PENNSTATECreative Campus

Department of Mechanical and Nuclear Engineering

Modifications to Various Systems for a Rolling Dance Vehicle

A design specification report for a transmission and braking mechanism for a twelve foot dance vehicle, capable of supporting six dancers.

March 15, 2012

Stephen Thor

Brett Cowan

Jon Tackie

Jason KurucIntellectual Property Rights Agreement:No

Steven BatesNon-Disclosure Agreement:No

Executive Summary

This design specification report (DSR) by The Penn State Engineering Design Team is an outline for the development and design of a gliding transmission that will be implemented on a large dance vehicle. This dance vehicle will have an inner cage that rotates freely on 12 diameter wheels. The team was tasked with designing a fully functional mechanism that would be completed in 10 weeks (due April 2nd, 2012) within a $1000 budget. The primary needs of the dancers and architects are to minimize noise and friction while ensuring that the vehicle is safe to use.

A roller coaster wheel design was selected to construct the gliding mechanism. The primary design consists of four wheels mounted in a T configuration. There are two in-line wheels on the bottom of to bear the load of the inner cage and dancers. There is one guide wheel on either side of the guide rail to prevent the cage from slipping off of the 12 diameter wheels that they are attached to.

The design team was requested by the sponsor to produce a pre-alpha prototype, allowing them to visually understand the chosen design for the gliding mechanism. Three 2 wide by 3.5 diameter brown phenolic wheels were ordered for this pre-alpha prototype. The team spent one week manufacturing the gliding mechanism, primarily out of plywood and metal shafts. After completion, the sponsor and the architects were better able to grasp the teams proposed concept. During manufacturing, the team discovered that the brown phenolic wheels would not be suitable for the final design due to the low quality of the roller bearings in them. Only the inside of the wheel would spin freely which would cause additional friction between the wheel and the casing.

The next step for the team was to order wheels with stronger bearings that would not cause any friction between the wheel and the casing and could still withstand the loads that will be applied. The team decided to order four 1 wide by 5 diameter performance rubber-tred wheels because they met all the needs that were discovered during the pre-alpha prototype. A new SolidWorks drawing of the casing was generated for the new wheels. This SolidWorks drawing was used to water jet the casing out of 1/16 thick stainless steel sheet metal to manufacture the alpha prototype for testing. In addition to the 1/16 thick stainless steel, the team used 1.5 square steel tubing for additional supports. After completion, the team met with the sponsor and tested the strength of the alpha prototype. The prototype was loaded and rolled down a rail to analyze friction and deflection of the wheels. The wheels and the casing proved to be satisfactory for the final design. The team has recently ordered the steel and additional wheels for the 6 sets of 4 gliding mechanisms.

The total cost of the gliding mechanisms and sheet metal come to $700. The steel used for the framing of the dance vehicle was donated which means there is $300 available to machine components and make small purchases as needed as the project progresses. The budget for this project is $1000 and since the team only has $700 spent, the project is under budget and on schedule thus far.

Table of ContentsExecutive Summary21.0 Introduction41.1 Background41.2 Initial Problem Statement41.3 Objectives52.0 Customer Needs Assessment52.1 Gathering Customer Input52.2 Weighting of Customer Needs63.0 External Search73.1 Patents83.2 Existing Products84.0 Engineering Specifications94.1 Establishing Target Specifications94.2 Relating Specifications to Customer Needs95.0 Concept Generation & Selection105.1 Problem Clarification105.2 Concept Generation115.3 Concept Selection166.0 System Level Design187.0 Special Topics197.1 Preliminary Economic Analyses- Budget and Vendor Purchase Information197.2 Project Management207.4 Ethics Statement218.0 Detailed Design228.0.1. Modifications to Statement of Work228.0.1.1. Introduction228.0.1.2. Customer Needs Assessment228.0.1.3. External Search228.0.1.4. Engineering Specifications228.0.1.5. Concept Generation and Selection238.0.1.6. System Level Design238.0.1.7. Special Topics248.1 Manufacturing Process Plan248.2 Analysis258.3 Material and Material Selection Process268.4 Component and Component Selection Process278.5 CAD Drawings278.6 Test Procedure288.7 Economic Analysis- Budget and Vendor Purchase Information29References29Appendices31Appendix A: Full Customer Needs List31Appendix B: Engineering Parameters33Appendix C: Design Team Budget34Appendix D: Bill of Materials35Appendix E: Gantt Chart37Appendix F: Layout of transmission piece for water jetting38Appendix G: Dimensioned drawings of transmission components39Appendix H: Team Resumes43

1.0 Introduction

1.1 Background

A group of Penn State faculty was issued a grant from the Doris Duke Foundation to work with the Diavolo dance company to create a new performance piece. Diavolo Dance Theater is an internationally renowned modern acrobatic dance company (www.diavolo.org). The theme of the project is walking and focuses on the relationship between people, technology, and public spaces. The faculty and students brainstormed and generated an idea for a 12 ft. dance vehicle that would successfully incorporate all of these elements. The idea is that people can walk within the 12 ft. diameter wheels of the dance vehicle to make it transverse terrain, thus connecting people (dancers), technology (the dance vehicle), and public spaces (the terrain upon which the dance vehicle maneuvers). A prototype with a planetary gearing system was built before the engineering design team was presented with the project.

1.2 Initial Problem Statement

The Penn State University engineering design team was presented with a problem concerning the transmission of a large 12 ft. dance vehicle. A design was to be implemented for a gliding/braking mechanism that would allow the inner cage of the dance vehicle to rotate independently from the outer wheels that maneuvered on the terrain. The gearing system of the prototype had to be improved in order for the dance vehicle to operate smoothly and to allow the inner cage to rotate freely. All of this had to be done while minimizing noise and friction that would be created by metal-on-metal contact points. The dance vehicle would not be moving faster than about 5-10mph which influenced the sponsors decision in manufacturing a braking system. The sponsor stated that if time permitted, the design team would create a braking mechanism after the completion of the gliding system. The team has a number of goals to achieve while working under a $1000 budget.

1.3 Objectives

The objective of the project for the design team was to design a gliding mechanism that allowed the inner cage to rotate freely from the outer wheels. This gliding mechanism was to have a braking system that would lock the cage to the wheels; thus the cage would rotate as the wheels rotated. The sponsor noted that manufacturing the braking system was a secondary goal for the team and that completion of that component was not paramount. The architects and the dancers were mainly focused on generating a smooth gliding system. The steel tubing used to construct the dance vehicle did not come out of the Design Teams $1000 budget. The team had sufficient funds to create and manufacture the gliding/braking mechanism. Because the entire budget was allocated entirely towards such a small scope of the design, few limitations were placed on the design. This provided the opportunity for much creative freedom. The team was expected to deliver all aspects of the project on time, as indicated by the sponsor, and with high quality. The design teams main priority was to satisfy most, if not all, of the customer needs listed in section 2.

2.0 Customer Needs Assessment

2.1 Gathering Customer Input

The engineering design team worked closely with the Penn State faculty in architecture, landscape architecture, and dance. The customers for the 12ft. dance vehicle were the three architects (Marcus Shaffer, Alex Bruce, and Kyle Brown) and six selected dance performers that would be using the vehicle in April. The design team worked closely with the architects multiple times each week to specify what issues needed to be resolved. Meetings were held every Friday with both the architects and dancers to discuss what alterations needed to be made to the design and what were the goals for the following week. Detailed records of the customer needs are included in the Appendix A.

The primary needs of the customers were for the design team to redesign and improve the transmission and gearing elements to allow the inner cage to spin freely from the outer two wheels while reducing friction and noise. It is important to address that the design team decided that safety is paramount in this particular project. Heavy materials were used and dancers were performing in the vehicle while it is in motion.

2.2 Weighting of Customer Needs

By gathering the customer needs, the team was then able to assess each one. Weighting of these needs was vital to the project because the team could clearly identify what main requirements would be needed in the vehicle. Weighting the customer needs also enabled the team to prioritize what aspects of the vehicle to work on to ensure the highest satisfaction by the customer. Speaking directly with the architects and dancers gave the team substantial amount of information to generate a Comparison Chart to weigh the most important needs.

Table 1. AHP Comparison Chart to Determine Weighting for Main Objective Target Specifications

Safe

Ease of Use

Ease of Mfg

Cost

Aesthetics

Stability

Dur.

Visib.

Precise/Accurate

Total

Weight

Safe

1.00

2.00

2.00

2.00

4.00

2.00

2.00

5.00

2.00

22.00

0.16

Ease of Use

0.50

1.00

1.00

0.33

3.00

0.33

0.25

3.00

0.33

9.75

0.09

Ease of Mfg

0.50

1.00

1.00

1.00

5.00

1.00

0.50

3.00

2.00

15.00

0.11

Cost

0.50

3.00

1.00

1.00

3.00

1.00

1.00

4.00

2.00

16.50

0.11

Aesthetics

0.25

0.33

0.20

0.33

1.00

0.25

0.20

1.00

0.25

3.82

0.08

Stability

0.50

3.00

1.00

1.00

4.00

1.00

1.00

5.00

2.00

18.50

0.14

Durability

0.50

4.00

2.00

1.00

5.00

1.00

1.00

5.00

2.00

21.50

0.14

Visibility

0.20

0.33

0.33

0.25

1.00

0.20

0.20

1.00

0.25

3.77

0.08

Precise/ Accurate

0.50

3.00

0.50

0.50

4.00

0.50

0.50

4.00

1.00

14.50

0.1

Table 2 lists each customer need in order from most important to least important

Table 2. Weighted Hierarchal Customer Needs

1. Safety (0.15, 0.15)

0. Large hand and foot placements (0.05, .333)

0. Moving parts are concealed (0.1, 0.666)

1. Durability (0.13, 0.13)

1. Strong material (0.065, 0.5)

1. Strong under dynamic force loading (0.0325, 0.25)

1. Tolerate long periods of operation (0.0325, 0.25)

1. Stability (0.13, 0.13)

2. Structure can support the loads (0.065, 0.5)

2. Minimal vehicle vibration (0.065, 0.5)

1. Cost (0.10, 0.10)

3. Inexpensive components (0.033, .333)

3. Stay within the budget (0.067, 0.666)

1. Ease of Manufacturing (0.10, 0.10)

4. Easy to assemble (0.05, 0.5)

4. Purchase completed components (0.05, 0.5)

1. Precise/Accurate (0.10, 0.10)

5. No rough edges (0.025, 0.25)

5. 90 degree bent angels (0.025, 0.25)

5. Tightly secures roller mechanism (0.05, 0.5)

1. Ease of Use (0.08, 0.08)

6. Dancers can move freely (0.06, 0.75)

6. Vehicle can move without having to use excessive force (0.02, 0.25)

1. Visibility (0.07, 0.07)

7. User can be seen while operating/dancing (0.035, 0.5)

7. Audience can see from any angle the performance (0.035, 0.5)

1. Aesthetics (0.07, 0.07)

8. Pleasing to the eye of the audience (0.035, 0.5).

8. Get a sense of play while watching the performance (0.035, 0.5).

After completing the Comparison Chart and the Hierarchical Needs List, the team was able to determine that safety, stability, durability, and ease of manufacturing were the areas of most concern and required greatest concentration during the design process. The outcome of the AHP Chart and the Hierarchical Needs List aided the team in the generation and selection of concepts for the vehicle while meeting the primary needs of the customer.

3.0 External Search

The design teams external search focused primarily on a way to allow the inner cage of the dance vehicle to move independently from the outer wheels. In order to accomplish this, the team researched systems involving objects moving on rails. One design was a monorail car, which hung from a grooved horizontal bar with two wheels oriented at angles that fit inside the grooves (as seen in References). Another system was a roller coaster car that had two wheels above and below the rail and an additional two wheels either on the inside or outside of the rail (as seen in References).The reason for the multitude of wheels in these systems was to avoid wheels disengaging from the guide rail and to support the heavy loads. For the monorail, the wheels were kept in place because of their location within the groove of the rail. As for the roller coaster car, the wheels above and below are load bearing, while the wheels on the side keep the system in place. Both systems were under consideration when generating concepts, which is further detailed in Section 5.Along with the rail systems, braking systems were also researched. The team focused on simpler designs, including brake pads, because they would be easier to install and would be less of a hazard for the dancers within the vehicle.

3.1 Patents

Prior to establishing the engineering specifications and beginning the concept generation process, a patent search was carried out. By performing this search, it was determined that there were several existing technologies which could be incorporated into the design of the dance vehicle. The types of technologies that were most highly researched were patents for roller coaster wheels and gliding assemblies, roller coaster braking systems, and motorcycle and bicycle hydraulic disk brake systems. The team concluded through the research that while roller coaster braking systems would not be suitable for this project, the gliding mechanisms could certainly be adopted and modified as necessary. Additionally, the hydraulic disk brake systems seen on modern bicycles could be integrated to work with the dance vehicles sub-systems (gliding mechanism).

Table 3: Art-Function Matrix

3.2 Existing Products

The search for existing dance vehicles yielded few results. An extensive search to find other dance vehicles of this nature did not present any results similar to the PSU Creative Campus 1 Project. This presents the unique and challenging problem of having essentially no existing research or knowledge in the art of building a dance vehicle. However, this also affords much opportunity for creative freedom in design without being restricted by any sort of standard. Because there are no current designs such as the one which is being proposed, the vehicle can take on virtually any form deemed to be appropriate by the design team.

4.0 Engineering Specifications

4.1 Establishing Target Specifications

The established target specifications, shown below in Table 1, resulted from both customer needs and the design teams expectations for the dance vehicle. The safety and well-being of the dancers was a huge concern for the team, so metrics like guards on hazard areas, stepping bars for the dancers, and a slow speed for the dance vehicle were included to address this issue.

Table 4: Target engineering specifications

From external research and personal experience with roller coasters, it was established that the track should roll smoothly on the rail in order to provide the dancers with a stable vehicle. Based on the external search and progress with the project, the team believed that the target values for these metrics were completely attainable.

4.2 Relating Specifications to Customer Needs

The Needs-Metrics Matrix in Table 2 below specifies how the metrics of the target specifications meet the customer needs outlined in Section 2. The design team was uncertain whether it could satisfy the need Braking system for inner cage due to time constraints, so no metric is allocated to this particular need. Once the team has established the final design concept and is able to implement it in the dance vehicle, further consideration will be made for the braking system.

Table 5: Needs-Metrics Matrix

5.0 Concept Generation & Selection

5.1 Problem Clarification

The PSU Creative Campus 1 project is to design and build a dance vehicle to be used as a prop for the Diavolo dance company. The vehicle consists of two 12 ft. diameter wheels attached by a central cage. The center cage and the wheels will each hold two dancers (for a total of six dancers). The first iteration of the design (constructed entirely by architects prior to the induction of the engineering design team) presented several problems. Firstly, the wheels on the previous design had a tendency to bow outwards away from the cage. Secondly, the inner cage is meant to roll independently from the wheels, which should also need to roll independently from one another. Finally, a locking system needs to be implemented so that the dancers are able to arrest the independent motion between the wheels and inner cage from inside the vehicle itself (so all three main components roll as one). The design team determined that all three of these problems may be solved by installing a roller mechanism, similar to those seen on modern roller coasters. To help understand the design requirements, a functional decomposition flow chart (e.g. black box diagram) was used. This chart shows the basic functions that need to be carried out, sub-functions, and outputs.

Smooth independent rolling

Smooth independent rolling

Reduce friction b/w cage & wheels

Reduce friction b/w cage & wheels

Cage & wheels

Move independently

Cage & wheels

Move independently

Gliding mechanism

Gliding mechanism

Wheels held vertically in place

Wheels held vertically in place

Thermal energy

Thermal energy

Kinetic energy from wheels

Kinetic energy from wheels

Locking mechanism

Locking mechanism

Dancer input

Dancer input

Induced stress on mechanism

Induced stress on mechanism

Cage & wheels can lock together

Cage & wheels can lock together

5.2 Concept Generation

After performing an external search and researching many different patents relating to roller coaster rolling and breaking systems, the concept generation process began. The designs for the roller mechanism/locking system are to be incorporated into one apparatus. It was decided that the rolling system would be based on the designs that roller coasters use. An entirely new braking/locking system needed to be design since the brakes used with modern roller coasters are actually located in the tracks and not on the car. To assist the team with governing what engineering principles needed to be applied to the design in order to fulfill specific parameters, a TRIZ chart was created as featured below in Table 6. The full List of the Engineering Parameters is located in Appendix B.

Table 6. TRIZ Method for the Dance Vehicle

Parameter Conflict (Trade-off)

Parameter to Improve

Weight

Force on Transmission

Shape

Stability

Durability

Manufacturability

Complexity

Weight

Force on Transmission

8, 28, 40

4, 13, 22, 28

8, 18, 28

3, 5, 28

21, 24

1, 33

Shape

3, 14, 35, 40

4, 13, 22, 28

1, 4, 7, 15

1, 4, 14, 40

3, 14, 33

1, 14, 33

Stability

4, 8, 18

8, 18, 28

1, 4, 7, 15

8

1, 4, 14, 22

5, 28, 33

Durability

1, 3, 21, 40

3, 5, 28

1, 4, 40

8

35, 40

3, 4, 6, 22

Manufacturability

1, 6, 14, 26

21, 24

3, 14, 33

1, 4, 14, 22

35, 40

1, 4, 6, 24

Complexity

1, 6, 14, 22

1, 33

1, 14, 33

5, 28, 33

3, 4, 6, 22

1, 4, 6, 24

The first concept was a five-wheel design that would implement a braking system similar to the disk brakes used on a bicycle or motorcycle. All of the concepts generated implement similar roller systems that travel over a large square-tube guide rail, however the methods used to lock the cage and the wheels are all different. For this particular concept, the front four wheels were all to be used as guide wheels, while the fifth wheel, located in the back, was to be a dedicated braking wheel. In this design, the rolling motion of the braking wheel itself was retarded. A rotor is attached to the dedicated braking wheel so that they move together. The rotor runs through a brake caliper which is controlled by a hand lever. By using a braking system of this fashion, friction between the castor rail and the braking wheel would cause the larger wheels of the vehicle and the inner cage to lock together.

Casing

Guide Wheels

Load Bearing Wheels

Brake Lever

Caliper

Rotor

Braking Wheel

Guide Rail

Figure 1. Concept A

The next three designs are very similar to the first in that they all utilize a motorcycle-like brake caliper and rotor system. After examination of the previous system, it was determined that, with the correct placement of the guide wheels, a dedicated braking wheel was not necessary. Therefore the fifth wheel was eliminated to produce a new-four wheel system. In this second concept, the back guide wheel also acts as the braking wheel. There are three rollers of these systems on each side of the cage (although only one on each side includes the brake). By reducing the number of wheels from five to four on each apparatus, the total number of wheels is reduced from thirty to twenty four. This design reduces the size and weight of the system as well as lowers the manufacturing cost while maintaining the same braking force.

Figure 2. Concept B

Load Bearing Wheels

Guide Wheels

Guide Rail

Rotor

Caliper

Brake Lever

Casing

Figure 3. Concept B (section view)

Guide Rail

Guide Wheels

Casing

Load Bearing Wheels

Rotor

Brake Lever

Caliper

The four-wheel design was widely accepted by the design team and therefore is present in all of the following concepts. Notwithstanding, the locking system for each concept is different. The third concept is much the same as the second, still using four wheels with the back wheel as the primary braking wheel. The new design is focused on increasing the surface area between the guide wheels and the guide rail so that the overall braking force is enhanced. In order to do this, the concept uses two wheels out of the four that act as both guide and braking wheels. Like the previous design, there is still only one rotor and an attached caliper. To incorporate the secondary braking wheel, a gear is mounted on top of the back wheel where the rotor is attached. A second gear is then placed on the front wheel. A chain links these two gears so that when the caliper is activated both wheels seize simultaneously.

Caliper

Guide Rail

Guide Wheels

Rotor

Brake Lever

Casing

Chain

Gears

Load Bearing Wheels

Figure 4. Concept C

The fourth concept was generated from the idea that two guide wheels could be active as part of the locking mechanism as opposed to only one. This design utilizes a similar gear-to-gear system as in the previous design. This design takes further advantage of a gear ratio that is not 1:1 so that braking force can be further increased. In addition to this change the rotor is mounted completely independent of the wheels so that it rotates on its own. There are two large gears that rotate in a concentric manner with the rotor. Each of these large gears are connected by chain to smaller gears that are mounted on each of the guide/braking wheels. When activated, the caliper stops the motion of the rotor which in turn stops the rotation of the wheels because of the chain linkage.

Chain

Caliper

Guide Rail

Guide Wheels

Load Bearing Wheels

Casing

Brake Lever

Rotor

Gears

Figure 5. Concept D

Unlike the previous four designs, the fifth concept only uses a motorcycle-like brake caliper, but does not require the use of a rotor or chain linkage. In this design, none of the guide wheels are used in the braking system. Instead, a secondary rail is attached to the guide rail. This rail is the same thickness as the rotors used in the previous designs only it extends the entire way around the guide rail. The caliper is attached to the roller system and the secondary rail runs through the caliper. This system is a direct locking mechanism in that it directly links the outer wheel to the cage. This is different from previous designs that use friction between the guide wheels and the castor rail to link the vehicle wheels to the inner cage together.

Guide Wheels

Load Bearing Wheels

Guide Rail

Caliper

Casing

Load Bearing Wheels

Guide Rail

Secondary Braking Rail

Guide Wheels

Caliper

Figure 6. Concept E

The sixth and final design is the most unlike all of the previous designs. This concept utilizes a direct locking mechanism like the fifth design. Unlike the fifth design, however, this concept does not use a rotor or a caliper. Nor does this design require the addition of a secondary rail. Instead, the walls of the castor rail itself are used as the braking surface. A V-brake system (similar to those used on road bicycles and older mountain bikes) is attached to the housing of the four-wheel roller mechanism. The brake pads of this V-brake run along either side of the guide rail. When the brake is activated the pads come into contact with the guide rail and lock the vehicle wheels to the cage.

Guide Rail

V-Brake

Guide Rail

V-Brake

Casing

Guide Wheels

Load Bearing Wheels

Brake Lever

FFigure 7. Concept F

5.3 Concept Selection

After the concept generation process, a final concept had to be selected. To do this, the design team first went through a concept screening process. This process eliminates extraneous concepts so that only the best designs will be scored and ranked. This is done by creating a concept screening matrix. A variety of selection criteria are chosen by the design team and each concept is screened against these criteria. The screening process involves three basic ratings; pluses, minuses, and zeros. Either a plus, minus, or zero is assigned to each concept for each criterion. These values are then added to give the net score and then concepts are ranked. The lowest ranking concepts are cut and are no longer taken into consideration as viable options for the final design.

Table 7. Concept Screening Matrix

Concepts

Selection Criteria

1

2

3

4

5

6

Cost

-

-

-

-

-

+

Safety

-

0

0

-

+

0

Size

-

+

+

-

+

+

Manufacturability

0

0

0

0

-

-

Reliability

0

+

+

0

+

+

Brake power

+

+

+

+

+

+

Overall strength

-

0

-

-

+

-

Easy to mount to cage

0

0

0

0

-

0

Sum +

1

5

3

1

5

4

Sum 0

3

2

3

3

0

2

Sum -

4

1

2

4

3

2

Net Score

-3

3

1

-3

2

2

Rank

4

1

3

4

2

2

Continue?

No

Yes

Yes

No

Yes

Yes

1

Five-wheel Design

2

Wheel mounted rotor w/o gearing

3

Wheel mounted rotor with gearing

4

Independently mounted rotor with gearing

5

Caliper with secondary rail (no rotor)

6

V-brake system

After the screening process was completed, a Pugh chart was created and each concept was scored based on different criteria. A weight factor was assigned to each of these criterions. Each concept is than ranked on how well it fulfills the criteria on a one-to-five scale (five being the best performance). The score multiplied by the weight gives a weighted score for one category. After all the concepts have been assigned weighted scores for each criterion, these scores are added to determine the best designs. The highest scoring design was concept number six (with the V-brake arrangement). This design proved to be the most practical and simplistic solution. Concept three (a four-wheel arrangement with added gearing system) was chosen as an alternative design in the event that the V-brake system proves to be unsuitable during preliminary testing.

Table 8. Concept Scoring Chart

Concept

2

3

5

6 (ref)

Selection Criteria

Weight

Rating

Wgtd. Score

Rating

Wgtd. Score

Rating

Wgtd. Score

Rating

Wgtd. Score

Safe

0.16

2

0.32

1

0.16

4

0.64

3

0.48

Ease of Use

0.09

3

0.27

3

0.27

3

0.27

3

0.27

Ease of Mfg.

0.11

5

0.55

1

0.11

1

0.11

3

0.33

Cost

0.11

1

0.11

2

0.22

2

0.22

3

0.33

Aesthetics

0.075

2

0.15

2

0.15

3

0.225

3

0.225

Stability

0.13

3

0.39

3

0.39

3

0.39

3

0.39

Durability

0.13

5

0.65

4

0.52

3

0.39

3

0.39

Visibility

0.075

2

0.15

2

0.15

2

0.15

3

0.225

Precise/Accurate

0.1

3

0.30

3

0.30

3

0.30

3

0.30

Total Score

2.755

2.270

2.695

2.940

Rank

2

4

3

1

Continue

Yes-Alt

No

No

Yes-Prim

Relative Performance

Rating

Much worse than reference

1

Worse than reference

2

Same as reference

3

Better than reference

4

Much better than reference

5

6.0 System Level Design

The primary design consists of six sets of four wheels mounted in a T configuration, as shown in Figure 8. There are two load bearing wheels located on the inner side of the guiderail that is attached to the inner cage. There is also one guide wheel on either side of the guiderail to form the top of the T. The guide wheels are positioned slightly away from the guiderail so as to not induce unnecessary friction. As opposed to the first set of wheels, these function mainly as guides to keep the vehicle wheels in place and rolling on a collinear axis with the inner cage. These wheels do not bear the load of the inner cage.

To hold the wheels in place is an outer housing. This housing is made of sheet metal which is bent around the wheels. The housing has pieces of square tubing connecting the top corners of the T to the base. These pieces are present to increase the overall strength of the housing. Attached to the housing is the locking mechanism. The locking mechanism used in the primary design (concept 6) consists of a V-brake which is attached to the housing via an extension of the sheet metal and extends around the guide rail. This brake is controlled by a hand lever. The alternative design (concept 2) uses a disk brake system. The rotor is attached to the back wheel so that the two rotate together. The rotor runs through a caliper which is attached to the housing. Like the V-brake design, the caliper is also controlled with a hand lever. Both systems are hydraulic (as opposed to a cable system) to increase braking force. See Figure 7 in section 5.2 for details.

Casing

Figure 8. Wheel Configuration

Square Tubing

Square Tubing

Casing

Load Bearing Wheels

Guide Wheels

Load Bearing Wheels

Guide Wheels

Figure 9. Transmission Assembly

7.0 Special Topics

7.1 Preliminary Economic Analyses- Budget and Vendor Purchase Information

The budget for this project is split between materials, components, and other assorted expenses. These values are approximate and are therefore subject to change. Fortunately, all of the steel tubing required for this project was acquired for free through the sponsor, which dramatically cut down on material expenses. Other material that needed to be purchased was sheet metal for the housing of the gliding mechanism. The pricing estimate on this item came from the McMaster-Carr website. Components that needed to be purchased included the wheels for the gliding mechanism, in addition to a braking system, or materials that needed to be purchased to fabricate a braking system. The price estimates for the wheels also came from McMaster-Carr and estimates for the braking system were based on the average price for bicycle braking components. Other expenses include a poster, and travel expenses. For all items that needed to be ordered, the estimated shipping costs are included in the prices seen on the budget. Since the sponsor is on-campus, no money was reserved for travel expense. In addition to materials, components and other expenses, twenty percent of the budget was allocated towards contingency. This was in case more money had to be spent on materials or components, or if there were last minute parts that needed to be purchased. The budget and Bill of Materials can be seen in the Appendix C and Appendix D, accordingly. The project is currently running under budget including the twenty percent contingency.

7.2 Project ManagementTo track the progress of the project, the team decided to use a Gantt chart with tasks, milestones, and responsibilities, which can be found in Appendix E. It will be important to track the progress, to know whether or not the project is on schedule. Falling behind schedule will cause a number of issues with the sponsor, because they have their own schedule to keep. A deliverables agreement was signed by each of the team members, acknowledging the key milestones with the sponsor, advisor, and team. The responsibilities and tasks from the Gantt chart were assigned to each person based on their individual technical skills and areas of experience. The strengths of each team member can be found in the team contract, in Appendix F and in their respective resumes, in Appendix F.7.3 Risk Plan and Safety

A vehicle of this type has never been created before, so there are many unknown or unproven aspects regarding its functionality. With so many unknown variables, safety becomes a huge concern, and is the major risk involved in this project. The team recognized six main potential risks in this project, as shown in Table 9, and four of them were safety or construction related. Needless to say, safety is highly important, and will be iteratively address throughout the design process.

The highest risk the team was able to predict was a potentially hazardous scenario where a dancer falls from the vehicle near the wheels, which will be addressed with netting and a guide rail. The most beneficial action that can be done is to construct the vehicle as soon as possible to allow the dancers to get accustomed to its movements. This will minimize the frequency of falling, while the guide rail and netting will minimize the severity of the event.

Table 9. Risk Plan for the Dance Vehicle

Risk

Level

Actions to Minimize

Fall Back Strategy

Dancer Falling from Wheel

High

Preliminary test with dancers Add netting in the wheel Larger platform for foot placement

Guide Rail to hold on to Fully enclose wheel

Wheel Stability

Moderate

Sufficient number of braces Low clearance between guide wheels and caster rail

Extra supports stemming from inner cage Remove a dancer

Schedule Delays

Moderate

Order parts early Construction progress Double check company's delivery time

Factor in additional time Go to manufacturer

Dancer Pinched in Between Mechanisms

Moderate

Casing over transmission Minimize distance between wheels and inner cage Maximize performance area

Transmission located outside of cage Dont allow dancer to transfer from wheel to inner cage

Customer Needs Not Satisfied

Low

Understand what their needs are Watch Diavolo for inspiration Speak with sponsor on regular basis

Go to every 6-9 pm Friday meeting to ensure proper progress

Faulty Braking System

Low

Order a brake and wheel set to avoid frictional issues

Have a backup braking system incase primary one fails

7.4 Ethics Statement

The team members hold each other to a high ethical standard. All members signed a team contract, which outlines the consequences for failing to uphold this standard. As mechanical engineers, the team will adhere to the American Society of Mechanical Engineers (ASME) Code of Ethics. Recognition will be given to all external sources (including existing patents, services, or emerging technology), which have contributed to the project. When the product is delivered to the sponsor, the team will be confident in its safety and success.7.5 Environmental StatementThe design developed by the sponsor and design team will be constructed primarily of steel. By ensuring the design is fully correct before construction, weld time will be minimized, decreasing projects carbon footprint. After the showcase, the vehicle will sit unused. If the team can reuse the materials for other projects, the University will save money and resources. Another possible option is selling the vehicle to a different creative dance team, such as Diavolo. The team will continue searching for opportunities to complete the project in an environmentally conscious manner.7.6 Communication and Coordination with Sponsor

Marcus Shaffer, an assistant professor in the Stuckeman School of Arts and Architecture will be the main point of contact for the Penn State Creative Campus 1 Team (design team). He will be contacted at least once each week by email and two personal meetings per week. The first meeting each week will be with the two architectural team members, Alex Bruce and Kyle Brown. This meeting will happen either Monday or Wednesday at 1:30pm, on the fourth floor studio of the Stuckeman Building. The second meeting each week is Friday at 6 pm in the IDEALab in the Stuckeman Building with the Penn State Creative Campus dance team. Only one design team member needs to be present for this meeting each week. These meetings will ensure the sponsor and teams are always brainstorming new ideas, while constructing the prototype.

8.0 Detailed Design

8.0.1. Modifications to Statement of Work

Revisions to the Statement of Work Proposal Sections 1 through 7 are listed as 8.0.1.X

8.0.1.1. Introduction- No changes made

8.0.1.2. Customer Needs Assessment- No changes made

8.0.1.3. External Search- No changes made

8.0.1.4. Engineering Specifications

Due to time constraints and budget concerns the team decided that a braking system will not be implemented into the final design of the gliding transmission mechanism for the dance vehicle. The architect team and sponsor have stressed multiple times that completing the gliding transmission mechanism is the design teams first and foremost priority; the braking system is a secondary goal if time permits. After the team has completely finished manufacturing all six transmission components, then a braking system can be considered for implementation. The sponsor has recently emphasized his concerns about covering the hazardous transmission areas on the vehicle after the team presented the completed alpha prototype. The design team continues to put safety as the primary metric when redesigning the alpha prototype for the final product. The design team has also decided to use galvanized steel instead of stainless steel for the final design. This material is cheaper than stainless steel, rust resistant, and very strong; further explanation for this chosen product can be found in the Material and Material Selection Process of the report.

8.0.1.5. Concept Generation and Selection

As stated in the engineering specifications section of the report, the team will no longer consider designs that have a braking system implemented in the gliding transmission mechanism. All the concepts that have been generated and provided in the report display some form of braking system. When referring back to the designs located in the 5.2 Concept Generation section, the team has chosen the concept 3 as the design without the braking system attachment.

8.0.1.6. System Level Design

After completing the alpha prototype, the design team was able to better understand the manufacturing process that will be used to construct the six transmissions necessary for the project. After building the first prototype, the design was slightly altered to accommodate for ease of manufacturing for the remaining transmissions. The team determined two minor improvements that could be made to the design, which solve a respective problem that was encountered during the alpha prototype creation. These problems include a need for wheel coverings and enlarging the wheel housings.

The first improvement that was made to the design was adding a cover to the wheels in the housing of the glide system. It is imperative that the team makes these transmissions safe for the dancers to operate, so keeping hazard areas to a minimum and out of reach is crucial. As of now, the wheels in the housing are exposed, which will allow fingers and clothing to get caught, potentially causing injury. In order to cover the wheels, caps were designed out of a thin 1/32 sheet metal. These caps are attached to the housing by drilling holes similar to those for the wheels, incorporating them with the same bolts that hold the wheels in place, as shown in Figure 10, for labeled parts refer to Appendix G. This will both reduce the manufacturing time installing the caps and allow easy removal if the wheels need to be accessed for maintenance.

Figure 10. Exploded View of Guide Wheel Housing

The second improvement involved ease of manufacturing. The housing around each wheel was enlarged and fixed to a rectangular shape. Although it is not as aesthetically pleasing, the ease of manufacturing is greatly increased. This also allows the caps to be removable and simple to design. The new wheel housings are shown in Figure 10 as well.

8.0.1.7. Special Topics

The Design Team Budget, Bill of Materials, and Gantt Chart in Appendices C, D, and E, respectively, have been updated to accordingly, due to the design changes and current project status.

8.1 Manufacturing Process Plan

The design of the transmission is as simple as possible to reduce number of welds and make assembly easy. The casing is made solely out of 1/16 steel sheet metal which is very easy to bend and also easy to weld. The water jet will cut out the shape and the bolt holes which means the only other components that need to be cut is the 45 supports. The manufacturing process to assemble one transmission is given below in Table 11, for a picture of the component refer to Appendix F. There will be a total of six transmissions built for this project.

Table 11: The Manufacturing Process Plan

ASSEMBLY NAME

MATERIAL TYPE

RAW STOCK SIZE

OPERATIONS

# OF PARTS

Casing

Galvanized Steel Sheet Metal

2' x 2'

Water jet shape on sheet metal using SolidWorks file (red lines are cut through lines)

4

Bend first line on part A 90

Bend second line on part A 45 out

Bend third line on part A 45 out

Bend first line on part B 45 out

Bend second line on part B 45 out

Bend part C on only line at 90

Bend part D on only line at 90

Weld part B to part A on the red line at 90

Weld part C to part B on the red line at 90

Weld part D to part A on the red line at 90

Supports

Steel Tubing

1.5" x 1.5" x .25"

Cut the steel tubing to size

2

Cut 45 degree cuts on both ends of the tubing

Weld the support onto the transmission casing

Repeat previous 3 steps for the 2nd support on the other side of the casing

Assembly

Bolt wheels in using 3/8"-24 bolts

4 wheels

4 bolts

4 nuts

8.2 Analysis

The only weak points in the design are the bolts that attach the transmission to the cage frame. A calculation was performed at the worst scenario to determine the factor of safety. This worst case scenario is with all the mass supported by one 3/16 bolt. By using the bolt material properties and a mass of the cage with four girls inside, the team determined that the factor of safety using the recommended bolts was 13.64. This scenario will likely never happen, but if it does, the transmission and bolts will not fail under shear. The calculations are shown below.

Given Information:

Shear Stress Calculation:

Factor of Safety Calculation:

8.3 Material and Material Selection Process

This project required a number of different materials to be used on various components throughout the whole dance vehicle. The original dance vehicle that was constructed prior to the induction of the engineering design team used wood for the twelve foot diameter wheels and steel tubing for the inner cage. After some discussion, the architects and engineering design team decided to construct the entire vehicle out of steel tubing, using no wood at all. Though this increased the weight of the vehicle, the overall strength was increased as well. The second major component of this project was the transmission (aka roller mechanism). There were several subcomponents that went into this piece of the machine and they all had to be selected very carefully. The transmission is of paramount importance because if a failure were to occur anywhere on this component, the entire dance vehicle is liable to fail as well. For this reason the engineering design team spent the majority of their time selecting the materials for this mechanism.

It was decided that 0.064 thick galvanized sheet metal was to be used for the housing of the transmission. In the alpha prototype of the transmission, stainless steel was used for the housing. The engineering design team decided to use galvanized steel instead because it is far cheaper and still highly machinable. Though stainless steel is more resistant to corrosion, given the application of this material in the context of a dance vehicle, a corrosion resistant material is not extremely important. This being said, galvanized steel still provides some corrosion resistance by using a sacrificial layer of zinc oxide. Galvanized steel is also highly weldable. In the early stages of the dance transmission vehicle project the team decided to use 1/8 thick sheet metal for the housing, however it quickly became apparent that this thickness of sheet metal was difficult to bend. Additionally, after testing the alpha prototype, it was revealed that 1/8 sheet metal was thicker than necessary. The transmission also required caps to cover the guide and load bearing wheels so that the dancers would not be at risk of accidentally getting their fingers caught. Though a final decision has not yet been made as to the material that will be used for these caps, they will likely be made from 1/32 galvanized steel. They do not need to be made from material that is as thick as the sheet metal used for the housing because they have comparatively insignificant forces applied to them.

The only other materials used are small pieces and fasteners such as bolts, washers, and nuts. Other materials are part of the wheels used in the transmission component and are discussed in Section 8.4. The bolts were chosen by looking on the McMaster-Carr website and viewing the tensile strength statistics. By performing several tests the engineering design team determined that the selected bolts would be sufficient for the given application. The specific bolts used can be found in appendix D. See Section 8.6 for further details on the test procedure.

8.4 Component and Component Selection Process

The only components that needed to be selected for this project were the wheels to be used on the transmission. These are the guide and load bearing wheels. There were two types of wheels that the engineering design team and architects selected initially. The first was a black phenolic wheel, 3.25 in diameter, 2.0 wide, used roller bearings, and was made of a very hard plastic. The second was a performance rubber wheel, 5.0 in diameter, 1.25 wide, used ball bearings, and was made from a softer rubber. Eventually the performance rubber wheels were selected for the final design. Though these wheels had nearly half the load capacity as the black phenolic wheels, it was determined through testing that they would be more than sufficient. Because of the softer rubber, they were much quieter when rolling along the guide rail than the harder wheels, and the larger diameter wheels also rolled more easily over imperfections along the guide rail than the phenolic wheels. Finally, they were significantly easier to integrate into the design because the ball bearing configuration allowed them to be mounted to the housing without any modification to the wheels. The only trade-off was that the selected wheels were slightly more expensive. However given the advantages, the team decided the extra expense was necessary.

8.5 CAD Drawings

The following are several pictures from a finalized CAD model of the transmission that was created using SolidWorks. For full dimensioned drawings see Appendix G.

Figure 11: One 12ft diameter wheel

Figure 10: The transmission cap to ensure dancer safety and prevent injuries

Cap

Mounting Bar

Bolts

Supporting Bars

Wheels

Casing

Figure 12: One of the six completed gliding transmission component with protective caps and mounting bar

8.6 Test Procedure

To ensure that the customer needs are met, it is necessary to test and evaluate the guide wheel system prototype before manufacturing of the final 6 products can be achieved. The test operation to be done will analyze if the guide wheel system can support a substantial load and still perform its purpose of rolling smoothly on the guide rail. The procedure for this test is outlined below:

1. Set 1 guide rail beam horizontally approximately 4 ft. off the ground, supported by 2 tables at each of its ends.

2. With the guide wheel system placed on top of the beam, it is pushed and observed if it freely rolls from one end of the beam to the other. This is repeated several times to determine any implications that the guide wheel system is unable to remain on the rail.

3. A mass of approximately 310 lbs. (15 lbs. below the rated support rate of a single wheel) is attached to the guide wheel system.

4. Have a team member push the guide wheel system with the mass across the beam

5. Observe how the guide wheel system operates under a load, especially if the wheels on the prototype are handling the load and are moving smoothly on the beam.

The previous test will evaluate the performance of the load bearing wheels, but tests on the guide wheels are also necessary because a much weaker load will still be applied to them. The procedure for this test will be similar to that outlined above, only changing the orientation of the guide wheel system.

8.7 Economic Analysis- Budget and Vendor Purchase Information

The team was fortunate enough to have acquired the steel tubing for the cage and wheels for free. Otherwise, this would have accounted for a significant portion of the budget. Without these additional costs, the total anticipated expense for this project is approximately $891.80. This includes the price of the roller mechanism wheels, sheet metal, bolts, washers, and nuts and tri-fold poster. Also included in this estimate is cost of water jet cutting. Nearly all materials have already been purchased. The only remaining expenses are for the use of the water jet machine and the poster. The team decided not to include a braking mechanism in their design, partly because of time constraints, but also largely because of budgetary constraints. The contingency was also reduced from 20% to 10% due to unexpected expenses. Both the Bill of Materials and Budget can be found in Appendices C and D.

All components and material excluding the metal tubing and sheet metal was purchased from McMaster-Carr. The sheet metal was purchased from Metals Depot, and the metal tubing was covered under the grant from the Doris Duke Foundation.

References

Diavolo.N.p., n.d. Web. 15 Jan. 2012. .

Bicycle Brake Shoehttp://www.google.com/patents?id=xUScAAAAEBAJ&pg=PA7&dq=bicycle+brakes&hl=en&sa=X&ei=oKgxT_inMuSL0QHBycXXBw&ved=0CDQQ6AEwAA#v=onepage&q=bicycle%20brakes&f=falseWheel Assembly for a Monorailhttp://www.google.com/patents?id=5M5sAAAAEBAJ&pg=PA4&dq=roller+coaster+wheel+assembly&hl=en&sa=X&ei=RPgyT9TuD8K10QG1-q3RBw&ved=0CD0Q6AEwAw#v=onepage&q=roller%20coaster%20wheel%20assembly&f=false

Roller Coasterhttp://www.google.com/patents?id=eIM8AAAAEBAJ&pg=PA5&dq=roller+coaster+wheel+assembly&hl=en&sa=X&ei=LfgyT5_mGeTn0QGx6OGMCA&ved=0CEwQ6AEwCA#v=onepage&q=roller%20coaster%20wheel%20assembly&f=falseWheel Hub Rider Conveyancehttp://www.google.com/patents?id=ZNbIAAAAEBAJ&pg=PA30&dq=roller+coaster+wheel+assembly&hl=en&sa=X&ei=5vsyT5r5OsXj0QGQ973OBw&ved=0CEkQ6AEwBw#v=onepage&q=roller%20coaster%20wheel%20assembly&f=false

Bicycle Hydraulic Brake (216289)

http://www.google.com/patents?id=hEdsAAAAEBAJ&pg=PA1&dq=hydraulic+bicycle+brake&source=gbs_selected_pages&cad=1#v=onepage&q=hydraulic%20bicycle%20brake&f=false

Train Railroad (3199463)

http://www.google.com/patents?id=wZtPAAAAEBAJ&pg=PA5&dq=train+railroad&hl=en&sa=X&ei=K_YzT8KpB6f20gGHiei6Ag&ved=0CDUQ6AEwAQ#v=onepage&q=train%20railroad&f=false

Cantilever Brake Device (0229929)

http://www.google.com/patents?id=mr7IAAAAEBAJ&pg=PA6&dq=V+brakes&hl=en&sa=X&ei=wPczT93nFJKz0QGxlMGyAg&ved=0CDQQ6AEwAA#v=onepage&q=V%20brakes&f=fals

Trolley (1318418)

http://www.google.com/patents?id=H8BjAAAAEBAJ&pg=PA1&dq=trolley&source=gbs_selected_pages&cad=1#v=onepage&q=trolley&f=false

Ball Bearings (3265449)

http://www.google.com/patents?id=JpdKAAAAEBAJ&pg=PA1&dq=ball+bearings&source=gbs_selected_pages&cad=2#v=onepage&q=ball%20bearings&f=false

Roller Bearings (3675978)

http://www.google.com/patents?id=M6ksAAAAEBAJ&pg=PA2&dq=roller+bearings&source=gbs_selected_pages&cad=2#v=onepage&q=roller%20bearings&f=false

Appendices

Appendix A: Full Customer Needs List

Redesign the dance vehicle to ensure stability

Lightweight

Minimal material usage

Simple Mechanical Design

Durable enough to withstand six dancers

Safe for dancers to move around in machine and not get pinned or cut

To design handle bars or guide rail for dancers to hold on to

To design extra footing to prevent slipping and falling through vehicle

Maximal visibility through and within structure

Aesthetically pleasing to the audience

Redesign and improve the gearing system

Redesign and improve transmission elements

Allow the inner cage to spin freely from the outer two wheels

Minimize friction

Make the vehicle more robust

Additional Dancer Needs include

Want to explore inside the vehicle (big enough to dance in)

Be able to play with the components

Platforms to sit and walk on

Appendix B: Engineering Parameters

Engineering Parameters

Design Principles

1

Weight of moving object

1

Segmentation

2

Weight of stationary object

2

Separation or extraction

3

Length of moving object

3

Local quality

4

Length of stationary object

4

Asymmetry

5

Area of moving object

5

Merging or combining

6

Area of stationary object

6

Universality

7

Volume of moving object

7

Nesting dolls

8

Volume of stationary object

8

Counter-weight

9

Speed

9

Preliminary counter-action

10

Force

10

Preliminary action

11

Tension, pressure

11

Previously placed pillow

12

Shape

12

Equipotential

13

Stability of object

13

Other way around

14

Strength

14

Spherical shapes

15

Durability of moving object

15

Dynamism

16

Durability of stationary object

16

Partial or excessive action

17

Temperature

17

Moving to another dimension

18

Brightness

18

Mechanical vibration

19

Energy spent by stationary object

19

Periodic action

20

Energy spent by stationary object

20

Continuity of useful action

21

Power

21

Rushing through

22

Waste of energy

22

Blessing in disguise (harm to benefit)

23

Waste of substance

23

Feedback

24

Loss of information

24

Intermediary

25

Waste of time

25

Self-service

26

Amount of substance

26

Copying

27

Reliability

27

Cheap disposable

28

Accuracy of measurement

28

Replace a mechanical system

29

Accuracy of manufacturing

29

Pneumatics or hydraulics

30

Harmful factors acting on object

30

Flexible films or membranes

31

Harmful side effects

31

Porous materials

32

Manufacturability

32

Optical changes

33

Convenience of use

33

Homogeneity

34

Reparability

34

Recycling (rejecting and regenerating)

35

Adaptability

35

Physical or chemical properties

36

Complexity of device

36

Use phase changes

37

Complexity of control

37

Thermal expansion

38

Level of automation

38

Strong oxidants

39

Productivity

39

Inert environment

40

Composite materials

Appendix C: Design Team Budget

Item

Cost ($)

Materials:

$249.51

Steel tubing

$0.00

Sheet metal

$178.94

Fasteners

$70.57

Components:

$335.95

Wheels

$335.95

Other:

$406.34

Machining Services

$253.34

Travel

$0.00

Contingency (10%)

$100.00

Poster

$53.00

Total:

$991.80

Appendix D: Bill of Materials

Date

Item No.

Description

Vendor

Price Per Item ($)

Number of Items Purchased

Total Amount With 6% Tax ($)

Shipping ($)

Balance ($)

Jan 10, 12

$1,000

Jan 14, 12

N/A

Steel Tubing

N/A

$0.00

1

$0.00

$0.00

$1,000

Jan 23, 12

2829T74

PerformanceRubber-Tread Wheel5 X 1-1/4, 3/8 Axle,Ball Bearing, 325#Capacity

McMaster-Carr

$12.30

4

$52.15

$5.00

$943

Feb 27, 12

N/A

Water jetcutting

LearningFactory

$27.00

1

$28.62

$0.00

$914

March 1, 2012

91241A432

Black-Oxide AlloySteel Socket HeadCap Screw 3/8"-24Thread, 2" Length

McMaster-Carr

$12.39

1

$13.13

$5.00

$896

March 1, 2012

2829T74

PerformanceRubber-Tread Wheel5 X 1-1/4, 3/8 Axle,Ball Bearing, 325#Capacity

McMaster-Carr

$12.30

21

$273.80

$5.00

$617

March 2, 2012

93852A103

18-8 SS Type A USSFlat Washer 5/16"Screw Size, 7/8" OD,.06"-.11" Thick

McMaster-Carr

$5.60

1

$5.94

$5.00

$606

March 3, 2012

91845A125

18-8 Stainless SteelHex Nut 3/8"-24Thread Size, 9/16"Width, 21/64" Height

McMaster-Carr

$6.05

1

$6.41

$5.00

$595

March 4, 2012

S216

16 GA. (.064 thick)Steel Sheet 2x2ft

Metals Depot

$27.32

4

$115.84

$18.00

$461

March 14, 2012

91251A472

Black-Oxide AlloySteel Socket HeadCap Screw 3/8"-24Thread, 2-3/4" Length

McMaster-Carr

$7.89

3

$25.09

$5.00

$431

N/A

N/A

Tri-fold Poster

TBD

$50.00

1

$53.00

$0.00

$378

N/A

N/A

Water jetcutting

LearningFactory

$212.00

1

$224.72

$0.00

$153

N/A

N/A

Welding

Learning Factory

$0.00

1

$0.00

$0.00

$153

N/A

N/A

Sheet metal

Metals Depot

$35

1

$37.10

$8.00

$108

TotalExpenditure:

$891.80

Appendix E: Gantt Chart

Appendix F: Layout of transmission piece for water jetting

This is a picture of one gliding transmission a one complete piece. This is what the transmission component looks like before it is water jetted, bent, and welded for manufacturing.

Appendix G: Dimensioned drawings of transmission components

Labeled exploded view of all components in the gliding transmission mechanism

Side View of Dance Vehicle

Front View of Dance Vehicle

Mounting Bar connecting the inner cage to the lower part of the transmission component

Mounting Bar connecting the inner cage to the upper guide wheel of the transmission component

Trimetric View of Dance Vehicle

Isometric View of Dance Vehicle

Large cap to cover guide wheel

Small cap to cover guide wheel

Dimensioned housing for one of the six gliding transmission mechanisms

Appendix H: Team Resumes

Steven A. Bates

Sab450@psu.edu

224 South Burrowes Street,

State College, PA 16801

(215)858-3596

Objective

To gain valuable work experience by applying my skills and knowledge

in engineering theory

Education

Bachelor of Science in Mechanical Engineering

The Pennsylvania State University, Expected Graduation date May 2012

GPA 3.39

Relevant Courses

Mechanical Engineering Design Methodology

Machine Design

Mechanical Responses of Engineering Materials

Strength of Materials

Vibration of Mechanical Systems

Dynamics

Technical Writing

Fluid Flow

Skills

Proficient in Microsoft Excel and Word

MATLAB

Public Speaking

Self Motivated

Lab Experience

Mechanical Engineering Design Methodology Lab

Built a functioning automatic jar opener using drill components

Gained experience with abrasive machinery

Spring 2011

Industrial Engineering Lab

Experience testing engineering materials

Processes include casting, joining, plastic molding, welding

Spring 2011

Work Experience

Position: Engineering Scientific & Technical Intern

Penn DOT, Clearfield PA

Inspected bridge construction progress

Recorded material properties and delivery processes

May 20011- Aug 2011

Position: Busser, Host, Food Runner, Server

Houlihans Restaurant, Warrington, Pa

Trained 5 new employees; provided feedback on performance

Assisted guests with their concerns, managed hospitality

May 2005- Oct 2010

Leadership

President of High School Class; sophomore, junior, senior years

President of Student Government

Aug 2005-June2008

Sept 2007-June 2008

Attended the Rotary International Camp (rewarded outstanding Leader)

June 2006

Attended National Student Leadership Camp

July 2005

Weekend Warrior for Penn State THON weekend

Feb 2011

Activities &Awards

Deans List

Spring 2011, Fall 2010

Tenor Saxophonist in Penn State Marching Blue Band

Aug 20080-Present

Member, Morale committee for THON

Aug 2009-Present

Awarded Mr. Engineer

Spring 2009

Won Best Innovation for solar clothes dryer competition in engineering Design and Graphics

Fall 2008

Member of Penn State Engineering House Social Committee

Organized social event for the committee

Aug 2008-May 2009

Community Service

Red Cross

Donate Blood, deliver packages, communicate with donors

Jan 2011-Feb 2011

Stephen Thor

954 Grace StreetSjt5089@psu.edu

State College, PA 16801cell: 814-574-3587

ObjectiveTo obtain a full time position in the fields of Industrial Design or in Mechanical Engineering

with a focus in product design.

EducationThe Pennsylvania State University University Park, PA 2008 - present

Bachelor of Science in Mechanical Engineering

Certificate in Engineering Design Program

Current GPA of 3.23 / 4.0 Expected graduation: May 2012

cole Centrale de Nantes Nantes, France Summer 2011

Summer Design Academy

Final GPA of 4.0 / 4.0

ExperiencePenn State Applied Research Labs State College, PA Summer 2010 - present

Assisted in design of embedded system controllers and component housing

Assembled and operated test rigs for diesel fuel pump health monitoring system

Used DAQ to collect pressure data and flow information and analyze it with MATLAB

Installed and replaced fuel pumps, accelerometers, and throttle position sensors on medium

tactical vehicle replacement (MTVR) for US Marines

New Leaf Initiative Intern Coordinator State College, PA Fall 2011 - present

Supervised a team of 8 interns as a project head and coordinator

Drew up business plans, marketing strategies, grant proposals, and sponsorship contracts

Assisted in creating a Leadership Development Program with Penn State

Microcomputer Interfacing Design Project University Park, PA Fall 2011

Designed and constructed semi-autonomous vehicle

Created C code for PIC microcontroller to interact with multiple sensors

Design Methodology Class Design Project University Park, PA Spring 2011

Participated in a small group to design and construct a functional electric jar opener

Generated concepts based upon customer needs data gathered through external research

Conducted cost analysis for product ramp-up

BAE Systems Sponsored Design Project University Park, PA Fall 2008

Effectively worked in a group of four to research prices, create model in SolidWorks and

scale prototype, and complete design process

Awarded Best Design by class for cost-effectiveness, usability, and functionality

Relevant Courses

Design Methodology Mechanical DesignSolidWorks

Engineering Design Vibration AnalysisRapid PrototypingThermodynamics MATLABFluid Mechanics

SkillsCertified SolidWorks ProfessionalMicrosoft Office Suite

MATLAB, AutoCAD, CATIAPublic Speaking

JASON KURUC

2657 Nixon Street Lower Burrell, PA 15068 724-337-1070 jrk5209@psu.edu

OBJECTIVE

To acquire a position that will allow me to expand my knowledge in mechanical engineering while gaining experience in the work field.

EDUCATION

The Pennsylvania State University Erie, The Behrend College/University ParkExpected Graduation Date: May 2012Major: Mechanical Engineering Deans List Fall 2008Current CGPA 3.2

WORK EXPERIENCE

Siemens New Kensington, PA Summer 2010 and 2011

Assembled a variety of products used in HV/MV variable frequency drives by following engineering schematics and drawings

Practiced with 5S method of organizing work area

Worked with teams to improve flow of assembly lines using one-piece flow concepts

Contributed to $100K sub assembly department relocation project, moving a 30,000 square foot work area to a 20,000 square foot area.

Organized tool cabinets and production floor

Contributed during team meetings to improve team efficiency

Burrell Rentals Lower Burrell, PA Summer 2009

Answered customer support phone calls

Organized display yard to help promote and improve sales

Performed maintenance on machinery such as oil changes, hydraulic fluid changes, etc.

Delivered and operated machinery for customers

Assisted head mechanic on service calls fixing any on problems with the machinery on the fly

AK Tent Rental Lower Burrell, PA Summer 2008

Delivered and set up party supplies and tents quickly and efficiently

Drove company vehicles to customer sites and performed weekly maintenance on them

Worked with team to coordinate large parties up to a 1000 person graduation party

Valley Sports Complex Lower Burrell, PA November 2007 to June 2008

Worked after school hours

Patrolled free skates ensuring the safety of all customers

Serviced Zamboni by checking water levels, changing oil, etc.

Worked front desk dealing with paying customers at the cash register

17

Function

Mechanical DesignBraking MechanismGliding Mechanism

Provide load rollers7594473

3265449

3675978

Secure dance cage3194178

0229929

216289

3791305

Provide stability7594473

Art

No.MetricImportanceUnitsTarget Value

1Unit production cost4US$< 1000

2Operational life4Yrs10

3Number of maintenance appointments per year3Appts< 3

4Simple mechanical design4-Subj.

5Hazard areas guarded5-Subj.

6Track wheels roll on glide rail smoothly4-Subj.

7Minimize number of steel rods for structure4lbs< 1200

8Track wheels support machine weight5lbs/wheel> 300

9Simply powered3-Subj.

10Speed of dance vehicle4ft/s< 14.7

11Stepping bars within wheels for dancers5Amt./wheel20

METRICSHazard areas guardedMinimize number of steel rods for structureSimply poweredNumber of maintenance appointments per yearUnit production costSimple mechanical designWheels support machine weightOperational lifeWheels roll on glide rail smoothlySpeed of dance vehicleStepping bars within wheels for dancers

NEEDS

Noise reductionXX

Minimal frictionX

Dance machine is durableXXXXX

Remains within budgetXX

Rolling System supports inner cageX

Dance machine is safeXXX

Accomodates six dancersX

LightweightX

Easy to stopXX

Slow movementX

Low maintenanceXX

Maximum visibility of dancersXXX

Braking system for inner cage