Design and testing of a prototype foot orthosis that uses the principle of granular jamming
Autor: | Emily Simonds, Young-Hui Chang, Geza F. Kogler, Jonathan S. Colton |
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Rok vydání: | 2020 |
Předmět: |
030506 rehabilitation
business.product_category Braces Computer science Interface (computing) Rehabilitation Stiffness Mechanical engineering Uniaxial compression Foot Orthoses Jamming Equipment Design Health Professions (miscellaneous) 03 medical and health sciences 0302 clinical medicine Energy absorption medicine Humans medicine.symptom 0305 other medical science business Material properties 030217 neurology & neurosurgery Foot orthosis |
Zdroj: | Prosthetics and orthotics international. 45(3) |
ISSN: | 1746-1553 |
Popis: | STUDY DESIGN A mechanical testing protocol was used to compare the material properties of commercially available foams with that of a newly designed granular jamming orthosis prototypes. BACKGROUND Foot orthoses have an inherent limitation of predetermined mechanical material properties coupled with a fixed orthotic interface shape that cannot be readily changed. OBJECTIVES To develop and test a novel orthotic insole design concept that incorporates principles of granular jamming. METHODS Granular media were used in combination with vacuum pressure to create a variable stiffness granular foot orthosis. Four types of granular media (rice, poppy seeds, micropolystyrene, and polystyrene beads) were tested in different prototype configurations varying in volume fill and particulate size. Stress-strain curves were obtained from uniaxial compression tests to characterize granular foot orthosis prototypes in comparison with commercial orthotic foams. RESULTS Increasing vacuum pressure increased prototype stiffness for most configurations. A single granular jamming orthosis could exhibit energy absorption values that spanned the entire commercial foam performance range, and in some cases extended far beyond the upper values of the tested foams. CONCLUSION The results suggest that granular jamming principles can provide clinicians the capability for rapid selection of mechanical properties over a wide range of orthosis stiffnesses. Importantly, patients could don the orthosis because the clinician makes real-time assessments and adjustments in the clinic. |
Databáze: | OpenAIRE |
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