHARTS ................................................................................. 92 15.5 UTP - 110 PATCH BLOCK ID CHART ................................................................... 92 15.6 UTP - PATCH PANEL ID CHART .......................................................................... 92 15.7 TEST RESULTS .................................................................................................... 93 15.8 MANUFACTURER’S SPECIFICATIONS ............................................................... 93

16.0 UNITERRUPTIBLE POWER SUPPLY (UPS) SYSTEMS ............................................................ 94

16.1 GENERAL .............................................................................................................. 94 16.2 UPS SYSTEM ........................................................................................................ 94 16.3 BATTERY SYSTEM ............................................................................................... 96 16.4 MAINTENANCE (WRAP-AROUND) BYPASS ....................................................... 97 16.5 INSTALLATION ..................................................................................................... 97 16.6 START-UP ............................................................................................................. 98

17.0 CRITICAL FAILITIES MONITORING SYSTEM (CFNS) ............................................................... 99

17.1 GENERAL .............................................................................................................. 99 17.2 EQUIPMENT AND MATERIALS ............................................................................ 99 17.3 INSTALLATION ................................................................................................... 100 17.4 COMMISSIONING ............................................................................................... 103 17.5 THIRD-PARTY (NON-EMERSON) EQUIPMENT MONITORING ........................ 103

APPENDIX A: MATERIAL LISTS ........................................................................................................... A-1

APPENDIX B: LABELING SCHEMES .................................................................................................... B-1

APPENDIX C: DRAWING STANDARDS ................................................................................................ C-1

APPENDIX D: TYPICAL DESIGN DRAWINGS ....................................................................................... D-1

APPENDIX E: ARCHITECTURAL GUIDELINES FOR WORK AREAS ................................................ E-1

APPENDIX F: PROJECT PLANNING ..................................................................................................... F-1


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SUMMARY OF CHANGES – RELEASE 2.5 A. This document represents the current release (Release 2.5, dated November 2015) of the ITD

Standard: Specifications for Technology Facilities, Infrastructure, and Low Voltage Cabling. The purpose of this release is to incorporate relevant changes and improvements in technology and industry best practices, and provide revisions to approved manufacturer’s equipment and associated material part numbers.

B. Throughout the document, all revisions and additions as part of this release are listed below for ease in identification. Note that minor changes, such as grammatical, spelling, punctuation errors, paragraph numbering and other common corrections that occur as part of any release have not been specifically called out and highlighted as these types of corrections do not impact the content or intent of the document.

C. The following sections have been added or modified, and are listed by Section Number and Paragraph:

1. Section 1.2, Paragraph B and E

2. Section 1.4, Paragraph K

3. Section 1.5, Paragraph C

4. Section 1.6, Paragraph C, Sub-paragraph 2

5. Section 3.3, Paragraph B, Sub-paragraph 2

6. Section 3.4, Figure 2

7. Section 4.2, Paragraph D, Sub-paragraph 4

8. Section 4.2, Paragraph F, Sub-paragraph 1

9. Section 4.2, Paragraph G, Sub-paragraph 4 and 8

10. Section 4.2, Paragraph H, Sub-paragraph 2

11. Section 4.2, Paragraph I, Sub-paragraph 2 and 7

12. Section 4.2, Paragraph K, Sub-paragraph 6

13. Section 4.2, Paragraph L, All

14. Section 4.2, Paragraph N

15. Section 4.3, Paragraph H

16. Section 5.1, Paragraph G and I

17. Section 5.2, Paragraph B


19. Section 5.5, Paragraph C, Sub-paragraphs 10 and 14

20. Section 5.5, Paragraph D, Sub-paragraph 8, 10 and 13

21. Section 5.5, Paragraph G, Sub-paragraph 6

22. Section 5.5, Paragraph H, Sub-paragraph 4


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24. Section 6.3, Paragraph A, Sub-paragraph 4 and 11


26. Section 8.2, Paragraph B, Sub-paragraphs 7-band 8-b

27. Section 9.2, Paragraphs B, Sub-paragraph 10



30. Section 9.2, Paragraph E, Sub-paragraphs 1 and 7

31. Section 9.2, Paragraph F, Sub-paragraphs 1, 5, 6 and 9

32. Section 9.2, Paragraph G, Sub-paragraphs 4 and 5

33. Section 9.2, Paragraph H, Sub-paragraphs 6 and 9

34. Section 9.2, Paragraph I, Sub-paragraph 4

35. Section 10.2, Paragraph A, Sub-paragraph 6


37. Section 10.2, Paragraph D

38. Section 10.3, Paragraph O

39. Section 11.2, Paragraph A, All

40. Section 11.2, Paragraph B, All

41. Section 11.2, Paragraph C, All

42. Section 11.2, Paragraph D, Sub-paragraphs 3 and 6

43. Section 11.2, Paragraph E, Sub-paragraphs 1 and 6

44. Section 11.3, Paragraph G, Sub-paragraphs 1, 2 and 3

45. Section 12.1, Paragraph F, Table 12-A

46. Section 12.2, Paragraph A, Sub-paragraph 6


48. Section 12.2, Paragraph C, Sub-paragraphs 1 and 2


50. Section 12.2, Paragraph E, Sub-paragraphs 1, 3 and 4

51. Section 14.3, Paragraphs C, D and O

52. Section 15.1, Paragraph D

53. Section 15.2, Paragraph A

54. Section 15.3, Paragraph B

55. Section 16.0, Entire Section is New

56. Appendix A, Updated Material Lists

57. Appendix C, Updated Telecommunications Outlet Symbol Legend


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Any questions or comments regarding this document should be brought to the attention of ITD Facility Planning and Design Department. END SUMMARY OF CHANGES


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1.0 GENERAL SPECIFICATIONS 1.1 PURPOSE

A. The specifications outlined in this document are intended to provide Architects, Engineers Consultants and Contractors with a comprehensive set of structural, electrical, mechanical, and installation requirements for equipment rooms, technology rooms, and low voltage systems and associated pathways (e.g., cable tray, conduit, etc.) within a Cleveland Clinic facility. Furthermore, this standard is intended to meet the following objectives.

1. Establish a uniform enterprise-wide standard by which all new building construction and renovation projects are governed.

2. Ensure that the equipment rooms, technology rooms, and cable pathways meet the current and future business needs, and growth expectations of Cleveland Clinic.

3. Facilitate network operations, including equipment maintenance and upgrades, and the moves, adds and changes (MAC) process.

4. Provide a reliable and secure network infrastructure that meets or exceeds industry standards, and federal, state and local codes and regulations.

B. The ITD Facility Planning & Operations Group (located in Cleveland, Ohio) has responsibility for creating, amending and enforcement of these specifications and standards.

1.2 SCOPE OF WORK

A. At Cleveland Clinic, telecommunications and network technologies are critical elements in the design and commissioning of all new buildings and renovation projects. In turn, a well designed and implemented structured cabling plant is fundamental to enabling these technologies. This document provides detailed Specifications and Drawings for the construction and implementation of equipment rooms, technology rooms and low voltage structured cabling for new construction and renovation projects.

B. The standards and Specifications detailed in this document are adapted from relevant industry standards and practices including the IEEE, NEC, NFPA, ANSI, EIA, TIA, FGI and BICSI. As industry standards and best practices continue to change and evolve, and as new technologies are brought to market, this standard will also change overtime as needed to encompass new technologies and business directions.

C. Part Numbers as well as technical specifications are subject to change by the manufacturer without notice. Cleveland Clinic has endeavored to ensure the accuracy of all information within these Specifications. Contractors shall be responsible to verify the accuracy of all part numbers and specifications with the respective manufacturers.

D. Only products and manufacturers listed as approved shall be utilized. Substitutions shall not be allowed. Loss of certification by Contractor, or unavailability of product to Contractor that is not of a market wide nature, shall not be construed as an unavoidable circumstance.

E. The design intent is to provide a manufacturer specific, end-to-end solution for the low voltage structured cabling systems. Contractors shall bid the cabling as an end-to-end solution in accordance with the design intent. The approved end-to-end solutions are Berk-Tek/Leviton and Berk-Tek/Ortronics. Mixing or substituting of different manufacturers products shall not be permitted.


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F. Cables and terminations shall be provided and located as shown, and in the quantities indicated on the Drawings.

1.3 DEFINITIONS

A. As used throughout this document, and any associated Cleveland Clinic documents, including but not limited to Contract Documents, Construction Documents, RFP Documents and Attachments, the terms below shall have the following definitions.

B. The term "Acceptance" shall be defined as Cleveland Clinic’s notification to Contractor that the work, as defined herein, has been delivered and installed in accordance with this RFP and all associated Appendices, Amendments and Change Orders and that Contractor has satisfactorily completed all System Testing and Documentation as specified herein.

C. The term “Building” shall refer to the Site where those portions of the Work shall include the internal horizontal and/or vertical fiber, copper and/or coaxial cabling within a given physical structure.

D. The term “Campus” shall refer to the Site where those portions of the Work shall include interconnecting or backbone cabling, comprised of either fiber, copper and/or coaxial(s) between two or more buildings.

E. The term “Construction Management Company” shall mean the contracting company responsible for the general construction and commission of a new building or building renovation project and its site project management staff.

F. The term “Contract Agreement” shall mean The Construction Management or General Contractor Company’s Subcontract Agreement.

G. The term “Contractor” shall mean the successful bidder selected by Cleveland Clinic to perform all or a portion of the installation work for the structured cabling project as described in these Specifications.

H. The term "Documentation" shall mean all current product descriptions, technical manuals, supporting materials; warranties and Contractor produced detailed technical drawings and illustrations, including copies thereof, which are to be provided by Contractor to Cleveland Clinic pursuant to these Specifications.

I. The term “Drawings” shall mean the graphic and pictorial portions of the Contract Documents showing the design location and dimensions of the Services, generally including plans, elevations, sections, details, schedules and diagrams.

J. The term “Furnish” shall mean to supply and deliver to the Project Site, ready for unloading, unpacking, assembly, installation, and similar operations.

K. The term “Install” shall mean work that includes the actual unloading, unpacking, assembly, erecting, placing, anchoring, applying, working to dimension, finishing, curing, protecting, cleaning, and similar operations.

L. The term "Materials" shall mean the materials, products, supplies and components, which are to be provided by the Contractor for incorporation into, or in connection with the installation of the structured cabling system, including those items listed in this RFP and Appendices.

M. The term “Project” shall mean the total construction of which the Work performed under the Contract Documents may be the whole or a part and which may include construction by Cleveland Clinic or by separate Contractors.


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N. The term "Project Manager" shall mean and include the sole representative of either party, and such representative shall have full responsibility for coordination of the activities of his or her respective party.

O. The term “Provide” shall mean to furnish and install, complete and ready for the intended use.

P. The term "Services" shall mean those Contractor obligations including, but not limited to, Materials, installation labor, testing, project management and Documentation that are to be provided by Contractor to Cleveland Clinic pursuant to the specific Contract Documents and RFP.

Q. The term "Site" shall be defined as the land, building and environment provided by Cleveland Clinic where work is to take place and Services and Materials are to be rendered as defined herein.

R. The term “Specifications” shall mean that portion of the Contract Documents consisting of the written requirements for Materials, equipment, systems, installation standards and methods, and installation workmanship for the Work, and performance of related Services.

S. The term “Subcontractor” is a person, entity or business concern who has a direct contract with Contractor to perform all or a portion of the Work at the Site. The term Subcontractor does not include a separate Contractor or Subcontractors of a separate Contractor.

T. The term “Work” shall mean those Contractor obligations including, but not limited to, materials, equipment, labor, testing, project management and documentation that are required by the Contract Documents, whether completed or partially completed. The Work may constitute the whole or apart of the Project.

1.4 APPLICABLE STANDARDS

All infrastructure design and construction shall conform to current industry standards, federal, state and local codes. The following documents form a part of, and are applicable to these Specifications. Where an effective date is not shown for any given document or publication, the issue in effect on the effective date a project is awarded shall apply. Any express conflict in documents shall be resolved by the ITD Facility Planning and Operations Department.

A. NFPA 70, National Electrical Code (NEC)

B. ANSI C2, National Electrical Safety Code (NESC)

C. ANSI/EIA/TIA-568-B.1, Commercial Building Telecommunications Cabling Standard, Part 1: General Requirements

D. ANSI/EIA/TIA-568-B.2, Commercial Building Telecommunications Cabling Standard, Part 2: Balanced Twisted-Pair cabling Components (including the Category 6 Addendum)

E. ANSI/EIA/TIA-568-B.3, Commercial Building Telecommunications Cabling Standard, Optical Fiber Cabling Components Standard

F. ANSI/EIA/TIA-569-A, Commercial Building Standard for Telecommunications Pathways and Spaces Standard, (including all TSBs and Addenda)

G. ANSI/EIA/TIA-J- 607-STD-A, Commercial Building Grounding (Earthing) and Bonding Requirements for Telecommunications

H. ANSI/TIA/EIA 758, Customer Owned Outside Plant Telecommunications Infrastructure Standard


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I. BICSI Telecommunications Distribution Methods Manual

J. NECA / BICSI 568 Installing Commercial Building Telecommunications Cabling

K. The Facility Guidelines Institute (FGI) Guidelines for Design and Construction of Hospitals and Outpatient Facilities

L. UL 910, Test for Flame-Propagation and Smoke Density Values for Electrical and Optical Fiber Cables in Spaces Transporting Environmental Air, 1997

M. UL 1685, Vertical-Tray Fire Protection and Smoke Release Test for Electrical and Optical Fiber Cables

N. NEMA VE-2, Cable Tray Installation Guidelines

O. IEEE 1100-2005, Powering and Grounding of Electronic Equipment

P. Cleveland Clinic - Fire Protection & Life Safety Design Standard

Q. Cleveland Clinic Office of Construction - Design Standards

R. Cleveland Clinic Office of Construction - Energy Management Standards Manual 1.5 CONTRACTOR QUALIFICATIONS

A. Contractor shall be fully qualified to perform installations as described on the Drawings and within these Specifications. The following qualifications apply to all Work unless otherwise noted. Cleveland Clinic reserves the right to wave any or all of these requirements.

B. Contractor shall have been active in bidding, being awarded, and performing Work consistent with that indicated on the Drawings and in the Specifications for a period not less than five (5) years.

C. Contractor shall possess current installation and maintenance training and certifications by the specified manufacturers including, but not limited to Berk-Tek/Leviton, Berk-Tek/Ortronics, Corning EWP, MaxCell and Specified Technologies. Furthermore, Contractor must possess all respective certifications prior to bidding any project. Certifications that are Site specific and not universal shall not be recognized by Cleveland Clinic.

D. Contractor shall meet all union labor agreement and contract requirements as required by Cleveland Clinic and/or Construction Manager. All dues, fees and costs associated with Contractor’s union affiliation shall be the sole responsibility of Contractor.

E. Contractor shall possess current BICSI certifications for the installation and maintenance of all low voltage cabling and associated equipment.

F. Contractor shall maintain an installation staff whose sole function is the installation of low voltage structured cabling and equipment and shall not utilize additional personnel obtained by means of a temporary placement or staffing agency.

G. Contractor shall not utilize apprentice or trainee personnel for the pulling or termination of low voltage structured cabling. Furthermore, apprentices or trainees may only assist in the pulling of low voltage structured cabling. The primary laborer for installing low voltage structured cabling must be a certified installer.

H. All installation personnel assigned to the task of pulling or terminating cabling shall possess a current certification by BICSI and/or the manufacturer for the specified cabling and connectivity products.


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I. Contractor’s installation staff shall consist of 85% certified installation personnel. The remaining shall be either apprentice installation personnel or laborers under full time employment by Contractor. Of the certified staff, 40% shall be Journeymen/BICSI Installers. The remainder shall be BICSI Level I or Level II Installers.

J. Contractor shall have a dedicated RCDD assigned to the project as Project Manager. Contractor’s RCDD/Project Manager shall be the sole point of contact for Cleveland Clinic. The RCDD/Project Manager shall provide regular project updates to Cleveland Clinic’s Project Manager as to percentage of job completed broken down by category of work, for example, horizontal cabling, backbone copper, backbone fiber, etc., the status of any unforeseen circumstances, and/or changes to the project design necessitated by field conditions.

1.6 ENVIRONMENTAL DUST PREVENTION

A. Contractor shall take appropriate safeguards to prevent dust or fumes caused by construction activities (such as drilling or cutting concrete, drywall and brick; grinding or welding metals, or use of paints or solvents) from contacting nearby equipment, adjacent offices or any areas where potential damage, harm or injury may occur.

B. Contractor shall be responsible for all environmental dust containment requirements within and around the area of Work, and ensure that all environmental dust is contained by usage of a ceiling to floor barrier unit.

C. All environmental dust containment associated with the installation of the low voltage cabling system(s) shall comply with Cleveland Clinics Department of Infection Control and Epidemiology Policy # 207, “Infection Control Dust Prevention Requirements for Wiring Projects”. Minimum environmental dust prevention requirements are as follows:

1. All inpatient-care nursing areas shall require the use of Contractor provided environmental containment unit to be erected from the floor to ceiling for ceiling tile removal and the installation of low voltage cabling.

2. All inpatient-care areas shall require the use of Contractor provided environmental containment unit with negative air pressure and High Efficiency Particulate Air Filtration (HEPA) to be erected from the floor to the ceiling for ceiling tile removal and the installation of low voltage cabling.

3. All environmental containment units shall be vacuumed out prior to dismantling.

4. All environmental containment units shall be dismantled and stored during all breaks/lunch.

5. Under no circumstances shall a wall or ceiling tile remain open during breaks/lunch, overnight or over a weekend.

1.7 WORKMANSHIP

A. All Materials shall be installed in compliance with the recommendations of the respective manufacturer, current industry standards, these Specifications, the National Electrical Code, and all applicable state and local building and fire codes.

B. All work shall conform to the requirements of the Specifications. The installation, construction, cable terminations, and splicing shall be performed by workers trained and skilled in this type of work.


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C. Contractor shall meet all OSHA requirements related to safety and equipment operation. Work shall be performed during normal, day shift working hours, except where Cleveland Clinic has elected second or third shift option.

D. Contractor shall be responsible for repairing all building and outside cable plant faults, due to Contractor’s installation defects, poor workmanship, and/or negligence, at no additional cost to Cleveland Clinic prior to acceptance of the Work. Cleveland Clinic’s personnel and/or agents shall have free access to the work at all times.

1.8 VERIFICATION OF DETAILS

A. Contractor shall become familiar with details of work in the field and shall advise Cleveland Clinic in writing of any discrepancy in the design prior to commencement of Work.

B. Contractor shall acknowledge that it has investigated and satisfied itself as to all of the conditions affecting the Work. Any failure by Contractor to become acquainted with the available information shall not relieve Contractor from responsibility for estimating properly the difficulty or cost of successfully performing the requested Work. Cleveland Clinic shall assume no responsibility for any erroneous conclusions or misinterpretations made by Contractor based on information made available by Cleveland Clinic.

C. Errors and/or omissions from the Specifications or Drawings detailing the tasks necessary to perform the Work and carry out the intent of the design or that are customarily performed shall not relieve Contractor from performing such omitted details of the Work.

D. Contractor shall be responsible to verify quantities for all equipment, cabling, components and Materials prior to submitting a bid. Contractor shall accept full responsibility for accurately estimating the Work and Materials based on the Specifications and Drawings.

1.9 PERMITS AND FEES

A. Secure and pay for permits and inspections required for the Work. Submit certificates of approval to Cleveland Clinic promptly when received. Cleveland Clinic shall not make payment for Work until certificates are received.

B. Give authorities proper notice as required by law relative to the Work in their charge. Comply with the regulations regarding temporary enclosures, obstructions or excavations and pay all legal fees involved.

C. Work shall be installed in accordance with all applicable provisions of the National Electrical Code, as interpreted by the local authority having jurisdiction, as well as any further modifications or regulations published by local or state authorities.

1.10 LABOR AND MATERIALS

A. Contractor shall provide and pay for labor, materials, equipment, tools, construction equipment and machinery, water heat utilities, transportation and other facilities and services necessary for the proper execution and completion of the Work.

B. Contractor shall enforce strict discipline and order among Contractor’s employees and Subcontractors in performance of the Work.

C. Contractor retains title to all Materials until fully installed and accepted by Cleveland Clinic.


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D. Contractor shall not utilize unfit persons or persons not skilled in tasks assigned to them. 1.11 SAFETY

A. Contractor shall adhere to the latest edition of the American National Standard Institute (ANSI) National Electrical Safety Code (NESC), OSHA Standards, and all local fire and safety regulations.

B. Cleveland Clinic reserves the right to inspect Contractor's work at any time to ensure compliance with the aforementioned documents and specific safety procedures stated herein.

C. Contractor shall be responsible to follow all safety requirements, conditions and procedures as set forth by Cleveland Clinic.

D. Should the Contractor violate any safety procedures or requirements, Cleveland Clinic reserves the right to issue a stop work order. The stop work order shall remain in effect until Contractor has resolved the violation. Responsibility for the stop work order shall rest solely with Contractor with no cost or schedule impact to Cleveland Clinic.

1.12 PROTECTION OF PERSONS AND PROPERTY

A. Contractor shall be responsible to provide all safety equipment and for the enforcement of all safety requirements including, but not limited to, use of hard hats, safety glasses, hearing protection, safety belts, tool tethers while working overhead, safety cones, and preventing personnel from working overhead while others are working underneath.

B. Contractor shall provide protection of persons and property throughout the progress of the Work. Contractor shall provide the necessary safety equipment, barricades and signs to protect personnel and property, of their own, their employees, Subcontractor’s employees, and other trades working on the Site.

C. Contractor agrees to exercise reasonable care to avoid damage to Cleveland Clinic facilities and property of others. Contractor shall assume full responsibility for all damages to such Cleveland Clinic facilities arising out of or caused by the conduct or property of Contractor’s negligence. Contractor shall make an immediate report to Cleveland Clinic of occurrence of any such damage and hereby agrees to repair or replace at Contractor's expense, or to reimburse Cleveland Clinic, or such other parties for expenses incurred by them in making necessary repairs and replacements.

1.13 CLEANING

A. In performance of the Work, Contractor shall make every reasonable effort to protect floors, carpets, ceiling tiles, walls and other property from damage, and shall restore all such property, subject to the Work, to conditions substantially the same as when Work began.

B. Contractor shall be responsible for daily cleanup and removal (within Contractor's work areas) of all non-salvageable materials and debris resulting from the execution of Work. Contractor shall be responsible for removal of materials and debris from Site. Oil waste, rags or flammable materials must be removed from the building immediately after use.

C. Contractor shall ensure that all work in finished areas of the building are cleaned and restored to the same conditions as before the Work. All salvageable materials not used or not yet installed shall be properly stored and secured.


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D. Contractor shall properly firestop all rated penetrations in accordance with Cleveland Clinic Health & Environmental Safety Standards. Contractor shall ensure that all ceiling tiles are replaced and properly seated.

1.14 EXPLOSIVES

A. Explosives shall not be used under any circumstances without the written approval of Cleveland Clinic.

1.15 STORAGE SPACE

A. Storage space is limited and/or not secure. Storage of Materials shall be the responsibility of Contractor. Outside space for placement of a construction trailer or storage container must be coordinated through Cleveland Clinic or the Construction Manager. All costs associated with a construction trailer and/or storage container shall be included in Contractor’s bid proposal.

B. Contractor shall furnish and pay for all utilities, insurance, and security for any construction trailer and/or storage container placed on Site. Contractor shall be responsible for all connections to utility sources, including any required hardware and/or equipment required for making the connections.

C. Contractor shall remove all construction trailers and/or storage containers placed on the Site by the Contractor or his/her subcontractors within ten (10) calendar days of notice from Cleveland Clinic or Construction Manager, or ten (10) calendar days of Project completion date.

D. Contractor shall restore the site of the construction trailer and/or storage containers to its original condition. Contractor shall be responsible for all removal and restoration costs.

1.16 BADGES AND PARKING PERMITS

A. Contractor shall be responsible to purchase from Cleveland Clinic Parking Permits and Identification Badges for all Contractor vehicles and installation personnel needing access to the Site.

B. Contractor agrees to abide by all Cleveland Clinic parking and badging rules and guidelines. Contractor shall submit a list of vehicles and personnel to Cleveland Clinic prior to commencement of Work. Cleveland Clinic shall provide the necessary approval letters and access privileges as needed for the project.

C. As part of the badging process, all Contractor personnel shall be subject to finger printing and criminal background checks.

D. Contractor shall be permitted to park in designated areas as determined by Cleveland Clinic. Contractor is not permitted to park in Cleveland Clinic garages. Cleveland Clinic shall not be responsible for lost, stolen or damaged Contractor vehicles or property while parked on Cleveland Clinic premises.


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1.17 RESPONSIBILITY FOR TOOLS AND EQUIPMENT

A. Contractor shall be responsible to supply, maintain and secure all tools, ladders, lift equipment and safety equipment. Cleveland Clinic shall not accept any responsibility for the loss, theft, disappearance, or damage to equipment, tools, materials, or supplies of Contractor, its employees, agents or Subcontractors.

1.18 CHANGE ORDERS

A. All change orders shall be approved in writing by Cleveland Clinic. Under no circumstances shall verbal statement(s) be considered binding.

B. Justification for changes requiring cost increases or schedule delays shall be required in writing. Action on the change or Work affected by the change shall not be performed until Contractor receives written approval from Cleveland Clinic.

C. Any work performed by Contractor on a change order without following Cleveland Clinic procedures shall be at the risk and expense of Contractor, and at no cost to Cleveland Clinic.

D. As requested by Cleveland Clinic, Contractor shall perform all necessary appraisals and field surveys to provide an estimate of the cost and schedule impact of the change request.

E. Based on the information provided in the change request, field notes and surveys, Contractor Shall provide Cleveland Clinic with a written proposal with detailed unit prices for all labor and Materials. Where applicable all Materials and labor shall be priced in accordance with the Unit Prices in the Contractor’s base bid proposal. Contractor shall ensure that all information and pricing submitted with the proposal are complete, and shall meet the intent of the change request.

F. Change order pricing shall remain effective for a period of 90 (ninety) days from date of receipt by Cleveland Clinic. Cleveland Clinic will evaluate the change request in light of the cost and/or schedule impact on the Project and either approve or disapprove followed by notification to Contractor.

G. Upon receipt of written approval, Contractor shall assign a change order number to the change request. Approved changes shall be invoiced upon completion and acceptance. Change orders shall be separately itemized on all invoices.

1.19 WARRANTY

A. Contractor shall warrant that the Work shall be free of defects in material and workmanship for a period of one year from the date of Acceptance. Contractor shall promptly and at its own cost and expense correct Work that is rejected by Cleveland Clinic or Work that fails to conform to the requirements of these Specifications.

B. Contractor shall assign to Cleveland Clinic all manufacturers’ warranties relating to any of the equipment and materials, specifically the respective manufacturers’ extended warranties. Contractor shall deliver to Cleveland Clinic copies of all such warranties.

C. Contractor shall warrant that it has obtained all applicable licenses for Cleveland Clinic to use the Materials and has paid all required royalties for use of the system for its expected useful life.


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D. Contractor warrants that it has absolute title to and full right to sell said Materials to Cleveland Clinic as components of the system, and there are no liens, claims, or encumbrances of any kind whatsoever against said Materials. Materials shall remain as so warranted at the time of delivery and final installation.

E. Contractor’s warranty excludes remedy for damage or defect caused by abuse, modifications not executed by Contractor, improper or insufficient maintenance, improper operation, normal wear and tear and normal usage.

F. No inspection, acceptance of, or payment for the Work by Cleveland Clinic shall constitute waiver of any warranties.

1.20 SUBMITTALS

A. Prepare shop drawings and product data sheets for technology equipment with adequate details and scales as necessary to show construction in a clear and concise manner.

B. Indicate operating characteristics for each required item and design conditions. Submit the actual cable test data as generated by the manufacturer for the stock to be utilized for construction. Contractor shall review each submittal prior to submission, and check for compliance with Contract Documents. Corrections shall be noted. Mark with approval stamp prior to submission. Submittals that do not bear Contractor’s approval stamp will be returned without action.

C. Shop drawings and product data shall include: 1. Copper Cabling 2. Fiber Cabling 3. Coaxial Cabling 4. Low Voltage Protection Devices 5. Fiber Connector Housings 6. Faceplates 7. Jacks/Inserts 8. Modular Patch Panels 9. 110 Wiring Blocks 10. Fiber Connectors 11. Coupler Panels 12. Fiber Connector Housings 13. Racks 14. Cable Tray 15. Cable Runway 16. Firestop Details 17. Cable and Component Mounting Hardware 18. Technology Grounding System Materials 19. UPS Systems 20. CATV/Broadband Distribution System Cable, Components and Connectors 21. Distributed Antenna Systems (DAS) 22. 802.11 Wireless Antenna Systems

D. The submittals shall be reviewed for general compliance and not for dimensions, quantities, etc. The submittals that are returned shall be used for procurement. The responsibility of correct procurement remains solely with Contractor. The submittal review shall not relieve Contractor of responsibility for errors or omissions and deviations from the Contract requirements.


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E. EQUIPMENT SUBSTITUTIONS SHALL BE PROHIBITED. Any submittal showing a change or variation from the Specifications herein, for any reason, shall be rejected.

F. Contractor shall note in red on the submittal any change in design or dimension on the items submitted including changes made by the manufacturer that may differ from catalog information.

G. Contractor agrees that shop drawing submittals, processed by the Architect, Technology Engineer, or Cleveland Clinic are not change orders or a means for equipment substitution. Contractor further agrees that the purpose of shop drawing submittals is to demonstrate Contractors understanding of the design intent. This understanding is demonstrated by articulating which equipment and material is required, and by what methods of fabrication and installation shall be utilized.

H. Contractor agrees that if deviations, discrepancies or conflicts between shop drawing submittals and Contract Documents are discovered, either prior to or after shop drawings submittals are processed, Contract Drawings and Specifications shall take precedent and be followed.

I. Shop Drawings shall be submitted in an electronic format on CD. The file format shall be Adobe portable data file (.pdf) or provide software to enable viewing of files of the other formats at no additional cost to Cleveland Clinic.

1.21 PROJECT COMPLETION AND CLOSE OUT

A. Project completion shall be defined at a minimum by the following requirements.

1. Contractor shall submit all applicable as-built Documentation to Cleveland Clinic for review and written acceptance as required elsewhere in these Specifications.

2. For Work where Contractor is under Contract to a Construction Manager or General Contractor, Contractor shall submit a duplicate copy of all Documentation to Cleveland Clinic at the same time Documentation is submitted to Construction Manager or General Contractor.

3. At the discretion of Cleveland Clinic, Contractor shall provide demonstration of system performance. Upon completion of each system demonstration, Cleveland Clinic shall provide a written acceptance of each system

4. Contractor shall submit all test results, record drawings, and all other documents necessary to commence the warranty periods for all equipment and devices as provided under the scope of the Project. Contractor shall provide proof of these submissions to Cleveland Clinic.

5. Cleveland Clinic shall provide a final punch list to Contractor. Contractor shall rectify all items on this list, or at the discretion of Cleveland Clinic, provide a credit back to Cleveland Clinic based on unit pricing garnered at the time of the bid. If no such unit pricing is available, a mutually agreed upon price, based on current recognized market value, shall be utilized.

B. Contractor shall complete all requirements of these Specifications. Any additional effort required at the time of the final walk-through due to the lack of submittals during the construction process shall cause forfeiture of final retainer either in part or in whole based on the degree of additional effort required. The exact nature of the magnitude of this forfeiture is at the discretion of Cleveland Clinic.

END OF SECTION 1.0


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2.0 PROJECT MANAGEMENT 2.1 PROJECT MANAGER

A. Contractor shall provide a Project Manager to manage and coordinate the Labor and Materials supplied by Contractor for the Work as described in the site-specific RFP documents. Contractor's Project Manager shall be a single point of contact to Cleveland Clinic. Contractor's Project Manager shall be responsible for fulfilling all project submittals and communications as stated herein and in the Contract Documents.

B. Contractor's Project Manager shall plan, direct and control all portions of the Work as described on the Drawings and in the Specifications. Contractor shall conduct all phases of Work relevant to the project and any Change Orders in such a manner as to assure minimum interference to any Cleveland Clinic related or other building construction related activities in the areas of work.

C. Contractor’s Project Manager shall attend regularly scheduled meetings with Cleveland Clinic. The purpose of these meetings shall be to discuss Work progress, scheduling, identify problem areas, as well as opportunities to improve efficiency by recommending alternative procedures. Contractor’s Project Manager shall contact Cleveland Clinic after contract award, but prior to installation start-up to determine the date of the Project Kickoff Meeting. At the Kickoff Meeting the frequency, day and time of the project meetings will be jointly established.

D. Upon completion of the project, including submission of all as-built drawings and documentation, Contractor’s Project Manager and Cleveland Clinic shall hold a Project Closeout Meeting. The purpose of this meeting shall be to discuss remaining contractual issues; warranty start date and Contractor’s warranty call procedures, and review all final as-built documentation for completeness and accuracy.

2.2 PROJECT SCHEDULE

A. Contractor shall be required to adhere to the project milestone and implementation schedule contained in the Contract Documents and agreed to as part of Contractor’s proposal. Upon award of Contract, Contractor shall submit a detailed implementation schedule to Cleveland Clinic. Contractor's Project Manager shall provide weekly updates as to the progress of performance compared to the project schedule. Any changes to the schedule shall be reviewed and approved in writing by Cleveland Clinic. Approved schedule changes as revised shall be reflected in the project schedule presented at the next project meeting.

B. Contractor shall be responsible to meet schedule milestones and completion timeframes. Delays shall not be permitted unless approved in writing by Cleveland Clinic. Contractor shall be responsible to make up for all schedule changes resulting in lost time that are caused by Contractor's inability to plan or properly coordinate his work effort in accordance with the Project Schedule.

2.3 QUALITY CONTROL

A. Contractor shall provide quality control throughout the duration of the Project. Contractor’s Project Manager shall conduct regular weekly inspections of all Work under Contractor’s control.


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B. Contractor shall warrant the installation against all product defects, and shall warrant that all approved cabling components meet or exceed the requirements of the ANSI/TIA/EIA 568-B standards and addendum, and the ISO/IEC 11801 including amendments.

C. Contractor shall ensure that all Work is performed in accordance with Drawings and Specifications.

D. Contractor shall generate punch lists noting all deficiencies in the construction and installation of the system. A copy of these punch lists shall be provided to Contractor's installation personnel. Punch lists shall be accompanied with action-required statements.

E. Cleveland Clinic reserves the right to conduct progress inspections of Contractor’s Work in order to ensure quality and workmanship standards are being met. After each inspection and as necessary, Cleveland Clinic shall generate a punch list of all areas where deficiencies in the Work are noted. The Contractor shall immediately correct all deficiencies noted on Cleveland Clinic’s punch list at no additional cost to Cleveland Clinic.

F. Contractor shall be responsible to identify and notify Cleveland Clinic immediately of any issues causing the cabling and/or equipment to be installed in such a way as to cause that part of the installation to be in violation of the accepted standards and practices governing these types of installations. Failure to do so shall place the burden of the necessary repairs on Contractor.

G. Upon completion of all Work, including testing and labeling, Contractor shall conduct a final inspection and punch list with Cleveland Clinic’s Project Manager. Prior to Cleveland Clinic’s final Acceptance of any portion of the Materials and/or Work, Contractor shall ensure that all deficiencies are corrected.

2.4 MATERIALS MANAGEMENT

A. Contractor shall provide Materials management for all equipment, tools, materials and hardware supplied by Contractor.

B. Contractor shall order the required Materials, track the orders through delivery, confirm receipt of Materials, store Materials, and distribute Materials to the Site as required.

C. Contractor shall be responsible to ensure that the Materials are properly stored and secured, and conform to Cleveland Clinic’s requirements as described in this Specification.

D. Contractor, at no cost to Cleveland Clinic, shall replace all Materials believed and/or found to be defective, damaged, stolen or missing.

E. Material orders and acknowledged ship dates shall be included in updates to the project schedule.

2.5 SUBCONTRACTS MANAGEMENT

A. Contractor may hire, as necessary, qualified Subcontractors for the installation of all or any portion of the network in accordance with the provisions and requirements in these Specifications.

B. Contractor shall include in their proposals the names of all Subcontractors that are proposed or planned to participate in the work. Cleveland Clinic reserves the right to reject any proposed Subcontractors in whole or in part


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C. Any Subcontractor used to perform backbone or horizontal cabling Work shall be fully certified by the Specified manufacturers. Subcontractor shall also meet all other qualifications as required of the Contractor listed elsewhere in these Specifications.

D. Contractor shall have sole responsibility for managing, coordinating, quality control and evaluating the efforts of the Contractor's subcontracted labor, including pre-installation walk-through, supervision, project communications, project meetings, material storage, security, phone service, and change order notification and preparation.

END OF SECTION 2.0


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3.0 OUTSIDE PLANT & ENTRANCE FACILITIES 3.1 MAINTENANCE HOLES

A. General

1. Maintenance holes shall be constructed of pre-cast concrete materials with a minimum wall thickness of 6-inches and a strength factor of 3500psi.

2. All materials used in a maintenance hole shall be resistant to corrosion. All steel shall be galvanized or zinc coated.

3. Maintenance holes shall not to be used to house splice cases. All splicing and terminating of cables shall be within designated equipment rooms within a building.

B. Exterior

1. Telecommunications maintenance holes shall not be adjacent to or share any walls with electrical maintenance holes. In addition, electrical power cables are not to be placed within telecommunications maintenance holes.

2. A conduit exiting a maintenance hole shall be aligned opposite the wall and at the same elevation where it entered the maintenance hole.

3. All conduits entering a maintenance hole will be sealed from the outside of the maintenance hole prior to backfilling.

4. Any joints in maintenance holes are required to be watertight.

5. The cover shall be a minimum of 30-inches in diameter and shall be cast with the word "COMMUNICATIONS". The cover shall have recessed handles that pull out when needed for removal, or indented pick points.

6. A lockable, weatherproof, inner seal, as manufactured by LockDown-LockDry, shall be provided under the maintenance hole cover. Owner to provide locks (keys shall be same as ITD Technology Room lockset).

7. Double sealed manhole covers with handles shall be used in areas with the potential of vandalism and/or flooding.

8. Maintenance holes should not be used as a means for making or accommodating 90-degree turns in the underground pathway.

C. Interior

1. Minimum interior dimensions shall be 6'W x 6’L x 7’H. The maximum depth of all manholes shall be ten (10) feet from the bottom.

2. Racking equipment and cable supports are mandatory for all maintenance holes. A minimum of two cable racks, per side, shall be provided.

3. All racking within maintenance holes shall be nonmetallic. Stanchions shall be a minimum of 36”, and capable of supporting up to four (4) levels of cabling using support arms. The length of each support arm shall be based on the number cables at initial installation plus 50% growth. Minimum length of each support arm shall be 8”. Nonmetallic racking system shall be manufactured by Underground Devices Incorporated.

4. Maintenance holes shall have pulling rings cast into the wall opposite to each conduit entrance.


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5. All maintenance holes shall have a grounded, galvanized ladder for climbing in and out.

6. Maintenance holes shall be equipped with an approved ground and bonding ribbon.

7. All maintenance holes shall have a minimum 8” sump for drainage.

8. All maintenance holes shall be placed on a minimum of 12” of compacted rock or sand.

MAINTENANCE HOLE COVER

WATERPROOF INNER SEAL

FINAL GRADE

PVC END BELLS (TYPICAL)

DUCT ENTRANCE (TYPICAL)

DUCT WINDOW WITH WATERTIGHT DUCT TERMINATORS (TYPICAL SUITABLE LOCATION AS DETERMINED BY CONTRACTOR

PROVIDE 3" PVC SLEEVE FOR GROUND ROD. SEAL SLEEVE WITH SEALANT TO MAKE WATERTIGHT AFTER INSTALLATION OF GROUND ROD.

PULLING IRONS: 7/8" GALVANIZED STEEL WITH TRIANGULAR SHAPED OPENING. PROVIDE OPPOSITE EACH DUCT ENTRANCE.

CORROSION RESISTANT GALVANIZED LADDER.

8" MINIMUM SUMP WITH CAST IRON GRATE, SUMP SHALL BE OPEN TO CRUSH STONE BASE

GROUND ROD

REINFORCEMENT BARS (TYPICAL).

GROUT MAINTENANCE HOLE CHIMNEY TO FRAME AS REQUIRED.

RISER CONCRETE SHALL BE INSTALLED SO THAT TOP OF MAINTENANCE HOLE COVER IS FLUSH AND LEVEL WITH FUTURE GRADE WHEN GRADING IS COMPLETE.

NONMETALLIC CABLE RACKS (36"L MINIMUM)

3'-0

" M

IN.

4"

NOTES:1. MAINTENANCE HOLES SHALL BE NORWALK INDUSTRIES OR CLEVELAND CLINIC APPROVED EQUAL.2. TECHNOLOGY MAINTENANCE HOLE SHALL BE TYPE “A” WITH 12-SPLAYED CONDUIT WINDOWS AT EACH END AND 12 CONDUIT WINDOWS IN THE SIDE. PLACE MAINTENANCE HOLE SO AS 12-CONDUIT WINDOWS WILL LOGICALLY ACCOMMODATE FUTURE DUCT BANKS. MAINTENANCE HOLE SHALL BE EQUIPPED WITH MINIMUM OF 2 NONMETALLIC CABLE RACKS PER SIDE.3. ALL MAINTENANCE HOLE COVERS SHALL BE LEBARON FOUNDRY, INC. OR CLEVELAND CLINIC APPROVED EQUAL. COVER SHALL BE LABELED COMMUNICATIONS. MAINTENANCE HOLES SHALL BE WATER TIGHT WITH ADDITIONAL INNER SEALED COVER INSTALLED BELOW MAIN COVER. MAINTENANCE HOLE COVER SHALL BE TYPE “BW” FOR MAINTENANCE HOLES LOCATED IN EARTH OR TYPE “SW” FOR MAINTENANCE HOLES LOCATED IN DRIVES OR ROADS. 4. WARNING LABEL SHALL READ “WARNING – PROPERTY OF CC ITD – NO UNAUTHORIZED ENTRY. TO OBTAIN ACCESS TO THIS MAINTENANCE HOLE, PLEASE CONTACT CC ITD.”5. FOUR (4) KEY WRENCHES SHALL BE PROVIDED TO CLEVELAND CLINIC ITD FOR EACH MAINTENANCE HOLE INSTALLED.6. MAINTENANCE HOLE SIZES ARE BASED ON CONDUCTOR BENDING RADIUS. SIZES MAY BE ADJUSTED FOR FIELD CONDITIONS IF ALL CODE REQUIREMENTS ARE MET, AND WRITTEN APPROVAL GRANTED BY CLEVELAND CLINIC ITD.7. MAINTENANCE HOLES SHALL BE PRE-CAST CONCRETE MEETING AMERICAN ASSOCIATION OF STATE HIGHWAY AND TRANSPORTATION OFFICIALS (AASHTO) H20 LOADING REQUIREMENTS. EACH MAINTENANCE HOLE SHALL CONTAIN: MAINTENANCE HOLE COVER AND FRAME (MINIMUM SIZE 30" DIAMETER), GALVANIZED FORGED STEEL PULLING IRONS LOCATED OPPOSITE EACH CABLE ENTRY POINT, NONMETALLIC CABLE RACKS AND CROSS ARMS, SUMP PIT, SOLID BOTTOM, GROUNDING BUS BAR, LADDER (GROUNDED) A ¾” DIAMETER BY 10' DRIVEN COPPER CLAD STEEL GROUND ROD BONDED TO THE BUS BAR WITH EXOTHERMIC WELD, (ALL HARDWARE SHALL BE GALVANIZED OR NONMETALLIC).8. MAINTENANCE HOLES SHALL BE INSTALLED ON A MINIMUM OF 12" CRUSHED STONE (ODOT #57) ON COMPACTED SUBGRADE.

Figure 1: Typical Maintenance Hole Diagram (Not to Scale)


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3.2 HAND HOLES

A. General

1. Hand holes shall only be used in pathways where duct-banks do not exceed three conduits (not more than a total of six conduits, three in and three out).

2. Hand holes shall not be used as an intersection of two independent pathways, but can be used to form a radial branch of a single pathway (e.g. three in one side, one out of three sides, etc.). Cleveland Clinic may waive the conduit count specifications in special circumstances where a maintenance hole cannot be installed.

3. Pathways shall be designed to ensure that the hand-hole is not exposed to vehicular traffic. Hand holes shall be placed in the tree lawn whenever possible and may be placed within sidewalks and other walkways or areas otherwise restricted to occasional traffic by light vehicles.

4. Hand holes shall not to be used to house splice cases. All splicing and terminating of cables shall be within designated equipment rooms within a building.

5. The maximum hand hole size shall be 1.2 m (4.0 ft.) in length by 1.2 m (4.0 ft.) in width by 1.2 m (4.0 ft.) height.

6. Horizontal penetrations of the box shall be made using designated knockout locations, when available. Sidewalls of the hand hole shall not be penetrated in other locations without pre-approval from Cleveland Clinic. Conduits may “stub-up” into the hand hole. Conduits that stub-up shall be within 2” of the hand hole sidewall.

7. Conduits entering a hand hole shall be aligned on opposite walls at the same elevation.

8. Hand holes without bottoms shall be installed with at least a 4” layer of small rock in the bottom to prevent mud from intruding into the hand hole.

B. Materials

1. Hand hole enclosures shall be designed and installed to withstand all loads likely to be imposed, and shall meet the requirements in ANSI/SCTE 77-2002.

2. All hand holes shall be UL-listed, and shall meet or exceed Tier 15 loading requirements.

3. Hand hole covers shall be rated for heavy duty applications and rated for extra heavy duty applications where vehicular traffic is anticipated.

4. Hand hole covers shall be lockable and labeled “Communications”.

5. Hand holes shall be available in various size configurations, and be equipped with pulling eyes, cable racks and hooks and knockouts for conduit.

6. Hand hole boxes and covers shall be standard gray. In flowerbeds or grassy areas, the covers shall be green. Confirm color with Cleveland Clinic prior to installation.

7. Approved manufacturer shall be Strongwell Quazite.

C. Installation

1. Hand holes shall be installed in accordance with the manufacturer’s specifications and the local codes and ordinances.

2. Hand holes with a depth > 24” shall be equipped with pulling eyes installed on the shorter sides of the box (or opposite sides of a square box), and galvanized steel cable racking.


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3. Compacted aggregate shall be used to form a bed under the hand hole. Aggregate shall be composed of crushed stone or gravel fill. The use of sand or gravel dust as compacted aggregate shall not be permitted.

4. Hand holes shall rest on a bed of gravel or crushed rock measuring six or more inches deep and extending six or more inches beyond the sides of the box.

5. Specify 4”-6” of gravel or crushed rock outside the box prior to backfilling to grade. Hand holes shall be installed so that covers are flush with the final grade, and shall match any slope in the final grade.

3.3 UNDERGROUND CONDUITS / DUCT-BANKS

A. Clearances

1. The underground conduit/duct-bank shall be designed so that telecommunications cables do not share conduits, maintenance holes, hand holes vaults, pull boxes or tunnels with any part of the electrical power distribution system.

2. The OSP pathways shall maintain the minimum separation distance from the electrical power distribution system as required by the National Electrical Code. The following table summarizes the typical underground clearances.

ADJACENT STRUCTURE MINIMUM SEPARATION

Power or Other Foreign Conduit: 3-inches of concrete, or 4-inches of masonry, or 12-inches of well tamped earth

Pipes (Gas, Oil, Water, etc.) 6-inches when crossing 12-inches when parallel

Railroad Tracks 50-inches below top of the rail

Street Railways 3-feet below the top of the rail

Table 3-A: Underground Clearances

B. Conduits

1. The maximum distance between pulling points in a duct bank shall be < 600-feet.

2. A minimum of four (4), trade size 5-inch conduit are required for telecommunications utility entry in a building. A minimum of six (6), trade size 5-inch conduits are required between buildings.

3. Either Schedule 40 and/or Schedule 80 are required for all OSP pathways depending on the route.

4. All conduits shall have a factory formed bell on one end for interconnecting segments.

5. All conduits and ducts shall be terminated with bell ends at the maintenance hole, building or other termination point.

6. A nylon pull cord shall be installed and tied off in each conduit. The nylon pull cord shall have a minimum tensile strength of 200 pounds.

7. OSP conduits designated for fiber optic cables shall be fully loaded with MaxCell® cell packs, and sized as specified on the Drawings.


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C. Concrete Encasement

1. All duct banks shall be encased in concrete along the entire pathway. The duct encasement shall have a rectangular cross section and provide a minimum concrete thickness of 3-inches on all sides of all conduits.

2. The minimum Depth for the top of the duct bank shall be 36-inches below ground surface. Where local conditions require a lower depth, the local conditions shall apply.

3. High impact spacers shall be used along the entire pathway in all multi-duct systems. They shall conform to NEMA TC-2, TC-6, TC-8, and ASTM F 512 dimensions. Duct spacers shall be installed at or near joints, and no more than 5-feet apart to provide adequate support and keep ducts uniformly separated.

4. Where the conduit is placed beneath vehicular traffic (i.e., drives, roadways, etc.) the concrete encasement shall be rebar reinforced with #6, ¾ ” rebar, and possess a minimum load strength of 3500psi. A minimum of four (4) steel reinforcing rods shall be installed parallel to the conduit. In addition, these rods shall be reinforced every 6’ with perpendicular rods centered in between the spacers. Where conduits enter a building or a manhole the rebar must be doweled into the structure to prevent shearing of the conduits in case of settlement.

5. Where trench walls are unstable or the trench width is wider than the designed encasement, the encasement shall be formed as required.

6. Each duct-bank run shall be installed with a continuous concrete pour. Broken pours are not allowed without written exception from Cleveland Clinic. In the event of an approved broken pour, the rebar will extend twenty-four-inches (24”) beyond the end of the encasement and at all stub-outs at the end of each day's pour.

7. Concrete shall be tinted orange for all telecommunications duct banks.

D. Bends

1. Long radius bends (over 30 feet) shall be used whenever possible to make changes in direction. When necessary to place a 90-degree bend in the conduit run, a factory-made sweep with a minimum 42-inch radius shall be used.

2. Cold-formed trench bends shall have a minimum radius of 40-inches, and shall pass mandrel integrity.

3. The bend radius criteria for conduits 2-inch or less shall be 6-times the inside diameter of the conduit and, for any conduit larger than 2-inches, 10-times the inside diameter of the conduit.

4. The maximum equivalent of two 90-degree bends is allowed between pulling points, including offsets.

5. Any single bend shall not exceed 90-degrees.

E. Drainage of Duct-banks

1. Duct banks shall be pitched to drain toward manholes. All conduit, tubing, raceways, ducts and duct banks shall be installed in such manner to insure against collection of trapped condensation. Raceway runs shall be arranged to be void of traps.

2. When conduits pass through exterior concrete walls of any facility, the entrance shall be watertight.


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3. Wall sleeves at entrance points must be sized to provide a minimum of ½-inch clearance around the conduit to allow for proper sealing of the penetration.

4. All conduits shall have watertight connections and be sloped so they drain away from the building entrance. All empty conduits are to be plugged and sealed with the proper materials to prevent water drainage into the building.

F. Tracer Wire

1. All new non-metallic duct banks shall be installed with tracer wire. Duct banks constructed of metallic conduits do not require a tracer wire unless the metallic conduit is not continuous along the entire route of the duct bank. Tracer wire shall be installed to enable the detection of plastic pipes and fiber optic cables.

2. The tracer wire shall be designed specifically for the purpose of detecting buried utilities. Tracer wire shall 12AWG copper wire coated with a 30-mil polyethylene jacket designed specifically for buried use.

3. The tracer wire shall be installed continuously along the entire pathway. Splices in the Tracer Wire shall only be permitted in maintenance holes, hand holes or vaults.

4. Splices in the tracer wire shall be connected by means of a split bolt or compression type connector to ensure continuity. Wire nuts shall not be used. Splices shall be sealed/waterproofed in shrink tubing rated for underground applications.

G. Warning Tape

1. Place warning tape a minimum of 18-inches above the duct-bank.

2. Warning tape shall contain metallic tracings to make it detectable.

3. Warning tape shall be a minimum of 3-inches wide, orange in color, and possess a non-degradable imprint that reads, “CAUTION FIBER OPTIC CABLE BURIED BELOW”.

H. Photographic Records

1. Contractor shall photograph each segment of the conduit duct bank prior to concrete encasement, and after concrete encasement.

2. All photographs shall be provided in digital JPEG format and labeled by segment in sequential order, and submitted with the Contractor’s as-built documentation.

3.4 DIGGING AND TRENCHING

A. All digging and trenching shall be in accordance with codes and regulations established by all applicable local, state, and federal agencies and departments.

B. There may be congestion and convolution of underground utilities. Contractor shall be responsible to locate utilities within the work area. Information from Cleveland Clinic on underground utility placement does not waive Contractor’s responsibility from confirming the presence and location of all underground utilities in the work area.

C. All digging and trenching shall be done in a neat and skillful manner. All methods of construction and details of workmanship shall be subject to the control and approval of Cleveland Clinic.


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NOTES:1. CONTRACTOR SHALL LOCATE UNDERGROUND CONDUIT AT A MINIMUM OF 10'-0" FROM NEAREST TREE, OR IF NOT PRACTICAL, AS DIRECTED IN FIELD BY THE LANDSCAPE

ARCHITECT.2. ALL DUCT BANKS SHALL BE ENCASED IN CONCRETE ALONG THE ENTIRE PATHWAY. THE DUCT ENCASEMENT SHALL HAVE A RECTANGULAR CROSS SECTION AND PROVIDE A

MINIMUM CONCRETE THICKNESS OF 3 INCHES ON ALL SIDES OF ALL CONDUITS.3. THE MINIMUM DEPTH FOR THE TOP OF THE DUCT BANK SHALL BE 36 INCHES BELOW GROUND SURFACE. WHERE LOCAL CONDITIONS REQUIRE A LOWER DEPTH, THE LOCAL

CONDITIONS SHALL APPLY. 4. HIGH IMPACT SPACERS SHALL BE USED ALONG THE ENTIRE PATHWAY IN ALL MULTI-DUCT SYSTEMS. THEY SHALL CONFORM TO NEMA TC-2, TC-6, TC-8, AND ASTM F 512

DIMENSIONS. DUCT SPACERS SHALL BE INSTALLED AT OR NEAR JOINTS, AND NO MORE THAN 5 FEET APART TO PROVIDE ADEQUATE SUPPORT AND KEEP DUCTS UNIFORMLY SEPARATED.

5. WHERE THE CONDUIT IS PLACED BENEATH VEHICULAR TRAFFIC (I.E., DRIVES, ROADWAYS, ETC.) THE CONCRETE ENCASEMENT SHALL BE REBAR REINFORCED WITH #6, 3/4" REBAR, AND POSSESS A MINIMUM LOAD STRENGTH OF 3500 PSI. A MINIMUM OF FOUR (4) STEEL REINFORCING RODS SHALL BE INSTALLED PARALLEL TO THE CONDUIT. IN ADDITION, THESE RODS SHALL BE REINFORCED EVERY 6' WITH PERPENDICULAR RODS CENTERED IN BETWEEN THE SPACERS. WHERE CONDUITS ENTER A BUILDING OR A MANHOLE THE REBAR MUST BE DOWELED INTO THE STRUCTURE TO PREVENT SHEARING OF THE CONDUITS IN THE CASE OF SETTLEMENT.

6. WHERE TRENCH WALLS ARE UNSTABLE OR THE TRENCH WIDTH IS WIDER THAN THE DESIGNED ENCASEMENT, THE ENCASEMENT SHALL BE FORMED AS REQUIRED.7. EACH DUCT BANK RUN SHALL BE INSTALLED WITH A CONTINUOUS CONCRETE POUR. BROKEN POURS ARE NOT ALLOWED WITHOUT WRITTEN EXCEPTION FROM CLEVELAND

CLINIC. INTHE EVENT OF AN APPROVED BROKEN POUR, THE REBAR WILL EXTEND TWENTY-FOUR-INCHES (24") BEYOND THE END OF THE ENCASEMENT AND AT ALL STUB OUTS AT THE END OF EACH DAY'S POUR.

8. CONCRETE SHALL BE TINTED ORANGE FOR ALL TELECOMMUNICATIONS DUCT BANKS.9. ALL UNDERGROUND CONDUIT SHALL HAVE (3) DETECTABLE WARNING TAPES INSTALLED 12" BELOW GRADE - DIRECTLY ABOVE THE CONDUIT CENTER AND EACH EDGE.

WARNING TAPE SHALL BE "TERRA TAPE", 3" WIDE, LABELED WITH "CAUTION "FIBER OPTIC CABLE", BURIED BELOW". CONTACT: REEF INDUSTRIES, INC. 1-800-231-6074.10. MINIMUM SEPARATION BETWEEN CONDUITS SHALL BE 3". MINIMUM SPACING BETWEEN POWER AND COMMUNICATION CONDUITS SHALL BE 12". REFER TO DRAWINGS FOR

EXACT CONDUIT REQUIREMENTS. EXACT CONFIGURATION AND DEPTH SHALL BE ADJUSTED AFTER COORDINATION WITH OTHER TRADES ON SITE. REFER TO COORDINATION NOTES ON THE DRAWINGS.

11. CONTRACTOR SHALL PROVIDE A SLOPE OF NO LESS THAN 1 PERCENT TOWARDS MAINTENANCE HOLE. CONDUITS PASSING THROUGH EXTERIOR CONCRETE WALLS MUST BEWATERTIGHT.

12. LONG RADIUS BENDS (OVER 30 FEET) SHALL BE USED WHENEVER POSSIBLE TO MAKE CHANGES IN DIRECTION. WHEN NECESSARY TO PLACE A 90 DEGREE BEND IN THE CONDUIT RUN, A FACTORY MADE SWEEP WITH A MINIMUM 42 INCH RADIUS SHALL BE USED. COLD-FORMED TRENCH BENDS SHALL HAVE A MINIMUM RADIUS OF 40-INCHES, AND SHALL PASS MANDREL INTEGRITY. THE BEND RADIUS CRITERIA FOR CONDUITS 2-INCH OR LESS SHALL BE 6 TIMES THE INSIDE DIAMETER OF THE CONDUIT AND, FOR ANY CONDUIT LARGER THAN 2 INCHES, 10 TIMES THE INSIDE DIAMETER OF THE CONDUIT. THE MAXIMUM EQUIVALENT OF TWO 90 DEGREE BENDS IS ALLOWED BETWEEN PULLING POINTS, INCLUDING OFFSETS. ANY SINGLE BEND SHALL NOT EXCEED 90 DEGREES.

13. ALL NEW NON-METALLIC DUCT BANKS SHALL BE INSTALLED WITH TRACER WIRE. DUCT BANKS CONSTRUCTED OF METALLIC CONDUITS DO NOT REQUIRE A TRACER WIRE UNLESS THE METALLIC CONDUIT IS NOT CONTINUOUS ALONG THE ENTIRE ROUTE OF THE DUCT BANK. TRACER WIRE SHALL BE INSTALLED TO ENABLE THE DETECTION OF PLASTIC PIPES AND FIBER OPTIC CABLES. THE TRACER WIRE SHALL BE DESIGNED SPECIFICALLY FOR THE PURPOSE OF DETECTING BURIED UTILITIES. TRACER WIRE SHALL BE 12AWG COPPER WIRE COATED WITH A 30-MIL POLYETHYLENE JACKET DESIGNED SPECIFICALLY FOR BURIED USE. THE TRACER WIRE SHALL BE INSTALLED CONTINUOUSLY ALONG THE ENTIRE PATHWAY. SPLICES IN THE TRACER WIRE SHALL ONLY BE PERMITTED IN MAINTENANCE HOLES, HAND HOLES, OR VAULTS. SPLICES IN THE TRACER WIRE SHALL BE CONNECTED BY MEANS OF A SPLIT BOLT OR COMPRESSION TYPE CONNECTOR TO ENSURE CONTINUITY. WIRE NUTS SHALL NOT BE USED. SPLICES SHALL BE SEALED/WATERPROOFED IN SHRINK TUBING RATED FOR UNDERGROUND APPLICATIONS.

TRENCH WIDTH AS REQUIRED

1'-0"

3'-0" MIN

(3) DETECTABLE UNDERGROUND WARNING TAPES

SELECTED BACKFILL

REBAR

MS GRADE CONCRETE

INTERMEDIATE SPACER ON MAX. 5'-0" CENTERS

5" PVC CONDUITS TYPICAL

BASE SPACER ON 5'-0" MAX. CENTERS

CRUSHED STONE

COMPACTED SUBGRADE

3" MIN.

3" MIN.

12" MIN.

3" MIN.(TYPICAL)

Figure 2: Typical Conduit Duct Bank Diagram (Not to Scale)


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D. Protect from direct damage during construction and damage resulting from construction all surrounding environments, including, but not limited to, existing roadways, sidewalks, curbing, trees and shrubs, open grass areas, and flowerbeds. Contractors shall use planks and ramps as needed to protect these areas.

E. Provide and install all necessary barriers to prevent unauthorized entry into the construction area.

F. Provide temporary walkways to divert pedestrian traffic safely around the construction area.

G. Contractor shall identify and submit for approval all temporary walkway locations.

H. Contractor shall provide traffic control, signage, plating, etc. as necessary to maintain the safe flow of vehicular traffic as deemed necessary by Cleveland Clinic and/or the local authority having jurisdiction.

I. Contractor shall arrange with Cleveland Clinic and/or the local authority having jurisdiction as required to arrange street closures and detours.

J. Contractor shall restore, repair, rebuild, or replace any items including, but not limited to, adjacent property, existing fences, trees and shrubs, roadways and curbs, sidewalks, and surface utilities and parts damaged during construction. Damaged items shall be restored, repaired, rebuilt, or replaced to their original condition, and to the satisfaction of Cleveland Clinic and/or the local authority having jurisdiction.

K. Contractor shall provide a detailed photographic survey of all pathways and areas to be disturbed prior to construction. Contractor shall deliver a set of these photographs to Cleveland Clinic prior to construction.

L. Contractor shall locate and stake all pathways and spaces to be installed. Contractor shall confirm all staked pathways and spaces with Cleveland Clinic. Contractor shall notify Cleveland Clinic of any discrepancies in the site plan and the existing conditions.

M. Contractor shall protect, support, and maintain all existing utilities in the work area as they are encountered during excavation. Shallow utilities to light posts or other devices may be temporarily re-routed or disconnected if pre-approved by Cleveland Clinic and/or the local authority having jurisdiction.

N. Install erosion control measures as needed to minimize erosion and to prevent soil run-off from the construction area.

O. Provide and install bracing, shoring, and sheathing as necessary to protect personnel and surrounding conditions. Contractors shall adhere to all local, state, and federal requirements for safe excavations.

P. Contractor shall hand remove and stack all paving bricks and marble pavers in the construction pathway for re-installation later. Contractors shall remove granite or other stone or brick curbing pavers in the construction pathway for re-installation later.

Q. Contractor shall remove as necessary all material excavated including soil, rubble, debris, or other materials encountered during excavation. Excavated material from duct bank trenches may be left near the trench to be used as backfill, if adhering to later backfilling specifications. Contractor shall properly dispose of any material taken from the construction area per local disposal requirements.


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R. Contractor shall provide pumps as necessary to keep water out of the excavation. Contractor shall direct effluent towards the nearest storm drain only if the effluent is free from dirt and debris. Otherwise, the effluent shall be diverted to an area free from vehicular and pedestrian traffic and other construction areas.

3.5 AERIAL CABLE PLANT

A. General

1. Utility poles shall have very limited use on Cleveland Clinic campuses. New utility poles shall not be installed. Utility poles shall not be used as a pathway without Cleveland Clinic approval.

2. Aerial pathways shall only be used when existing poles are in place and available. Poles may be Cleveland Clinic owned or available for lease from local utilities.

3. Contractor shall obtain permits, lease agreements, and any other required documentation for Cleveland Clinic use of non-owned poles. All documentation shall be in the name of Cleveland Clinic and shall be submitted to Cleveland Clinic prior to installation.

4. Contractor shall adhere to requirements of the utility pole owner when using non-owned poles.

5. Contractor shall be responsible to survey the proposed pole line route and provide a detailed summary of all make ready requirements. Contractor shall perform all make ready work on Cleveland Clinic owned poles. For non-owned poles, Contractor shall coordinate make ready requirements with the pole owner.

6. Contractor shall provide all necessary tools and equipment for safely working on utility poles. Contractor shall comply with all local, state and federal codes and regulations regarding pole line work. Personal protective equipment is required and shall be the responsibility of the Contractor.

B. Clearances

1. Clearances above streets, sidewalks, railroad and trolley tracks, alleys, etc. shall conform to the latest version of the National Electrical Safety Code (IEEE C2) and local codes and ordinances.

2. Clearances between cables, conductors and/or electrical devices at each pole and the mid-spans shall conform to the latest version National Electrical Safety Code (IEEE C2) and local codes and ordinances.


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Required Separation From… Is…

Power at pole: 40-inches below power supply services 0 to 8.7kV plus 0.4-inches per kV over 8.7kV

Power at mid-span (max sag of power): 12-inches below power supply services

Power at building attachments: 4-inches (horizontally) 12-inches (vertically)

Telephone twisted pair cabling at pole: 12-inches above telephone cable (coax)

Grounded supply equipment (transformers, etc.): 30-inches below

Drip loops for street lights or traffic signals: 12-inches below

Mid-span (between two poles) clearances: 75% of the clearance required at the pole (minimum)

Required Clearance From… Is…

Streets, alleys & driveway surfaces 18.0-feet vertically

Pedestrian traffic 10.0-feet vertically

Rooftops 8.0-feet vertically

Railroad tracks 27.0-feet vertically from top of tracks

Vertical roof conductors (e.g. antennas) 6.0-feet horizontally

Table 3B: Aerial Clearances C. Installation

1. Cables shall be handled carefully to reduce unwanted bending.

2. The strand used to support aluminum-sheathed cables must be galvanized or aluminum-coated 0.25-inch EHS (extra heavy steel). The lashing wire will be stainless steel to prevent galvanic action from damaging the aluminum sheath. Cable support straps will be either stainless steel or UV rated PVC.

3. Cable reel flanges shall be carefully inspected to insure that the surface is smooth and free from nails or other imperfections that will damage the cable while unreeling.

4. Prior to pulling the cable, ensure that all safety equipment and barricades are in place along the route to be pulled.

5. Cable blocks (rollers) will be placed on the strand along the entire length of the cable run at a maximum of 25-foot intervals. (Use of cable blocks will reduce pullout pressure, keep the cables straight and reduce the possibility of cable damage.) A guide chute will be used at the first pole location for safe cable reel payout.

6. As the cable is pulled along the strand, 45 and 90 (degree) turns may be required. Bends of 45 and 90 (degrees) should be carefully pulled. The Contractor will use corner blocks for successfully pulling 45 and 90 (degree) bends in the cable runs.

7. Contractor shall use a pulling eye and break away swivel when installing aerial cable. The pulling eye and break away should have pull tensions that are rated less than that of the cable.

8. When using a winch or other mechanical pulling device, a dynamometer must be utilized when installing all cable along the strand to ensure the pulling tension of the cable is not exceeded.


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9. All aerial cable(s) will be double lashed using .038" stainless steel lashing wire. When lashing the cable, the lasher should always be pulled in the same direction as the messenger strand was installed.

10. Cable/reel trailers must have tension brakes to ensure a steady pull and proper placement of the cable. Before pulling the cable onto the strand, the reel brakes should be applied. The amount of tension needed on the brake should be enough to turn the reel by using the strength of one hand. When the hand method of turning the reel is stopped, the reel should stop immediately.

11. There should be a person stationed at the cable reel at all times during cable pulling to ensure the cable pays-off the reel correctly.

12. All cable to component connections will be weather sealed with a heat-shrink tube type sealant properly sized for the respective connector (DSG-Canusa – Model CFTV-Series or approved equivalent).

D. Expansion Loops

1. All expansion loops shall be formed using a loop-forming tool. Under no circumstances shall expansion loops be hand formed.

2. Expansion loops shall be formed at every pole and on both sides of all active and passive devices. When a device is located at a pole, the loops at the device are the only ones necessary. In order to handle the increased expansion of long spans, an additional loop is recommended for spans over 200-feet.

3. Expansion loops should cover a minimum span of 36-inches with swag of not less than 6-inches from the cable line.

4. Where multiple cables are included in the same run, all the cables shall have a primary expansion loop at each pole location. Where devices are installed, only cables actually interfaced to the device shall require additional expansion loops.

E. Pole Guys

1. Contractor shall be responsible to install any additional pole back-guys in all locations where new pole mounting hardware is installed and the cable does not run through the pole at 180- degrees. All pole guy wires shall be installed in accordance with the latest release of the National Electrical Safety Code (IEEE C2) and/or local state and federal codes and regulations.

2. All appreciable horizontal loads imposed by the new aerial cabling on non-self-supporting structures (e.g., poles) should be guyed.

3. Whenever possible, guys shall be attached at the same elevation as the messenger, preferably to the same bolt or attachment band.

4. Guy leads should be of a length to create an angle of 35° - 40° (degree) between the guy and the pole.

5. Whenever a short guy lead is unavoidable, especially on a substantial load, Contractor shall perform all calculations necessary to determine adequate guy strand and anchor size requirements.

6. Guy strand shall not be subjected to tensions above 60% of its ultimate rating during maximum loading conditions. (Refer to the National Electrical Safety Code for overload factors for specific situations).


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7. All anchors shall be properly sized and installed for the maximum expected messenger tension to ensure minimum “creepage”.

3.6 BUILDING ENTRY POINTS

A. Underground

1. The duct systems shall be sloped to permit penetrating water to drain towards the manhole(s). The highest point of the duct array will be at the center of each run, or the building entry point.

2. Conduits shall be plugged with inserts to ensure that foreign matter does not enter the building.

3. Routing of conduits under the building foundation should be minimized.

B. Above Ground

1. Rigid hot-dipped galvanized steel, 4-inch conduits shall be used as part of the duct system where conduits are exposed, cross open ditches, are attached to bridges or similar structure, etc.

2. All exposed pull boxes, junction boxes, etc., shall be NEMA-4 enclosures constructed of rigid hot dipped galvanized steel or approved equal.

C. Building Entry

1. OSP cables shall be enclosed in metal conduit from the point of entry to the Equipment Room.

2. EMT or rigid metal conduit shall be extended from the building entry point into the equipment room. Appropriate sized pull boxes shall be designed into the pathway for all conduit runs that exceed 100-feet and/or have more than the equivalent of two 90°bends.

3. All conduits must be grounded at both the building entry and Equipment Room to an approved ground with a minimum #6 conductor, not to exceed 13-feet in length.

3.7 DUAL ENTRANCE PATHWAYS

A. All new buildings should be equipped with dual entrance facilities, originating from separate and diverse pathways.

B. All standards that apply to the primary pathway and entrance facility shall apply to the redundant facilities.

C. Redundant OSP pathways must maintain a minimum 25-foot separation up to the building entry. Once inside the building, diverse pathways shall be maintained until entering the Equipment Room.

END OF SECTION 3.0


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4.0 TECHNOLOGY ROOMS 4.1 GENERAL

A. Technology Rooms are special-purpose rooms that house data, voice, video, nurse call, patient monitoring, security and/or other low voltage equipment, and associated interconnecting hardware and cabling.

B. Technology Rooms have stringent requirements due to the nature, size, expense and complexity of the equipment housed in them.

C. Technology Rooms are specifically designated for low voltage voice, data and clinical systems, such as telemetry, nurse call, security, cable TV, distributed antenna systems, servers, etc.

D. The purpose of a Technology Room is to provide a secure, controlled environment to house low voltage equipment and cabling.

E. Technology Rooms (TR) are building and floor-serving rooms that provide a connection point between the backbone and horizontal cable systems. They are the location of the Main Cross Connect (MC), Intermediate Cross Connect (IC) and/or the Horizontal Cross Connect (HC).

F. Design and implementation shall always include a main Technology Room for a building. This room is called the Technology Equipment Center (TEC). Technology Rooms that serve individual floors or an area of a floor are now called Technology Distribution Rooms (TDR). (For reference purposes, the Technology Equipment Center was once referred to as the MDF, and the Technology Distribution Room was once referred to as the IDF.)

4.2 DESIGN

A. General

1. TRs shall be located above any threat of flooding, and shall avoid locations that are below or adjacent to areas of potential water and steam hazards (e.g., kitchens, restrooms, laboratories, water fountains, steam pipes, etc.).

2. The TEC shall be a dedicated room that shall serve as the MC or IC. Typically, this room should be located in the lowest level of the building. Alternate locations must be approved by Cleveland Clinic.

3. The quantity and placement of Technology Rooms is dependent on building size. A TDR is required for every 10,000 ft2 of work area space and/or 288 faceplates with a minimum of one TDR per floor.

4. Minimum room dimensions (dimensions shall be maintained):

a) TEC = 30’ x 30’ (9.2m x 9.2m) b) TDR = 15’ x 20’ (4.6m x 6m)

5. Each TR must be accessible from a main hallway or other common area.

6. The preferred location for the TDR is in the center of the floor or area it is serving to minimize horizontal cable lengths.

7. In buildings with multiple floors, TRs shall be vertically aligned (stacked).


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B. Floor

1. Minimum loading:

a) MC/IC - The floor shall be rated for a distributed load of 12Kpa (250 lbf/ft2) with a concentrated load of 8.8kN (2000 lbf).

b) HC - The floor shall be rated for a distributed load of > 4.8Kpa (100 lbf/ft2)

2. All Technology Distribution Rooms shall be tiled with a static dissipative vinyl tile. The tile shall be gray in color.

a) Static Dissipative Vinyl Tile shall be manufactured by Flexco Corporation or approved equal.

b) Cover base shall be Roppe 40CR3P159-010, 1/8” Light Gray. c) The static dissipative floor system shall be grounded to the local TGB. A copper strap

(minimum 1” x 18” x .004) thick shall be used to ground the floor to the TGB; minimum 9-inches of copper strap shall be imbedded under the floor.

d) The static dissipative tile must be installed using the manufacturer’s ESD epoxy adhesive in complete accordance with manufacturer’s installation instructions.

e) Concrete sub-floor shall cure for a minimum of 28 days prior to installation of flooring material. Moisture testing of concrete sub-floor per ASTM F 1869 and/or ASTM F 2170 is mandatory.

f) All preparation of the sub-floor shall be in accordance with the tile manufacturer’s requirements and recommendations.

C. Ceiling

1. Suspended or false ceilings are not required or desired.

2. The minimum deck height shall be 12’.

3. Structural decking shall be treated to minimize dust.

4. Ceiling/decking shall be painted to match walls. Provide paint that is compatible with fireproofing system.

D. Walls

1. Walls shall be finished with drywall (completely taped, sanded, and painted) prior to attaching plywood backboards.

2. All walls shall be painted white with two coats of paint to match plywood.

3. All walls within the Technology Room shall extend from the floor to the deck (structural ceiling).

4. Two finished walls shall be lined with CDX grade, fire rated plywood (4” x 8” x 3/4”). Plywood shall be installed so that the bottom edge is 6” AFF and the top edge is 8’-6” AFF.

5. Plywood shall be securely fastened to wall framing members using lag screws to ensure that it can support attached equipment.

6. Plywood shall be void free, and treated on all sides with at least two coats of paint.

7. When mounting plywood, the UL Fire-Retardant treated plywood stamp shall remain in full view (facing outward and not covered) after installation and painting is complete.

8. All equipment that is to be wall mounted must be mounted to the plywood backboard.


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9. Architect’s design team shall be responsible to determine fire rating of the wall based on the requirements of the Authority Having Jurisdiction (AHJ), and shall amend the Construction Documents accordingly.

10. Approved manufacturers: Benjamin Moore (Chantilly Lace OC-65), and Sherwin Williams (Snowbound SW7004)

E. Door

1. Size:

a) TEC = 48” W x 80” H (a double door configuration may be substituted) b) TDR = 36” W x 80” H

2. The door shall be of steel or solid wood construction to match facility, removable, fully opening (180-degrees), and open outward.

3. Doors must have a neoprene anodized aluminum automatic door bottom.

4. In corridor or adjacent space, provide 6’ of clearance in front of door.

5. Provide door sweep for the purposes of noise reduction and contamination control.

F. Security

1. Secure each door with electronic access control. Door hardware and electronic access control device(s) shall be consistent with current Cleveland Clinic Standards, and shall be coordinated with Cleveland Clinic Protective Services, the architect and door hardware provider.

G. Power

1. Multiple AC outlets shall be provided to power telecommunications equipment interfaces, servers and other telecommunications equipment. Coordinate exact power requirements with Cleveland Clinic.

2. Each outlet will be fed by a dedicated branch circuit from dedicated breaker panels located in each respective room unless otherwise noted.

3. Provide two sources of power to each Technology Room, normal utility power and UPS power. Both sources shall be backed up by emergency generator power when available. UPS power shall be from a dedicated centralized UPS.

4. Convenience outlets (double duplex) shall be installed on the rack, and each wall of the TR. Convenience outlets shall not be placed on emergency power.

5. Wall outlets shall be installed 18-inches on center AFF, and must be flush when cut through plywood.

6. All room circuits are to be labeled and identified at the breaker panel and on the faceplate of the outlet.

7. Conduits feeding rack-mounted power receptacles shall not route through the rungs of cable runway, slotted cable tray or basket cable tray. Conduits shall be installed and routed on the outside of the cable runway and/or cable tray.

8. Minimum Power Requirements (Minimum power requirements are provided for reference purposes only. Power requirements are subject to change based on building size and clinical or administrative utilization):


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a) TEC = 15 - 25kW b) TDR = 5 - 10 kW (each)

9. Coordinate exact placement and circuit type with Cleveland Clinic.

H. Uninterruptible Power Supply (UPS)

1. Provide centralized UPS system to supply all Technology Rooms. UPS shall comply to UL 1778 Class A specifications.

2. For detailed UPS system specifications, refer to Section 16.0 in this document.

I. Lighting

1. Provide minimum equivalent of 500 lux (50 foot-candles) as measured 3-feet above finished floor at each point of cable and equipment termination.

2. Provide standard 1’ x 4’, (2) lamp LED lighting fixtures.

3. Locate light fixtures a minimum of 8’ 6” above finished floor.

4. Light fixtures are to be positioned parallel to rack rows and wall fields, and located between rack rows.

5. Coordinate lighting layout with the equipment and cable tray layout to ensure light is not obstructed. Light fixtures shall be positioned to ensure 12” (minimum) separation from ballast and low voltage copper and 5” (minimum) from the light fixture.

6. Locate light switches at the entrance of each room.

7. Provide emergency lighting fixtures on emergency power as required by code.

J. Grounding and Bonding

1. All grounding shall be in compliance to the Specifications detailed under Section 6.0 Telecommunications Grounding System.

K. Cable Tray/Runway, Conduits, Floor Cores and Wall Sleeves

1. Wire mesh cable tray (minimum 12” x 4”) shall be installed on top of the equipment racks to support patch cables. Wire mesh tray shall be attached to the racks with unistrut as shown on the Drawings.

2. Cable runway and/or cable tray shall be installed to support cabling above the wall field and racks, and to support cabling as it enters the room.

3. Use the manufacturer specified connecting pieces (e.g., 45 and 90 horizontal, inside, and outside bends, tees, crosses, etc.) when designing and constructing the cable tray system.

4. The front edge of the cable runway shall line up with the divider of the vertical cable managers, and located 12” above the wire mesh tray.

5. Conduits for the electrical outlets and other electrical service must be contained within the wall structure. Electrical conduit should not be placed where it might be crossed by a communications cable or where it disrupts backboard utilization.

6. Cable tray shall not be continuous through partitions and shall be stopped 6”to 12” before the partition. Passage through the partition shall be of equal or greater area than that of the cable tray (e.g., for a 12”x4” cable tray (4) series 44 EZpaths shall be provided as pathway through a one-hour rated partition). Passage type shall be based upon the partition type (fire rated, smoke rated or acoustically sensitive).


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L. Environmental

1. Cooling strategy for each Technology Room shall be based on the following guidelines:

a. IT Load < 400W – Conduction method is sufficient for cooling and no other device or modification to the room is necessary.

b. IT Load > 400W but < 700W – A passive ventilation system shall be used as long as the room can be properly vented. Note that the fire rating of the walls may inhibit or negate this method.

c. IT Load > 400W but < 2000W – Fan assisted ventilation is required. Note that the fire rating of the walls may inhibit or negate this method.

d. IT Load > 2000W – Dedicated cooling system is required for the room.

2. TRs shall be environmentally controlled to maintain a room temperature of optimal 75F (18C to 24C) with a relative humidity level between 37% to 55% non-condensing. (The standard set points: temperature of 74F and humidity of 42%).

3. For the TEC only, the HVAC cooling system shall be configured to provide redundancy. Redundancy shall be accomplished by providing N+1 cooling capability. Each cooling unit shall be sized for approximately 75% of full capacity. Operation of the cooling units shall be coordinated by a central control unit (such as Liebert’s iCOM system) to establish an active/passive, lead/lag, or load sharing arrangement such that in the event of a single unit failure, the remaining unit(s) shall automatically come on-line or ramp-up to carry the entire heat load for the space.

4. Provide HVAC design to accommodate 24/7 positive pressure differential within the TR relative to areas outside the TR. Positive pressure within the TR shall prevent contaminant (dust and/or debris) buildup within the TR. The in-room CRAH/CRAC units only provide for room humidity and cooling through air circulation that does not address the internal TR requirements for positive air pressure. The typical method to create positive pressure within the room is to provide an HVAC air supply “house air” to the TR. Note that under this design, return air is not required. The CFM required will vary by room size. Review adjacent room/corridor air supply and well as TR room size to determine internal house supply “CFM” to maintain positive pressure.

5. Provide continuous and dedicated environmental control (24 hours per day, 365 days per year). Air handling equipment must dissipate heat generated by active devices, and satisfy building codes (refer to Section 15.0 below for more detail on the Critical Facilities Monitoring System).

6. Provide dedicated thermostat within each room. Thermostat is to be located on wall opposite of the door.

7. Provide emergency generator power where available to the A/C systems in each TR

8. To protect equipment from any leakage, drainage troughs and associated plumbing shall be installed underneath ceiling mounted units (specifically the condensate pump and supply and return piping). Drainage troughs shall be properly sloped and routed to the nearest drain outside the Technology Room. Do not design or install drains in Technology Rooms.

9. Provide gravity drain for condensate drainage. Condensate Pump shall only be used when approved by Owner.

10. Provide Electric Reheat for Dehumidification Control.


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11. Provide Electrical Disconnect Switch to Evaporator Unit.

12. Connect common alarm interface to Building Management System via centralized SiteLink-*E Module. Coordinate with Cleveland Clinic and manufacturer for additional configuration and system requirements.

13. Architect/MEP Engineer shall determine nominal tonnage, and system configuration (Air Cooled Split, Glycol Loop, or Chilled Water).

14. Coordinate all additional options and features with manufacturer.

15. Approved manufacturer: Liebert

TR COOLING APPLICATION NOTE Size Liebert Model Type Application

1-3 Ton (5-11 kW) DataMate Wall/Console Technology Distribution Room 1-8 Ton (5-29 kW) MiniMate2 Ceiling Technology Distribution Room when

wall space not available 5-8 Ton (17-29 kW) PDX (DX) PCW (CW) Floor mount

up or down flow Central UPS Room Technology Equipment Center (small)

6-10 Ton (20-40 kW) CRV In Row Technology Equipment Center (large) w/Cold Aisle Container configuration DX and CW versions

8-30 Ton (28-105 kW) DS Floor Mount up or down flow

Technology Equipment Center (large) DX Direct Expansion – Refrigerant

8-50 Ton (26-181 kW) CW Floor Mount up or down flow

Technology Equipment Center (large) CW Chilled Water

20-45 Ton (80-165 kW)

DSE Floor Mount down flow

Technology Equipment Center (large) DX w/Econophase

M. Fire Protection

1. Smoke detectors shall be provided. Provide fire protection for rooms as required by code. The Architect, Engineer, or Contractor when there is no Architect/Engineer, shall verify requirements with the Authority Having Jurisdiction.

2. When sprinkler systems are required, use a 2-stage, “dry sprinkler” system.

3. When sprinkler heads are used, provide high temperature and install wire cages over the heads to prevent damage.

4. Fire/smoke ratings of all architectural structures and assemblies, including but not limited to walls, plywood and paint, shall be verified and approved prior to construction with the Authority Having Jurisdiction.

5. Sprinkler mains shall not be installed or routed through Technology Rooms. Only piping specific to in-room sprinkler heads shall be permitted.

N. Vapor Barrier

1. A vapor barrier shall be installed for damp proofing on the wall, ceiling and floor assemblies for any Technology Room that is located on an exterior wall of the facility.

!


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2. Permeability is to be reported in perms with a rate of transfer of water vapor through a material of 1.0 US perm = 1.0 grain/square-foot·hour – inch mercury SI perm = 57 ng/s·m2·Pa and tested in accordance with the ASTM E96 desiccant, or dry cup method.[1] Vapor retarding materials are generally categorized as:

a) Impermeable (≤1 US perm, or ≤57 SI perm) (Materials such as asphalt-backed kraft paper, vapor-retarding paint, oil-based paints, vinyl wall coverings, extruded polystyrene, plywood, OSB),

b) Semi-permeable (1-10 US perm, or 57-570 SI perm) (Materials such as unfaced expanded polystyrene, fiberfaced isocyanurate, heavy asphalt-impregnated building papers, some latex-based paints),

c) Permeable (>10 US perm, or >570 SI perm) (Materials such as unpainted gypsum board and plaster, unfaced fiber glass insulation, cellulose insulation, unpainted stucco, cement sheathings, spunbonded polyolefin or some polymer-based exterior air barrier films).

4.3 IT WORKROOM

A. The purpose of the workroom is to provide a separate and secure area where spare parts, tools and test equipment can be stored, and provide technical workspace.

B. One workroom per building is required. When possible locate this room adjacent to the Technology Equipment Center Room.

C. Room Dimensions: The size of the room is dependent upon the size of the facility; minimum room dimensions shall be 12’ x 16’ (3.7m x 3.7m)

D. Floor: flooring shall be tiled with a durable vinyl composition tile (VCT).

E. Ceiling: suspended or false ceiling.

F. Walls: finish with drywall; completely taped, sanded, and painted. Architect’s design team shall be responsible to determine fire rating of the wall based on the requirements of the Authority Having Jurisdiction (AHJ), and shall amend the Construction Documents accordingly.

G. Door: 36” W x 80” H, and shall be of steel or solid wood construction to match facility.

H. Secure each door with electronic access control. Door hardware and electronic access control device(s) shall be consistent with current Cleveland Clinic Standards, and shall be coordinated with Cleveland Clinic Protective Services, the architect and door hardware provider.

I. Power: Coordinate with Cleveland Clinic and furniture layout. At a minimum, convenience outlets (double duplex) shall be flush mounted at standard height on each wall of the room. Convenience outlets shall not be placed on emergency power.

J. Lighting: Provide standard ceiling mount work area light fixtures.

K. HVAC: provide standard building heating and cooling

L. Fire Protection: Provide standard, work area, fire protection. END OF SECTION 4.0


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5.0 BUILDING PATHWAYS 5.1 GENERAL

A. Plan and construct all telecommunications building pathways in compliance with applicable local, state and federal codes and regulations.

B. Contractor shall verify the proper installation and sizing of the pathway system with the Electrical Contractor prior to installation of the cabling to ensure that all pathways meet Specifications.

C. Ensure the support system design can accommodate the number of cables, and makes optimum use of the ability of the horizontal cabling system to accommodate change.

D. Horizontal pathways and spaces consist of structures that support, protect and sometimes conceal horizontal cables between the Telecommunications Outlet and the Technology Room.

E. Grounding and bonding of pathways shall comply with applicable codes and regulations, in addition to any requirements indicated in these Specifications.

F. Pathways shall not have exposed sharp edges or other surfaces that could cause damage or otherwise cause substandard installation that may come into contact with the low voltage cabling system.

G. The number of cables placed in any type of pathway shall not exceed 40% fill after initial installation. The design of the pathway system shall allow for future growth up to 60% fill in accordance with the NEC.

H. Pathway loading shall not exceed manufacturer’s specifications.

I. Elevator shafts and stairwells shall not be used as pathways.

J. Bridle rings shall not be permitted.

K. All pathways shall have an appropriately sized pull string, rope or wire installed. Each end of the string, rope or wire shall be fastened in such a fashion to assure its availability in the future, and shall be tagged with the locations of the other end of the pull string.

L. Cable trays, cable runways and other communications pathways are for the exclusive use of the backbone and horizontal voice/data cabling. Other low voltage cabling systems such as broadband cable, audio/visual, security, etc. shall be installed in separate pathway systems unless otherwise approved by Cleveland Clinic.

M. It is preferred that all pathways are designed and installed in common areas such as hallways and corridors whenever feasible. For serviceability and accessibility purposes, placing pathways through patient areas (e.g., exam rooms, treatment rooms, procedure rooms and in-patient rooms), private administrative offices and other private work areas shall be avoided. When it is necessary to pass through one of these areas, Consultant and/or Contractor shall obtain written approval from the Cleveland Clinic ITD Facility Planning and Design Department. When it is necessary for the pathway to pass through one of the aforementioned areas, a continuous enclosed pathway, such as conduit, shall be provided through the area. Consultant and Contractor shall allow for 100% future growth when sizing the pathway.


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5.2 VERTICAL (RISER) INTERCONNECTING PATHWAYS

A. In multi-floor buildings, Technology Rooms shall be vertically aligned and connected with a series of slots or sleeves.

B. A modular floor grid system shall be placed in the vertical riser between Technology Rooms (a minimum of 4 x 4-inch EZ-Path 44+ series sleeves). The actual size of the pathway (number of sleeves) is dependent upon the number and size of interconnecting cables and the number of Technology Rooms in the riser.

C. Provide vertical sections (8’ to 12’) of 18” (minimum) cable runway in each Technology Room to support riser cables between rooms, and from floor sleeve to equipment rack.

5.3 HORIZONTAL DISTRIBUTION PATHWAYS

A. Ceiling Pathways

1. Horizontal distribution pathways in ceilings shall be constructed of cable tray support systems.

2. In all cases, cable tray shall be the preferred and desired means of cable support. Open architecture pathways shall only be used to support cabling from the tray to the drop location.

3. Cable pathways must follow the natural contours of the building whenever possible. All cabling support devices must be attached to structural steel, structural ceilings/decking, or walls with the appropriate mounting hardware.

4. Under no circumstances shall cables be mounted, attached or supported on ceiling panels, support channels (T-bars) and/or vertical ceiling support wires.

5. Install appropriately sized conduit where the path travels over inaccessible ceilings or in areas where cable tray or open architecture access parameters cannot be met.

6. In modular furniture areas, cables will route from the ceiling to the furniture via in-floor boxes or poke through devices from the ceiling below. Modular furniture installed adjacent to a hard wall shall be fed from the wall using grommeted faceplates and spiral wrap or flexible conduits to support cabling.

7. In hard-wall office environments, cables shall route from the ceiling to the faceplate via conduit stubs or wall-fish.

8. In overhead or ceiling pathways, open architecture and cable tray systems must maintain a 5-inch clearance from any light fixture, and a 12-inch clearance from any electrical ballast.

B. Access Floor Pathways

1. Horizontal cable distribution pathways under access floors shall be primarily constructed of a cable tray system.

2. There should be a minimum of 2-inches of free space between the top of the tray side rails and the underside of the stringers or floor panels.

3. Typical tray depth shall be 4-inches.

4. Cable tray pathways must follow main public hallways and furniture aisles. Never route tray under offices, conference rooms, training rooms etc., or directly under modular furniture.


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5. Cable tray systems shall be installed before the installation of access floor stringers or floor panels.

C. Open Architecture

1. Contractor shall adhere to ANSI/EIA/TIA 569-A/B (including most recent additions and addendum), BICSI General Guidelines for Ceiling Systems, and the following Specifications.

2. Contractor shall provide proper support for cables in all situations requiring open architecture installation. Under no circumstances shall Contractor mount, attach or support cabling on ceiling panels, support channels (T-bars) and/or vertical ceiling support wires.

3. Cabling shall be attached to structural steel, structural ceilings/decking, or walls with the appropriate mounting hardware.

4. Contractor shall provide and install J-hooks in all areas requiring open architecture support. Devices, other than J-hooks, shall not be permitted.

5. Cable pathways shall follow the natural contours of the building whenever possible. J-hooks shall be securely attached to structural walls, steel or decking.

6. Open architecture pathways shall have adequate support to withstand the pulling of cables through the supports. Once the cables are installed, they shall be secured to each support using cable ties.

7. Contractor is responsible to repair any damage to the lay-in ceilings and spray-on fireproofing caused by the installation of the support infrastructure or cabling.

D. Equipment Rooms and Technology Rooms

1. Cable runway shall be installed in each equipment and Technology Room to support cabling from the room entry to the wallfield and/or equipment racks, and to support the cable service loop.

2. Mesh type cable tray shall be installed to provide pathways for patch cables from the wallfield to the equipment racks.

3. Cable runway and cable tray shall be installed in accordance with the Drawings and Specifications.

5.4 ROOF PENETRATIONS

A. Provide a minimum of three (3) 4” conduit roof penetrations as identified on the drawings.

B. Provide 12” (on center) separation between conduits, and extend conduits to 24” above roof surface.

C. Provide and install pull box (NEMA 4 rating) at conduit location on roof.

D. Conduit penetrations shall be installed and sealed in accordance with roofing contractor/manufacturer specifications and requirements.

E. Conduits shall route to the nearest Technology Room. The total number of bends along the path shall not exceed 180 (degrees) without a pull box.


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5.5 EQUIPMENT AND MATERIALS

A. Cable Tray – Trough Type

1. Standard cable tray systems shall be “trough” type with a minimum actual loading depth of 4”. Cable trays shall be of louvered ventilated construction with louvered openings a minimum of 3" wide.

2. Straight sections shall be one-piece construction. Top flanges shall be rolled outward and downward for safety of cables and personnel. Cable bearing surface shall be 3" wide. Openings shall be on 6" centers with metal drawn downward so cables can drop out at any location along the tray-without cutting or using a gasket at the openings. Standard length shall be 12 feet. Width shall be 12", 18" or 24" depending on the number of cables to be supported by the pathway.

3. Fittings shall be 3-piece welded construction. Fittings shall have a 3" tangent for easy fit-up in field. Splice plates shall be made of .125" thick aluminum with a four-bolt design with slotted holes. All elevation transitions shall use 45 bend fittings, maximum.

4. Radius drop cross members shall be provided for transition of cabling to rack or cabinet.

5. Cable tray systems shall be built and tested to NEMA VE-1 standards and shall have a UL classification for cable trays to be used as a grounding conductor.

6. Cable tray shall be of welded wire construction with rounded edges, and be available in galvanized, electro zinc or stainless steel materials.

7. Cable tray shall be constructed of aluminum 5052H32 alloy.

8. Hardware shall be 3/8" x 3/4" 302 stainless steel serrated round head bolts. SS hex nuts shall have an integral lock washer.

9. Cable trays shall be built and tested to NEMA VE-1 and shall have a UL classification for cable trays to be used as an equipment grounding conductor.

10. Cable tray systems shall be grounded in accordance with the National Electric Code and TIA/EIA/ANSI J-STD-607-A – Commercial Building Grounding and Bonding Requirements for Telecommunications.

11. Above ceilings, a minimum 8” clearance above the tray must be maintained at all times. All bends and tees must be fully accessible from above the tray.

12. Cable trays shall terminate at each fire rated barrier and resume on the opposite side such that cables pass independently through fire-rated pathway devices. Cable tray shall be rigidly supported independent from fire-rated pathway devices on each side of barrier.

13. Any change in mounting level height shall incorporate a continuous transition.

14. Tray support system shall be a trapeze type system constructed of a unistrut with ½’ threaded rods on each side of the tray. Center hung support systems shall not be permitted. Separate conduit sleeves or segments must be provided as a pathway through any wall or over any obstruction or obstacle to access, such as a fire-rated hallway or fixed ceiling.

15. Approved manufacturer: Chalfant Series 6

B. Cable Tray – Wire Mesh

1. Wire mesh cable tray systems may be used under limited circumstances, and only when approved by ITD Facility Planning & Design.


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2. Wire mesh cable tray shall have minimum actual loading depth of 4”, and shall have a UL Classification.

3. Cable tray will consist of continuous, rigid and welded steel wire mesh, cable management system, to allow continuous ventilation of cables and maximum dissipation of heat.

4. Wire mesh tray wider than 6” shall be specified and installed with solid bottom steel tray liners on all straight sections, tees, crosses and turns. Pan width shall be same as tray, and shall be installed in accordance with manufacturer’s specifications. The pan liner shall be of the same manufacturer as the wire mesh tray.

5. Provide UL listed splice plates, supports, and other fittings necessary for a complete, continuously grounded system in accordance with manufacturer’s specifications, industry standards, and code requirements.

6. Wire mesh cable tray fittings shall be factory produced or field-fabricated from straight tray sections, in accordance with manufacturer’s instructions.

7. Connecting hardware, including splice connectors and support components, shall be furnished by the manufacturer.

8. Standard section length shall be 10 feet. Width shall be 6”, 9”, 12", 18" or 24" depending on the number of cables to be supported by the pathway.

9. Radius dropouts shall be provided for any transition of cabling to rack or cabinet, and/or elevation change from tray to tray. Radius dropouts shall securely fasten to the tray and shall be the same width as the cable tray.

10. The finish for the carbon steel wire shall be applied after welding and bending of mesh, and shall be a powder coated, black painted finish for above ceiling installations or a white painted finish for exposed or open ceiling installations (ASTM D 3451633). Painted wire mesh cable tray shall meet NEC 392.

11. Provide all hardware required to maintain a continuous ground along the entire length of the tray shall be supplied by the manufacturer, and installed by the Electrical Contractor.

12. Cable trays shall terminate at each fire rated barrier and resume on the opposite side such that cables pass independently through fire-rated pathway devices. Cable tray shall be rigidly supported independent from fire-rated pathway devices on each side of barrier.

13. Tray support system shall be a trapeze type system constructed of a unistrut with ½’ threaded rods on each side of the tray. Center hung support systems shall not be permitted. Separate conduit sleeves or segments must be provided as a pathway through any wall or over any obstruction or obstacle to access, such as a fire-rated hallway or fixed ceiling.

14. Provide bottom-panning equal to width of the wire mesh tray in areas where access on top of the tray is limited for a distance of > 10-feet. Panning shall be of the same manufacturer as the wire mesh tray.

15. In all areas excluding Technology Rooms, provide bottom-panning equal to width of the wire mesh tray for all wire mesh trays > 18-inches wide. Panning shall be of the same manufacturer as the wire mesh tray.

16. Approved manufacturers: Horizontal Distribution: Cablofil Technology Rooms: Cablofil


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C. Cable Runways

1. Unless otherwise specified, provide metal cable runways, of types, classes and sizes indicated with splice connectors, bolts, nuts and washers for connecting units.

2. Cable runway shall be ladder type, constructed of rectangular steel tubing with a minimum stringer height of 1½”. The rungs shall be ½” by 1” steel welded to the stringers at 9” intervals. Color shall be black.

3. Cable runway shall be capable of carrying a uniformly distributed maximum load of 135 lbs. /ft. when supported every 5 ft.

4. Standard length shall be 9’-8½”. Width shall be 12", 18 and/or 24" as indicated on the Drawings.

5. All fittings, supports, splices, etc. for the runway system shall be installed to provide a complete assembly including fasteners, hardware, and other items required to complete the installation as indicated on the drawings. Use heavy-duty splices in all areas where cable runway will support > 100 UTP cables.

6. Radius dropouts shall be used when transitioning cables from cable runway to a rack, wall field, and/ or other cable management device. Radius dropouts shall securely fasten to the rung or stringer, and shall be the same width as the cable runway.

7. Radius dropouts shall be used when transitioning from one cable runway elevation to another. Radius dropouts shall be the same width of the cable runway. A Transition shall not exceed the length of the radius drop out.

8. Wall mounted angle support brackets shall be installed when attaching the cable runway to a wall. The brackets shall be securely fastened to the wall in such a fashion that it will not break away under heavy loading conditions. The cable runway shall be attached to the bracket using J-bolts.

9. Threaded rod (1/2”) and ceiling kits shall be used to support the cable runway to the decking or structural steel. Ceiling supports shall be placed every 5-feet along the cable runway. In heavy loading environments or in stacked environments, ceiling supports shall be placed every 3-feet. All threaded rods that may come in contact with cable shall be covered with threaded rod covers.

10. Within Technology Rooms, the cable runway shall be attached to the racks using a rack-to-runway mounting plate (Chatsworth Model No. 10595-X##, or approved equivalent).

11. Vertical wall brackets shall not be permitted as an acceptable means of support the cable runway.

12. End Closings shall be installed at the end of open sections of cable runway that do not terminate at a wall.

13. In some equipment rooms, it may be necessary to tier cable runways in order to support a high density of cables. Under these circumstances, the cable runway shall be vertically tiered 12” apart. No more than two levels of cable runway will be permitted without written approval from Cleveland Clinic.

14. Approved manufacturer: Chatsworth or approved equivalent

D. Conduit & Backboxes

1. All conduits shall be EMT, IMC or Rigid depending on the environment, application and code requirements.


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2. The minimum bend radius of a conduit is equal to 10-times the conduit’s diameter.

3. The total number of bends along a conduit path shall not exceed 180 (degrees) without a pull box.

4. All conduits designated for low voltage telecommunications cabling shall be color coded blue.

5. All conduits shall be fitted with the proper sized fittings and bushings.

6. Provide dedicated conduits for backbone cabling as shown on the drawings.

7. Conduit capacity planning should ensure that no conduit exceeds a 40% fill at the time of the initial installation. When calculating conduit fill, use a fill deration factor of 15% for each 180 of bends.

8. Conduit sleeves (minimum of NEZ33 smoke/sound) must be installed through any wall along the pathway. Fire rated walls require the install of an EZ-Path fire rated pathway.

9. In retrofit installations, provide flex conduit for all in-wall cable installations. Flex conduit shall be sized one trade size larger than the standard requirements for rigid or EMT conduit.

10. Conduit stubs with device boxes shall be installed in all areas for the purposes of routing the horizontal cabling to the telecommunications outlet. These conduits will stub directly into the nearest lay-in ceiling.

a. Conduit stub for 1-3 port faceplates shall be 1” emt. b. Conduit stub for faceplates greater than 3 cables shall be 1-1/4” emt min. c. In all surgical rooms, conduits shall stub into the nearest hallway with a lay-in ceiling.

11. All conduits shall be installed complete with pull-strings.

12. Backboxes shall be one of the following options unless noted otherwise on the drawings.

a. 5”x5”x2-7/8” by RANDL b. 4-11/16”x4-11/16”x3-1/4” by RACO #260H c. 5”x5”x2-7/8” by Thomas and Betts

13. Backboxes shall be fitted with either a single or double gang plaster ring as required.

14. Blank cover plates shall be provided for all unused outlet boxes.

E. Pull Boxes

1. Pull boxes shall be placed in conduit runs that exceed 100 feet and/or 180-degrees in bends.

2. Pull boxes must be located to provide easy access.

3. Pull boxes shall never be used for a right angle bend, and must be installed to allow cable to pass through from one conduit to another in a direct line.

4. Pull boxes shall be sized according to conduit size and bend radius of the cable. Pull boxes must have a length at least eight (8) times the trade-size diameter of the largest conduit.

F. Innerduct

1. Innerduct or cell-packs shall be used in internal pathways unless otherwise specified.

2. Corrugated innerduct shall be sized to provide an adequate pathway for the fiber optic cable (minimum 1.0” inner diameter).

3. Innerduct shall be orange (non-plenum) or white (plenum) and shall have a pre-installed pull tape or Pull rope.


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4. The flame ratings shall meet or exceed UL-910 for Plenum, UL-1666 for Riser and UL 1581-0 for General Purpose as outlined in the current National Electrical Code, Article 770.

5. Sections of innerduct shall be connected using couplers and connectors designed specifically for connecting innerduct.

6. Approved manufacturer: Interior Innerduct: Carlon

Innerduct Couplers and Adaptors: IPEX – Kwikpath System Cell Packs: MaxCell

G. Floor Boxes

1. Floor-boxes must have separate entry points for power and communications cabling.

2. The floor-box manufacturer shall provide a complete line of bezels to facilitate mounting of UTP, and coaxial cables.

3. The unit will contain accommodations for a minimum of four connectors for UTP, coaxial, audio, and/or video connections. All inserts shall be nonmetallic.

4. The minimum depth of the floor-box shall be 4-inches with a preferred depth of 5-inches. The floor-box wiring chamber shall provide two separate compartments to accommodate power wiring on one side of the box and communication wiring on the other side. The chamber shall also provide complete access to the communication wiring plate, which will allow for removal of the wiring plate, without the need to disconnect the wiring of any communication device outlets.

5. The lid of the floor-box shall provide a removable cable guard for egress of power and communication workstation cables. The cable guard, when in use, should extend above the surface of the lid for the purpose of added protection of the workstation cables.

6. Approved manufacturer: UTP Cabling: FSR or Wiremold Audio/Visual Cabling: Wiremold Evolution

H. Poke-thru

1. Poke-thru devices must have separate entry points for power and communications cabling.

2. Poke-thru device manufacturer shall provide a complete line of bezels to facilitate mounting of UTP, and coaxial cables. The unit will contain accommodations for a minimum of four connectors for UTP, coaxial, audio, and/or video connections. All communication inserts shall be nonmetallic.

3. Jacks in the poke-thru device shall be capable of being installed either flush or recessed. The poke-thru device shall provide slide-type dust covers for protection of the jacks.

4. The poke-thru device shall accept discrete, keystone type devices from multiple manufacturers including Cleveland Clinic standard connectivity devices.

5. The poke-thru device shall accommodate a mechanism to permit protection of communication cabling. This mechanism shall be zinc die-cast with two openings to accept both flexible and rigid conduit.

6. Approved manufacturers: Hubbell or Wiremold


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I. Surface Mount Raceway

1. This Specification addresses only the surface raceway requirements for vertically routing of the cables from the ceiling to a single TO when routing or concealing the cables within the wall via wall fish or conduit is not possible.

2. For surface mount raceway systems that exceed the requirements of this Specification, refer to Cleveland Clinic’s Master Electrical Specifications.

3. All nonmetallic surface mount, raceway systems shall consist of raceway, and the appropriate fittings and device boxes to complete installation per the Drawings.

4. Work shall include furnishing all raceway sections and appropriate fittings and device plates to install a fully functional nonmetallic surface raceway system as indicated in the Specifications and Drawings.

5. Surface nonmetallic raceway shall be utilized in dry interior locations only as covered in Article 352 Part B of the National Electrical Code, as adopted by the National Fire Protection Association and as approved by the American National Standards Institute and Section 12-16000 of CEC.

6. The raceway and all system components shall be UL Listed and exhibit nonflammable self-extinguishing characteristics, tested to comparable specifications of UL94V-0.

7. The raceway shall have a minimum inside diameter of 1square inch unless approved in writing by Cleveland Clinic.

8. A full complement of fittings must be available including but not limited to flat, inside and outside corner fittings, tees, drop ceiling entrance fittings, cover clips, and end caps. The fittings shall overlap the cover and base to hide uneven cuts. All fittings shall be supplied with a base where applicable to eliminate mitering. A transition fitting shall be available to adapt to other series raceways. All fittings shall be of the same manufacturer and model or series as the raceway.

9. Device boxes shall be available for mounting standard TO faceplates. A device box shall be available in single gang; two gang and three gang configurations and have a minimum depth of 2.75-inches [70mm] for extra deep devices. All device boxes shall be of the same manufacturer and be fully attachable to the raceway.

10. The raceway, device boxes and all fittings shall comply with detailed manufacturer’s instruction sheets, which accompany system components as well as system instruction sheets. Raceway shall be securely supported in accordance to manufacturer’s installation sheets.

11. Approved manufacturers: Panduit LD***6-A Series, or Wiremold 2300BC-** Series 5.6 INSTALLATION

A. Conduits and Backboxes

1. All conduits shall be installed complete with pull-wires.

2. Provide conduit from each outlet up to the nearest accessible corridor ceiling space, cable tray or other area as indicated on the Drawings, and provide an insulated bushing at each stub.

3. Contractor shall protect cabling from all sharp or rough edges or points.


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4. Continuous conduit runs installed by Electrical Contractor shall not exceed 30.5 m (100 ft.) or contain more than two (2) 90-degree bends without utilizing National Electrical Code sized pull boxes, unless otherwise indicated in these Specifications or on the Drawings.

5. Maximum conduit pathway capacity shall not exceed a 40% fill with the exception of perimeter and furniture fill, which is limited to 60% fill for moves, adds and changes, unless otherwise noted on Drawings.

B. Innerduct and Cell-Packs

1. Between termination points (MC-to-MC, MC-to-IC/HC and IC-to-HC), fiber optic cables shall be installed within innerduct (internal pathways), or cell-packs (internal conduit pathways and outside plant pathways).

2. Separate innerduct pathways shall be installed between the MC and each IC/HC, and between the IC and each HC. When possible, the backbone multimode and singlemode fiber optic cables for each termination point shall be installed in the same respective innerduct.

3. All fiber optic cabling routed through hallways (open architecture and cable tray systems) and unsecured risers shall be installed in innerduct. Innerduct or cell-packs shall not be required in secure riser areas. Secured risers are defined as those contained within stacked Technology Rooms or other secure closet system.

4. Innerduct shall not be required once the cabling enters an Equipment Room, Technology Room or Low Voltage Equipment Room.

5. When utilizing internal conduit pathways, cell-packs shall be used.

6. Between termination points, innerduct and cell-packs shall run continuous with no breaks. In cable tray or cable runway, the innerduct shall be secured every 5’ (feet) with tie-wraps. In open vertical risers, the innerduct shall be secured to the wall every 3’ (feet) using conduit straps.

7. In open architecture areas, the innerduct shall be secured every 3’ (feet), using J-hooks. The mid-span sag of the innerduct between attachments shall not exceed 2-inches at the time of installation completion.

8. All innerduct splice points shall be coupled using the specified couplings and/or terminal adapters. Innerduct couplings and adaptors shall be sized appropriately based on the size of the innerduct. The use of electrical tape, duct tape, or any other form of joining material or device, other than that specified, shall be prohibited.

9. All cell-pack splice points shall be joined in strict accordance with the manufacturer’s specifications and requirements.

10. Sizing of Cell-packs shall be based on Table 5A and manufacturer’s recommendations


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Min Conduit

ID

Max Cable Dia.

per Cell

Max # of

Cables

Product

Max # of Packs

Typical Pull Length

Max Pull Length

2" .70" 2 2" x 2 Cell 1 800' 1500' 3 2" x 3 Cell 1 800' 1500'

3" 1.03" 6 3" x 3 Cell 2 1250' 2000' 1.34" 3 4" x 3 Cell 1 1500' 2000'

4" 1.03" 9 3" x 3 Cell 3 1500' 2500' 1.34" 6 4" x 3 Cell 2 1500' 2500'

5" 1.03" 12 3" x 3 Cell 4 1500' 2500' 1.34" 9 4" x 3 Cell 3 1500' 2500'

6" 1.03" 15 3" x 3 Cell 5 1500' 2500' 1.34" 12 4" x 3 Cell 4 1500' 2500'

1. MaxCell 4" x 3 Cell Designed for use in 4" or larger ducts. Multiple combinations of large and medium cable sizes are applicable. Since larger cable applications are anticipated, the number of cables and packs that can be placed is reduced, therefore a smaller number of cables are available.

2. MaxCell 3" x 3 Cell Designed for use in 3" or larger ducts. Multiple combinations of large, medium and smaller cable sizes are applicable and anticipated.

3. MaxCell 2" x 3 Cell Designed for use in 2"or larger ducts where three cables are being placed.

4. MaxCell 2" x 3 Cell Designed for use in 1.75" or larger ducts where two cables are being placed.

Table 5A: MaxCell Cell Pack Sizing

.

C. Cable Tray and Cable Runway

1. Install cable tray and cable runway level and plumb according to manufacturer's written instructions, coordination Drawings, original design, and referenced standards.

2. Provide straight sections, curved sections, hangers, support rods, clamps, related fittings and mounting accessories as recommended by the system supplier. Conflicts shall be brought to the attention of Cleveland Clinic for resolution.

3. Standard support systems shall consist of wall mounting, trapeze mounting, and under floor mounting hardware – as described on the Drawings. Trapeze systems must be supported from each side of the cable tray or runway (the preferred method of mounting shall be trapeze with strut, using two 3/8” threaded rods with sections directly attached to the building structure). Center support systems shall not be permitted or approved.

4. Solid bottom Cable tray shall be used in all cases where access from the top of the tray is restricted, e.g., solid ceilings, under HVAC ductwork, plumbing, etc.

5. The Drawings indicate intended routings. Contractor shall provide horizontal and vertical transitions as required to suit field conditions in order to meet routing requirements. Any deviation from the indicated route, due to either field conditions or coordination issues, must be brought to the attention of Cleveland Clinic immediately, as these may affect the design of the pathway and the subsequent cable routing.

6. Any unapproved routing of cable tray and/or cable runway shall be corrected by Contractor at no cost to Cleveland Clinic.


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7. Provide a minimum of 8” clearance above all cable tray sections from the finished structure of any device or equipment installed or routed above the cable tray.

8. Contractor shall coordinate clearances and routing of the cable tray with all other trades prior to installation, and shall monitor the installation of the other trades during the progress of the project. Contractor shall hold all other trades accountable to this coordination. Any deviation by other trades to this coordination effort shall be brought to the immediate attention of the Construction Manager for immediate resolution.

9. Installation shall comply with NEC Article 392. Ground cable trays that support as required for conductor enclosures in NEC Article 250. Cable tray and runway shall be provided with bonding jumpers or UL listed splice plates sized in accordance with NEC Section 250.102 between sections, raceways, and equipment. Bonding shall be in accordance with NEC Section 250.96.


D. Surface Mounted Raceways

1. Surface Mounted Raceways for technology cabling shall be provided where shown on the Drawings. For other locations, permission must be obtained for the Architect as described elsewhere in the section. Conductor fill shall comply with the National Electrical Code, the latest published revisions of the TDMM and with the manufacturer’s guidelines.

2. If possible, transitions from conduit shall occur above ceilings.

3. Raceways shall be mechanically fastened to the walls or ceilings. Adhesive mounting is not permitted.

4. Cabling shall be properly supported in the raceways. Sectional barriers shall be provided between power and communication wiring.

5. All Surface Mounted Raceways shall be installed in an orderly manner as directed by Cleveland Clinic and/or Architect.


E. Cable Ties

1. All cable ties shall be properly sized and designed to conform to the environment in which they are installed (i.e., plenum rated cable ties in plenum ceilings, etc.).

2. Within the TR, provide only Velcro type tie-wraps.

3. Cable ties shall be attached so as not to crimp or kink the cables and be applied at random intervals. Cables should move freely within the tie-wrapped bundle.

END OF SECTION 5.0


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6.0 TECHNOLOGY GROUNDING SYSTEM 6.1 GENERAL

A. Contractor shall provide the Technology Grounding System (TGS) as described in the Specifications and as shown on the Drawings.

B. Contractor shall provide labeling and documentation regarding the TGS in accordance with the Specifications and Drawings.

C. Contractor shall bond voice, data and video equipment to the TGS in accordance with the Specifications and Drawings.

D. The TGS shall be a supplemental grounding system and shall be bonded to the main electrical service ground.

E. The TGS shall comply with the latest revisions of the NEC, NFPA, ANSI-J-STD-607-B Commercial Building Grounding (Earthing) and Bonding Requirements for Telecommunications, and IEEE 1100-2005 Powering and Grounding of Electronic Equipment.

F. The minimum gauge of each bonding conductor shall be based on the distance between bonding points as specified in the ANSI-J-STD-607-B.

G. Distribution of the low voltage grounding system shall be in accordance with the Specifications and Drawings.

H. Each entrance facility, equipment room, technology room, low voltage equipment room and cross connect area shall be equipped with a Technology Grounding Busbar (TGB) that shall be bonded to the Technology Main Grounding Busbar (TMGB).

I. The TGS shall not be connected in a way that creates pathways for circulating currents.

J. The TGS shall be constructed to implement the design as indicated on the Drawings. If for any reason a conflict arises between the Specifications and the Drawings, the intent of the Drawings shall be the governing factor in the execution of the TGS.

K. The TGS and TGMB shall remain electrically connected through any transfer switches. 6.2 EQUIPMENT GROUNDING

A. Contractor shall bond all non-current carrying equipment provided by Contractor including, but not limited to, cable trays, cable runways, racks, wall fields, protection devices, etc., to the local TGB.

B. Where copper cabling is routed to an area, either from another building, or from an area with a separate electrical service, Contractor shall provide primary protective equipment, and ground the equipment to the local TGB.

C. The resistance for the Technology Grounding System, as measured at the TMGB or any TGB Busbar shall not exceed 5-ohms.


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A. Busbars

1. All busbars shall be ¼” solid electro-tin plated copper.

2. All busbars shall be ASTM B187-C11000 compliant.

3. All busbars shall be UL and cUL listed to UL 467 and c22.2 respectively.

4. All TMGB and TGB busbars shall be a minimum of 20” long by 4” high, and have a minimum of 24 pairs of 5/16” holes and 6 pairs of 7/16” holes.

5. All insulators shall be manufactured from an environmentally friendly, halogen free nylon material, reinforced with fiberglass.

6. All insulators shall be 2” tall.

7. All insulators shall meet UL 94 VO for self-extinguishing.

8. All brackets and fasteners shall be constructed of stainless steel.

9. All brackets shall be 1/8” thick.

10. Approved manufacturer: Bussbar - Panduit GB4B0624TPI-1

B. Irreversible Compression Connections

1. All irreversible compression connections shall be two-hole lug type.

2. All irreversible compression connections shall have color-coded barrels that correspond to the correct crimp die; possess an inspection window for visual assurance of conductor insertion, and shall be tin-plated to inhibit corrosion.

3. All irreversible compression connections shall be UL Listed for use up to 35KV, temperature rated 90°C and CSA Certified to 600V when installed in compliance with the manufacturer’s specifications.

4. Approved manufacturer: Panduit LCC-** Series.

C. Taps

1. All taps shall be made from high conductivity copper, and shall be electro tin-plated to inhibit corrosion.

2. All taps shall be of slotted design and have legible, color-coded die index numbers for crimping dies that remain legible after crimping.

3. Taps shall be housed in an optically clear cover to allow 360° inspections.

4. Tap covers shall be of snap-on design and shall be constructed of a high impact strength, self-extinguishing plastic with UL 94V-0 flammability rating and minimum oxygen index of 31.

5. Approved manufacturer: Panduit GCE Series for bonding conductors < 250 kcmil Panduit HTWC Series for bonding conductors < 250 kcmil

Panduit SPF2-500-12 for bonding 500 kcmil conductors


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D. Cable

1. All ground cable shall be stranded, and either bare-copper (plenum) or jacketed (non-plenum and riser rated) depending on the environment in which the cable is installed. All non-jacketed cable shall be placed in plenum rated innerduct between termination points.

E. Ground Washers

1. Provide ground washers as part of rack assembly.

2. All ground washers shall be paint piercing type, green in color, and constructed of electro zinc plated steel.

3. Approved manufacturer: Panduit RGW Series.

F. Equipment Rack Bonding Screws

1. All screws used to attach the ground bus to the equipment rack shall provide a bond to the rack by removing paint from the threaded holes without creating metal shavings.

2. Approved manufacturer: Panduit Trilubular Screws – RGTS-C Series.

G. Intersystem Bonding Termination Bar - IBTB

1. All floor system 9” copper strapping that is used to ground the floor to the TGB shall be terminated on a bonding termination bar located between the local TGB.

2. Approved manufacturer: IBTB - ERICO Part# IBTB

6.4 INSTALLATION

A. Prior to materials and equipment procurement and installation, Contractor shall meet with Cleveland Clinic ITD to clarify grounding requirements and installation methods.

B. The Technology Bonding Backbone (TBB) shall be installed in a continuous run (without splices) between the TMGB and every TGB. Where the TBB is installed in a riser, or multiple TGBs are connected to the same TBB cable, approved taps shall be used to connect the TBB to each TGB.

C. The bonding conductor used between the TBB and TGB shall be the same size as the TBB.

D. Bonding conductor lugs shall be installed on the TMGB and TGB so as not to block other lugs or open positions on the bar. Each conductor lug shall be freely removable without the need to remove another conductor lug.

E. The bonding conductor used to bond the TMGB to the main electrical service equipment (power) ground shall be at a minimum the same size as the TBB.

F. Horizontal cable equipment shall be grounded in compliance with ANSI/NFPA 70 and local requirements of the AHJ. Horizontal equipment includes but is not limited to cross connect frames, patch panels and racks, cable runway, active telecommunications equipment, and test apparatus and equipment.

G. The bonding conductor used to bond the horizontal cable equipment to the TGB shall be a minimum of 6-AWG, stranded, jacketed, copper wire. The color of the jacket shall be green.

H. Paint piercing grounding screws and antioxidant shall be used when attaching ground lugs to equipment racks and enclosures.


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I. Sharp bends in the TBB and the bonding conductors shall be avoided. The maximum sweep radius shall be less than or equal to 90. All 90 bends shall be sweeping. All bends in the bonding conductors shall flow towards the TGB or the source of the TBB.

J. The TBB shall be supported by a separate and independent support system, and shall not share electrical or telecommunications pathway support systems. When non-insulated (non-jacketed) copper cable is used, the bonding conductor shall be installed in innerduct and the support system shall be insulated and non-conductive. Extreme care shall be taken to ensure the cable does not come into contact with structural steel, plumbing piping and fixtures, sprinkler system, electrical conduit, or other metallic device or apparatus.

K. The TGS shall be an independent system from the building grounding electrode system with the exception of the bond to the main electrical service ground.

L. Contractor shall bond all non-current carrying equipment to the local TGB included, but not limited to, shall be cable trays and runways, equipment racks and cabinets, and continuous point-to-point conduit and associated pull boxes.

M. Racks and cabinets shall be individually bonded to the local TGB. Racks and cabinets shall not be connected in series. Contractor may bond to a local TBB ground bus that is installed in the room. The ground bus shall be sized (correct gauge) based on length and in compliance with the ANSI-J-STD-607-B.

N. Contractor shall bond the TMGB and each TGB to the building steel and the local power panel with a minimum 6-AWG, stranded, jacketed, copper wire.

O. Contractor shall provide engraved placard next to the TGMB and each TGB. Placard shall be white with black lettering.


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Figure 3: Typical Technology Room Grounding System Schematic

END OF SECTION 6.0


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7.0 FIRESTOP 7.1 GENERAL

A. Furnish and install fire stopping for fire rated construction in the following areas:

1. All openings in fire rated floors and wall assemblies accommodating penetrating items such as cables, conduits, raceways, cable trays, etc.

2. Openings at each floor level in shafts or stairwells.

3. Empty openings in fire rated construction made by Contractor but not utilized for the aforementioned materials.

B. Cleveland Clinic’s Fire Protection & Life Safety Design Standards contain additional information regarding fire protection standards, and fire and life safety requirements of Cleveland Clinic. This Section is intended to compliment these Documents. Any conflict between this Section and the referenced Appendices shall be brought to the attention of Cleveland Clinic for resolution.

7.2 QUALITY ASSURANCE

A. General

1. Fire stopping materials shall conform to Flame (F) and Temperature (T) ratings required by local building code and as tested by nationally accepted test agencies per ASTM E-184 or UL 1479 fire tests in a configuration that is representative of field conditions. The F rating must be a minimum of one (1) hour but not less than the fire resistance of the assembly being penetrated.

2. Owner shall rely on the judgment and decision of the manufacturer for non-standard applications of the product. Drawings for engineering judgments must indicate the UL tested system or systems upon which the judgment is based, in order to evaluate the engineering judgment against a known performance. For tracking purposes, Owner shall issue an Engineering Judgment (EJ) Flow Sheet for each judgment requested.

3. Fire stopping material shall be non-halogenated, lead and asbestos free and shall not incorporate nor require the use of hazardous solvents.

4. Firestop products that dissolve in water after curing are not acceptable.

5. Fire stopping materials shall not shrink upon drying as evidenced by cracking or pulling back from contact surfaces.

6. All fire stopping materials shall be manufactured by one manufacturer. Deviations from the specified manufacturer shall not be permitted without written approval from Cleveland Clinic.

7. Fire stopping shall be performed by a Contractor trained or approved by the firestop manufacturer. (A manufacturer’s willingness to sell its products to a contractor does not itself confer qualification on the buyer.) Each employee of the Contractor must be trained and possess a valid FIT I Certification. A company certification shall not be accepted.

8. Contractor shall be responsible for the correct replacement of firestop material in all existing wall and floor penetrations used as pathways for any cabling installed by Contractor.


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9. Contractor shall install a Cleveland Clinic label at each point of penetration. Label shall include type of firestop system installed and the date of installation.

10. Conform to the manufacturer’s printed instructions for installation in accordance with a UL rated system or engineering judgment of the manufacturer.

11. During delivery and storage, Contractor shall ensure manufacturer’s original, unopened, undamaged containers, identification labels intact identifying product and manufacturer, date of manufacture; lot number; shelf life, if applicable; qualified testing and inspection agency’s classification marking; and mixing instruction for multicomponent products.

12. Contractor shall handle and store products according to manufacturer’s recommendations published in technical materials. Leave products wrapped or otherwise protected, and in clean, dry storage conditions until required for installation. Store materials protected from exposure to harmful weather conditions and at temperature and humidity conditions recommended by manufacturer.

B. Codes and Standards

1. ASTM E 84 - Surface Burning Characteristics of Building Materials

2. ASTM E 119 - Fire Tests of Building Construction and Materials

3. ASTM E 814 - Fire Tests of Penetration Firestop Systems

4. ANSI/UL263 - Fire Tests of Building Construction and Materials

5. ANSI/UL723 - Surface Burning Characteristics of Building Materials

6. ANSI/UL1479 - Fire Tests of Through Penetration Firestops

7. Underwriters Laboratories Inc. (UL) – Fire Resistance Directory

8. National Fire Protection Association (NFPA) – NFPA 101: Life Safety Code

9. National Fire Protection Association (NFPA) – NFPA 70: National Electrical Code. AST

10. Ohio Building Code

11. AHJ (Authority Having Jurisdiction)

C. All firestop work shall be inspected and certified by an independent third party consultant contracted by Cleveland Clinic under a separate contract. Contractor shall rework and/or replace all firestop materials and/or installation work that fail inspection.


A. All firestop materials shall be installed prior to expiration of shelf life.

B. Use only firestopping products that have been tested for specific fire resistance rated construction conditions conforming to construction assembly type, penetrating item type, annular space requirements, and fire rating involved for each separate instance.

C. The preferred method of firestopping for all cabling applications is EZ PATH. Contractor shall endeavor to utilize this method of firestopping whenever possible.

D. Firestop Sealants: STI SpecSeal® Brand single component latex formulations that upon cure do not re-emulsify during exposure to moisture.

Approved manufacturer: Specified Technologies Inc. (STI) - SpecSeal® Series SSS Sealant SpecSeal® Series LCI Sealant


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E. Firestop Putty: STI SpecSeal® Brand intumescent, non-hardening, water resistant putties containing no solvents, inorganic fibers or silicone compounds, the following products are acceptable:

Approved manufacturer: Specified Technologies Inc. (STI) - SpecSeal® Series SSP Putty

F. Firestop Pillows: STI SpecSeal® Brand re-enterable, non-curing, mineral fiber core encapsulated on six sides with intumescent coating contained in a flame retardant poly bag, the following products are acceptable:

Approved manufacturer: Specified Technologies Inc. (STI) - SpecSeal® Series SSB Pillows

G. Fire Rated Cable Pathways: STI EZ-PATH™ Brand device modules comprised of steel raceway with intumescent foam pads allowing 0 to 100 percent cable fill, the following products are acceptable:

Approved manufacturer: Specified Technologies Inc. (STI) - EZ-PATH™ Fire Rated Pathway

H. Firestop Plugs: Re-enterable, foam rubber plug impregnated with intumescent material for use in blank openings and cable sleeves, the following products are acceptable:

Approved manufacturer: Specified Technologies Inc. (STI) - SpecSeal Series FP Firestop Plug

I. Fire-Rated Cable Grommet: Molded two-piece grommet made from plenum grade polymer with a foam inner core for sealing individual cable penetrations up to 0.27 in. (7 mm) diameter, the following products are acceptable:

Approved manufacturer: Specified Technologies Inc. (STI) - Ready Firestop Grommet 7.4 INSTALLATION

A. General

1. Conform to the manufacturer’s printed instructions for installation and when applicable, curing in accordance with temperature requirements.

2. Coordinate this Work as required with all other trades.

3. Fire stopping shall precede finishing of gypsum board.

4. Where fire stopping is installed at locations that shall remain exposed in the completed work, provide protection as necessary to prevent damage to adjacent surfaces and finishes, and protect as necessary against damage from other construction activities.

B. Performance Requirements

1. Fire rated pathway devices (EZ PATH) shall be the preferred product and shall be installed in all locations where frequent cable moves, add-ons and changes will occur, such devices shall:

a) Meet the hourly rating of the floor or wall penetrated. b) Permit the allowable cable load to range from 0% to 100% visual fill thereby

eliminating the need to calculate allowable fill ratios. c) Not require any additional action on the part of the installer to open or close the

pathway device or activate the internal smoke and fire seal, such as, but not limited to opening or closing of doors; twisting an inner liner or removal or replacement of any material such as, but not limited to, sealant, caulk, putty, pillows, bags, foam plugs, foam blocks, or any other material.


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2. Fire rated pathway devices (EZ PATH) shall be the preferred product and shall be installed in all locations where frequent cable moves, add-ons and changes will occur, such devices shall:

a) Permit multiple devices to be ganged together to increase overall cable capacity. b) Allow for retrofit to install around existing cables. c) Include an optional means to lengthen the device to facilitate installation in thicker

barriers without degrading fire or smoke sealing properties or inhibiting ability of device to permit cable moves, add-ons, or changes.

3. Where single cables (up to 0.27 in. (7 mm) diameter) penetrate gypsum board/stud wall assemblies, a fire-rated cable grommet may be substituted. Acceptable products shall be molded from plenum-grade polymer and conform to the outer diameter of the cable forming a tight seal for fire and smoke. Additionally, acceptable products shall lock into the barrier to secure cable penetration.

4. Where non- mechanical products are utilized, provide products that upon curing do not re-emulsify, dissolve, leach, and/or otherwise breakdown and deteriorate over time from exposure to atmospheric moisture, sweating pipes, ponding water or other forms of moisture characteristic during or after construction.

5. Where it is not practical to use a mechanical device, openings within floors and walls designed to accommodate telecommunications and data cabling shall be provided with re-enterable products that do not cure or dry.

C. Inspection

1. Examine all areas and conditions where firestop is to be installed, and notify Cleveland Clinic of conditions detrimental to the proper and timely completion of the work. Do not proceed with work until Contractor, in a manner acceptable to Cleveland Clinic, has corrected unsatisfactory conditions.

2. Verify that surfaces shall be free of dirt, grease, oil, scale, laitance, rust, release agents, water repellants, and any other substances that may inhibit optimum adhesion.

3. Provide masking and temporary covering to protect adjacent surfaces.

D. Conditions Requiring Fire stopping

1. Contractor shall be responsible to verify the fire rating of each wall, and supply firestop materials that meet or exceed the rating.

2. Provide fire stopping for conditions specified elsewhere whether or not fire stopping is indicated and, if indicated whether such material is designed as insulation, safing, or otherwise.

3. All fire stopping shall be installed in accordance to the UL rated system designed for the application.

4. Insulation types specified in other sections shall not be installed in lieu of fire stopping material specified.

5. Grout, Mortar or Gypsum based products shall not be installed in lieu of fire stopping material specified.

6. All smoke walls (smoke barriers, smoke partitions, etc.), rated or non-rated, shall be fire stopped with systems designed to maintain a minimum 1 hour rating or that which is equal to the rating of the wall, whichever is greater.


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7. Provide fire stopping for penetrations including conduits, raceways, cables, cable trays or other equipment that pass through one or both surfaces of a fire rated floor or wall.

8. Except for floor on grade, provide fire stopping for penetrations that occur through a structural floor or roof and a space that would otherwise remain open between the surfaces of the penetration and the edge of the adjoining structural floor or roof.

9. Where a penetration occurs through fire rated walls or partitions of hollow-type construction, provide fire stopping to fill spaces around the penetration, on each side of the wall or partition.

10. The requirements for penetrations shall apply whether or not sleeves have been provided, and whether or not penetrations are to be equipped with escutcheons or other trim. If penetrations are sleeved, firestop annular space, if any, between sleeve and wall opening.

11. Provide fire stopping to fill miscellaneous voids and blank openings in fire rated construction where existing raceways, conduits, cables, cable trays or other equipment have been removed.

E. Preparation

1. Surface to receive firestop shall be free of dirt, dust, grease, oil, oil from release agents, or other matter that would impair the bond of the firestop material to the substrate or penetrating items.

2. Substrate shall be frost-free.

F. Installation

1. Sleeves and core-drilled holes shall be sized at least 1-1/2” larger in diameter than penetrating items.

2. Installation of firestop shall be performed by applicators/installers qualified and trained by the Manufacturer. Installation shall be performed in strict accordance with the Manufacturer’s detailed installation procedures.

3. Apply firestop in strict accordance with UL rated system designs, and Manufacturer’s recommendations.

4. Coordinate with plumbing, mechanical, electrical and other trades to assure that all conduits, raceways, cables, cable trays, and other equipment that penetrate fire rated construction have been permanently installed prior to installation of firestop. Schedule and sequence the work to assure that partitions and other construction that would conceal penetrations are not erected prior to the installation of firestop.

5. Gun grade sealants and putties shall be tooled into place to insure proper adhesion to penetrations and surrounding surfaces.

6. Install dams when required to contain firestopping materials within openings, and as required to accomplish required fire resistance rating.

7. Placement of dams shall not interfere with functions or adversely affect the appearance of adjacent construction.

8. Install work in full accordance with the rules, regulations, and safety requirements of Federal, State, County and City authorities having jurisdiction over premises. Do not construe this as relieving Contractor from compliance with any requirements of the Specifications that are in excess of Code requirements and not in conflict therewith.


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9. Correct unacceptable fire stopping and provide additional inspection to verify compliance with this Specification at no additional cost.

10. Finish surfaces of fire stopping that is to remain exposed in the completed work to a uniform and level condition.

END OF SECTION 7.0


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8.0 EQUIPMENT ENCLOSURES & RACKS 8.1 GENERAL

A. Each MC, IC and HC shall be equipped with equipment racks and/or cabinets for mounting Cleveland Clinic provided equipment and Contractor provided cable termination hardware.

B. Equipment enclosures and racks shall be able to support and organize electronic equipment, cross connection and/or termination hardware for fiber optic cabling, horizontal cabling, riser cabling, or building entrance cabling as may be required by the design.


A. Equipment Racks

1. All racks shall be provided with all necessary hardware to assemble the frame and/or enclosure.

2. Racks shall be packed in cartons with suitable shipping inserts such that no damage occurs to the rack finish. Finishes shall not be scratched, chipped, or marred.

3. Contractor shall provide all accessories and related hardware associated with equipment racks unless otherwise noted on the Drawings.

4. Provide dual upright (4-post) and/or standard (2-post) open relay racks as specified. All racks shall have a usable rack space of 78” and a mounting width of 19”. Dual upright racks shall have a mounting depth of 26”.

5. All rack components shall be charcoal black in color and made of lightweight 6061-T6, extruded aluminum.

6. Racks shall be self-supporting and self-squaring, and equipped with ½” holes for securing multiple-rack-lineups.

7. Provide 19” x 3.5” rack mountable horizontal cable management panels with black, polyester powder, paint finish.

8. Regardless of rack or enclosure type, provide rack mountable (19” W x 15” D), stationary shelves with black paint finish, and a 75 lb. weight capacity. Quantity four (4) in the Technology Equipment Center, and one (1) in each Technology Distribution Room.

9. Provide minimum 7’H x 6”W, double sided vertical cable managers between equipment racks. (Note that wider vertical managers shall be required for higher cable densities.) Vertical Cable managers shall have a hinged door cover or brackets over the guide fingers on the front. Guide fingers shall be spaced at 1RU intervals for securing and routing patch cables. The rear of the vertical cable manager shall have cable rings for securing and routing horizontal cables. All parts shall be black in color.

10. For Chatsworth and Great Lakes racks, provide Chatsworth vertical cable managers.

11. Approved manufacturer: Racks - Chatsworth or Great Lakes Cable Management – Chatsworth Rack Mountable Shelves – Great Lakes (1984ST15)


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B. Equipment Enclosures

1. In Technology Rooms designed with a raised access flooring system (typically the TEC), provide freestanding cabinets that will sit on top of the floor panels without the need for mechanical attachment to the subfloor or raised access floor stringer system.

2. Cabinets shall be provided with all necessary hardware to assemble the frame and enclosure.

3. Cabinets shall be packed in cartons with suitable shipping inserts such that no damage occurs to the cabinet finish. Finishes shall not be scratched, chipped, or marred.

4. Contractor shall provide all accessories and related hardware associated with equipment cabinets unless otherwise noted on the Drawings.

5. All Cabinets shall be configured with 19” EIA 310-E compliant mounting rails, with a 45 RMU (Rack Mounting Units) of total mounting space.

6. All cabinets shall be black in color.

7. Network Enclosures designated for backbone and horizontal cabling patch panels and/or network electronics shall have the following minimum configuration:

a) Dimensions shall be 84"H x 32"W x 42"D.

b) EN Series Frame with mounting rails and cable management "fingers" on all rails and eight (8) levelers.

c) Front and rear doors and top panel shall not be required.

d) Side panels only required for end of row cabinets.

e) Networking/Ganging Kit used to gang two enclosures together.

f) Grounding kit.

8. Server Enclosures designated for servers, local disk storage and/or other computer equipment shall have the following minimum configuration:

a) Dimensions shall be 84"H x 32"W x 42"D.

b) EN Series Frame with two pair of mounting rails and cable management "fingers" on all rails and eight (8) levelers.

c) Mesh front door, split mesh rear door, and solid top panel shall be required.

d) Side panels only required for end of row cabinets.

e) Networking/Ganging Kit used to gang two enclosures together.

f) Grounding kit.

9. Approved manufacturer: Enclosures - Great Lakes EN Series

C. Storage Cabinets

1. Provide two (2) lockable storage cabinets in the Technology Equipment Center. Coordinate final placement within the room with Cleveland Clinic.

2. Cabinets dimensions shall be 72”H x 36”W x 24”D. Cabinets shall be constructed of steel with a black, powder coat finish. Cabinet doors shall include handles and key lock.

3. Each cabinet shall contain four (4) adjustable shelves. Each shelf shall have a weight capacity of 200 lbs.


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4. All storage cabinets shall be delivered fully assembled, excluding shelves and door handles, and shall be provided with all necessary hardware required for final assembly.

5. Cabinets shall be packed in cartons with suitable shipping inserts such that no damage occurs to the cabinet finish. Finishes shall not be scratched, chipped, or marred.

6. Approved manufacturer: Storage Cabinets – Granger, Part #2TER7 8.3 INSTALLATION

A. Contractor shall ensure that all enclosures and/or racks specified for each room are positioned in accordance with the Drawings.

B. Racks shall be secured to the floor and to the overhead cable runway and/or an adjacent wall to ensure racks do not move.

C. Vertical cable managers shall be secured between equipment racks in accordance with manufactures instructions using manufacturers mounting hardware.

D. Enclosures and racks shall have a minimum 3’ (feet) clearance front and back from the rack base.

E. Contractor shall supply and install cable runway between the enclosures and/or rack(s) and the wall field as required. All backbone fiber optic cables shall be routed and secured between the rack(s) and the mounting board via the cable runway.

F. To protect the service loop from damage, secure the fiber optic cable service loop to the underside of the cable runway and attach using Velcro tie-wraps.

G. Assemble enclosures and racks with paint piercing grounding washers to ensure all rack-framing members are bonded together.

H. Equipment enclosures and racks shall be grounded to an appropriate ground in accordance with the NEC, ANSI/NFPA 780, ANSI J-STD 607-A (including most recent additions and addendum), and ANSI/IEEE Std.1100 standards.

I. Grounds shall be constructed using an insulated (green jacket), stranded copper bonding conductor (minimum 6-AWG, stranded, jacketed, copper wire), two-hole lug compression type connectors, and trilubular screws. Actual bonding conductor size shall depend on the distance from the TGB to the racks using the distance chart specified in the ANSI J-STD 607-A.

J. Contractor shall remove paint/finish from equipment enclosure, rack, and cable runway where two-hole lug is installed.

END OF SECTION 8.0


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9.0 OUTSIDE PLANT & ENTRANCE FACILITIES 9.1 GENERAL

A. The backbone cabling system is designed in a star topology with no more than two hierarchical levels of cross-connects in the backbone. Typically, from the Horizontal Cross Connect (HC), there are no more than two cross-connects needed to reach the Main Cross Connect (MC) and network core (see figure 1).

Figure 4: Backbone Fiber Optic Cable Topology

B. The MC is located in a network core Equipment Room (ER). The MC feeds multiple Intermediate Cross Connects (IC) and/or Horizontal Cross Connects (HC) in a campus environment and normally just HCs in a single building environment, such as a remote facility or clinic.

C. The IC is typically located in the primary Equipment Room within a building in a campus environment (also referred to as MDF). In some cases, an IC may serve a cluster of two or more buildings depending on their proximity and size.

D. The HC is located in the Technology Room that serves a single floor within a building. Depending on the square footage and outlet density of a particular floor, there may be more than one HC per floor. (Note, in accordance with Cleveland Clinic ITD Standards HCs shall not service multiple floors.)

E. The backbone fiber optic cabling is comprised of multimode and singlemode cables, LC or SC connectors, LC or SC coupler panels, and rack-mount connector housings.

F. The backbone fiber optic cabling shall be comprised of both singlemode and multimode fibers in the following configurations unless otherwise noted on the Drawings.

ORIGIN/DESTINATION SINGLEMODE MULTIMODE

MC-to-MC 72-fibers 72-fibers MC-to-IC 72-fibers 72-fibers MC/IC to HC 36-fibers 36-fibers

Table 9A: Backbone Fiber Strand Counts

MC

IC

HC HC

IC

HC HC

Level 1

Level 2


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G. For internal building pathways, the backbone fiber optic cable shall be a tight buffered (either plenum or riser rated depending on the environment). For OSP pathways, the backbone fiber shall be a loose tube type cable rated for underground duct and/or aerial installation depending on the pathway.

H. All fiber optic cables and connecting hardware shall meet ANSI/TIA/EIA 568-B.3 standard. 9.2 EQUIPMENT AND MATERIALS

A. General

1. Fiber optic cabling shall be provided with the quantity of fibers indicated on the Drawings and/or Specifications.

2. All fiber optic cables shall be the same manufacturer and shall be the same type, unless otherwise indicated on the Drawings. A mix of fibers from different manufacturers shall be prohibited.

3. Outdoor and indoor/outdoor rated cable shall be of loose tube construction, and rated for underground duct or aerial installation depending on the pathway. Each buffer tube shall contain a maximum of 12 fibers, and the fibers shall not adhere to the inside of the buffer tube.

4. Cables shall comply with EIA/TIA 492 specifications, NEC Article 770, OFNP (plenum), OFNR (riser) or OFN (non-plenum) and ISO 11801 Standards.

5. All fibers shall be color coded to facilitate individual fiber identification. Fibers shall utilize a coating to ensure color retention, to minimize micro-bending losses and to improve handling. The coating shall be mechanically strippable.

B. Singlemode Fiber Optic Cable

1. All single-mode fiber optic cables shall be classified as indoor, indoor/outdoor or outdoor as indicated on the Drawings.

2. Each single-mode optical fiber shall be comprised of a Germania-doped silica core surrounded by a concentric silica glass cladding. The fiber shall be a matched clad design manufactured by the outside vapor deposition process (OVD). The optical fiber refractive index profile shall be step index.

3. The single-mode fiber shall meet EIA/TIA-492CAAA, “Detail Specification for Class lVa Dispersion-Unshifted Single-Mode Optical Fibers,” and ITU-T G.652, “Characteristics of Single-mode Optical Fiber Cable.” Fiber shall have a mode field diameter of 9.20 + 0.40m at 1310nm and 10.40 + 0.80m at 1550nm. Fiber core-clad concentricity shall be ≤ 0.5µm. Fiber cladding diameter shall be 125.0 + 0.7m. Fiber cladding non-circularity shall be ≤ 1%. Fiber coating diameter shall be 245 + 5m.

4. Fibers shall comply with NEC Article 770, OFNP (plenum), OFNR (riser) or OFN (non-plenum), and ISO 11801 Standards.

5. The single-mode fiber cable shall support laser-based Gigabit Ethernet (GbE) operation according to the 1000Base-LX (1310 nm) specifications up to 5000 meters, in accordance with the GbE standard.

6. The maximum dispersion shall be ≤ 3.2ps/ (nmkm) from 1285nm to 1330nm and shall be < 18ps/ (nmkm) at1550nm.


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7. The attenuation specification shall be a maximum value for each cabled fiber at 23 + 5oC on the original shipping reel. The cabled fiber attenuation shall be ≤ 0.4dB/km at 1310nm and ≤ 0.3dB/km at 1550nm. The attenuation at the water peak (1383nm) shall not exceed 2.1 dB/km. The attenuation due to 100 turns of fiber around a 50 + 2mm diameter mandrel shall not exceed 0.05 dB at 1310nm and 0.10dB at 1550nm. There shall be no point discontinuities greater than 0.10dB at either 1310nm or 1550nm.

8. The single-mode fiber shall support 10 Gigabit Ethernet (10GbE) operation according to the 10GBASE-LX4 (1300 nm region), 10GBase-L (1310 nm) and 10GBase-E (1550 nm) specifications for distances of 10km, 10km and 40km, respectively.

9. The single-mode optical fiber shall support industry-standard multi-gigabit Fiber Channel physical interface specifications.

10. Approved manufacturer: Outdoor Loose Tube Applications – Berk-Tek (w/Corning Glass) Indoor/Outdoor Applications - Berk-Tek (with Corning Glass)

Indoor Applications – Berk-Tek (with Corning Glass)

C. Enhanced Multimode Fiber Optic Cable

1. All standard multimode, fiber optic cables shall be classified as indoor, indoor/outdoor or outdoor as indicated on the Drawings.

2. The multimode fiber shall meet EIA/TIA-492AAAA-A-1997, “Detail Specification for 62.5-μm Core Diameter/125-μm Cladding Diameter Class 1a Graded-Index Multimode Optical Fibers."

3. The maximum attenuation shall be 3.5dB/km at 850nm and 1.0dB/km at 1300nm.

4. The cabled effective Modal Bandwidth shall be > 385MHz at 850nm.

5. The IEEE 802.3 GbE distance (in meters) shall be up to 500m for the 1000BASE-SX Window (850nm) and up to 1000m for the 1000BASE-LX Window (1300nm).

6. Approved manufacturer: Outdoor Loose Tube Applications – Berk-Tek Indoor/Outdoor Applications - Berk-Tek

Indoor Applications – Berk-Tek

D. Laser Optimized Multimode Fiber Optic Cable

1. All laser optimized multimode, fiber optic cables shall be classified as indoor, indoor/outdoor or outdoor as indicated on the Drawings.

2. The jacket color for all laser optimized fiber optic cable classified for indoor use shall be Aqua.

3. The fiber shall meet the requirements of EIA/TIA-492AAAC, “Detail Specification for 850nm Laser-Optimized; 50μm Core Diameter/125μm; Cladding Diameter Class 1a Graded-Index Multimode Optical Fibers.”

4. The maximum attenuation shall be 3.5dB/km at 850nm and 1.0 dB/km at 1300nm.

5. The cabled effective Modal Bandwidth shall be > 2000MHz at 850nm.

6. The IEEE 802.3GbE distance (in meters) shall be up to 1000m for the 1000BASE-SX Window (850nm), and up to 600m for the 1000BASE-LX Window (1300 nm).

7. The 802.3 10GbE distance (in meters) shall be up to 300m for the 10GBASE-SX Window (850 nm), and up to 300m for the 10GBASE-LX4 Window (1300nm).

8. Fibers shall be optimized for the use of VCSEL light sources.


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9. Approved manufacturer: Outdoor Loose Tube Applications – Berk-Tek (Corning Glass) Indoor/Outdoor Applications - Berk-Tek (Corning Glass)

Indoor Applications – Berk-Tek (Corning Glass)

E. Fiber Optic Connectors

1. All fiber terminations shall be type LC unless otherwise noted on the Drawings.

2. All multimode fiber strands shall be field terminated with splice on connectors.

3. All single-mode fiber strands shall be terminated with splice on connectors.

4. The typical loss for each multimode fiber optic connector shall be < 0.2dB with a repeat mating loss of < 0.2dB per 1000 rematings.

5. The typical loss for each singlemode fiber optic connector shall be < 0.2dB with a repeat mating loss of < 0.2dB per 500 rematings.

6. The reflectance parameter for each singlemode connector assembly shall be < -58dB

7. Approved manufacturer: Sumitomo

F. Fiber Optic Cable Housings

1. Closet connector housings shall be self-contained modular enclosures that shall be populated with LC connector panels, and other necessary parts to provide cross connect, interconnect or termination capabilities for fiber optic cables.

2. The unit shall possess hardware for maintaining a minimum bend radius of 1.5” for buffer tubing, provisions for labeling connector panels, and be UL listed.

3. Closet connector housings shall be mountable in a 19” wide rack utilizing standard EIA 1.75” hole spacing, and shall possess a patch cable routing trough.

4. The connector housing shall be accessible from front and rear hinged doors, and possess a slide out shelf to allow ease in access from above the shelf.

5. The unit shall be available in 1U, 2U, 3U and 4U configurations with the following maximum capacities unless otherwise noted.

a) LC = 48-strands b) LC = 96-strands c) LC = 144-strands d) LC = 288-strands

6. Closet connector housings shall have field installable connector panels to configure the terminations required within the patch panel.

7. Connector panels shall be specifically designed for the respective cable/connector type, and shall be of the same manufacturer as the closet connector housing. Connector Panels shall possess plastic covers on the front of the housing to prevent dust or other debris from entering unused ports.

8. All unused panel sections of the connector housings shall be covered with a blank plate produced by the closet connector housing manufacturer.

9. Approved manufacturer: Leviton

G. Fiber Optic Cable Splice Housing

1. Closet splice housings shall provide interconnect or cross-connect functionality, and shall be mountable in a 19” wide rack utilizing standard EIA 1.75” hole spacing.


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2. The splice housing shall be designed to utilize the open space behind the corresponding jumper management panel.

3. The unit shall be available in 2U and 3U configurations with the following maximum capacities unless otherwise noted.

a) 2U accepts up to four 0.2” splice trays b) 3U accepts up to eight 0.2” splice trays

4. Splice trays shall be used to store all singlemode, fusion-splice connections up to a maximum of 24 splices per tray, and shall contain an organizer that seals bare splices with the use of RTV.


H. Wall Mountable Fiber Optic Cable Housings

1. Wall mount, connector housings shall provide fiber-splice storage functionality, and shall be wall mountable.

2. Wall mount, connector housings are specified for areas where it is not practical or possible to install a freestanding rack or cabinet. The unit shall be sized to accommodate 100% of the backbone fiber to be installed.

3. The unit shall have patch cord routing guides that allow a transition and segregation point for jumpers exiting the top and bottom of the housing.

4. Each cable entry point shall be fitted with a grommet to minimize dust/water intrusion.

5. The unit shall be available in two configurations, 48-strand maximum and 144-strand maximum unless otherwise noted.

6. Wall mount, connector housings shall have field installable connector panels to configure the terminations required within the patch panel. The connector panels shall accommodate LC connectors in removable, snap-in/out panels.

7. Connector panels shall be specifically designed for the respective cable/connector type, and shall be of the same manufacturer as the closet connector housing. Connector Panels shall possess plastic covers on the front of the housing to prevent dust or other debris from entering unused ports.

8. All unused panel sections of the connector housings shall be covered with a blank plate produced by the closet connector housing manufacturer.


I. MUTOA (Multi-User Telecommunications Outlet Assembly)

1. MUTOA’s shall provide low density fiber connectivity in areas such as Operation Rooms, Catheterization Labs, Procedure Rooms or other areas as indicated on the Drawings.

2. MuTOA’s shall be wall mountable to a standard 5” x 5” backbox, and shall be white in color.

3. Provide six (6) duplex coupler panels with SC and/or LC couplers as indicated on the Drawings.



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9.3 INSTALLATION

A. Fiber Optic Cable

1. Fiber optic cables shall not be placed in any raceway, compartments, outlet box, or junction box with conductors of electric light and power circuits.

2. All fiber optic cable strands shall be tested on the reel after arriving on Site and prior to installation.

3. Multimode strands shall be field terminated at both ends with LC or SC type connectors, and properly installed, labeled and secured in a rack mountable Closet Connector Housing (CCH).

4. Singlemode strands shall be fusion spliced at both ends to a factory terminated and LC/PC or SC/PC ultra-polished cable/connector assembly, and properly installed, labeled and secured. Cable assembly splice points shall be labeled and neatly organized into splice trays, which shall be loaded into a Closet Splice Housing (CSH). Cable assemblies shall be routed from the CSH to the CHH, labeled and mounted in connector panels.

5. Pathways shall be sized to accommodate a 20-foot service loop at each pull-box and/or maintenance hole and termination point. At the termination point (MC, IC and HC), the service loop shall be neatly coiled and placed on either the backboard (excluding the wall with the cooper wall-field), cable runway or within the fiber rack.

6. Fiber optic cables shall be installed in such a manner as to avoid kinks and other deformities. Extreme care shall be taken when handling, fishing, and pulling all fiber optic cables to avoid damage to fibers and jacketing/cladding. Avoid excessive and sharp bends.

7. The minimum bend radius of all fiber optic cables shall be carefully observed in accordance with the manufacturer’s specifications. During the installation of the fiber optic cable, the manufacturer's maximum pulling tension shall be strictly followed.

8. The backbone fiber optic cables shall be installed in a single, continuous length between termination points. Intermediate splicing of the backbone fiber optic cables shall not be permitted.

9. Whenever possible, pull cables, including fiber optic cables, simultaneously where more than one is being installed in same raceway. Avoid multiple pulls whenever possible.

10. Use pulling lubricant where necessary. The lubricant used must not deteriorate the cable conductors or insulation. Use of soap or grease is not permitted as pulling lubricant.

11. Use a pulling means such as fish tape, cable, rope, and basket weave wire/cable grips that will not damage the cables or support infrastructure.

12. All outdoor rated inter-building fiber optic cable shall transition to an indoor rated cable within fifty-feet (50’) of entering a building unless installed in conduit to the termination point. All indoor rated cabling shall meet the restrictions of the environment in which it is installed.

13. All riser cables shall be secured at the top of the riser using a split mesh grip to secure the cable. The attachment point for the split mesh grip shall be carefully selected so as not to exceed the minimum bend radius of the cable. Intermediate supports are required when the maximum vertical rise of the cable is exceeded. Table 7B below details typical vertical rise values for fiber optic cables. Contractor shall verify manufacturer’s vertical rise values for each cable type.


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APPLICATION STRAND COUNT MAX. VERTICAL RISE (FT.)

Campus Backbone 2-84

85-216 640’ 226’

Building Backbone 2-72

73-116 1,640’ 226’

Horizontal Cabling 2 - 8 1,640’

Table 7B: Typical Vertical Rise Values for Fiber Optic Cables

B. Innerduct/Cell-Packs

1. Between termination points (MC-to-MC, MC-to-IC/HC and IC-to-HC), fiber optic cables shall be installed within innerduct (internal pathways), or cell-packs (internal conduit pathways and outside plant pathways).

2. Separate innerduct pathways shall be installed between the MC and each IC/HC, and between the IC and each HC. When possible, the backbone multimode and singlemode fiber optic cables for each termination point shall be installed in the same respective innerduct.

3. All fiber optic cabling routed through hallways (open architecture and cable tray systems) and unsecured risers shall be installed in innerduct. Innerduct or cell-packs shall not be required in secure riser areas. Secured risers are defined as those contained within stacked Technology Rooms or other secure closet system.

4. Innerduct shall not be required once the cabling enters an Equipment Room, Technology Room or Low Voltage Equipment Room.

5. When utilizing internal conduit pathways, cell-packs shall be used.

6. Between termination points, innerduct and cell-packs shall run continuous with no breaks. In cable tray or cable runway, the innerduct shall be secured every 5-feet with tie-wraps. In open vertical risers, the innerduct shall be secured to the wall every 3-feet using conduit straps.

7. In open architecture areas, the innerduct shall be secured every 3-feet, using J-hooks. The mid-span sag of the innerduct between attachments shall not exceed 2-inches at the time of installation completion.

8. All innerduct splice points shall be coupled using the specified couplings and/or terminal adapters. Innerduct couplings and adaptors shall be sized appropriately based on the size of the innerduct. The use of electrical tape, duct tape, or any other form of joining material or device, other than that specified, shall be prohibited.

9. All cell-pack splice points shall be joined in strict accordance with the manufacturer’s specifications and requirements.

C. Fiber Termination Points

1. All multimode fibers shall be field terminated with multi-mode grade, LC and/or SC type connectors and mounted into the respective closet connector housing. The closet connector housings shall be populated with multi-mode grade, duplex, LC and/or SC couplers and coupler panels.


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2. All single-mode fibers shall be fusion spliced, in the field, to factory terminated; ultra PC polished cable/connector assemblies, and mounted into closet splice housings and closet connector housings.

3. Fusion splices shall be stored and secured within the closet splice housing in accordance to the manufacturer’s specifications.

4. Closet connector housings shall be populated with single-mode grade, duplex, LC and/or SC couplers and coupler panels.

5. Unless otherwise specified on the Drawings, the backbone multi-mode and single-mode fibers shall be installed in separate connector housings in the MC and IC, but shall share the same closet connector housing in the HC.

6. In the HC, the horizontal, multimode fibers shall be installed in a dedicated closet connector housing separate from the backbone fiber optic cables.

7. All loose-tube fiber optic cables shall be properly prepped and installed in fan-out assemblies in each respective closet connector housing.

8. The slack from the multi-mode and single-mode fiber strands shall be properly coiled and labeled within the closet connector housing in accordance with the Specifications. Proper strain relief shall be provided at the connection points to avoid damage to the fibers.

9. All LC and/or SC connectors shall be of push-pull design, and must be pull-proof when attached.

10. In the MC and IC, Contractor shall provide and install rack mount closet connector housings for the multimode fibers and singlemode fibers as shown on the Drawings.

11. In each HC, Contractor shall provide and install a rack-mount closet connector housing for both the multimode and singlemode fibers. Unless otherwise indicated on the Drawings, the multimode and singlemode fiber strands shall be placed in the same housing, but on separate coupler panels.

12. As indicated on the Drawings, Contractor shall provide and install a wall mount connector housing. Both the multimode and singlemode fiber strands shall be placed in the same housing, but on separate coupler panels.

13. Contractor shall provide and install wire management panels as shown on the Drawings. The wire management panels shall be rack mountable, and will normally be installed in the rack immediately below the closet connector housing or in front of the closet splice housing.

END OF SECTION 9.0


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10.0 BACKBONE COPPER CABLING (HIGH PAIR COUNT) 10.1 GENERAL

A. The backbone copper cabling system is designed in a star topology similar to the backbone fiber cabling. The primary difference is that the Main Cross Connect for the copper may not always be collocated with the fiber.

B. The voice-interconnect cables shall be capable of supporting all standard voice and low-speed data applications, and shall meet the required Specifications.


A. Intra-building High-pair Copper Cable

1. Unshielded high-pair copper cables shall be used as the intra-building backbone cables. The cable shall support voice, data and building service applications.

2. The high-pair copper cables shall be UL Listed Type CMP (plenum), CMR (riser), or CM (non-plenum) depending on the environment in which the cable is installed.

3. High-pair copper cables shall consist of 24-AWG solid copper conductors insulated with color-coded jacket.

4. Cables shall be available in pair counts of 25, 50, 100, 200, and 300, and shall be ETL certified to current revisions of ANSI/TIA/EIA 568 for Category 3.

5. Cabling shall be UL Listed for Fire Safety.

6. Approved manufacturers: Superior Essex or Berk-Tek

B. Inter-building High-pair Copper Cable

1. Shielded high-pair copper cables shall be used as the inter-building backbone cables. The cable shall support voice, low-speed data and building service applications.

2. The cable shall be rated for outdoor aerial or underground duct use, depending on the pathway.

3. Shielded high-pair copper cables shall consist of 22-AWG solid annealed copper conductors.

4. Conductors shall be dual insulated with an inner layer of foamed polyolefin covered by an outer layer of solid, colored polyolefin.

5. Individual conductors shall be twisted into pairs with varying lay lengths to minimize crosstalk.

6. The core assembly shall be filled with ETPR compound, completely filling the interstices between the pairs and under core tape.

7. The shield shall be constructed of a corrugated, copolymer coated, 8-mil aluminum tape applied longitudinally with an overlap.

8. Cables shall be available in pair counts from 25 to 300 and shall be RUS listed.


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9. The jacket shall be black, and designed to withstand exposure to direct sunlight, atmospheric temperature changes and stresses expected in standard installations. The jacket shall be marked with manufacturer, pair count, gauge, part number, and sequential footage.

10. Approved manufacturers: Superior Essex or General Cable

C. Wiring Blocks

1. The 110 wiring blocks shall support up to Category 6 applications and facilitate cross connection and interconnection using either cross-connect wire or the appropriate patch cords.

2. The wiring blocks shall be fire retardant, molded plastic consisting of horizontal index strips for terminating 25 pairs of conductors each. These index strips shall be marked with five colors on the high teeth, separating the tip and ring of each pair, to establish pair location. A series of fanning strips shall be located on each side of the block for dressing the cable pairs terminated on the adjacent index strips.

3. The wiring block shall accommodate 22-AWG through 26-AWG conductors and shall be able to mount directly on wall surfaces with or without backboards or on a 24” freestanding frame.

4. Clear label holders with the appropriate colored designation strips shall be provided with the wiring blocks. The insert label shall contain vertical lines spaced based on circuit size (3, 4, or 5 pair) and shall not interfere with running, tracing or removing jumper wire/patch cords.

5. The wiring blocks shall be available in 25, 50, 100, and 300 pair sizes. The 100 and 300 pair wiring blocks shall be available with or without legs. The legs shall allow the cables to pass behind the wiring block and fan out each side. The space created by the feet, on each side of the block, shall allow it to be used as a vertical jumper trough.

6. The wiring blocks shall capable of mounting to a wall frame or equipment rack.

7. The 25 and 50 pair sizes shall be utilized for low pair count and/or depth restrictive situations.

8. Wiring blocks shall be equipped with connecting blocks configured for 5-pairs.

9. The wiring block shall be able to accommodate over 500 repeated insertions without incurring permanent deformation and it shall pass the reliability test of no more than one contact failure in 10,000 connections.

D. Approved manufacturers: Ortronics Clarity6 110 Wiring Blocks

E. Building Entrance Terminals and Protection Modules

1. All copper circuits shall be provided with protection between each building or between areas with separate electrical service. Protection shall be provided with entrance cable, protector panels at each end. All building-to-building circuits shall be routed through this protector.

2. Each protector shall be connected with a minimum 6-AWG, jacketed, copper bonding conductor between the protector ground lug and the local TGB unless otherwise noted on the Drawings.

3. Each protector panel shall be provided with plug-in protector modules for each pair terminated on the chassis.


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4. Protector Units shall have 110 type, 100-pair wiring blocks on both the input and output.

5. Surge protection modules shall be 5-pin (gold pins), solid state, with over current protection (min. 240V).

6. Approved manufacturers shall be Porta Systems or Circa Telecom. 10.3 INSTALLATION

A. Contractor shall provide manufacturer trained and qualified installation personnel to install all high-pair count copper cables and termination hardware.

B. Contractor shall utilize proper tools and test equipment when installing, terminating and testing cables, and wiring blocks.

C. Prior to installation, inspect cable reels or cartons for damage. Repair or replace defective cables at no cost to Cleveland Clinic as required prior to installation.

D. High-pair count copper cables shall not be placed in any raceway, compartments, outlet box, or junction box with conductors of electric light and power circuits.

E. Cables shall be installed in such a manner as to avoid kinks and other deformities.

F. The minimum-bending radius of all cables shall be carefully observed in compliance with the manufacturer’s specifications. The manufacturer's maximum pulling tension shall be strictly followed.

G. All outdoor rated inter-building cables shall transition to an indoor rated cable within fifty-feet (50’) of entering a building unless installed in conduit up to the termination point. All indoor rated cabling shall meet the restrictions of the environment in which they are installed.

H. All cables shall be installed in a single, continuous length between termination points. Splicing of any cable shall not be permitted.

I. In open vertical risers, the cables shall be secured every 3-feet using conduit straps or other approved mounting method.

J. Pathways shall be sized to accommodate a 20-foot service loop at each pull-box and/or maintenance hole and termination point. At the termination point (MC, IC and HC), the service loop shall be neatly coiled and placed on either the backboard (excluding the wall with the cooper wall-field), or the upper tier cable runway cable runway.

K. In open architecture areas, cables shall be secured every 3’ using J-hooks.

L. In the MC/IC, and HC cables shall terminate on 300-pair 110 wiring blocks. The pairs shall be broken out and numbered in sequential order on the block, left to right, top to bottom (e.g., 1-100, 101-200, 201-300, etc., depending on the number of pairs). Actual pair assignments shall be provided by Cleveland Clinic.

M. The 110 wiring blocks shall be placed in the wall field as indicated on the Drawings.

N. Contractor shall provide and install all C5 clips for the 110 wiring blocks in order to populate the block.

O. Cross-connects shall be the responsibility of the Contractor unless otherwise specified in the Contract Documents.

END OF SECTION 10.0


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11.0 HORIZONTAL CABLING 11.1 GENERAL

A. Horizontal UTP cabling shall be designed in a Star Configuration with cables originating in the HC and routing to the Telecommunications Outlets (TOs).

B. Cable jacket shall comply with Article 800 of the NEC for use as a plenum or non-plenum cable as required by these Specifications and by the local authority having jurisdiction. The four- pair UTP cable shall be UL Listed Type CMP (plenum) or CM (non-plenum).

C. For environments requiring CMP (plenum) rated cable, the cable jacket and the insulation of all individual conductors shall be constructed of plenum rated materials.

D. Cabling shall comply with the latest ANSI/TIA/EIA specifications for Category 6 and Category 6A cable, and shall be certified under the UL (Underwriters Laboratories) LAN Cable Certification Program.

E. In the HC, cables shall terminate on modular patch panels, or 110 wiring blocks as indicated on the drawings.

F. Standard voice/data cables shall be color-coded (white, green, blue and red) to match the color of the modular jacks in the TO.

G. Clinical telemetry/patient monitoring data cables shall be color coded lilac. 11.2 EQUIPMENT AND MATERIALS

A. UTP Cable

1. Category 6 UTP horizontal cables shall consist of 4-pair, 24-AWG, unshielded conductors, and shall terminate onto an 8-pin modular jack provided at each TO. Category 6 UTP shall support IEEE 802.3/1000GBASE-T data rates.

2. Category 6A UTP horizontal cables shall consist of 4-pair, 23-AWG, unshielded conductors, and shall terminate onto an 8-pin modular jack provided at each TO. Category 6A UTP shall be constructed with an aluminum/polyester tape surrounding the cable core, and shall support IEEE 802.3an/10BGBASE-T data rates.

3. Cables shall be a round cable design with fluting to maintain the appropriate pair spacing relationship. Cables shall support all current and future applications designed to run on each respective cable type. Use of a bonded pair cable shall be prohibited.

4. Voice and data cabling shall be color coded the same as the jacks. Typically, position 1 shall be white; position 2 shall be green; position 3 shall be blue and position 4 shall be red.

5. Patent Monitoring cabling and jacks shall be color coded the same as the data cabling (red and/or blue).

6. All Category 6 cable shall be specified to a minimum of 250MHz, and Category 6A shall be specified to a minimum of 500MHz.

7. Approved manufacturer: Berk-Tek Category 6 - LanMark 2000 Category 6A – LanMark XTP


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B. Wiring Blocks

1. The 110 wiring blocks shall be rated in accordance with the respective UTP horizontal cable type in use within the structured cabling system (e.g., Category 6 or Category 6A), and support the respective data rates and applications of each cable type, both current and future. 110 wiring blocks shall facilitate cross connection and interconnection using either cross connect wire or the appropriate patch cords.

2. The wiring blocks shall be fire retardant, molded plastic consisting of horizontal index strips for terminating 25 pairs of conductors each. Index strips shall be marked with five colors on the high teeth, separating the tip and ring of each pair, to establish pair location. A series of fanning strips shall be located on each side of the block for dressing the cable pairs terminated on the adjacent index strips.

3. The wiring block shall accommodate 22-AWG through 26-AWG conductors and shall be able to mount directly on wall surfaces with or without backboards or on a 24” freestanding frame.

4. Clear label holders with the appropriate colored designation strips shall be provided with the wiring blocks. The insert label shall contain vertical lines spaced based on circuit size (3, 4, or 5 pair) and shall not interfere with running, tracing or removing jumper wire/patch cords.

5. The wiring blocks shall be available in 100 and 300 pair sizes. Wiring blocks shall be available with or without legs. The legs shall allow the cables to pass behind the wiring block and fan out each side. The space created by the feet, on each side of the block, shall allow it to be used as a vertical jumper trough.

6. The wiring blocks shall capable of mounting to a wall frame or equipment rack.

7. Wiring blocks shall be equipped with connecting blocks configured for 4-pairs.

8. The wiring block shall be able to accommodate over 500 repeated insertions without incurring permanent deformation and it shall pass the reliability test of no more than one contact failure in 10,000 connections.

9. Approved manufacturers: Leviton or Ortronics

C. Modular Patch Panels

1. The modular patch panels shall be rated in accordance with the respective UTP horizontal cable type in use within the structured cabling system (e.g., Category 6 or Category 6A), and support the respective data rates and applications of each cable type, both current and future.

2. All modular patch panels shall be wired to EIA/TIA 568B.

3. Modular patch panels shall utilize IDC type connections for terminating horizontal cables, and be able to accommodate 23-AWG and/or 24-AWG cable conductors.

4. Modular patch panels shall be capable of greater than 750 insertions and 200 terminations.

5. Modular patch panels are limited to 24-port and/or 48-port configurations. 96-port patch panels shall not be permitted.

6. The modular patch panel shall be Underwriter’s Laboratories (UL) listed, and ETL certified. All modular patch panels shall be UL listed Category 6 or Category 6A

7. Approved manufacturers: Leviton or Ortronics


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D. Patch Cables

1. Patch cables shall be RJ45-to-RJ45 type for data connections, 110-to-RJ45 type for voice connections, and 110-to-110 for legacy voice/data connections.

2. Patch cables shall be rated in accordance with the respective UTP horizontal cable type in use within the structured cabling system (e.g., Category 6 or Category 6A), and support the respective data rates and applications of each cable type, both current and future shall be Patch Cables shall be 4-pair UTP, and shall be wired to EIA/TIA 568B. Patch cables shall be color coded to match the respective horizontal cable color or application.

3. The Contractor shall furnish, label and install a quantity of patch cables equal to 100% of the red horizontal cables, 40% of the blue horizontal cables and 100% of the white cable, and 100% of the patient monitoring lilac cables.

4. Contractor shall complete patching matrix forms for each TR. Forms shall be created in MS-Excel format, and submitted to the Owner within 5 business days of completing the patching. Owner shall provide the patching matrix form.

5. Patch cables shall be provided in equal quantities of 2m and 3m lengths for each color.

6. Approved manufacturers: Data RJ45-to-RJ45 - Ortronics or Leviton Voice 110-to-RJ45 – Quicktron 591-125-###

E. Coaxial Drop Cable and Connectors

1. Coaxial drop cables shall be RG6/u (plenum and non-plenum).

2. Non-plenum rated cables shall be of quad shield construction with the dielectric material covered by a bonded tape, 60% braid, non-bonded tape, 40% braid, and PVC jacket.

3. Plenum rated cables shall be constructed of a foam FEP dielectric, bonded tape, 60% braid, non-bonded tape, 40% braid, and a plenum rated Kynar jacket.

4. Provide 75 Ohm, solder less coaxial cable connectors.

5. Provide 1m RG-6/u work area cable for each television connection.

6. Approved manufacturers: RG-6/u Cable– CommScope RG-6/u Connector – Gilbert #

11.3 INSTALLATION

A. General

1. Contractor shall provide manufacturer trained and qualified installation personnel to install all horizontal cables and termination hardware.

2. Contractor shall utilize proper tools and test equipment when installing, terminating and testing horizontal cables, and termination points.

3. Prior to installation, inspect cable reels or cartons for damage. Repair or replace defective cables at no cost to Cleveland Clinic as required prior to installation.

4. No horizontal cables, regardless of media type, shall exceed 90 m (295 ft.) from the Telecommunications Outlet in the Work Area to the Horizontal Cross Connect.

5. The combined length of jumpers, patch cords and equipment cables in the HC and the Work Area shall not exceed 10m (33 ft.).


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6. Contractor shall minimize the amount of UTP cable jacket (< 1-inch) removed at each termination point (TO, HC and CP).

B. Cable Routing

1. Horizontal cables shall not be placed in any raceway, compartments, outlet box, or junction box with conductors of electric light and power circuits.

2. Horizontal cables shall be installed in a single continuous run between the HC and the TO. Splicing of a cable shall not be permitted.

3. From the point of entry into the HC, the cables shall be separated by color, and routed to their respective termination points.

4. Cables shall be properly protected from damage from any sharp edges when entering and exiting the cable tray.

5. Contractor shall ensure horizontal UTP cables are placed and terminated in such a manner as to avoid kinks and other deformities.

6. Broadband coaxial cables, A/V cables, Security System cables and Building Automation/Control cables shall not be installed in cable tray systems designated for voice/data cabling. Broadband coaxial cables, A/V cables, Security System cables and Building Automation/Control cables shall be installed in other approved pathway systems.

7. Where Contractor is required to install non-continuous pathways, Contractor shall keep hallway crossover to a minimum. Furthermore, non-continuous pathways shall be routed to follow logical paths parallel and perpendicular to the building structure.

8. Where duct, cable trays or conduit are not available, the Contractor shall bundle, in bundles of 50 cables or less, horizontal cabling with Velcro snug, but not deforming the cable geometry. Where cable bundles are to be supported by J-hooks, the J-hooks shall be attached to the building structure and framework per local codes and regulations at a maximum of five (5) foot intervals.

9. Cable ties and other methods of binding cabling shall not be installed in such a fashion to as to bend, crimp or deform the cabling in any way to alter the electrical or transmission characteristics of the cabling.

10. Telecommunications Pathways, spaces and metallic raceways, which run parallel with electric power or lighting cables or conduits, which is less than or equal to 480 Vrms, shall be installed with a minimum clearance of 50 mm (2 inches).

11. The installation of cabling shall maintain a minimum clearance of 3 m (10 ft.) from power cables or conduits in excess of 480 Vrms.

12. No telecommunications cross connects shall be physically located within 6 m (20 ft.) of electrical distribution panels, or step down transformers, which carry voltages in excess of 480 Vrms.

13. The Contractor shall provide all devices for routing the cabling as indicated on the Drawings, and as required by the manufacturer, to maintain the long-term health and operability of the cabling.

14. The number of horizontal cables placed in a cable support or pathway shall be limited to the manufacturer’s stated capacity, or TIA/EIA 569-B cable fill guidelines.

15. Horizontal cables shall not be exposed in the Work Area or other locations with public access, unless otherwise noted on Drawings.


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16. Cables routed in a suspended ceiling shall not be draped across the ceiling tiles. Cable supports shall be mounted a minimum of 75 mm (3 inches) above the ceiling grid supporting the tiles.

17. Where cable tray is installed and usable, Contractor shall route the cable from the Telecommunications Outlet to the nearest available cable tray. From the conduit stub or “wall fish” to the tray, the Contractor shall install additional cable support apparatus as necessary to properly support the cables.

18. Cabling shall maintain clearance from Line Voltage cabling and devices at all times, and shall be spaced from these devices to comply with the TDMM, the NEC, and any other local codes or regulations.

19. When working around existing cabling, the Contractor will take extra precautions to ensure that existing services are not disrupted in any way.

20. Cables shall not be attached to or supported by fire sprinkler heads or delivery systems or any environmental sensor located in the ceiling space.

21. Prior to the point of entry into the TR, cables shall be separated by color and routed via the cable tray or runway to the their respective termination point. The cable bundles (by color) shall be maintained on the wall field or rack, and into the 110 wiring blocks or modular patch panels.

C. Pulling Tension

1. The maximum pulling tension for all cables shall not exceed the respective manufacturer’s specifications, or the limits as published in current edition of the TDMM.

D. Bending Radius

1. Horizontal pathways shall be installed such that the minimum bending radius of the horizontal cables is kept within manufacturer specifications both during and after installation.

2. The Contractor shall adhere to the manufacturer’s requirements and as indicated in the TDMM for bending radius and pulling tension of all data and voice cables. Where the manufacturer’s specifications differ from those cited in the TDMM, the Contractor shall abide by the greater bending radius and the lesser pulling tension.

3. The minimum bending radius for any cable shall not exceed the respective manufacturer’s specifications.

4. In spaces with cable terminations, the bending radius for all 4-pair cables shall not exceed four times (4x) the outside diameter of the cable and ten times (10x) the outside diameter of a larger high pair count cable, unless this violates the manufacturer’s specifications.

5. During the actual installation, the bending radius of a 4-pair cable shall not exceed eight times (8x) the outside diameter of the cable and ten times (10x) the outside diameter of a larger high pair count cable, unless this violates the manufacturer’s specifications.

E. Slack

1. In the Work Area, a minimum of 1m (3’) shall be left for UTP and fiber cables. The slack shall be coiled and tie-wrapped in the ceiling above the faceplate.

2. In TRs, a minimum of 1.5m (5’) of slack shall be left for all horizontal cables. This slack shall be neatly managed on cable trays, cable runways, or other approved means of support.

F. Special Requirements for Cable Routing and Installation


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1. All cabling shall comply with the requirements as outlined in the National Electrical Code Articles 725, 760, 770, and 800 and the appropriate local codes. All cabling shall bear CMP (plenum rated), CM/CMR (riser rated) and/or appropriate markings for the environment in which they are installed.

2. The Contractor shall be responsible for the determination of the necessity of limited combustible cable, plenum cable, and/or non-plenum cable, and shall be aware of any local codes regarding the use of these cable types.

3. Cables shall terminate on the patch panels in sequential order based on Cleveland Clinic’s Standard TO numbering scheme. There will be no gaps or open termination points on the patch panels, even if a gap exists in the room numbering system.

4. On the wall field, the cables shall be neatly bundled and held in place with D-rings attached to the plywood backboard. D-rings shall be installed every 6-inches, and cable bundles shall be attached to the D-rings using Velcro cable ties. In addition, cable bundles shall be tie-wrapped with Velcro ties between D-rings. Cables shall be neatly routed into their respective wiring block bay.

5. At each TO location, pathways will be sized to accommodate a neatly coiled, 3-foot loop of UTP cable above the ceiling at the top of the conduit stub, power pole and/or “wall fish”. In raised floor and thru-floor environments, the cable loop shall be placed beneath floor near where the cable enters the modular furniture or floor box.

6. Cable ties shall conform to the environment in which they are installed (i.e., plenum rated cable ties in plenum ceilings, etc.). Cable ties shall be attached so as not to crimp or kink the cables. Cables should move freely within the tie-wrapped bundle.

G. Wireless Devices

1. Contractor shall furnish and install two Horizontal cables to each faceplate designated as wireless on the Construction Drawings. Contractor shall coil 25-feet of slack (red and blue cables) at each wireless TO location.

2. The wireless site survey design performed by others will determine the final location of the wireless TO and normally averages one (1) each wireless TO for every 1,100 square feet. Contractor shall relocate as necessary each wireless TO as shown on the wireless survey design drawing(s).

3. Contractor shall leave the amount of slack to 25’ once the wireless TO is installed in the final location.

END OF SECTION 11.0


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12.0 WORK AREA 12.1 GENERAL

A. The Work Area consists of the Telecommunications Outlet (TO) terminated on the end of the horizontal cable and provides modular connectivity to a single point device.

B. Contractor shall provide all connecting hardware and install TOs as indicated on the Drawings.

C. Contractor shall install all wireless access points as shown on the Drawings and the site survey design Drawings. The wireless site survey shall be performed by others under a separate contract.

D. Modular jacks shall be compliant with ANSI/TIA/EIA 568-B standards including the most recent release, revisions and addendum.

E. Data and voice line cords shall be provided by Cleveland Clinic unless otherwise noted in the Specifications or Drawings.

F. All modular jacks shall be color coded as indicated below in Table 12-A.

TO Type Drawing

Designation Jacks Faceplate Pos. 1 Pos. 2 Pos. 3 Pos. 4

Wall Phone W 1 Simplex White N/A N/A N/A

Emergency Phone RAV 1 Simplex White N/A N/A N/A

Voice Only A1 1 Simplex White N/A N/A N/A

Video 1 A2 2 Duplex White Coax N/A N/A

Video 2 A3 2 Duplex White White N/A N/A

Dual Data H 2 Duplex Blue Red N/A N/A

Single G 1 Simplex Red N/A N/A N/A

Duplex B 2 Duplex White N/A N/A Red

Triplex C 3 Triplex White N/A Blue Red

Quad D 4 Quad White Green Blue Red

Multimedia S See Note 1

1. Multimedia outlets are project specific and may contain multiple copper, fiber and coaxial cables. If multiple types of multimedia TO’s are required in a project, a sub-numbering scheme shall be devised to distinguish between different configurations (e.g., S1, S2, S3, etc.)

Table 12-A: Telecommunications Outlet Configurations and Color Code


A. Faceplates

1. Contractor shall provide all faceplates, including blank cover plates.

2. All Faceplates shall be available in single, duplex, triplex, quadplex, or sixplex arrangements in a single gang configuration.

3. Blank inserts shall be used to fill empty jack openings on the faceplate.


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4. Contractor shall coordinate faceplate type and color with the Architect and/or Cleveland Clinic.

5. Faceplates installed in ICU and CCU areas shall be stainless steel.

6. Approved manufacturer: Ortronics TracJack Series (Color 88 unless otherwise specified) Leviton Extreme Series (Color White)

B. Outlets

1. All modular outlets shall meet or exceed Category 6 or Category 6A transmission requirements for connecting hardware, as specified in the most recent revisions of TIA/EIA 568, and related addenda, regarding the Commercial Building Telecommunications Cabling Standard, Horizontal Cable Section, and have readily available numeric test results from ETL for passive model testing and TOLLY for active model testing.

2. All modular outlets shall be capable of being installed flush in any modular faceplate, frame, or surface mounted box provided by the approved manufacturer.

3. Modular outlets shall be capable of greater than 750 insertions and 200 terminations.

4. Modular outlet jacks shall be capable of terminating 23/24 AWG UTP cable, and shall be equipped with IDC type contacts.

5. Modular outlets shall be designed with an integral locking mechanism, which, upon insertion of a modular plug, provides maximum pull out strength at the plug/jack interface.

6. Modular outlets shall be compliant with ANSI/TIA/EIA 568-B standards including the most recent release, revisions and addendum.

7. Approved manufacturer: Cat6 - Leviton Extreme or Ortronics Clarity6 Series Cat6A – Leviton Atlas

C. Video Faceplate

1. Video faceplate shall be constructed of a duplex faceplate (minimum), with either one Category 6 or 6a white jack and one 75-ohm coaxial connection or two Category 6 or 6a white jacks.

2. The video faceplate shall be placed wherever a television is to be located (e.g., inpatient room, waiting area, infusion bays, post op, etc.)

D. Wall Phone Faceplate (Non-VoIP)

1. For analog or TDM digital handsets, faceplate shall be capable of terminating up to 6-conductors onto screw type terminals, and shall be compliant with USOC wiring standard.

2. For VoIP handsets, faceplate shall be 8-conductor termination onto a standard Category 6 or Category 6A jack.

3. Faceplate shall be equipped with mounting lugs for wall-mounted telephone sets, and shall be UL certified.

4. Faceplate shall be constructed of a stainless steel plate that resists scratching, cleaning solutions and corrosive atmospheres.

5. Approved manufacturers: Suttle 630AD6 (non-VoIP applications) Leviton or Ortronics (VoIP applications)


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E. Work Area Cables

1. Furnish two (2) Category 6 or Category 6A work area cables for each wireless TO. All other work area cables shall be provided by others.

2. Work area cables shall be RJ45-to-RJ45, and shall not be less than 3’ or longer than 5’. Excess cable shall be neatly coiled at the faceplate.

3. Work area cables shall support up to Category 6A data rates and applications, and color coded to match the respective horizontal cable color code.

4. Approved manufacturer: Leviton Atlas. 12.3 INSTALLATION

A. General

1. Drawings detail the relative locations of each TO. Contractor shall verify with Architect and/or Cleveland Clinic the precise location of each TO prior to installation. Contractor shall be required to re-verify that the UTP cable length of 90-meters is not exceeded for each TO location that changes by more than 2-meters from that shown on the Drawings.

2. Unless otherwise noted on the Drawings, wall phone faceplates shall be mounted on center at 48” AFF, time clock faceplates shall be mounted on center at 48” AFF.

3. Wall phone faceplates shall have 12-inches of clearance on all sides from any type of interfering wall, door jam, signage or other apparatus or structure.

4. Contractor shall verify ADA (Americans with Disabilities Act) requirements for each faceplate by location type.

5. For renovation and retrofit cabling projects, Contractor shall place new wall phone faceplates at same height as existing faceplates, and as close to the existing faceplate location as possible.

6. Contractor shall be responsible to determine connection requirements for emergency phones, pay phones and ATM machines in renovation or retrofit projects. If the device currently utilizes a faceplate with jack as the connection, then Contractor shall place the new faceplate at the same height as the existing faceplate, and as close to the existing faceplate as possible. If the connection is hardwired, Contractor is not responsible to make the connection. For hardwired devices, the Contractor shall install the cable and coil it in the drop ceiling above the device, leaving enough slack to drop down to the device. The Cleveland Clinic will be responsible to make hardwired connections.

7. For adjacent Work Area spaces separated by a full wall (does not include modular furniture or half walls), back-to-back faceplate installations shall be prohibited. Faceplates in adjacent Work Areas must be installed between separate wall-stud zones as shown in Figure 2.


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Figure 5: Faceplate Installations between Adjacent Work Areas

B. Wireless Access Points (WAP)

1. Owner shall be responsible to perform a wireless site survey and design via a separate consulting contract. The wireless site survey and design Drawings shall determine the final placement of each WAP.

2. All WAPs shall be powered via the Horizontal cabling (POE). Separate 110vac power will not be required.

3. Contractor shall install all WAPs in accordance with the wireless site survey and design drawings. Any change in quantity (add or delete) from the Construction Documents to the site survey design shall be governed by the unit price schedule submitted with Contractor’s bid.

4. WAPs shall be purchased, staged and labeled by the Owner. Owner shall release WAPs to Contractor for installation. Upon receipt, Contractor shall accept all responsibility for securing and installing the WAPs.

5. Contractor shall mount each WAP using the mounting kits provided. Contractor shall supplement the mounting kit with additional mounting hardware as needed to ensure each WAP is properly and securely mounted.

6. WAPs shall be installed below lay-in and fixed ceilings, unless approved by Cleveland Clinic ITD.

7. Contractor shall furnish two (2) work area cables (1 Red and 1 Blue) for each WAP. Contractor shall use the work area cables to connect the WAP to the designated TO (red and blue cables to red and blue jacks respectively).

8. Contractor shall provide on-site technical assistance during final testing of the WAPs.

END OF SECTION 12.0


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13.0 CABLING SYSTEM ADMINISTRATION 13.1 GENERAL

A. Contractor shall accurately label all cables, faceplates, cabling enclosures, patch panels, connector housings, wiring blocks, equipment enclosures and racks, and related hardware. Refer to Appendix B for additional information.

B. All labels shall be permanently attached, and shall be constructed of materials to assure the lifespan of the identification marker to be equal or greater than that of the device being identified.

C. The identification tag or placard shall be self-adhering or attached by means of a permanent adhesive listed for the application, or other permanent mechanical means.

D. All means of identification shall be visible and clearly identifiable by personnel in charge of maintaining the cabling infrastructure.

E. All labels shall be machine generated onto adhesive labels or tags, or engraved on plastic laminated placards. Use of “P Touch” tape or other domestic/light duty type of label shall be prohibited.

F. Several of the numbering schemes described in this Specification include Cleveland Clinic’s Standard Room Number (SRN). The room numbers shown on the Drawings may or may not reflect the actual SRN for each respective room. Contractor shall be responsible to verify the SRN information prior to labeling any cables, wiring blocks, patch panels or faceplates.


A. Tape Based Labels

1. All tape-based products shall be manufactured for identifying flexible communications cabling.

B. Placards

1. All placards shall be constructed of a laminated polyvinyl process, and shall be engraved.

2. All placards shall be black with white letters unless otherwise noted. 13.3 INSTALLATION

A. Faceplate

1. All faceplates shall be labeled as indicated on the Drawings. Contractor shall provide and install a machine-printed label with the correct TO number and Technology Room SRN.

2. Each faceplate shall have four labels:

(a Upper left corner - TO Number (b Top window - TO Number (c Upper right corner – TR Number and SRN (d Bottom window - TR Number and SRN

3. Faceplate labels shall be 1” W x 0.25” H


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4. Font size for the labels shall be a minimum of 11pt.

5. Labels shall be affixed on the beveled portion at the top of the faceplate as well as the windows.

6. All faceplate labels shall be machine-printed with black lettering onto a white or clear adhesive backed label.

7. All faceplates installed above the ceiling must be identified with a purple circular label affixed to the ceiling grid immediately below the faceplate.

B. Horizontal UTP Cable

1. Label all horizontal UTP cables at both ends (at the TO and the HC wiring block or patch-panel) with the respective faceplate number.

2. All labeling shall be machine printed on adhesive type labels designed for use on communications cables, and shall remain in place through normal use.

3. Cable labels shall be wrap around type, and shall be placed on the cable jacket approximately 2-inches from the point of termination.

C. Horizontal Wiring Block

1. All 110 wiring blocks used to terminate horizontal cables shall be labeled with the appropriate color-coded designation strips (white, green, blue or red).

2. Contractor shall label each 110-wiring block, 8-wire position with the respective faceplate number in sequential order.

3. All 110 wiring block designation strips shall be machine-printed and attached to the 110 wiring blocks in the space provided.

4. The designation strips shall be protected with the plastic holder specifically designed for use with 110 blocks.

D. High Pair Count Copper Cable Wiring Block

1. All 110 wiring blocks used to terminate high pair count copper cables shall be labeled with the appropriate color-coded designation strips. Inter-building (MC to IC) backbone cables shall use white designation strips and intra-building (MC/IC to HC) shall use gray designation strips.

2. Copper pairs shall be labeled on each end with corresponding numbers. Blocks shall be labeled left-to-right/top-to-bottom in numerical sequence. Pair numbers shall be provided by Cleveland Clinic.

3. All 110 wiring block designation strips shall be machine-printed and attached to the 110 wiring blocks in the space provided.

4. The designation strips shall be protected with the plastic holder specifically designed for use with 110 blocks.

E. Patch Panel

1. All patch panels shall be labeled with the respective color-coded designation (white, green, blue or red). The label shall be a laminated placard that shall be placed in the upper right corner of the patch panel. Contractor shall ensure that the position of the placard shall not interfere with the installation or removal of the patch panel.


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2. The Contractor shall label each patch panel position with the respective faceplate number in sequential order. The label shall be installed in the space provided by the manufacturer for this purpose.

F. High Pair Count Copper Cable

1. The jacket of each high pair count copper cable shall be labeled immediately above the respective termination block so the cable can be easily identified.

2. Each cable shall be labeled on both ends (MC or IC and HC).

3. Cable labels shall be wrap-around type.

4. Label shall identify the cable source, cable destination and cable number.

G. Fiber Connector Housing

1. Each fiber connector housing shall be labeled on the outside cover (upper left corner) as either “MULTIMODE FIBER OPTIC CABLE” or “SINGLEMODE FIBER OPTIC CABLE”, and shall include the cable length and strand count. The label size shall be 1” H x 2” W with a minimum font size of 18pt.

2. Each closet connector housing shall have a “CAUTION FIBER OPTIC CABLE” label placed in the upper right corner.

3. Contractor shall label the connector housing using the strand identification chart provided by the manufacturer. A separate chart shall be generated for each connector housing. An electronic copy (in MS Word or Excel format) of each chart shall be submitted with the Contractors as-built documentation in the Service Manual.

H. Fiber Optic Cable

1. All fiber optic cabling and innerduct that is exposed (not installed in conduit) within ceiling space, risers, equipment rooms, technology rooms, maintenance holes, pull boxes, etc., shall be identified with a pre-printed tag stating, “WARNING FIBER OPTIC CABLE”. Tags shall be placed every 20-feet along the cable route. All tags shall be readily visible by any personnel working in the area.

2. The jacket of each fiber optic cable shall be labeled outside of the connector housing. The label shall be placed so that it can so the cable can be easily identified. The label shall be wrap-around type.

3. Label shall identify the cable source, cable destination and cable number.

I. Equipment Racks

1. Each equipment rack shall be labeled using engraved tags. Engraved tags shall be a 1”H x 2”L with 1/2” lettering and shall be white in color with black lettering.

2. Engraved tags shall identify the Technology Room identification or SRN, and the rack number.

3. The tags shall be mounted on the front, top center of the outside of the rack.

J. Grounding System

1. All bonding conductors related to the telecommunications and other low voltage equipment shall be labeled at both ends within 2” of the end of the outer sheaths.

2. The label shall be pre-printed or machine generated, permanently self-adhering or adhered by means of clear shrink tubing, and shall be clearly legible.


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3. Labels shall indicate length (from TMGB), source (room no.) and destination (room no.) of the bonding conductor, the source being the device or equipment closest to the TMGB. Labels shall be white with black letters.

4. All busbars shall be identified with a permanent laminate placard. The identification placard shall be permanently mounted directly above the busbar at a distance no greater than 6” above the top edge of the busbar. The placard shall be 2 ½” by 5”, with white letters on a green field stating:

“WARNING: TECHNOLOGY GROUND BUS BAR FOR DATA, VOICE AND LOW VOLTAGE EQUIPMENT ONLY. DO NOT USE AS AN ELECTRICAL OR MECHANICAL SYSTEMS GROUND. IF CONNECTORS OR CABLES SHOW SIGNS OF BECOMING LOOSE, OR REQUIRE REMOVAL, CONTACT CLEVELAND CLINIC INFORMATION TECHNOLOGY DIVISION”

K. Pull Boxes

1. All pull-boxes shall be labeled by the Contractor both internal to the pull-box, and visibly on the cover plate with laminated placards.

2. The identification shall be derived from the room or corridor number and a sequential letter, and shall be identified with the word “TELECOMMUNICATIONS”. For example, PB113-02, where 113 is the corridor number and 02 indicates that it is the second pull-box in that corridor.

L. Conduits and Boxes

1. All conduits, with the exception of those installed for work area outlets, shall be tagged by means of a brass tag permanently affixed to the conduit at each end. The tag shall indicate the source Telecommunications Space on the first line, and the final destination Telecommunications Space on the last line. If the conduit route utilizes pull-boxes, the tag shall also include the ID of the next pull-box in the route, engraved on the second line of the tag.

2. Backboxes used for work area outlets shall have the locations of the stub legibly written in permanent magic marker inside the backbox.

3. Conduit stubs for work area outlets not contained within the same room as the backbox it serves, shall be legibly marked by means of a permanent marker on the exterior of the stub as to the location of the backbox.

END OF SECTION 13.0


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14.0 TESTING 14.1 GENERAL

A. All testing shall conform to the latest release of ANSI/TIA/EIA 568-B, the manufacturer’s warranty criteria, and Cleveland Clinic’s acceptance criteria. Contractor shall be responsible to repair or replace any cable that does not meet Specification at no additional cost to Cleveland Clinic.

B. Contractor shall review every test report for accuracy, completeness and conformance to the Specifications.

C. After delivery of Materials to the Site, and prior to installation, all cables, cable reels and shipping cartons shall be visually inspected to detect possible damage incurred during the shipping and transport. Visibly damaged goods should be immediately reported to the vendor and returned for replacement.

D. All test results shall be documented and submitted in hard copy (summary only) and electronic (softcopy) format with the as-built documentation.

E. Contractor shall provide unaltered electronic test results submitted in the original software format of the respective test equipment manufacturer. Text files or files that have been imported into a word processor or other text editor application shall not be acceptable.

F. Cleveland Clinic retains the right to be present at any or all testing. Contractor shall provide written notice 48 hours prior to the beginning of the testing process.

G. Independent 3rd party system testing may be required, at the discretion of Cleveland Clinic in the event of non-performance of the specified testing procedures, submittals and/or installation procedures. The extent and logistics of the independent testing shall be arranged by Cleveland Clinic. All costs associated with the testing shall be the responsibility of the Contractor.

H. Cleveland Clinic reserves the right to mandate re-termination or other reasonable rework to improve the performance of any cable indicated as “fail or “marginal pass”.

I. All cables shall pass testing before Owner acceptance of the cables. 14.2 FIBER OPTIC CABLE TESTS

A. Pre-installation Test

1. Contractor shall be responsible to pre-installation test all fiber optic cables. Tests shall be performed while the cable is on the spool.

2. Contractor shall submit test plan that shall include procedure and acceptance criteria for meeting this requirement.

3. Contractor shall replace the entire cable spool should any strand fail to meet the acceptance criteria. Replacing the cable shall not relieve Contractor of meeting project deadlines and milestones.

4. Contractor shall provide Cleveland Clinic with written notification as to the results of the pre-installation testing within five (5) business days of completing the tests.

B. Optical Power Test


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1. Each strand of each fiber optic cable (backbone and horizontal) shall be tested to verify the optical loss performance.

2. Contractor shall perform optical power tests in both directions for each level of the backbone fiber optic cable (MC to MC, MC to IC and MC/IC to HC).

3. Each multimode fiber strand shall be tested at 850nm and 1300nm. Each singlemode fiber strand shall be tested at 1310nm and 1550nm.

4. All optical power meter tests shall be performed using a stable light source.

5. Contractor shall use the test equipment manufacturer’s standard form. Test data shall include the following information:

a) Project b) Origination Bldg./TR c) Destination Bldg./TR d) Cable Manufacturer e) Cable Part Number f) Cable Type (e.g., Multimode or Singlemode) g) Cable Construction (e.g., Tight Buffered, Loose Tube or Ribbon) h) Jacket Rating (e.g., OFNR, OFNP, etc.) i) Connector Type j) Transmit Level k) Wavelength l) Origin Panel/Port Number m) Destination Panel/Port Number n) Strand Color o) Receive Level p) Link Loss

6. The total allowable link loss shall be based on the calculations shown below. For calculation purposes, a cable segment is based on an individual strand of multimode or singlemode fiber strand terminated on each end with a fiber connector, excluding patch cables. These calculations shall be used as the Acceptance Criteria for the backbone cable.

a) Multimode Fiber Link Loss Calculation

(MMCl X Fl) + (FCTl x FCt) = Lt

Where: MMCl is the actual installed length of the multimode fiber optic cable in meters,

Fl is the fiber loss at either 850nm or 1310nm for multimode fiber, FCl is the typical loss of a single multimode Fiber Connector, FCt is the total loss of connectors in the link (do not include patch cables), Lt is the total link loss for a specific multimode, fiber optic cable segment.

b) Singlemode Fiber Link Loss Calculations

(SMCl X Fl) + (STl x STt) = Lt

Where: SMCl is the actual installed length of the fiber optic cable in meters,

Fl is the fiber loss at either 1310nm or 1550nm for 8.3/125, singlemode fiber, FCl is the typical loss of a single singlemode Fiber Connector assembly, FCt is the total loss of connector assemblies in the link (do not include patch cables), Lt is the total link loss for a specific singlemode, fiber optic cable segment.


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C. OTDR

1. Contractor shall perform OTDR (Optical Time Domain Reflectometer) testing in the outbound direction only for each level of the backbone fiber optic cable (MC to MC, MC to IC, and MC/IC to HC). The purpose of the OTDR tests shall verify the length of each strand, and the optical integrity of each fiber (e.g., opens, terminations, loss/km, micro-bends, etc.).

2. Contractor shall ensure that the launch cable used during the OTDR tests conforms to the OTDR manufacturer’s specifications.

3. Contractor shall also ensure that the refractive index parameter is set to equal that of the fiber manufacturer’s specifications.

4. All results shall be documented and provided in Contractor’s standard format.

D. Return Loss (Reflectance)Test

1. Contractor shall perform return loss (reflectance) tests on each singlemode fiber strand in both directions for each level of backbone fiber optic cable (MC to MC, MC to IC and MC/IC to HC).

2. The minimum acceptable return loss (reflectance) shall be -58dB.

3. Any singlemode cable/connector assemble failing to meet the acceptance criteria shall be repaired or replaced by the Contractor at no additional cost to Cleveland Clinic.

E. Acceptance

1. Each strand shall pass testing before Owner acceptance of the cables.

2. Any multimode strand and/or connector failing to meet the acceptance criteria shall be repaired or replaced by the Contractor at no additional cost to Cleveland Clinic.

3. Any singlemode strand and/or connector assemble failing to meet the acceptance criteria shall be repaired or replaced by the Contractor at no additional cost to Cleveland Clinic.

4. In the event a multimode and/or singlemode strand does not pass one of the tests described above, the Contractor shall repair the defect or replace the entire cable at no cost to the Cleveland Clinic.

14.3 UTP CABLE TESTS

A. Upon completion of UTP cable installation, Contractor shall perform complete certification tests on every cable.

B. Testing shall be performed to published standards, including but not limited to, the latest revisions of EIA/TIA 568, ISO/IEC 11802 and all other applicable standards at the time of installation.

C. All tests shall be performed with a certified Level IIe or III UTP test device. Certified test equipment as manufactured by Fluke shall be acceptable. Contractor shall utilize the latest model/software revision for all testing. Cleveland Clinic shall approve the use of alternate test equipment. All costs associated with calibrating test units shall be Contractor’s responsibility.

D. All UTP field testers shall be factory calibrated every 12 months by the respective manufacturer. The calibration certificate shall be provided to Cleveland Clinic for review prior to the start of testing.


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E. New test leads and/or calibration of testing instruments shall be provided at the beginning of each project.

F. For any given project, the Contractor must use the same test equipment (manufacturer and model) for all UTP cable tests. Mixing of different manufacturer’s test equipment shall not be permitted.

G. All test equipment shall be operating under the latest version of firmware/software as provided by the manufacturer. Contractor shall be responsible for all costs associated with test equipment firmware/software upgrades.

H. Prior to testing, Contractor shall perform the following setup procedures on the test equipment.

1. Enter all relevant project data into the test equipment, including technician/operator name, date of test, project name, building, floor, TO number and jack position number, etc.

2. Enter appropriate cable manufacturer, manufacturer’s model number and electrical parameters of the cable, including nominal velocity of propagation.

3. Calibrate the scanner to the injector.

4. Setup the test equipment to fully test for all of the parameters listed below.

I. All UTP cable tests shall be performed by connecting an injector to the respective jack and the scanner to the respective 110-wiring block or patch panel.

J. A Permanent Link test, as described in the ANSI/TIA/EIA 568-B standards (including most recent additions and addendum) is required for all UTP testing. At a minimum, each UTP cable shall be tested for the following parameters.

1. Pair-to-Pair NEXT (Near End Cross Talk) 2. Power Sum NEXT 3. Pair-to-Pair ELFEXT (Equal Level Far End Cross Talk) 4. Power Sum ELFEXT 5. Attenuation (Insertion Loss) 6. Return Loss 7. Propagation/Delay Skew 8. Cable length 9. Wire map

K. All UTP cable tests shall be performed by connecting an injector to the respective jack and the scanner to the respective 110-wiring block or patch panel.

L. Contractor shall verify that the TO number matches the number on the 110 wiring block or patch panel.

M. Contractor shall troubleshoot and correct, repair or replace each cable that does not meet Specification.

N. A test result marked with an “*” will not be accepted.

O. A test summary and each individual UTP cable test shall be included as part of Contractor’s as-built documentation submittal. Only the Test Summary Sheet shall be printed, and submitted in hardcopy format. The individual UTP cable tests shall be submitted in electronic format only. The Test Summary Sheet for each Technology Room shall be signed and dated by Contractor’s Project Manager. Contractor shall submit all cable test results in electronic form on a flash drive. The electronic test results must be submitted in the original software format of the respective test equipment manufacturer. Text files or files that have been imported into a word processor will not be accepted.


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14.4 BACKBONE COPPER HIGH PAIR COUNT CABLE TESTS

A. Contractor shall test all high pair count copper cables in order to verify continuity and wire map of the cables.

B. Each cable pair shall be tested for shorts, opens, crosses, splits and reversed polarity. All testing shall be performed using an Owner approved tester.

C. For the backbone cable only, the total number of failed pairs shall not exceed 1% (one percent) for each cable segment.

D. Contractor shall troubleshoot and correct, repair or replace each cable that does not meet Specification.

END OF SECTION 14.0


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15.0 AS-BUILT DOCUMENTATION 15.1 GENERAL

A. Contractor shall submit to Cleveland Clinic as a condition of final payment and acceptance all as-built documentation as required in these Specifications.

B. Copies of the Contractor’s red-lined drawings showing handwritten changes and TO numbers shall be submitted to the Cleveland Clinic immediately upon completion of testing.

C. All final documentation and record drawings shall be submitted within 10 business days of completion of all Work.

D. All documentation shall be submitted in hard copy and/or soft copy format depending on the type of documentation. Soft copy shall be submitted on a flash drive, readable in MS-Windows.

E. Contractor is required to submit all as-built documentation in person and review it with Cleveland Clinic during the Project Closeout Meeting.

15.2 LOW VOLTAGE CABLING SYSTEM DOCUMENTATION

A. Documentation requirements for the Low Voltage Cabling System shall include the following information. Contractor shall electronically organize the documentation into folders for each section as follows:

1. Backbone & Horizontal Fiber Test Results

a) Backbone Fiber - Summary of testing and Power Meter Test Sheets b) Backbone Fiber – Summary of testing and OTDR Traces c) Horizontal Fiber – Summary of testing and Power Meter Test Sheet d) Horizontal Fiber – Summary of testing and OTDR Traces

2. UTP Horizontal Cable Tests

a) Summary b) Individual Cable Detail Sheets

3. ID Charts

a) Backbone Fiber Strand ID Charts b) Horizontal Fiber Strand ID Charts c) UTP Wiring Block ID Charts or Patch Panel Charts

4. Record Drawings

a) Floor Plans showing TO locations and their respective faceplate number b) All Technology Room and Rack Layout Drawings c) All schematic detail drawings

5. Manufacturer’s Specifications and Project Specific Warranties (Hard copies are acceptable when furnished by manufacturer.)


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15.3 RECORD DRAWINGS

A. Contractor shall modify the design drawings to reflect all conditions of the low voltage cabling systems, including but not limited to backbone and horizontal cabling, TO numbers, cable tray locations, floor core locations, wall sleeve locations, equipment rack and wallboard layouts, etc.

B. Contractor shall provide soft copy of all as-built drawings in AutoCAD format (.dwg) and portable document format (PDF).

C. Contractor shall add all revision information in the appropriate title block space. All drafting will be two-dimensional and scaled as appropriate and clearly perceptible.

D. Contractor shall be responsible to obtain all of the electronic AutoCAD files from the Architect and/or Engineer. Contractor shall be responsible for all costs associated with obtaining the files.

E. “X References” or XREF clipping will not be used. Match Lines will be provided detailing the adjacent drawing number as required. Details or other drawing entities will be provided as blocks rather than bound to the drawing file.

F. All text fonts will be the original typeface and sized for clarity (notes, dimensions, etc.) to help distinguish annotations for the drawing. Text sizing will be dependent on drawing scales, but will be consistent throughout the individual site.

15.4 FIBER STRAND ID CHARTS

A. A separate fiber strand ID chart shall be generated for each backbone and horizontal closet connector housing in the MC, IC and HC.

B. Contractor shall follow the same format as the strand ID charts provided in each closet connector housing and as shown elsewhere in the Specifications.

C. Contractor shall provide a copy of these charts electronically in either MS Word or MS Excel format.

15.5 UTP - 110 PATCH BLOCK ID CHART

A. A separate UTP wiring block ID chart shall be generated for each HC 110 wiring block. The chart shall represent the physical layout of the 110 wiring blocks and shall identify the TO number, cable length, and the cable’s destination.

B. General data such as Project Name, Date of Installation and Technology Room Location/Designation shall be included on the chart. Unused ports on the chart shall be left blank for future use.


15.6 UTP - PATCH PANEL ID CHART

A. A separate UTP patch panel ID chart shall be generated for each patch panel. The chart shall represent the physical layout of the patch panels and will identify the TO number, cable length, and the cable’s destination.


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B. General data such as Project Name, Date of Installation and Technology Room Location/Designation shall be included on the chart. Unused ports on the chart shall be left blank for future use.


15.7 TEST RESULTS

A. Contractor shall provide detailed test documentation on all of the required testing. Test Results shall include the following:

1. All fiber optic cable test results 2. Horizontal UTP test results 3. Backbone high pair count copper cable test results 4. Broadband video system test results

B. Horizontal UTP cable test results shall be documented, and shall include the following general information:

1. Contractor’s Company Name 2. Owner’s Name: Cleveland Clinic 3. Project Name 4. Date of Testing 5. Time (optional) 6. Telecommunications Outlet & Cable Number 7. Test Technician or Operator 8. Test Equipment Model/Serial No. 9. Test Acceptance Criteria 10. Test Frequencies

C. Contractor shall provide a copy of the horizontal UTP test results electronically in the original software format of the respective test equipment manufacturer.

15.8 MANUFACTURER’S SPECIFICATIONS

A. Contractor shall provide all cable and associated hardware manufacturer’s specifications, operational manuals, and warranties as normally provided by the manufacturer.

END OF SECTION 15.0


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16.0 UNITERRUPTIBLE POWER SUPPLY (UPS) SYSTEMS 16.1 GENERAL

A. This Specification describes an on-line solid state Uninterruptible Power Supply System hereafter referred to as the UPS. The UPS shall operate in conjunction with the building electrical system to provide power conditioning, back-up power protection and distribution for designated electronic equipment loads.

B. Provide a centralized UPS per building to provide uninterruptable power for all Technology Rooms. UPS shall comply to UL 1778 Class A specifications.

C. UPS and associated PDUs shall be placed in a dedicated electrical room, either adjacent to the Technology Equipment Center or within reasonable proximity. UPS room shall be designed with a redundant cooling system to provide a nominal temperature of 72ºF with a relative humidity between 0 and 95% non-condensing.

D. UPS System shall have true online topology with double conversion operation.

E. Provide a minimum of two DC sources, either two battery strings or a combination of a flywheel and one battery string. Each DC source (battery or flywheel) shall have its own disconnect to allow for maintenance and service while the UPS is online and operational.

F. UPS shall connect to central monitoring system for full monitoring of status and alarm conditions. The UPS shall also incorporate battery monitoring. Both UPS and battery monitors shall support IP/Ethernet connectivity

G. UPS shall be sized to operate at 90% (maximum) of manufacturer’s specified output power (kW).

16.2 UPS SYSTEM

A. The UPS shall be sized for 90% of the calculated load. Load voltage and bypass line voltage shall be 3-phase, 3-wire. Input voltage shall be 3-phase, 3-wire. The battery system shall have a minimum capacity of 10 minutes at full load at 25 degrees C.

B. The UPS shall operate as an on-line reverse transfer system in the following modes:

1. Normal: The critical AC load shall be continuously powered by the UPS inverter. The rectifier/charger shall derive its power from the utility AC source and shall supply DC power to the inverter, while simultaneously float charging the battery system.

2. Emergency: Upon failure of utility AC source, the critical AC load shall be powered by the inverter, which without any switching, shall obtain its power from the battery system. There shall be no interruption in power to the critical load upon failure or restoration of the utility AC source.

3. Recharge: Upon restoration of the utility AC source, the rectifier/charger shall automatically restart, walk-in and gradually assume the inverter and battery recharge loads. This shall be an automatic function and shall cause no interruption to the critical AC load.

4. Bypass: If the UPS must be taken out of service for maintenance or repair, or should the inverter overload capacity be exceeded, the static transfer switch shall transfer the load to the bypass source. The transfer process shall cause no interruption in power to the critical AC load.


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5. Off-Battery: If the battery system only is taken out of service for maintenance, it shall be disconnected from the rectifier/charger and inverter by means of an integral disconnect switch. The UPS shall continue to function in a bypass mode.

C. The AC output neutral shall be electrically isolated from the UPS chassis. The UPS chassis shall have an equipment ground terminal. Provisions for local bonding shall be provided.

D. Noise generated under any normal condition shall not exceed 65dBA measured 1-meter from the UPS.

E. The UPS shall be in NEMA Type 1 enclosures, designed for floor mounting. The UPS shall be structurally adequate and have provisions for hoisting, jacking, and forklift handling. Adequate ventilation shall be provided. Fans shall be redundant so that a single fan failure will not cause temperatures to increase beyond acceptable limits. The thermal design along with all thermal and ambient sensors, shall be coordinated with the protective devices before excessive component or internal cabinet temperature is exceeded.

F. The UPS module shall consist of a rectifier/charger and a three-phase inverter with associated static transfer switch with bypass switch, synchronizing equipment, protective devices, and accessories. The load shall be automatically transferred to the bypass line uninterrupted for an internal UPS malfunction. The status of protective devices shall be indicated on a graphic display screen on the front of the unit.

G. A static transfer switch and bypass circuit shall be provided as an integral part of the UPS. The static switch shall be a naturally commutated high-speed static (SCR-type) device rated to conduct full load current continuously. The static transfer switch control logic shall contain an automatic transfer control circuit that senses the status of the inverter logic signals, and operating and alarm conditions. This control circuit shall provide an uninterrupted transfer of the load to an alternate bypass source, without exceeding the transient limits specified herein, when an overload or malfunction occurs within the UPS, or for bypassing the UPS for maintenance.

H. The UPS shall be provided with a microprocessor based unit status display and controls section. A system power flow diagram shall be provided as part of the monitoring and controls sections that depicts a single-line diagram of the UPS. Illuminated visual indicators shall be of the long-life light-emitting diode (LED) or liquid crystal display (LCD) type. All of the operator controls and monitors shall be located on the front of the UPS cabinet. The monitoring functions such as metering, status and alarms shall be displayed on an alphanumeric LCD display. Additional features of the monitoring system shall include:

I. The UPS system shall be provided with output feeders as shown on the Drawings.

J. Before shipment, the manufacturer shall fully test the system to assure compliance with the specifications. These tests shall include operational discharge and recharge tests to assure guaranteed rated performance.

K. The UPS manufacturer shall warrant the unit against defects in workmanship and materials for 24 months after successful completion of Start-up and shall include a minimum of one preventative maintenance visit during the second year of service.

L. The battery system manufacturer's standard warranty shall be passed through to the Owner.

M. Approved Manufacturer: Liebert NX Series for 225KVA/KW to 600KVA/KW eXM Series for 10KVA/KW to 200KVA/KW


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UPS MODULE

SS

EMERGENCY PWR DIST PANELM

AIN

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NA

NC

E B

YP

AS

S C

AB

INE

T

BA

TT

ER

Y C

AB

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T #

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BA

TT

ER

Y C

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T #

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1 #3/0 GRD

NOTES:1. The third battery cabinet is required for loads exceeding 325KW (confirm with manufacturer).2. Load on the UPS shall not exceed 90% of its rated capacity in KW.3. A Solenoid Key Release Unit (SKRU) system is required when an external Maintenance Bypass Unit is used. Approved manufacturer: Kirk Interlock Company.

BA

TT

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AB

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T #

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MBB

MIB

BIB

PWR DIST PANEL

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K1

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Figure 6: Typical UPS Configuration 16.3 BATTERY SYSTEM

A. The UPS shall have an integral battery disconnect switch (or contactor) as recommended by the manufacturer. The disconnect switch shall be a correctly rated VDC circuit breaker. The UPS shall automatically be disconnected from the battery system by opening the switch when the batteries reach the minimum discharge voltage level.

B. The battery system shall consist of sealed, valve regulated batteries with flame retardant jars and a battery disconnect switch for isolating the batteries from the UPS. The battery cells and disconnect switch shall be installed and housed in a NEMA-1 cabinet, matching the UPS style and design, that attaches to the UPS module to form an integral system. The inter-cabinet cables shall be provided by the UPS manufacturer.


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C. The batteries shall be lead-calcium, sealed, valve regulated type with a two (2) year full warranty and a five (5) year pro rated warranty under full float operation. The battery design shall utilize absorbent glass mat (AGM) technology.

D. Batteries shall be provided with Tab Washers, suitable for use with the Alber Battery Monitoring System wiring harness.

E. Approved Battery Manufacturers: Deka or Eaton Powerware 16.4 MAINTENANCE (WRAP-AROUND) BYPASS

A. The UPS shall be designed and installed with a maintenance/wrap-around bypass. The maintenance/wrap-around bypass shall be in a separate adjacent wall mount or free standing enclosure.

B. The maintenance/wrap-around bypass shall enable the UPS to be isolated for maintenance or repair without interrupting power to the load.

C. The maintenance/wrap-around bypass shall be designed and constructed in such a manner as to allow the UPS to be de-energized for service, or physically removed and replaced without interrupting power to the critical load.

D. The maintenance/wrap-around bypass shall be sized in accordance to the electrical specifications of the respective UPS.

E. The transfer from the UPS to the maintenance/wrap-around bypass shall occur without interruption and shall have a solenoid key release unit to protect the UPS from damage in the event of out of sequence transfers.

F. Approved Manufacturers: Emerson Network Power or Eaton. 16.5 INSTALLATION

A. Manufacturer and/or Contractor shall be responsible for equipment storage and delivery to the site, including all special packing materials, shipping and handling requirements such as special rigging, cranes, etc.

B. Install the UPS and maintenance/wrap-around bypass system as directed by the manufacturer(s). Coordinate exact location with Owner as required.

C. A factory trained representative shall be responsible for all start up services as well as for training of Owner's personnel.

D. Provide an appropriately sized load bank if the required load is not available at the time of start-up.

E. Provide a written start-up report (hard-copy and soft-copy) verifying all start-up services and testing required.

F. Submittals shall include product data, installation and wiring diagrams.

G. For a UPS system installed on a raised floor, provide all additional structural supports as recommended by the floor system manufacturer.


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16.6 START-UP

A. The manufacturer’s standard inspections, test procedures and start-up procedures shall be provided with the UPS equipment by factory trained field personnel during the UPS system start-up, and shall include the following:

1. Visual Inspection:

a) Inspect equipment for signs of damage. b) Verify installation per Drawings. c) Inspect cabinets for foreign objects. d) Verify neutral and ground conductors are properly sized and configured. e) Inspect all cell cases. f) Inspect each cell for proper polarity. g) Verify all printed circuit boards are configured properly.

2. Mechanical Inspection:

a) Check all control wiring connections for tightness. b) Check all power wiring connections for tightness. c) Check all terminal screws, nuts, and/or spade lugs for tightness.

3. Electrical Inspection:

a) Check all fuses for continuity. b) Confirm input and bypass voltage and phase rotation is correct. c) Verify control transformer connections are correct for voltages being used. d) Assure connection and voltage of the battery cabling.

4. Unit Start-up:

a) Energize control power. b) Perform control/logic checks and adjust to meet specifications. c) Verify DC float and equalize voltage levels. d) Verify DC voltage clamp and overvoltage shutdown levels. e) Verify battery discharge, low battery warning and low battery shutdown levels. f) Verify fuse monitor alarms and system shutdown. g) Verify inverter voltages and regulation circuits. h) Verify inverter/bypass sync circuits and set overlap time. i) Perform manual transfers and returns. j) Simulate utility outage. k) Verify proper recharge.

B. The UPS manufacturer shall provide basic operator training conducted as part of the system start-up. The training shall be at a time approved by the Owner, and shall include a minimum of 2 hours of instruction, with a follow-up training session 1 month later, for an additional 2 hours.

C. Manufacturer shall provide three (3) sets of instruction manuals. Manuals shall include a functional description of the equipment, safety precautions, instructions, step-by-step operating procedures and routine maintenance guidelines, including illustrations.

END OF SECTION 16.0


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17.0 CRITICAL FAILITIES MONITORING SYSTEM (CFNS) 17.1 GENERAL

A. In this section, unless otherwise specified, all Work and Materials shall be furnished and installed by the Technology Contractor.

B. This section contains the specifications for a Critical Facilities Monitoring System (CFMS). This system is not a Building Management System (BMS), it is strictly for the monitoring, trending and reporting of Technology Room electrical and mechanical infrastructure.

C. The CFMS shall provide the monitoring and control for Technology Room air conditioning systems, uninterruptible power supply (UPS) systems, power distribution units (PDU), Alber™ UPS battery monitoring and leak detection. Depending on the project, other critical infrastructure systems may be added as specified on the drawings.

D. Refer below to Figure 4 for a typical CFMS schematic. This schematic is provided for reference only and is subject to change based on site specific requirements, equipment configurations and manufacturers.

E. The system architecture shall be modular permitting expansion of application software, system peripherals, and field hardware.

F. The system shall utilize a distributed processing architecture so that polling of all points is not dependent on a single processor.

G. All cabling, mounting hardware and equipment shall be standard components, regularly manufactured and available and not custom designed especially for this project. All systems and components, shall have previously been thoroughly tested and proven in actual use prior to installation on this project.

H. Contractor shall furnish, install all cabling and equipment and shall coordinate as required with CFMS manufacturer, Owner, and various electrical and mechanical equipment manufacturers and/or suppliers during installation, testing and commissioning of the system.

I. Electrical and Mechanical Contractors shall provide BACnet or MODbus communication cards, programming, equipment upgrades, etc. required for all 3rd party equipment communications to SiteScan.


A. Contractor shall furnish and install one or more of the following CFMS components. Refer to the drawings to determine specific equipment requirements for the respective project.

B. All CFMS components shall be Liebert SiteScan Web, as manufactured by Emerson Network Power, Liebert Corporation unless approved in writing by Cleveland Clinic ITD.

C. Contractor shall provide via the manufacturer all programming and software system upgrades necessary to ensure the addition of the new equipment to the enterprise SiteScan control system.

D. Control Modules:

1. Liebert SiteLink™-12E, Emerson SiteLink-4E or Liebert SiteLink-2E Interface Modules for Liebert air conditioning unit(s), PDU’s and UPS equipment.


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2. Liebert SiteI/O-E™ Universal Input/Output Modules for that utilize dry contact , or 4– 20mV connections such as Alber battery monitor, and temperature sensors.

3. Liebert SiteTPI-E™ Modbus or BACnet third-party interface.

4. 120-230VAC/24VAC power supply for control modules listed in this section.

E. Cables:

1. Control cable shall consist of 1-pair of 22-AWG stranded (7x30) tinned copper conductors. Conductors shall be 100% shielded with an aluminum foil-polyester tape.

2. Cables shall not exceed the maximum distances based on application:

a) SiteLink to device (RS-422 – IGMnet): 1000 ft.

b) Site I/O to device: 300 ft.

c) Site TPI to device: 3000 ft.

3. Approved manufacturer: Belden – 88761 (CMP for plenum rated environments) 9461 (CM for non-plenum environments) 17.3 INSTALLATION

A. General

1. For single building facilities (e.g., Family Health Centers, Ambulatory Surgery Centers, Medical Office Buildings and small one or two building hospital campuses, etc.), it is Cleveland Clinic’s intent to centralize the control modules within the Technology Equipment Center (TEC).

2. The exception to the centralized design shall be based on the distance of the controller to the respective equipment. If the distance exceeds the respective specified cable length, then the controller shall be located within proximity to the equipment.

3. All control cabling from the controller to the equipment shall be shall be home run to each respective piece of electrical equipment (UPS, PDU and Alber UPS battery monitor) and/or mechanical equipment (AC units, leak detection and temperature sensor).

4. Contractor shall be responsible for final layout configuration in a manner that is both efficient and facilitates maintenance.

5. Contractor shall be required to acquire the MODbus registry for each piece of electrical and/or mechanical 3rd party equipment that is to be monitored. Contractor shall coordinate with Electrical and Mechanical Contractors in acquiring this information.

B. Controller Installation

1. When collocating multiple controllers in a Technology Room, Contractor shall provide a wall mount, nonmetallic enclosure sized to hold all modules and interconnecting cables in lieu of the individual housings supplied by the manufacturer. The enclosure shall have a hinged door with lockable handle, louvered sides for air flow, possess a mounting surface for the controllers and wire management system, and knockouts for up to a 2-inch conduit. The enclosure shall be manufactured by Hoffman.

2. Individual Controllers installed in remote locations shall be mounted to a plywood mounting board in the housing provided by the manufacturer.


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3. Contractor shall furnish and install a 120VAC to 24VAC power supply sized to power multiple controllers. Individual power bricks shall not be used in a centralized configuration.

4. Contractor shall furnish a 120VAC to 24VAC power supply brick for single controllers installed in remote locations.

5. All controller power supplies shall be powered from a UPS backed circuit. If a centralized UPS is not available, then Technology Contractor shall provide a standalone, wall mounted UPS at each controller location. The UPS shall be sized to provide backup power for 15-minutes, and shall be powered from a generator backed circuit. If there is no generator circuits available, then the UPS shall be sized provide backup power for 120-minutes.

C. Cable Routing and Pathways

1. Contractor shall furnish, install, terminate (both ends) and label all CFMS control cabling.

2. Control cables shall be installed in a single continuous run between the controller and the equipment. Splicing of a cable shall not be permitted.

3. Control cables shall not be placed in any raceway, compartments, outlet box, or junction box with conductors of electric light and power circuits.

4. Control cables shall be properly protected from damage from any sharp edges when entering and exiting conduit stubs or cable tray.

5. Contractor shall ensure control cables are placed and terminated in such a manner as to avoid kinks and other deformities

6. The minimum bending radius for any cable shall not exceed the respective manufacturer’s specifications.

7. Control cables shall not be installed in cable tray systems designated for voice/data cabling. Control cables shall be installed in other approved pathway systems.

8. During installation, Contractor shall ensure the cable manufacturer's maximum pulling tension is never reached. Contractor, at no additional cost to Cleveland Clinic, shall replace cables that are damaged because of Contractor’s installation procedures.

9. Where Contractor is required to install non-continuous pathways, Contractor shall keep hallway crossover to a minimum. Furthermore, non-continuous pathways shall be routed to follow logical paths parallel and perpendicular to the building structure.

10. In open architecture pathway systems, cables shall be supported by J-hooks, the J-hooks shall be attached to the building structure and framework per local codes and regulations at a maximum of five (5) foot intervals.

11. Cable ties and other methods of binding cabling shall not be installed in such a fashion to as to bend, crimp or deform the cabling in any way to alter the electrical or transmission characteristics of the cabling.

12. Control cable pathways that run parallel with electric power or lighting cables or conduits, that are less than or equal to 480 Vrms, shall be installed with a minimum clearance of 50 mm (2 inches). The installation of cabling shall maintain a minimum clearance of 3 m (10 ft.) from power cables or conduits in excess of 480 Vrms.

13. Control cables shall not be exposed below ceilings or other locations with public access, unless otherwise noted on Drawings.


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14. Control cables routed in a suspended ceiling shall not be draped across the ceiling tiles. Cable supports shall be mounted a minimum of 75 mm (3 inches) above the ceiling grid supporting the tiles.

15. When working around existing cabling, the Contractor will take extra precautions to ensure that existing services are not disrupted in any way.

16. Control cables shall not be attached to or supported by fire sprinkler heads or delivery systems or any environmental sensor located in the ceiling space.

17. Contractor shall leave 1m (3’) coil of cable at each termination point (controller and equipment). The slack shall be neatly coiled and tie-wrapped above the conduit stub.

18. All cabling shall comply with the requirements as outlined in the National Electrical Code and the appropriate local codes. All cabling shall bear CMP (plenum rated), CM/CMR (riser rated) and/or appropriate markings for the environment in which they are installed.

19. Contractor shall be responsible for the determination of the necessity of limited combustible cable, plenum cable, and/or non-plenum cable, and shall be aware of any local codes regarding the use of these cable types.

20. Cable ties shall conform to the environment in which they are installed (i.e., plenum rated cable ties in plenum ceilings, etc.). Cable ties shall be attached so as not to crimp or kink the cables. Cables should move freely within the tie-wrapped bundle

D. Conduit

1. Electrical Contractor shall furnish and install all conduit as required for control cabling. Minimum conduit size for individual cables shall be ¾-inch.

2. Typically, conduits shall stub up a minimum of 10-feet above controller and equipment and route through open architecture pathways. All conduit stubs shall, and shall have bushings installed.

3. CFMS conduit shall be black in accordance with Cleveland Clinic standards. In lieu of painted conduit, black vinyl, all-weather tape (2” minimum width) placed at all junction points, and at every 10-feet along the pathway shall be acceptable.

E. Cable and Controller Labeling

1. Contractor shall furnish and install all controller and cable labels.

2. Cables shall be labeled at both ends. On the controller side, label cable with equipment type and nomenclature as defined on the drawings (e.g., Generator #1, PDU-A, etc.). On the equipment side, label cable with the controller nomenclature as defined on the drawings (e.g., SL-BA, TPI-BA, etc.).

3. All cable labeling shall be machine printed on adhesive type labels designed for use on communications cables, and shall remain in place through normal use.

4. Cable labels shall be wrap around type, and shall be placed on the cable jacket approximately 2-inches from the point of termination.

5. Cable labels shall be installed so that they are visible and readable by maintenance personnel without having to touch or twist the cable.

6. Controllers shall be labeled using engraved plastic tags. Engraved tags shall be 1”H x 2”W with 1/4” lettering and shall be white in color with black lettering.


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7. Engraved tags shall identify the controller based on part number (top line), such as SiteLink 12E or Site I/OE, and nomenclature as defined on the drawings (bottom line), such as SL-BA or I/O-BC.

8. Within a Hoffman enclosure, the tags shall be mounted next to each controller so as to be easily identifiable to maintenance personnel. For a single controller, mount the tag in the center of the Liebert housing.

9. The front of the Hoffman enclosure shall be labeled using an engraved plastic tag. The engraved tag shall be a 2”H x 4”W with 1/2” lettering and shall be white in color with black lettering. The tag shall read “EMERSON SITESCAN” (Top Line), “CONTROLLER PANEL” (Bottom Line).

17.4 COMMISSIONING

A. Contractor shall be required to fully activate and commission the CFMS in conjunction with the Owner and manufacturer during or prior to Integrated Systems Testing and Commissioning.

B. Contractor shall coordinate with the Electrical and Mechanical Contractors to ensure their timely participation in the commissioning process, and equipment configuration readiness.

C. Contractor shall coordinate with Owner for network connectivity and IP address assignments

D. Contractor shall notify Owner when the installation of the CFMS is complete and power is available and all devices are ready to be energized (DO NOT ENERGIZE UNTIL TOLD TO DO SO BY OWNER), are properly connected to the Owner’s Ethernet network, and respective electrical and mechanical equipment. NOTE: THE ELECTRICAL AND MECHANICAL EQUIPMENT MUST ALSO BE ENERGIZED AND OPERATIONAL.

E. Owner, in conjunction with the manufacturer, shall verify the installation is complete and create a punch list as necessary. Contractor shall have five (5) business days to complete the punch list.

F. After punch list is complete, the Owner and manufacturer shall schedule the startup of the CFMS. The Contractor shall notify the electrical and mechanical contractors of the startup date and ensure representatives from each of the respective equipment manufacturers are present for startup.

G. Contractor shall provide as-built drawings and OEM manuals within 10 business days of completing all punch list and commissioning.

17.5 THIRD-PARTY (NON-EMERSON) EQUIPMENT MONITORING

A. The following tables contain the typical points to monitor for each type of third-party (non-Emerson) equipment. Contractor shall verify with the respective Electrical and Mechanical Contractor the points available for each piece of equipment.


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1. CRAC/CRAH

DIGITAL Summary alarm Low/high humidity alarm Low/high temp alarm Humidifier problem Water/leak detection High head pressure

ANALOG (IF AVAILABLE) Discharge or return air temp Discharge or return humidity

2. POWER DISTRIBUTION UNIT (PDU)

ANALOG Input

Voltage (L-L, L-N) Frequency

Output Voltage (L-L, L-N) KW KVA Power Factor Current (by Phase, Neutral & Average

DIGITAL Summary Alarm Output Overload Output Current Over 100% Transformer Over Temp

4. UNINTERRUPTABLE POWER SUPPLY (UPS)

ANALOG (METERS) Input KVA, KW Volts L-L, volts L-N Current Phase A, B, C , N & G

and Average A/B/C Frequency, Power Factor

Bypass Output Volts A, B, C and average

Output KVA, KW Voltage (L-L, L-N) Current Phase, A, B, C, N & G

& Average A/B/C Frequency, Power Factor

Battery Voltage Current % Battery Life

DIGITAL (ALARMS) UPS Module

Summary alarm UPS Off UPS on bypass UPS on battery Remote EPO Static Switch fail Bypass Breaker Fail Shutdown Imminent

DIGITAL (ALARMS) UPS Module (continued)

Output Breaker Open UPS on Battery UPS on Bypass Low Battery Shutdown

Input Under/Over Voltage Under/Over Frequency

Rectifier Input Overcurrent Rectifier Failed

Inverter Under/Over Voltage Overtemp Output Overcurrent

Charger Over voltage Overcurrent Over voltage Overcurrent

Bypass Under/Over Voltage

Output Under/Over Voltage Under/Over Frequency Overload

Battery Low DC Overvoltage


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Figure 6: Typical Critical Facility Monitoring System (CFMS) Schematic

END OF SECTION 17.0


Page A-1

APPENDIX A: MATERIAL LISTS


Page A-2

A.0 MATERIAL LISTS

The following lists provide equipment descriptions and part numbers by manufacturer for low voltage cabling and associated hardware approved for use at Cleveland Clinic. Part numbers are based on those provided by the manufacturer and are subject to change without notice. Cleveland Clinic reserves the right to change and/or modify these lists, and/or to add/remove approved manufacturers at Cleveland Clinic’s discretion and without notice. Contractor is responsible to verify all part numbers with Cleveland Clinic and each respective manufacture prior to purchase.


Page A-3

A.1 FIBER OPTIC CABLE & CONNECTING HARDWARE

A. CORNING LEGACY HARDWARE

ITEM MFR PART NO. DESCRIPTION 1. Corning CCH-CP12-91 12 Fiber, SC, Duplex, 62.5/125µm MM Coupler Panel 2. Corning CCH-CP12-E4 12 Fiber, LC, Duplex, 50/125µm OM3 MM Coupler Panel 3. Corning CCH-CP12-E7 12 Fiber, SC, Duplex, 50/125µm OM3 MM Coupler Panel 4. Corning CCH-CP24-E4 24 Fiber, LC, Duplex, 50/125µm OM3 MM Coupler Panel 5. Corning CCH-CP12-59 12 Fiber, SC, Duplex, SM Coupler Panel 6. Corning CCH-CP12-A9 12 Fiber, LC, Duplex, SM Coupler Panel

A.2 HIGH PAIR COUNT COPPER CABLE & CONNECTING HARDWARE

ITEM MFR PART NO. DESCRIPTION 1. Superior Essex 18-789-33 100-Pair Cat 3, 24 AWG, CMR Rated 2. Superior Essex 18-799-36 100-Pair Cat 3, 24 AWG, CMP Rated 3. Superior Essex 18-A99-33 200-Pair Cat 3, 24 AWG, CMR Rated 4. Superior Essex 18-A99-36 200-Pair Cat 3, 24 AWG, CMP Rated 5. Superior Essex 18-B99-33 300-Pair Cat 3, 24 AWG, CMR Rated 6. Superior Essex 18-B99-36 300-Pair Cat 3, 24 AWG, CMP Rated 7. Superior Essex 09-****-02 24 AWG, Solid Copper, OSP Cable, SEALPIC-PE-89 8. General Cable 7525**** 24 AWG, Solid Copper, OSP Cable, SEALPIC-PE-89 9. Ortronics OR-30200145 110 Wiring Block with Legs, 100-Pair 10. Ortronics OR-30200007 110 Wiring Block with Legs, 300-Pair 11. Ortronics OR-30200110 5-pair 110 Connecting Block 12. Ortronics OR-70400272 Designation Strips (White) with Transparent Holders 13. Ortronics OR-30200140 110 Jumper Tough with Legs 14. Ortronics OR-60400020 Cross Connect Backboard 15. Siemon S110MB5-300JP 110 Tower Modular Jack Panel Kit, 36-port 16. Siemon S110MB5-400JP 110 Tower Modular Jack Panel Kit, 48-port 17. Siemon S110MB5-500JP 110 Tower Modular Jack Panel Kit, 60-port 18. Siemon S110DB5-24RJP S110, 24-Port Jack Panel 19. Siemon S110DA2-200RWM 200-Pair, 19” Panel, 110 Field Termination Kit 20. Siemon S110DA1-300RFT 300-Pair, 19” Panel, 110 Field Termination Kit 21. Ortronics OR-302003253 200-Pair Panel Kit 22. Porta Systems 24100-110-M110C 110 Building Entrance Protection Panel – 100pr 23. Porta Systems 115SCN-240 4B1S; 5-pin 240V Solid State protector w/heat coils 24. Circa 1880ECA1-100 110 Building Entrance Protection Panel – 100pr 25. Circa 4B1FS-240 Solid-State Protector Unit w/Current Limiter (PTC)

**** Indicates Pair Count


Page A-4

A.3 HORIZONTAL UTP COPPER CABLE & CONNECTING HARDWARE

A. BERK-TEK

ITEM MFR PART NO. DESCRIPTION

1. Berk-Tek 10163222 (LM2000) Category 6 UTP Cable, 4-pair, Blue, CMP Rated 2. Berk-Tek 10167311 (LM2000) Category 6 UTP Cable, 4-pair, White, CMP Rated 3. Berk-Tek 10170668 (LM2000) Category 6 UTP Cable, 4-pair, Green, CMP Rated 4. Berk-Tek 10170684 (LM2000) Category 6 UTP Cable, 4-pair, Red, CMP Rated 5. Berk-Tek 10167476 (LM2000) Category 6 UTP Cable, 4-pair, Blue, CMR Rated 6. Berk-Tek 10167480 (LM2000) Category 6 UTP Cable, 4-pair, White, CMR Rated 7. Berk-Tek 10170693 (LM2000) Category 6 UTP Cable, 4-pair, Red, CMR Rated 8. Berk-Tek 10170687 (LM2000) Category 6 UTP Cable, 4-pair, Green, CMR Rated

B. ORTRONICS HARDWARE

ITEM MFR PART NO. DESCRIPTION 1. Ortronics OR-PHD66U48 Category 6 High Density Modular Patch Panel, 48-port 2. Ortronics OR-PHD66U24 Category 6 High Density Modular Patch Panel, 24-port 3. Ortronics OR-PHA66U48 Category 6 Angled Modular Patch Panel, 48-port 4. Ortronics OR-PHA66U24 Category 6 Angled Modular Patch Panel, 24-port 5. Ortronics OR-TJ600-88 Category 6 Jack, 8-position, Cloud White 6. Ortronics OR-TJ600-42 Category 6 Jack, 8-position, Red 7. Ortronics OR-TJ600-36 Category 6 Jack, 8-position, Blue 8. Ortronics OR-TJ600-45 Category 6 Jack, 8-position, Green 9. Ortronics OR-TJ600-27 Category 6 Jack, 8-position, Lilac 10. Ortronics OR-TJ600-44 Category 6 Jack, 8-position, Yellow 11. Ortronics OR-TJ600-00 Category 6 Jack, 8-position, Black 12. Ortronics OR-TJ600-78 Category 6 Jack, 8-position, Dark Gray 13. Ortronics OR-40300546-88 Faceplate, Single Gang, Quad Config, Cloud White 14. Ortronics OR-40300546-13 Faceplate, Single Gang, Quad Config, Ivory 15. Ortronics OR-42100002-88 Faceplate Blank Jack Insert, Cloud White 16. Ortronics OR-42100002-13 Faceplate Blank Jack Insert Ivory 17. Ortronics OR-403STJIWP Wall Phone Stainless Steel Faceplate (VoIP)

C. SUTTLE

ITEM MFR PART NO. DESCRIPTION 1. Suttle 630AD6 Wall Phone Stainless Steel Faceplate (Non-VoIP)


Page A-1

A.4 PRE-TERMINATED FIBER OPTIC CABLE & CONNECTING HARDWARE

A. BERK-TEK


1. Berk-Tek BMKP12ELLSCPXXX-Type B

Micro Data Center Interlocking Armor,Plenum,12 Fiber, 50/125um(2000/500MHz) GIGAlite 10, OM3 Multimode, Aqua Jacket, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

2. Berk-Tek BMKP24EXXSCPXXX-Type B

Micro Data Center Interlocking Armor,Plenum,24 Fiber, 50/125um(2000/500MHz) GIGAlite 10, OM3 Multimode, Aqua Jacket,24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length, 24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

3. Berk-Tek BMKP12CLLSCPXXX-Type B

Micro Data Center Interlocking Armor,Plenum,12 Fiber, 62.5/125um(200/500MHz), OM1 Multimode, Orange Jacket, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

4. Berk-Tek BMKP24CXXSCPxxx-Type B

Micro Data Center Interlocking Armor,Plenum,24 Fiber, 62.5/125um(200/500MHz), OM1 Multimode, Orange Jacket,24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length,24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

5. Berk-Tek BMKP12AEESCPXXX-Type B(COR)

Micro Data Center Interlocking Armor,Plenum,12 Fiber, Singlemode (Corning), Yellow Jacket, MTP Female with 3.0mm Round, 39 in. leg length, MTP Female with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD)

6. Berk-Tek BMKP24AEESCPXXX-Type B(COR)

Micro Data Center Interlocking Armor,Plenum,24 Fiber, Singlemode (Corning), Yellow Jacket, MTP Female with 3.0mm Round, 39 in. leg length, MTP Female with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD)

7. Berk-Tek BMDP12ELLSCPXXX-Type B

Micro Data Center,Plenum,12 Fiber,50/125um(2000/500MHz) GIGAlite 10, OM3 Multimode, Aqua Jacket, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

8. Berk-Tek BMDP24EXXSCPXXX-Type B

Micro Data Center,Plenum,24 Fiber,50/125um(2000/500MHz) GIGAlite 10, OM3 Multimode, Aqua Jacket,24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length, 24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

9.

Berk-Tek BMDP12CLLSCPXXX-Type B

Micro Data Center,Plenum,12 Fiber,62.5/125um(200/500MHz), OM1 Multimode, Orange Jacket, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, MTP Female(0.35 dB I.L.) with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),


Page A-2

A. BERK-TEK (Cont.)


10. Berk-Tek BMDP24CXXSCPxxx-Type B

Micro Data Center,Plenum,24 Fiber,62.5/125um(200/500MHz), OM1 Multimode, Orange Jacket,24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length,24 Fiber MTP Female(0.35 dB I.L.) with 3.6mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD),

11. Berk-Tek BMDP12AEESCPXXX-Type B(COR)

Micro Data Center,Plenum,12 Fiber, Singlemode (Corning), Yellow Jacket, MTP Female with 3.0mm Round, 39 in. leg length, MTP Female with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD)

12. Berk-Tek BMDP24AEESCPXXX-Type B(COR)

Micro Data Center,Plenum,24 Fiber, Singlemode (Corning), Yellow Jacket, MTP Female with 3.0mm Round, 39 in. leg length, MTP Female with 3.0mm Round, 39 in. leg length, Reversed Polarity(Type B), Standard PE Pulling End Only-(1.3" OD)

B. LEVITON NETWORK SOLUTIONS


1. Leviton 9XX-5R1UE-KIT

5R1UE-OPX: OPT-X 500i, 1RU Panel, Empty 5R1UL-CMT: OPT-X Patch Cord Management Tray, 1U, 4" Depth E2X1F-CMB: Rear Cable Manager For Flat Panel, w/Management Rings 5RCMR-KIT: OPT-X Clamp Kit, Multiple Cable Grommet For Rack Mounting 5F100-PLT: Adapter Plate Black, Blank

2. Leviton 5R1UH-S03 Enclosure 1U Ultra Empty+try 3. Leviton 5R2UH-S06 Enclosure 2U Ultra Empty+try 4. Leviton 5R4UH-S12 Enclosure 4U Ultra Empty+try 5. Leviton 5F100-PLT Adapter Plate Black, Blank

6. Leviton FM-E012CAC0BC Fiber Plug-n-Play MTP Module, 12-fiber OM3, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

7. Leviton FM-E012CAC0BE Fiber Plug-n-Play MTP Module, 12-fiber OM3, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]

8. Leviton FM-E024CDC0BC Fiber Plug-n-Play MTP Module, Unity Cassette, 24-fiber OM3, LC Connectors to 24-fiber MTP, Opt-X style footprint, black color, [MTP Method B, Core, black plungers]

9. Leviton FM-E024CDC0BE Fiber Plug-n-Play MTP Module, Unity Cassette, 24-fiber OM3, LC Connectors to 24-fiber MTP, Opt-X style footprint, black color, [MTP Method B, Edge, white plungers

10. Leviton FM-C012CAC0BC Fiber Plug-n-Play MTP Module, 12-fiber 62.5/125um OM1, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

11. Leviton FM-C012CAC0BE Fiber Plug-n-Play MTP Module, 12-fiber 62.5/125um OM1, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]

12. Leviton FM-C024CDC0BE Fiber Plug-n-Play MTP Module, 24-fiber 62.5/125um OM1, LC to 24-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]


Page A-3

B. LEVITON NETWORK SOLUTIONS (Cont.)


13. Leviton FM-C024CDC0BC Fiber Plug-n-Play MTP Module, 24-fiber 62.5/125um OM1, LC to 24-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

14. Leviton FM-C012AAC0BC Fiber Plug n Play Module, 12-fiber 62.5/125µm multimode OM1, ST Connectors to 12-fiber MTP(s), Opt-X style footprint, black color, [MTP Method B, Core, black plungers]

15. Leviton FM-C012AAC0BE Fiber Plug n Play Module, 12-fiber 62.5/125µm multimode OM1, ST Connectors to 12-fiber MTP(s), Opt-X style footprint, black color, [MTP Method B, Edge, white plungers]

16. Leviton FM-A012CAC0BC Fiber Plug-n-Play MTP Module, 12-fiber OS2, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

17. Leviton FM-A012CAC0BE Fiber Plug-n-Play MTP Module, 12-fiber OS2, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]

18. Leviton FM-A024CAC0BE Fiber Plug-n-Play MTP Module, 24-fiber OS2, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]

19. Leviton FM-A024CAC0BC Fiber Plug-n-Play MTP Module, 24-fiber OS2, LC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

20. Leviton FM-A012FAC0BC Fiber Plug-n-Play MTP Module, 12-fiber OS2, LC/APC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

21. Leviton FM-A012FAC0BE Fiber Plug-n-Play MTP Module, 12-fiber OS2, LC/APC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]

22. Leviton FM-A024FAC0BE Fiber Plug-n-Play MTP Module, 24-fiber OS2, LC/APC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Edge, white plungers]

23. Leviton FM-A024FAC0BC Fiber Plug-n-Play MTP Module, 24-fiber OS2, LC/APC to 12-fiber MTP, Opt-X style footprint, black color [MTP Method B, Core, black plungers]

A.5 FIELD TERMINATED FIBER OPTIC CABLE & CONNECTING HARDWARE

A. BERK-TEK


1. Berk-Tek PDRxxxEB3010/25 Premise Distribution, Tight Buffer, Riser, 50/125um, GIGAlite

10, OM3 MM

2. Berk-Tek PDPxxxEB3010/25 Premise Distribution, Tight Buffer, Plenum, 50/125um, GIGAlite

10, OM3 MM

3. Berk-Tek PDRxxxCB3510/25 Premise Distribution, Tight Buffer, Riser, 62.5/125um, GIGAlite,

OM1 MM

4. Berk-Tek PDPxxxCB3510/25 Premise Distribution, Tight Buffer, Plenum, 62.5/125um,

GIGAlite, OM1 MM


Page A-4

A. BERK-TEK (Cont.)


5. Berk-Tek PDRxxxAB0707-F1(COR) Premise Distribution, Tight Buffer, Riser, SM (Corning) 6. Berk-Tek PDPxxxAB0707-F1(COR) Premise Distribution, Tight Buffer, Plenum, SM (Corning)

7. Berk-Tek LTRxxxEB3010/25 Adventum, Dry Loose Tube, Indoor/Outdoor, Riser, 50/125um, GIGAlite 10, OM3 MM

8. Berk-Tek LTPxxxEB3010/25 Adventum, Dry Loose Tube, Indoor/Outdoor, Plenum, 50/125um, GIGAlite 10, OM3 MM

9. Berk-Tek LTRxxxCB3510/25 Adventum, Dry Loose Tube, Indoor/Outdoor, Riser, 62.5/125um, GIGAlite, OM1 MM

10. Berk-Tek LTPxxxCB3510/25 Adventum, Dry Loose Tube, Indoor/Outdoor, Plenum, 62.5/125um, GIGAlite, OM1 MM

11. Berk-Tek LTRxxxAB0403-F1(COR) Adventum, Dry Loose Tube, Indoor/Outdoor, Riser, SM (Corning)

12. Berk-Tek LTPxxxAB0403-F1(COR) Adventum, Dry Loose Tube, Indoor/Outdoor, Plenum, SM (Corning)

B. SUMITOMO / LEVITON NETWORK SOLUTIONS


1. Sumitomo Lynx2-LCUPCSM-900LT Fuse on Connector LC Single Mode Connector 900um Tight-Buffered

2. Sumitomo Lynx2-LCPCM6-900LT Fuse on Connector LC 62.5 Multi-Mode Connector 900um Tight-Buffered

3. Sumitomo Lynx2-LCPCM510G-900LT Fuse on Connector LC 50um Multi Mode Connector 900um Tight-Buffered

4. Leviton 5R1UH-S03 OPT-X ULTRA 1RU Enclosure, Accepts up to 3 OPT-X Adapter Plates

5. Leviton 5R2UH-S06 OPT-X Ultra 2RU Enclosure, Accepts up to 6 OPT-X Adapter Plates

6. Leviton 5R4UH-S12 OPT-X ULTRA 4RU Enclosure, Accepts up to 12 OPT-X Adapter Plates

7. Leviton OCS12-STD 12 Tray OCS Wall Mount Splice Enclosure (Lightspace Enclosure)

8. Leviton OCS18-STD 18 Tray OCS Wall Mount Splice Enclosure (Lightspace Enclosure)

9. Leviton 5W110-00N Small OPT-X Wall Mount Enclosure, Accepts 2 Adapter Plates

10. Leviton 5W310-00N Medium OPT-X Wall Mount Enclosure, Accepts 4 Adapter Plates

11. Leviton 5W710-00N Large OPT-X Wall Mount Enclosure, Accepts 12 Adapter Plates 12. Leviton 49280-AP6 Vertigo, Zero U Panel, 6" Cable Channel 13. Leviton 5F100-2IC OPT-X Adapter Plate, 12 Fiber, Duplex SC Mm Beige (62.5) 14. Leviton 5F100-2QL OPT-X Adapter Plate, 12 Fiber, Duplex LC MM Aqua (OM3/4) 15. Leviton 5F100-4QL OPT-X Adapter Plate, 24 Fiber, Quad LC MM Aqua (Om3/4) 16. Leviton 5F100-2LL OPT-X Adapter Plate, 12 Fiber, Duplex LC SM Blue 17. Leviton 5F100-4LL OPT-X Adapter Plate, 24 Fiber, Quad LC SM Blue 18. Leviton 5F100-6VC OPT-X Adapter Plate, 6 Fiber, Duplex SC/APC SM Green 19. Leviton 5F100-2VC OPT-X Adapter Plate, 12 Fiber, Duplex SC/APC SM Green 20. Leviton 5F100-2VL OPT-X Adapter Plate, 12 Fiber, Duplex LC/APC SM Green 21. Leviton 5F100-PLT Adapter Plate Black, Blank


Page A-5

B. SUMITOMO / LEVITON NETWORK SOLUTIONS (Cont.)

ITEM MFR PART NO. DESCRIPTION 22. Leviton 492RU-HFO Horizontal Front Only 2U Cable Management

23. Leviton T47BF-P06 4" W X 7" L X 0.35" H, Mini Splice Tray for Bare Fusion, 12 Fiber (Lightspace Enclosure)

24. Leviton T4LHS-P06 4" W X 11.75" L X 0.35" H, Standard Slice Tray for Heat Shrink, 12 Fiber (Lightspace Enclosure)

25. Leviton T4LHS-P12 4" W X 11.75" L X 0.35" H, High Density Slice Tray For Heat Shrink, 24 Fiber (Lightspace Enclosure)

26. Leviton T5PLS-12F 3.74" W X 5.59" L X 0.56" H, Precision Molded Mini Splice Tray for Heat Shrink, 12 Fiber (OPT-X Enclosure)

27. Leviton T5PLS-24F 4.5" W X 7.63" L X 0.50" H, Precision Molded High Density Splice Tray For Heat Shrink, 24 Fiber (OPT-X Enclosure)

28. Leviton 49887-06S Fiber Optic Fan-Out Kit, 6-Fiber, 24" Length 29. Leviton 49887-12S Fiber Optic Fan-Out Kit, 12-Fiber, 24" Length 30. Leviton 41296-MMW Mos Surface Mount Housing, 3 Unit With Fiber Storage 31. Leviton 5LDLC-MXX OM3 MM Patch Cables OFNR Duplex LC-LC 32. Leviton 5LDSC-MXX OM3 MM Patch Cables OFNR Duplex SC-SC 33. Leviton 62DLC-MXX OM1 MM Patch Cables OFNR Duplex LC-LC 34. Leviton 62DSC-MXX OM1 MM Patch Cables OFNR Y SC-SC

A.6 HIGH PAIR COUNT COPPER CABLE & CONNECTING HARDWARE

A. BERK-TEK


1. Berk-Tek 10032113 Category 3 UTP Cable, 100 pair, CMP Rated

2. Berk-Tek 10032472 Category 3 UTP Cable, 100 pair, CMR Rated







1. Leviton 41AW2-100 Category 5E 110-Style Wall Mount Wiring Blocks w/Legs, 100 Pair

2. Leviton 41AW2-300 Category 5E 110-Style Wall Mount Wiring Blocks w/Legs, 300 Pair

3. Leviton 49105-IDC Category 5E 110-Style Connector C-5 Clips, 5-Pair

4. Leviton 41LBL-00W Category 5E 110-Style Label Kit, 6/Kit

5. Leviton 41100-HLD Category 5E 110-Style Label Holder, 6/Kit

6. Leviton 41A10-HCM 110-Style Horizontal Cord Manager w/Legs


Page A-6

A.7 CAT 6 HORIZONTAL UTP COPPER CABLE & CONNECTING HARDWARE

A. BERK-TEK


1. Berk-Tek 10163222 (LM2000) Category 6 UTP Cable, 4-pair, Blue, CMP Rated

2. Berk-Tek 10167311 (LM2000) Category 6 UTP Cable, 4-pair, White, CMP Rated

3. Berk-Tek 10170668 (LM2000) Category 6 UTP Cable, 4-pair, Green, CMP Rated

4. Berk-Tek 10170684 (LM2000) Category 6 UTP Cable, 4-pair, Red, CMP Rated

5. Berk-Tek 10170672 (LM2000) Category 6 UTP Cable, 4-pair, Violet, CMP Rated

6. Berk-Tek 10167476 (LM2000) Category 6 UTP Cable, 4-pair, Blue, CMR Rated

7. Berk-Tek 10167480 (LM2000) Category 6 UTP Cable, 4-pair, White, CMR Rated

8. Berk-Tek 10170693 (LM2000) Category 6 UTP Cable, 4-pair, Red, CMR Rated

9. Berk-Tek 10170687 (LM2000) Category 6 UTP Cable, 4-pair, Green, CMR Rated

10. Berk-Tek 10170691 (LM2000) Category 6 UTP Cable, 4-pair, Violet, CMR Rated



1. Leviton 907-69586-L48 Category 6 2RU 48-Port Flat 110-Style Patch Panel

2. Leviton 907-69586-L24 Category 6 1RU 24-Port Flat 110-Style Patch Panel

3. Leviton 905-69587-L48 Category 6 2RU 48-Port Angled 110-Style Patch Panel

4. Leviton 905-69587-L24 Category 6 1RU 24-Port Angled 110-Style Patch Panel

5. Leviton 61110-RW6 Extreme Category 6 UTP Component-Rated Connector, White

6. Leviton 61110-RC6 Extreme Category 6 UTP Component-Rated Connector, Crimson

7. Leviton 61110-RL6 Extreme Category 6 UTP Component-Rated Connector, Blue

8. Leviton 61110-RV6 Extreme Category 6 UTP Component-Rated Connector, Green

9. Leviton 61110-RE6 Extreme Category 6 UTP Component-Rated Connector, Black

10. Leviton AB100-00W Connector Adapter Bezel, White

11. Leviton 42080-4WS Quickport 4-Port Wallplate w/ID Windows, White

12. Leviton 42080-3WS Quickport 3-Port Wallplate w/ID Windows, White

13. Leviton 42080-2WS Quickport 2-Port Wallplate W/ID Windows, White

14. Leviton 42080-1WS Quickport 1-Port Wallplate W/ID Windows, White

15. Leviton 41089-2WP Quickport 2-Port CMP Surface-Mount Box, White

16. Leviton 41084-BWB Module, Blank, White

17. Leviton 4108W-1SP Quickport SS Wall Phone Plate

18. Leviton 6H460-03* High-Flex HD6 High Density 1G Patch Cord, 3'






Page A-7

A.8 CAT 6A HORIZONTAL UTP COPPER CABLE & CONNECTING HARDWARE

A. BERK-TEK


1. Berk-Tek 11082057 (LM XTP) Category 6A UTP Cable, 4-pair, Blue, CMP Rated 2. Berk-Tek 11082058 (LM XTP) Category 6A UTP Cable, 4-pair, White, CMP Rated 3. Berk-Tek 11083158 (LM XTP) Category 6A UTP Cable, 4-pair, Green, CMP Rated 4. Berk-Tek 11090643 (LM XTP) Category 6A UTP Cable, 4-pair, Red, CMP Rated 5. Berk-Tek 11085661 (LM XTP) Category 6A UTP Cable, 4-pair, Violet, CMP Rated 6. Berk-Tek 11082062 (LM XTP) Category 6A UTP Cable, 4-pair, Blue, CMR Rated 7. Berk-Tek 11082063 (LM XTP) Category 6A UTP Cable, 4-pair, White, CMR Rated 8. Berk-Tek 11085549 (LM XTP) Category 6A UTP Cable, 4-pair, Green, CMR Rated 9. Berk-Tek 11091203 (LM XTP) Category 6A UTP Cable, 4-pair, Red, CMR Rated 10. Berk-Tek 11085668 (LM XTP) Category 6A UTP Cable, 4-pair, Violet, CMR Rated



1. Leviton 924-49255-L48 Category 6 2RU 48-Port Flat Quickport Mag Lens Patch Panel 2. Leviton 923-49255-L24 Category 6 1RU 24-Port Flat Quickport Mag Lens Patch Panel

3. Leviton 924-49256-L48 Category 6 2RU 48-Port Angled Quickport Mag Lens Patch Panel

4. Leviton 923-49256-L24 Category 6 1RU 24-Port Angled Quickport Mag Lens Patch Panel

5. Leviton 6AUJK-RW6 Atlas-X1 Category 6A UTP Component-Rated Connector, White

6. Leviton 6AUJK-RC6 Atlas -X1 Category 6A UTP Component-Rated Connector, Crimson

7. Leviton 6AUJK-RL6 Atlas-X1 Category 6A UTP Component-Rated Connector, Blue 8. Leviton 6AUJK-RV6 Atlas-X1 Category 6A UTP Component-Rated Connector, Green 9. Leviton 6AUJK-RE6 Atlas-X1 Category 6A UTP Component-Rated Connector, Black

10. Leviton 42080-4WS Quickport 4-Port Wallplate W/ ID Windows, White 11. Leviton 42080-3WS Quickport 3-Port Wallplate W/ ID Windows, White 12. Leviton 42080-2WS Quickport 2-Port Wallplate W/ ID Windows, White 13. Leviton 42080-1WS Quickport 1-Port Wallplate W/ ID Windows, White 14. Leviton 41089-4WP Quickport Surface-Mount Box, 4 Port 15. Leviton 41089-2WP Quickport Plenum Rated Surface-Mount Box, 2 Port 16. Leviton 41089-1WP Quickport Plenum Rated Surface-Mount Box, 1 Port 17. Leviton 41084-BWB Module, Blank, White 18. Leviton 4108W-1SP Quickport Ss Wall Phone Plate 19. Leviton 41089-2WP Quickport 2-Port CMP Surface-Mount Box, White 20. Leviton 6AS10-05* Atlas X-1 Category 6A Slimline Boot Patch Cord, 5' 21. Leviton 6AS10-07* Atlas X-1 Category 6A Slimline Boot Patch Cord, 7' 22. Leviton 6AS10-10* Atlas X-1 Category 6A Slimline Boot Patch Cord, 10' 23. Leviton 6AS10-15* Atlas X-1 Category 6A Slimline Boot Patch Cord, 15'

24. Leviton UAPPP-03* Cat 6A UTP Patch Cord, CMP, Plug-to-Plug, 3'

25. Leviton SAPPP-03* Cat 6A Shielded Patch Cord, CMP, Plug-to-Plug, 3'


Page A-8

A.9 EQUIPMENT ENCLOSURES, RACKS & ASSOCIATED HARDWARE

A. CHATSWORTH


1. Chatsworth 55053-703 Freestanding 2-Post 19” Open Relay Rack, Black 2. Chatsworth 15053-703 Freestanding 4-Post 19” Open Relay Rack, M6, Black 3. Chatsworth 12638-001 10-32 Square Punch Hardware Kit 4. Chatsworth 30162-703 Vertical Cable Management, Double Sided, 6” Wide 5. Chatsworth 30163-703 Vertical Cable Management, Double Sided, 10” Wide 6. Chatsworth 30139-719 Horizontal Cable Management, 1 RU High 7. Chatsworth 30130-719 Horizontal Cable Management, 2 RU High 8. Chatsworth 11564-719 Horizontal Cable Management, 2 RU High, Ring Type 9. Chatsworth 1196X-7** Fixed Wall-Mount Equipment Rack (Black) 10. Chatsworth 1179X-7** Standard Swing Gate Wall Rack (Black) 11. Chatsworth 1532X-7** Heavy duty wall-mounted rack

x Indicates Height and/or Width ** Indicates Depth

B. GREAT LAKES


1. Great Lakes GLRR-1984BA-RMUTA

2-Post Rack with mounting hardware; 84" x 20.31"W X 14"D; with two pair of tapped #12-24 mounting rails w/ cable management "fingers", Black Anodized Finish with RMU numbering label in ascending order

2. Great Lakes 4PM6-32 Freestanding 4-Post 19” Open Relay Rack, M6, Black 3. Great Lakes 4P1224-32 Freestanding 4-Post 19” Open Relay Rack, 10-32, Black 4. Great Lakes 1984ST15 19”W x 15”D Rack Mountable Shelf

5. Great Lakes GL840EN-3242MSS-NS

84"H x 32"W x 42"D EN enclosure with two pair of M6 mounting rails w/ cable management "fingers"; includes 8 levelers, solid top, mesh front door, and split mesh rear door; sides not included

6. Great Lakes GL840EN-3242-FK 84"H x 32"W x 42"D EN enclosure frame with two pair of M6 mounting rails w/ cable management "fingers" on all rails; includes 8 levelers; doors and sides not included

7. Great Lakes 8410-421ENLS Solid Side Panel for 42"D EN Enclosure

8. Great Lakes G101EN Networking/Ganging Kit used to gang two EN enclosures together

9. Great Lakes GR101 Grounding Kit


Page A-9

A.10 INNERDUCT & ASSOCIATED HARDWARE


1. Carlon DF4X1C 1.0" Riser Rated Innerduct with Pull Tape 2. Carlon CF4X1C 1.0” Plenum Innerduct with Pull Tape 3. Endot ICE1.00 1.0” Underground/Duct Innerduct with Pull Tape 4. Carlon DH4X1C 1.5" Riser Rated Innerduct with Pull Tape 5. Carlon CH4X1C 1.5” Plenum Innerduct with Pull Tape 6. Endot ICE1.50 1.5” Underground/Duct Innerduct with Pull Rope 7. Carlon DJ4X1C 2.0" Riser Rated Innerduct with Pull Tape 8. Carlon CJ4X1C 2.0” Plenum Innerduct with Pull Tape 9. Endot ICE2.00 2.0” Underground/Duct Innerduct with Pull Rope

10. KWIKPATH KPTA100 1.0” Plenum Rated Terminal Adapter: 11. KWIKPATH KPTA150 1.5” Plenum Rated Terminal Adapter: 12. KWIKPATH KPTA200 2.0” Plenum Rated Terminal Adapter: 13. KWIKPATH KRTA100 1.0” Riser Rated Terminal Adapter: 14. KWIKPATH KRTA150 1.5” Riser Rated Terminal Adapter: 15. KWIKPATH KRTA200 2.0” Riser Rated Terminal Adapter: 16. MaxCell 4x3 4” 3 Cells Rated for use in OSP Underground Duct 17. MaxCell 3x3 3” 3 Cells Rated for use in OSP Underground Duct 18. MaxCell 2x3 2” 3 Cells Rated for use in OSP Underground Duct

A.11 CABLE RUNWAY & ASSOCIATED HARDWARE

A. CHATSWORTH


1. Chatsworth 10250-7** Cable Runway (10’ section) 2. Chatsworth 10723-7** 90-degree Outside Radius Bend 3. Chatsworth 10724-7** 90-degree Inside Radius Bend 4. Chatsworth 10822-7** 90-degree Flat Bend 5. Chatsworth 11301-701 Butt Splice Kit 6. Chatsworth 10487-701 Adjustable Butt Swivel Splice Kit 7. Chatsworth 11302-701 Junction Splice Kit 8. Chatsworth 10616-701 Adjustable Junction Splice Kit 9. Chatsworth 10596-7** Retaining Post Kit 10. Chatsworth 11268-001 L-Bracket Kit 11. Chatsworth 12100-7** Radius Drop Kit 12. Chatsworth 12101-7** Stringer Radius Drop Kit 13. Chatsworth 11310-003 Ceiling Kit 5/8” Rod 14. Chatsworth 11309-001 Foot Kit 15. Chatsworth 10595-7** Rack to Runway Mounting Plate Kit 16. Chatsworth 10608-001 Vertical Wall Bracket 17. Chatsworth 11746-7** Triangle Support Bracket Kit 18. Chatsworth 11421-7** Wall Angle Support 19. Chatsworth 11306-701 J-Bolt Kit: to Auxiliary Framing Channel 20. Chatsworth 10642-001 End Cap Kit 21. Chatsworth 40164-001 Cable Runway Ground Strap Kit 22. Chatsworth 10595-X** Rack-to-Runway Mounting Plate


Page A-10

B. HOFFMAN


1. Hoffman LSS**BLK Cable Runway (10’ section): 2. Hoffman LOB**BLK 90-degree Outside Radius Bend: 3. Hoffman LIB**BLK 90-degree Inside Radius Bend: 4. Hoffman L90HB**BLK 90-degree Flat Bend 5. Hoffman LBSK Butt Splice Kit: 6. Hoffman LABSK Adjustable Butt Splice Kit: 7. Hoffman LJSK Junction Splice Kit: 8. Hoffman LAJSK Adjustable Junction Splice Kit: 9. Hoffman LRP Retaining Post Kit: 10. Hoffman LLB L-Bracket Kit: 11. Hoffman LRD**BLK Radius Drop Kit: 12. Hoffman LSRDBLK Stringer Radius Drop Kit: 13. Hoffman LCK Ceiling Kit: 14. Hoffman LFK Foot Kit: 15. Hoffman LRRMPBLK** Rack to Runway Mounting Plate Kit: 16. Hoffman LVWB Vertical Wall Bracket: 17. Hoffman LTSB**BLK Triangle Support Bracket Kit: 18. Hoffman LWASK** Wall Angle Support: 19. Hoffman LJBK J-Bolt Kit: 20. Hoffman LEC End Cap Kit: 21. Hoffman LGK Grounding Kit:

** Indicates Width (either 12”, 18” or 24”)

A.12 SURFACE MOUNT RACEWAY & ASSOCIATED HARDWARE

A. PANDUIT

ITEM MFR PART NO. DESCRIPTION 1. Panduit LD***6-A Single Channel Raceway: 2. Panduit JBD**-A Deep Device Box: 3. Panduit CFX***-X Coupler Fitting: 4. Panduit ICFC***-X Inside Corner Fitting: 5. Panduit OCFX***-X Outside Corner Fitting: 6. Panduit RAFC***-X Right Angle Fitting: 7. Panduit TFC***-X Tee Fitting: 8. Panduit ECFX***-X End Cap Fitting: 9. Panduit DCEFX**-X Drop Ceiling Entrance End: 10. Panduit RAEFX**-X Right Angle Entrance End: 11. Panduit RFX****-X Reducer Fitting:

B. WIREMOLD


1. Wiremold 2300BC-** Two-piece Snap-On Cover & Base Surface Raceway

2. Wiremold 2344 Deep Device Box

3. Wiremold 2306-** Cover Clip

4. Wiremold 2317DFO-** Inside Corner Fitting (2” Bend Radius)


Page A-11

5. Wiremold 2318DFO-** Outside Corner Fitting (2” Bend Radius)

6. Wiremold 2311DFO-** Right Angle Fitting (2” Bend Radius)

7. Wiremold 2310-** Blank End Fitting

8. Wiremold 2310A Drop Ceiling Entrance Fitting

9. Wiremold 2300WC** Wire Clip ** Indicates Size and/or Color

A.13 BACKBOXES

ITEM MFR PART NO. DESCRIPTION 1. RANDL TB-55057 5 Square x 2-7/8” Deep Telecom Outlet Box 2. RANDL D51G0** 5 Square x One Gang Extension Ring 3. RANDL R-55000 5 Square Blank Cover 4. RACO 260h 4 Square box

** Indicates Size

A.14 FIRESTOP

ITEM MFR PART NO. DESCRIPTION 1. SpecSeal EZD22 2” EZ-Path Pathway 2. SpecSeal EZD33FWS 3” EZ-Path Pathway 3. SpecSeal EZD44S 4” EZ-Path Pathway 4. SpecSeal NEZ33 3” EZ Smoke and Sound Pathway

A.15 LABELING

ITEM MFR PART NO. DESCRIPTION 1. Panduit LWS-10 Backbone & Horizontal Fiber Optic Cable Jacket: 2. Brady WML-305-502 Backbone & Horizontal Fiber Strand: 3. Panduit PST-FO Backbone Fiber Optic Cable Pathway: 4. Brady PTL-23-427 Voice Trunk Cables: 5. Brady PTL-21-427 Voice-interconnect Cables: 6. Brady CL-111-621 Faceplate Label: 7. Panduit LWS-10 UTP & ScTP Cable Jacket: 8. Panduit C200X050YJC Access Point & Ceiling Grid Label:


Page B-1

APPENDIX B: LABELING SCHEMES


Page B-2

B.1 FIBER STRAND ID CHARTS

A. The charts below are examples of the strand identification charts contained within the Leviton series fiber optic closet connector housings.

B. A separate chart shall be generated for each fiber optic closet connector housing. Upon completion of all fiber optic cable installation and testing, Contractor shall properly complete the fiber strand chart for each closet connector housing. All charts shall be printed on machine generated adhesive backed labels.

C. An electronic copy (in MS Word or Excel format) of each chart shall be submitted with the Contractors as-built documentation in the Network Service Manual.

D. The following is key corresponds to numbers on each chart.

1. Unit ID: Backbone Cabinet No. ## (e.g., MM-01, MM-02, MM-03, etc., numbered in sequential order by fiber type top of rack to bottom, left to right.

2. Serving: Technology Room - Hub No. and Room No. 3. Fed From: Technology Room - Hub No. and Room No. 4. Strand ID: Each block (e.g., A1, A2, etc.) represents a duplex connector; therefore, both

strands must be listed. Strand numbering shall be in sequential order. For MIC cables, numbering is 1, 2; 3, 4; 5, 6; etc. For loose tube cables, include tube color before strand number (e.g., Bl-1, Bl-2; Bl-3, Bl-4; etc.)

5. Date Fiber Optic Cable Installed, 6. Installed By (company name) 7. Link Length (as measured with the OTDR).

Unit ID: 1

Serving: 2 Fed From: 3

1 2 3 4 5 6 7 8

A 4 5 5

B 6 6

C 7 7

D

Figure B-1: Strand Identification Chart for Corning CCH-02U


Page B-3

Unit ID: 1

Serving: 2 Fed From: 3

A B C D E F G H I J K L M

1 4

2

3

4

5

6

7 5 6 7

8

Figure B-2: Strand Identification Chart

B.2 BACKBONE CABLE LABELS

Fiber Optic Cable = ###Orig. = ## / ###Dest. = ## / ###

Strand Count

Room Number

Bldg. Letter Designation

Figure B-3: Fiber Optic Cable Jacket Labeling Scheme

Voice Interconnect = ### pr.Orig. = ## / ###Dest. = ## / ###

Pair Count

Room Number

Bldg. Letter Designation

Figure B-4: High Pair Count Copper Cable Jacket Labeling Scheme


Page B-4

B.3 RACK PLACARDS

A. Each equipment rack shall be labeled using engraved placards. The engraved placards shall be a minimum 2” x 4” with 1/2” lettering and shall be white in color with black lettering.

B. The racks shall be identified by either the Technology Room identification or SRN as shown on the Drawings. The placards shall be mounted on the front, top center of the outside of the rack.

Figure B-5: Rack Labeling Scheme B.4 TELECOMMUNICATIONS OUTLET LABELS

1. Each TO shall be labeled as shown. The Contractor shall be responsible for installing a machine-printed label with the correct TO number and TR ID.

J1-01-115J1-120-01

J1-120-01

J1-01-115 Telecommunications Room ID

Faceplate ID

XX XX XXX

Room NumberTR Number on Floor Building/Floor Identifier

XX XXX XX

Faceplate Number in RoomRoom Number Building/Floor Identifier

Faceplate ID

Telecommunications Room ID

Figure B-6: Legacy Ortronics Faceplate Labeling Scheme

MC ROOM # SRN

RACK #

IC ROOM # SRN

RACK #

HC ROOM # SRN

RACK #


Page B-5

Figure B-7: Leviton 6/6a Faceplate Labeling Scheme


Page C-1

APPENDIX C: DRAWING STANDARDS


Page C-2

C.1 DRAWING STANDARDS

A. Architects and Engineers shall use the following graphical symbols and abbreviations in the development of Technology Design Drawings for Cleveland Clinic facilities.

TELECOMMUNICATIONS OUTLET SYMBOLS

DEVICE SYMBOL DESCRIPTIVE TEXT

WORK AREA DEVICE AT 18" AFF, UON. FOR ADDITIONAL INFORMATION, REFER TO FACEPLATE SPECIFICATIONS AND/OR DETAILS.

W = WALL PHONE RAV = EMERGENCY PHONE A1 = VOICE ONLY A2 = VIDEO 1 A3 = VIDEO 2 G = TIME & ATTENDANCE or Camera H = DUAL DATA

B = DUPLEX (VOICE/DATA) C = TRIPLEX (VOICE/DATA) D = QUAD (VOICE/DATA) K1 = DUAL PATIENT MONITORING K2 = QUAD PATIENT MONITORING S = MULTIMEDIA

WORK AREA ROUGH-IN OUTLET BOX AT 18" AFF, UON

FIRE RATED THROUGH FLOOR FITTING, WORK AREA DEVICE - RECESSED IN FLOOR.

FIRE RATED THROUGH FLOOR FITTING - VOICE/DATA ROUGH-IN - RECESSED IN FLOOR

WORK AREA DEVICE - CEILING MOUNTED.

VOICE/DATA ROUGH-IN OUTLET BOX - CEILING MOUNTED

FURNITURE SYSTEM WORK AREA DEVICE - MOUNTED PER MANUFACTURER’S REQUIREMENTS, UON.

WORK AREA DEVICE AT 8" ABOVE COUNTER, UON.

VOICE/DATA ROUGH-IN OUTLET BOX AT 8" ABOVE COUNTER, UON

WIRELESS ACCESS DROP LOCATION (WALL MOUNTED)

'D' = DATA 'R' = RADIO FREQUENCY TRANSMITTER 'T' = TELEMETRY 'V' = VOICE

WIRELESS ACCESS DROP LOCATION, CEILING MOUNTED

‘C’ = CELLULAR 'D' = DATA 'R' = RADIO FREQUENCY TRANSMITTER 'T' = TELEMETRY 'V' = VOICE

COMBINATION POWER AND WORK AREA DEVICE - IN FLOOR BOX. FLOOR BOX, CONDUIT, POWER DEVICE, AND RELATED POWER WIRING PROVIDED BY EC. FOR ADDITIONAL INFORMATION, REFER TO FACEPLATE DETAILS.


Page C-3

'F' = FLUSH MOUNTED 'S' = SURFACE MOUNTED

INFRASTRUCTURE SYMBOLS


CABLE TRAY – SLOTTED TRAY

‘X’ = SIZE (WIDTH)

CABLE TRAY – WIRE MESH


CABLE RUNWAY – 9” RUNG SPACING


SURFACE MOUNT RACEWAY – REFER TO DRAWINGS FOR REQUIREMENTS

VERTICAL SERVICE POLE

'PVD' = POWER/VOICE/DATA 'VD' = VOICE/DATA

SECURITY SYSTEM SYMBOLS


SECURITY SYSTEM (DEVICE) (ROUGH-IN OUTLET BOX) AT 48” AFF, UON.

'EIA' = EQUIPMENT ALARM INTERFACE ‘K’ = KEYPAD 'KS' = KEY SWITCH ‘M’ = MOTION SENSOR AT 84” AFF, UON. ‘P’ = Panic

SECURITY SYSTEM MAG LOCK - MOUNTED AS INDICATED ON THE DRAWINGS

SECURITY SYSTEM (CARD READER) (ROUGH-IN OUTLET BOX) AT 48” AFF, UON.

SECURITY SYSTEM DOOR CONTACTS - MOUNTED AS INDICATED ON THE DRAWINGS

SECURITY SYSTEM ELECTRIC DOOR STRIKE - MOUNTED AS INDICATED ON THE DRAWINGS

SECURITY SYSTEM GLASS BREAK SENSOR - MOUNTED AS INDICATED ON THE DRAWINGS

SURVEILLANCE VIDEO CAMERA MOUNTING HEIGHT AS INDICATED ON THE DRAWINGS.

SURVEILLANCE VIDEO CAMERA – CEILING MOUNT.

'EIA' = EQUIPMENT ALARM INTERFACE ‘F’ = FLUSH MOUNT 'S' = SURFACE MOUNT


Page C-4

NURSE CALL SYSTEM SYMBOLS


NURSE CALL DEVICE AT 48" AFF, UON

'B' = CODE BLUE STATION 'BIU' = HILLROM BED INTERFACE UNIT AT 18" AFF, UON 'DP' = DOUBLE PATIENT STATION 'DS' = DUTY STATION 'DS/C' = DUTY STATION CODES ONLY 'DS/T' = DUTY STATION CAPABLE OF DISABLING TONES 'EAI' = EQUIPMENT ALARM INTERFACE 'ES' = ENVIRONMENTAL SERVICES CALL BUTTON 'H' = HELP STATION 'HRB' = HILLROM ROOM BOX 'L' = DOME LIGHT AT 90" AFF, UON 'PSA' = PATIENT STATUS ANNUNCIATOR 'R' = ROUGH-IN OUTLET BOX FOR FUTURE NURSE CALL DEVICE 'S' = SHOWER STATION 'SA' = STAFF ASSIST STATION 'SE' = STAFF EMERGENCY 'SP' = SINGLE PATIENT STATION 'SS' = STAFF STATION 'ST' = STAFF PRESENCE 'T' = TOILET STATION

NURSE CALL ANNUNCIATOR - WALL MOUNTED AT HEIGHT AS INDICATED ON DRAWINGS

'A' = ANNUNCIATOR 'BA' = CODE BLUE ANNUNCIATOR 'RA' = REMOTE ANNUNCIATOR

N

NURSE CALL DEVICE - CEILING MOUNTED

'IR' = INFRARED RECEIVER 'L' = DOME LIGHT 'RF' = RADIO FREQUENCY DEVICE 'ZL' = ZONE LIGHT

NURSE CALL MASTER STATION - DESK MOUNTED, UON 'RM' = REMOTE MASTER STATION

NURSE CALL LIGHTING CONTROL RELAY - MOUNTED ABOVE LAY-IN CEILING


Page C-5

MISCELLANEOUS SYSTEM SYMBOLS


VIDEO (DEVICE) (ROUGH-IN OUTLET BOX) - HEIGHT AS SPECIFIED

'P' = PROJECTOR NONE = CATV FACEPLATE

V

VIDEO (DEVICE) (ROUGH-IN OUTLET BOX) - CEILING MOUNT


V

VIDEO DEVICE (DEVICE) (ROUGH-IN OUTLET BOX) - FLUSH IN-FLOOR BOX


PATIENT MONITOR CABLE OUTLET AT 72” AFF, UON.

M

PATIENT MONITOR CABLE OUTLET – CEILING MOUNT.

PAGING SPEAKER (ROUGH-IN OUTLET BOX) - HEIGHT AS SPECIFIED

“X” = ZONE ASSIGNMENT

P

PAGING SPEAKER – RECESSED CEILING MOUNT

“X” = ZONE ASSIGNMENT

INTERCOM STATION AT 48" AFF, UON

'D' = DESK MOUNTED 'HS' = WITH HANDSET 'MS' = MASTER STATION 'M' = MICROPHONE 'OR' = OPERATING ROOM MASTER 'RA' = RESCUE ASSISTANCE 'RAV' = RESCUE ASSISTANCE, VANDAL RESISTANT 'V' = VANDAL RESISTANT

ENTRANCE PROTECTION FOR CLASS II CABLING. FOR ADDITIONAL INFORMATION AND REQUIREMENTS, REFER TO SPECIFICATIONS.

CROSS CONNECT HARDWARE

‘MC’ MAIN CROSS CONNECT ‘MC’ INTERMEDIATE CROSS CONNECT ‘MC’ HORIZONTAL CROSS CONNECT


Page C-6

BROADBAND CATV SYMBOLS


DISTRIBUTION AMPLIFIER W/RETURN AMPLIFIER MODULE

PS

60VAC POWER SUPPLY W/BATTERY BACKUP

POWER INSERTER

IN-LINE EQUALIZER WITH VARIABLE PLUG-IN EQUALIZERS

2-PORT SPLITTER

3-PORT SPLITTER - BALANCED

3-PORT SPLITTER - UNBALANCED

(BLACK DOT INDICATES LOW LOSS PORT)

DIRECTIONAL COUPLER

(** DENOTES TAP-LEG VALUE IN DB)

** 8-PORT TAP

(** DENOTES TAP VALUE IN DB)

**

4-PORT TAP


**

2-PORT TAP


AC BLOCK – TYPICALLY REFERS TO FUSING OF SPLITTERS AND DIRECTIONAL COUPLERS

75-OHM TERMINATOR

DEVICE NODE NUMBER


Page C-7

TECHNOLOGY ABBREVIATIONS

SYMBOL DESCRIPTION

ADA AMERICANS WITH DISABILITIES

AFF ABOVE FINISHED FLOOR

BAS BUILDING AUTOMATION SYSTEM

BEF BUILDING ENTRANCE FACILITY

BFF BELOW FINISHED FLOOR

BICSI BUILDING INDUSTRY CONSULTING SERVICE INTERNATIONAL

CATV COMMUNITY ANTENNA TELEVISION (CABLE TV)

CBC COUPLED BONDING CONDUCTOR

CM CONSTRUCTION MANAGER

CT CABLE TRAY

EC ELECTRICAL CONTRACTOR

DAS DISTRIBUTED ANTENNA SYSTEM

DVR DIGITAL VIDEO RECORDER

EIA ELECTRONICS INDUSTRIES ASSOCIATION

EMT ELECTRICAL METALLIC TUBING

ETR EXISTING TECHNOLOGY DEVICE TO REMAIN

GC GENERAL CONTRACTOR

HC HORIZONTAL CROSS-CONNECT

HVAC HEATING, VENTILATING, AND AIR CONDITIONING

IC INTERMEDIATE CROSS-CONNECT

IG ISOLATED GROUND


Page C-8

SYMBOL DESCRIPTION

LAN LOCAL AREA NETWORK

LVER LOW VOLTAGE EQUIPMENT ROOM

MC MAIN CROSS-CONNECT

MM MULTIMODE

MUTOA MULTI-USER TELECOMMUNICATIONS OUTLET ASSEMBLY

NEC NATIONAL ELECTRICAL CODE

NESC NATIONAL ELECTRICAL SAFETY CODE

NEX

REMOVE EXISTING TECHNOLOGY DEVICE AND INSTALL NEW TECHNOLOGY DEVICE IN EXISTING OUTLET BOX. REFER TO NEW FLOOR PLANS FOR NEW DEVICE TYPE AND CABLING REQUIREMENTS. PROVIDE NEW FACEPLATE.

NFPA NATIONAL FIRE PROTECTION ASSOCIATION

NI NETWORK INTERFACE

NIC NOT IN CONTRACT

OBC OHIO BUILDING CODE

OFE OWNER FURNISHED EQUIPMENT

OSP OUTSIDE PLANT

PTZ PAN, TILT, ZOOM

RD NEW LOCATION OF RELOCATED TECHNOLOGY DEVICE

RCDD REGISTERED COMMUNICATIONS DISTRIBUTION DESIGNER

REX REMOVE EXISTING TECHNOLOGY DEVICE ALONG WITH RELATED CONDUIT AND CABLING, UON

RR REMOVE AND RELOCATE EXISTING TECHNOLOGY DEVICE AS SHOWN OR AS NOTED ON DRAWINGS

SM SINGLE MODE

STP SHIELDED TWISTED PAIR


Page C-9

SYMBOL DESCRIPTION

SVC SURVEILLANCE VIDEO CAMERA

TB TELECOMMUNICATIONS BACKBOARD

TBB TELECOMMUNICATIONS BONDING BACKBONE

TC TECHNOLOGY CONTRACTOR

TGB TELECOMMUNICATIONS GROUNDING BUS BAR

TGS TELECOMMUNICATIONS GROUNDING SYSTEM

TIA TELECOMMUNICATIONS INDUSTRY ASSOCIATION

TMGB TELECOMMUNICATIONS MAIN GROUNDING BUS BAR

TR TECHNOLOGY ROOM

UG UNDERGROUND

UPS UNINTERRUPTIBLE POWER SUPPLY

UON UNLESS OTHERWISE NOTED

WAP WIRELESS ACCESS POINT

WPF WEATHERPROOF


Page D-1

APPENDIX D: TYPICAL DESIGN DRAWINGS


Page D-2

This Section Left Intentionally Blank

Typical Design Drawings Provided by Project


Page E-1

APPENDIX E: ARCHITECTURAL GUIDELINES FOR WORK AREAS


Page E-2

E.0 ARCHITECTURAL GUIDELINES FOR WORK AREAS

A. The following sections provide guidelines for architects and consulting engineers related to the placement of technology outlets within the various clinical and non-clinical work areas.

E.1 WORK AREA FURNITURE

A. When designing work area furniture, placement and configuration, and the use of technology within these areas, architects should consider the following design points.

B. Furniture design and layout should be as ubiquitous as possible in terms of incorporating technology (e.g., brush grommets along the wall side of a desk vs. circular grommets cut into the desk provide greater flexibility for movement and greater cable capacity).

C. Furniture design should consider future state of equipment by providing a 20% increase in size and/or change in orientation (front-to-back airflow vs. side-to-side).

D. All PCs and printers must be fully accessible, movable and properly vented (provide at least 6-inches of space around the device and venting for enclosed devices.

E. Any pullout drawers and/or trays and associated slide apparatus that will be used to mount equipment should be rated for 100 lbs. and must have handles. Millwork extensions or pulls may not be sufficient to allow the drawer or tray to pull out easily once equipment is in place.

F. Millwork and modular furniture must provide continuous cable paths from point of entry to faceplate. Where possible factor a minimum 50% growth for future cable capacity.

G. Faceplates must be visible and not hidden behind millwork or modular furniture. E.2 POSITIONING OF WIRELESS ACCESS POINTS

A. Wireless Access Points (WAPs) shall be designed and installed below lay-in and/or fixed ceilings. WAPs are designed with the internal antennas to be between 8’ and 10’ in height from the work area. Access points with internal antennas also need to be installed a minimum of 1m away from metal objects. Placing WAPs above the ceiling will degrade signal strength and coverage (for more detailed technical information on WAP placement, refer to an internal whitepaper published by ITD).

B. WAPs shall be wall or ceiling mounted using manufacturer approved mounting hardware, and shall be placed so as not to interfere with other ceiling mounted services, such as telemetry, fire suppression systems, lighting, etc.

C. Whenever possible and based on site survey results, place WAPs in accessible areas, such as hallways, conference rooms, general work areas, etc.

ORK AREA/FACEPLATE MATRIX

matrix details the recommended number of faceplates by type for each workspace within a Cleveland Clinic Health System ate type and quantity by workspace are subject to change based on individual end-user department requirements. The eer is required to interview each end-user department to confirm faceplate type, quantity and location during Design

TELECOMMUNICATIONS FACEPLATE TYPECOMMENTS

Quad

Triplex

Duplex IP TV

Wall Phone

CableTV

Multi-Media

BMT) 1 1 1

1 1

2 1 1 Quad and Patient Monitor faceplates installed in headwall or gas column. Coordinate with user group.

2

6

4

1

1

1

1

5 1 1 1 One quad on each wall and in floor box under conference table.

1 Minimum one phone per corridor, confirm actual quantities and locations with nursing unit.

Minimum one wall phone per corridor (confirm locations with Cleveland Clinic security and telecom).

oom 2 1 1 Quad and Patient Monitor faceplates installed in headwall or gas column. Coordinate with user group.

1

1

Wall phone as needed (usually based on room size).


Page E-4

ROOM TYPE TELECOMMUNICATIONS FACEPLATE TYPE

COMMENTS Quad Triplex Duplex

IPTV

Wall Phone

Cable TV

Multi-Media

Electrical Room 1 1 Minimum requirements for building management system(s) coordinate with MEP engineers.

Elevator Lobby (Public)

Elevator Lobby (Service) 1

Elevator Equipment Room Minimum one quad for each elevator group (coordinate with elevator equipment company).

Exam Rooms 2

Intensive Care Unit (ICU) 2 1 1 Quad and Patient Monitor faceplates installed in headwall or gas column. Coordinate with user group.

Laboratories 1 1 Minimum one quad per each lab tech workstation, and PC and printer location.

Labor Delivery & Recovery (LDR) 2 1 1 1

Linen Chute Room

Lobby – Main/Reception Area 1 1 1 Minimum one quad at each receptionist workstation and one CATV drop at each TV location.

Lobby – Secondary/Reception Area 1 1 1 Minimum one quad at each receptionist workstation and one CATV drop at each TV location.

Lobby – Secondary/Waiting Area 1 1 1 Minimum one quad at each receptionist workstation and one CATV drop at each TV location.

Locker Rooms 1

Lounge – Staff 1 1 1 1

Main Entrance Vestibule 1

One quad at each valet parking station

Bone Marrow Transplant (BMT) 1 1 1

Mechanical Rooms 1 1 Minimum one quad for building management system(s), coordinate with MEP engineers.

Medical Gas Storage

Nurse Station 21


Page E-5



IPTV

Wall Phone

Cable TV

Multi-Media

Offices – Administrator 1 1

Offices – “C Level” 1 1

Offices – Dept Chair 1 1

Offices – Manager 1

Offices – Open Office (Modular) 1

Offices – Physician 1 1

Operating Rooms 9 2 2

Patient Hold 2 1

Patient Room 1 1 1 One quad located at headwall, and second quad located at wall mount computer location.

Patient Day Room 3 1 1

PET/CT Control Room 5 1

Pharmacy - Inpatient Minimum one quad per each pharmacist workstation, and PC / printer location.

Pharmacy - Outpatient 1 1 Minimum one quad per each pharmacist workstation, and PC and printer location.

Post Anesthesia Care Unit (PACU) 2 1 1

Post-Partum Rooms 2 1 1

Pre / Post Op 3 1 1

One quad located at headwall, and second quad located at wall mount computer location.

Equip Prep (Sterile Processing) Minimum one quad faceplate per each technician workstation, PC and printer location.

Procedure Rooms – Invasive 4 1 Locate one patient monitor quad on each side of patient bed.


Page E-6



IP TV

Wall Phone

Cable TV

Multi-Media

Procedure Rooms – Non-invasive 1 1

Radiology Rooms – General 1 1

Short Stay Room (SS) 2 1 1

Soiled Utility Room

Radiology Reading Room 1 1

Minimum one quad per each radiologist reading workstation.

SPEC/CT 5 1

Step Down Units 2 1 1 1

Storage Rooms

Telecommunications Rooms 1

NOTES:

1. Wireless faceplate locations are determined in two stages. During the design stage, the design engineer estimates the wireless faceplate locations based on one faceplate per 1,100sq/ft. Once the building is constructed (including internal walls, floors and ceilings), the placement of wireless faceplates is confirmed through an extensive site survey.

2. Both an IPTV (UTP Cable) connection and a Cable TV (Coaxial Cable) connection are provided for reference. The design engineer shall establish with The Cleveland Clinic, which system shall be incorporated into the design.


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APPENDIX F: PROJECT PLANNING


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F.0 PROJECT PLANNING

A. The following sections provide detailed planning information in regards to Technology Room build-out and turnover during construction. Note that turnover of the Technology Equipment Center and Technology Distribution Rooms can be sequentially phased based on substantial completion of each floor and/or go-live schedule.

F.1 Technology Room Readiness

B. Stage One – Room Turnover to Low Voltage Contractor

1. The General Contractor / Construction Manager shall ensure the following items are complete prior to permitting the low voltage Contractor into the room to pull/terminate cable:

a) Plywood Backboard (Painted white and installed) b) Flooring (static dissipative per standards) - masonite / ram board installed to protect

flooring c) Lighting (temporary is permitted, but prefer permanent fixtures should be installed) d) Grounding (floor and ground bar per standards, including labeling)

B. Stage Two – Room Turnover to ITD

1. The following tasks must be complete within each room in order for the Cleveland Clinic ITD Technology Services Teams to begin equipment installations, and end user voice /data activation and commissioning. Note that the Technology Equipment Center should be turned over first in order to facilitate backbone fiber and copper connectivity to the Technology Distribution Rooms.

a) Branch Panel installed if applicable b) Power receptacles and centralized UPS power available and operational (UPS and

Emergency Power is permissible) c) Equipment racks installed d) Cable Runway installed e) Overhead cable work complete f) Mechanical units installed and operational (temporary units are permissible until

commissioning is complete with prior notice to Owner) g) Fiber/copper backbone installed, secured and terminated in the racks h) Sprinkler lines installed and active i) Smoke head installed and active j) Horizontal Cabling terminated at the racks k) Test results provided to owner for all cabling/fiber, as-built drawings and warranty

certificates. l) All labeling completed m) Door security with restricted access to Construction Manager and LV contractor n) Final Clean o) Emergency power fully operational p) Matrix badge readers active

C. Stage Three – Room Turnover to ITD End User Technology Team

1. The following are required in order to have the room ready for the ITD End User Technology Team to deploy PC’s, WOW’s and printers. Specific durations for various


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teams to complete the work are sequentially based on a per floor/room timeline and are not in relation to building go-live.

2. Network Services complete network switch installation and configuration:

a) Technology Equipment Center – 4 weeks from turnover b) Technology Distribution Room – 2 weeks from turnover

3. Low Voltage Contractor and Matrix Systems activate access control system:

a) Technology Equipment Center – 4 weeks from turnover b) Technology Distribution Room – 2 weeks from turnover

4. Low voltage Contractor patching of ports into network switch with completed and printed patching matrix:

a) Technology Equipment Center - 1 week after switch install b) Technology Distribution Room – 1 week after switch install

5. Network team configuring ports:

a) Technology Equipment Center - 1 week after switch patching complete b) Technology Distribution Room – 1 week after switch patching complete