The nonlinear finite element analysis and plantar pressure measurement for various shoe soles in heel region.

T Y Shiang
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Abstract

The most influential factor contributing to foot and shoe comfort is underfoot cushioning. The shock absorbing ability of footwear in the heel area is of particular importance in reducing the impact load during athletic activities and in therapeutic footwear prescribed for heel pain. Furthermore, foot care for foot problem patients is an important part of treatment and educational programs. Therefore, a well-designed sport shoe which can provide comfort and protection is essential. In order to design a functional shoe, biomechanics and other new technologies should be considered, and the design process should be examined in the biomechanics laboratory over and over. The design process requires too much time and effort since the entire experimental and test work can only be done after the prototype is manufactured. Therefore, this study tried to introduce the Finite Element Method (FEM) into the shoe design process by building a three-dimensional FE model with various shoe soles and loading conditions. The material properties of shoe materials were tested using an Instron Testing Machine. An in-shoe pressure insole was used to measure the plantar pressure in different ambulation conditions with various shoe constructions. The subject for this study was a healthy young male without any foot problem. The average plantar pressures obtained from approximately 50 steps in the heel region for each of the various conditions were collected. The results showed that the mean peak plantar pressure of the running situation was significantly higher than that of the walking situation as predicted, and that the insole could provide better cushioning compared to the other shoe constructions. The stress strain relationship for shoe materials was approximated better by a second-order nonlinear curve according to the Instron test. The results of the finite element method suggested that only the second-order nonlinear stress strain curve could correctly describe the shoe material, which also confirmed a potential valuable role for FEM in designing functional shoes.

不同鞋跟区鞋底的非线性有限元分析及足底压力测量。
对脚和鞋子舒适度影响最大的因素是脚底缓冲。鞋跟区域的减震能力对于减少运动时的冲击负荷和治疗鞋跟疼痛特别重要。此外,足部问题患者的护理是治疗和教育计划的重要组成部分。因此,设计良好的运动鞋,既能提供舒适,又能提供保护是必不可少的。为了设计出功能鞋,需要考虑生物力学和其他新技术,设计过程需要在生物力学实验室中反复检验。设计过程需要太多的时间和精力,因为整个实验和测试工作只能在原型制造后完成。因此,本研究试图将有限元法(FEM)引入到鞋子的设计过程中,通过建立具有不同鞋底和载荷条件的三维有限元模型。采用Instron试验机对鞋用材料进行了性能测试。采用内压鞋垫测量不同鞋型下不同行走条件下的足底压力。这项研究的对象是一位没有脚部问题的健康年轻男性。收集了每种不同情况下脚跟区域大约50步的平均足底压力。结果表明,跑步时的平均峰值足底压力明显高于步行时的峰值,与其他鞋型相比,鞋垫具有更好的缓冲作用。根据Instron试验,用二阶非线性曲线较好地逼近了鞋材的应力应变关系。有限元方法的结果表明,只有二阶非线性应力应变曲线才能正确地描述鞋的材料,这也证实了有限元法在功能鞋设计中的潜在价值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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