Elastic Measurements in an Operating Shoe Sole

1. Elastic Measurementsin an Operating Shoe Sole BME 301 Steven Pauls, Timothy Rand Brian Schwartz, Brant Kochsiek Advisor: Professor Naomi Chesler Client: Professor David Beebe March 5, 2004

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3. Problem Statement • Device should fit into the sole of a shoe • Inform runner when shoe is worn • Decrease incidence of injury due to shoe wear • Measure the elasticity of the shoe sole • Direct measurement • Other methods

4. Problem Motivation • Running shoes last 300-500 miles • Worn shoes not always “worn” • Incidence of injury increases with worn shoes • Diagnostic tool in relation to running style

5. Client Requirements • Lightweight • Ergonomic with sole • Operable for life of the running shoe • Should not hinder performance • Have clear indicator

6. Elastic Effect • Elastic recoil cushions impact • Age/Wear decreases elastic effect • Similar stresses create more strain on material

7. Shoe Materials • Ethylene and Vinyl Acetate (EVA) • Polyurethane (PU) Upper Footbridge Midsole Outsole http://www.dummies.com/WileyCDA/DummiesArticle/id-450,subcat-SPORTS.html

8. Pronation Styles Wet sand imprints indicating foot shape and pronation style Most common strides (note: underpronation is also termed supination) http://www.dummies.com/WileyCDA/DummiesArticle/id-450,subcat-SPORTS.html

9. Shoe Wear Patterns • Forefoot Striking • Neutral • Overpronation • Supination http://www.fleetfeethouston.com/tips/basics.asp

10. Principles Design Matrix

11. Strain Gauge • Directly affected by elasticity (ε = σ∕ E) • Inexpensive • Small • Requires calibration • Incorrect alignment http://www.dur.ac.uk/richard.scott/gauges.html

12. Conductive PolymerForce Sensor • Resistive elements • Medium to high pressure range • Compact • Indirect Measurement • Requires calibration http://interlinkstore.com

13. Force Differential • Impact creates force (F), smaller dispersal force (f) • F α f as a function of shoe sole force absorbance • Force absorbance during impact is a function of elasticity • Set ratio F:f will trigger sensor, indicate elastic wear

14. Retroreflectors • Advantages • Small, lightweight, & cheap • Only taking one measurement (distance) instead of two • Virtually no wear on device • Disadvantages • Need for clear polymer in some portions of the shoe sole • Distance measurement may not correlate to shoe sole elasticity

15. Future Work • Polymer which degrades faster than EVA or polyurethane • Integrate retro-reflector, strain gauge, & a conductive polymer force sensor into polymer mold • Perform tests to determine which device is able to detect wear (elasticity) the best • Determine correlation between shoe wear and output of each device • Select ultimate wear value • Integrate chosen device into a shoe sole for field testing • Possible patent application

16. Prototype Design Matrix

17. Acknowledgments Professor Naomi Chesler Professor David Beebe Professor John Webster UW Biomedical-Engineering Dept.