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Wheelchair Dynamic Center of Gravity (D-COG)
Kyle Mobley, BMEGarrett Spiegel, BMEAndrew Lossing, ChBE (Not present)
Advisor: Dr. Mark Richter, President
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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Background
1.6 – 2.2 million wheelchair users in United States alone1
146.8% increase in wheelchair related injuries in U.S. from 1991 to 20031
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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Background (cont’d) Most users cannot climb hills greater than
8% grade for more than 30 feet [2] Necessitates user folding to maintain
stability. Leads to discomfort and greatly increased effort.
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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Basic Design Questions Seat or Axle movement? How will it move?
How is the movement controlled? How far does it need to move?
How will it stay in place? How is it designed?
Feasibility - upgrade possibility
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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Seat or Axle Movement? Axle Movement necessitates overcoming
weight at wheels’ point of contact Seat Movement is much more feasible
Similar to movement of driver or passenger seat in a car
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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How will it move? Use of concave wheels between two bars
Bars will move in relation to each other
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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How is the movement controlled?
8° decline biases seat in forward direction Releasing seat results in forward motion User can further facilitate motion by
braking Rear wheel propulsion naturally resets
COG to original position
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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How far does it need to move? Choosing tippiness is a “compromise
between risk of rearward instability and the ability to propel and maneuver easily”.3
Shorter wheelbase = more tippy = COG backwards Longer wheelbase = less tippy = COG forwards
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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How far does it need to move? (cont’d)
Determinations: 20% COG change necessary for desired
effect 4 inches of axle (or seat) movement
14 14.5 15 15.5 16 16.5 170.82
0.84
0.86
0.88
0.9
0.92
0.94
0.96
Wheelbase Length (inches)
Cent
er o
f Gra
vity
(% o
ver r
ear
whe
els)
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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How will it stay in place? User controlled clamping brake pads
When brake released, seat is free to move Clamping brake holds seat in desired
position
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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How is it designed? Altering pre-existing base design to
conform to our specifications Dimensional constraints Brake placement Roller placement
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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Future Directions Get assistance with AutoCAD Build prototype
Welding, Metalwork, Construction Test/Revise prototype
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10
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References
1. H Xiang, A-M Chany, G A Smith. 2006. “Wheelchair related injuries treated in US emergency departments”. Injury Prevention. 12:8–11.
2. “ADA Wheelchair Ramp Specifications”. Mobility Advisor. http://www.mobility-advisor.com/wheelchair-ramp-specs.html
3. “Guidance on the Stability of Wheelchairs”. March, 2004. MHRA. DB2004(02).
Lossing, Mobley, Spiegel http://www.bme.vanderbilt.edu/srdesign/2009/group5/ D-COG Senior Design 2009-10