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© The Epsten Group, Inc. 2014
About Us
Epsten Group Services:
Commissioning
Retro-Commissioning
Building Envelope Services
Roofing & Waterproofing Consulting
Architecture & Interior Design
LEED Consulting
Energy Modeling
• Established in 1991
• Multi-Disciplinary
• 6,000 LEED Reviews in 50+ Countries
• Small Disadvantaged Business; 8(m) WOSB
Guide to ASHRAE 90.1 Changes
P r e s e n t a t i o n f o r C x E n e r g y 2 0 1 4A A B C C o m m i s s i o n i n g G r o u p
L a s Ve g a s , N e v a d aA p r i l 2 3 , 2 0 1 4
At the end of this course, participants will be able to:
1. Participants will learn how the ASHRAE 90.1 energy standard has evolved in recent years up to the current version that has been adopted.
2. Participants will be able to distinguish the major amendments to the standard that have led to substantial energy improvements from the last version.
3. Participants will learn how the changes to 90.1 and its Appendix G will affect the latest version of LEED and consequentially building energy models.
4. Participants will learn how the changes to the standard will impact the building industry and particularly how it will impact commissioning providers.
Learning Objectives
1.0 Evolution
First drafted in 1975
Major re-write of the standard in 1999
Continuous maintenance began in 2001 (every 3 years)
ASHRAE 90.1-2007 updated from 2004 via 44 addenda
ASHRAE 90.1-2010 updated from 2007 with more than 100 addenda
1.1 ASHRAE 90.1-2010 Goal
Set out to achieve a 30% energy savings when compared to ASHRAE 90.1-2004.
Goal achievement proven by Pacific Northwest National Laboratory (PNNL)
Substantial energy efficiency improvement when compared to earlier iterations
Sidenote: Significant implications for LEED pursuit in LEED v4
1.2 Major Sections
5.X Envelope
6.X Mechanical
7.X Service Water Heating
8.X Power
9.X Lighting
Appendix G (Performance Rating Method)
1.3 Compliance
5.X Envelope
6.X Mechanical
7.X Service Water Heating
8.X Power
9.X Lighting
Appendix G (Performance Rating Method)
1.4 Climate Zones
1.5 Building Prototypes
Small/Medium/Large Offices Retail/Strip Mall Primary/Secondary Schools Outpatient Healthcare Hospital Small/Large Hotels Warehouse Quick/Full-Service Restaurants Mid-Rise/High-Rise Apartments
2.0 Envelope Changes
Continuous air barrier
Cool roofs
Constraints on glazing
2.0.1 Air Barriers
A properly functioning air barrier system provides a barrier against both the air leakage and the diffusion of air caused by wind, stack, and mechanical equipment pressures.– According to the ABAA, air leakage
can result in increased energy costs of up to 30-40% in heating climates and 10-15% in cooling climates
– The additional benefit to air barriers is that they keep unconditioned, moist air out of the building and reduce the possibility of mold growth
2.1.1Continuous Air Barrier
Permeance ≤ 0.004 cfm/sf– Individual materials: plywood, insulation
board, metal
Permeance ≤ 0.04 cfm/sf– Assemblies or materials
All air barrier components must be clear on documents
All joints, penetrations must be detailed Barrier must extend over all envelope
surfaces Barrier must be design to resist
positive AND negative pressures
2.1.2 Continuous Air Barrier
Construction of barrier must include sealing, caulking, gasketing, or weather-stripping:– Joints (windows and doors)– Junctions of walls to foundation or roofs– Openings– Any penetrations through vapor retarders
Exceptions:– Semi-heated spaces in Climate Zone 1
through Zone 6
2.2 Cool Roofs
Required in Climate Zone 1 through Zone 3
Certified by ASTM– 3 year aged solar reflectance ≥ 0.55 and
emmittance ≥ 0.75 OR– 3 year aged SRI ≥ 64 OR– Increased insulation of Table 5.5.3.1.2
Numerous exceptions are noted
2.3 Glazing
Window Wall Ratio ≤ 40% of gross wall area (prescriptive path)
Skylight roof ratio ≤ 5% of roof area
Major changes for SHGCs over 90.1-2004 which apply to all orientations
SHGC reductions through use of overhangs
3.0 HVAC Changes
Efficiency ratings on equipment
Energy recovery
Economizers
Duct sealing/leakage
Fan power
Reheat
3.1 Simplified Approach Option
Only applies to HVAC section
Acceptable for buildings that are 1 to 2 stories and < 25,000 sf
Must also meet 17 separate criteria
3.2 Efficiency Updates
Unitary AC and heat pumps Single zone VAV Water-cooled units Packaged units and heat pumps Water-to-water heat pumps CRAC units VRF Chillers Cooling towers Heat exchangers Heat pump pool heaters Furnaces and water heating
3.3 Economizers
Comfort cooling– Not required for 1A and 1B– Required for all other zones where the cooling
capacity is ≥ 54,000 Btu/h
Computer rooms– Not required in 1A, 1B, 2A, 3A, 4A– Required in other zones dependent on tonnage
Exempt:– If able to prove efficiency improvement for the
climate zone
3.4 Waterside
Two-position valves in water-cooled units (i.e. SWUD units)
Variable flow/pumping Pump pressure optimization No regulation downstream of booster pumps Maximum flows in nominal pipe sizes Significant insulation upgrades, particularly for
steam and hot water systems
3.5.1 Airside
Ventilation optimization Supply air temp reset Limitation on damper leakage Dual maximum for VAV terminal units Overhead heating temp limit Lab VAV exhaust air Demand control ventilation Fan power limitation
3.5.2 Airside
Exhaust air energy recovery
4.0 Lighting Changes
Lighting power density improvements
Exterior building lighting updates
Grounds lighting
4.1 Lighting Power Density
Most spaces defined in standard have lower LPDs than 2007 and reductions are substantial
Important to keep in mind impact of these requirements on cooling and heating load calculations
Average reduction of 16.2% in LPDs versus 90.1-2007
4.2 Auto Shutoff/Dimming
Time clock with separate shutoff for each floor or building > 25,000 sf OR
Occupancy sensors set to 30 minutes OR
Separate signal from controls indicated the space is unoccupied
Daylight switching for daylit areas > 250 sf
4.3 Exterior Lighting
Turn off when adequate daylight available
Façade and landscape lighting off between closing or midnight and 6 am or opening
Reduced lighting of advertising overnight
Reduction in lighting power densities, depending on zone
5.0 LEED EAp2 Impact
LEED v2009 requires a 10% energy cost savings when compared to the baseline building as defined by ASHRAE 90.1-2007
LEED v4 requires a 5% energy cost savings when compared to the baseline building as defined by ASHRAE 90.1-2010
5.1 LEED EAc1 Impact
0 2 4 6 8 10 12 14 16 18 200%
10%
20%
30%
40%
50%
60%
6%8%
10%12%
14%16%
18%20%
22%24%
26%
29%
32%
35%
38%
42%
46%
50%
54%
14%16%
18%20%
22%24%
26%28%
30%32%
34%36%
38%40%
42%44%
46%48%
50%
EAc1 Point Comparison
v2009
v4
6.0.1 Energy Modeling Impact
Appendix G– Section G1.4 has been revised to include a more
detailed list of required documentation to be submitted to the rating authority.
– Section G2.5 has been revised to more clearly explain the Exceptional Calculation Method procedure and what documentation is required to justify the results.
– Section G3.1.1 includes new exceptions for additional system types for kitchens and heated only spaces (new Baseline system types 9 and 10).
– Section G3.1.1.1 through Section G3.1.1.3 provide new guidance for modeling district heating and cooling systems.
6.0.2 Energy Modeling Impact
Appendix G (continued)– Table G3.1(14) includes new guidance regarding
“exterior conditions” (adjacent structures and terrain, ground temperatures, and water main temperatures).
– Section G3.1.2.6 has been revised to more clearly explain how to take credit for improved ventilation systems (i.e. demand control ventilation)
– Section G3.1.2.9 includes new provision for sizing supply air volumes in the Baseline model for laboratories.
– Section G3.1.3.13 includes additional requirements for VAV minimum setpoints in the Baseline model for laboratories.
7.0 Impact on Building Industry
Jump in energy performance requirements to drive vendors to be more aggressive
Architects, engineers and contractors will have a learning curve on new requirements
Initially expect increased cost of construction while industry catches up
Even more importance now on technical competence across all trades, but specific focus on controls technicians that are required to implement more complex strategies
7.1 Impact on Commissioning
Elevated performance requirements leading to more complex building systems– HVAC and Controls– Lighting controls– Integration of other systems
Commissioning providers required to be knowledgeable on optimization requirements stipulated in energy code
Opportunity for commissioning professionals to provide guidance and lessons learned on success of optimization strategies to design engineers
7.2 References
http://www.seco.cpa.state.tx.us/tbec/videos.php
http://www.pnnl.gov/publications/abstracts.asp?report=358270
Knowledge acquired:
1. Participants learned how the ASHRAE 90.1 energy standard has evolved in recent years up to the current version that has been adopted.
2. Participants are able to distinguish the major amendments to the standard that have led to substantial energy improvements from the last version.
3. Participants learned how the changes to 90.1 and its Appendix G will affect the latest version of LEED and consequentially building energy models.
4. Participants learned how the changes to the standard will impact the building industry and particularly how it will impact commissioning providers.
Conclusion
Please feel free to ask any questions you may have for today’s course presenters.
Questions
Thank You For Your Time
About Us
Epsten Group Services:
Commissioning
Retro-Commissioning
Building Envelope Services
Roofing & Waterproofing Consulting
Architecture & Interior Design
LEED Consulting
Energy Modeling
• Established in 1991
• Multi-Disciplinary
• 5,500 LEED Reviews in 50+ Countries
• 8(a) Certified; Small Disadvantaged Business; 8(m) WOSB