Influence of 3D-printed cellular shoe soles on plantar pressure during running − Experimental and numerical studies

IF 5.3 2区医学 Q1 ENGINEERING, BIOMEDICAL

Biocybernetics and Biomedical Engineering Pub Date : 2024-10-01 DOI:10.1016/j.bbe.2024.11.004

Paweł Baranowski , Aleksandra Kapusta , Paweł Płatek , Marcin Sarzyński

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Abstract

The paper explores the potential of additive manufacturing (AM), experiments and simulations to develop a personalized shoe sole, with cellular topology used as the insert that minimizes the plantar pressure during running. Five different topologies were manufactured by Fused Filament Fabrication 3D printing technique using thermoplastic polyurethane TPU 95 filaments and tested experimentally and using FEA under compression conditions. The error between the maximum peak force and specific energy absorbed (SEA) from the model and experiment were less than 4.0 % and 6.0 %, respectively. A deformable FE foot model was developed, which was validated against data from the literature on balanced standing and the landing impact test carried out in the study. For the first case, the predicted maximum pressure (P_peak = 0.20 MPa) was positioned between the data presented in previous papers (0.16 MPa ÷ 0.30 MPa). In the second case, the experimentally measured and numerically predicted force peak values were nearly identical: 1760 N and 1720 N, respectively, falling with the range of 2.2 ÷ 2.5 BW similarly to other studies. Finally, a shoe sole design was proposed based on these topologies, which was simulated in the rearfoot impact to investigate the deformation of the sole and its influence on the foot plantar pressure peak and its distribution. The findings indicated that the sole with cellular structure could drastically reduce plantar pressure and improve overall footwear performance. This research provides valuable guidance and insights for designing, modelling, and simulating customized shoe sole manufactured using the 3D printing technique.

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3d打印细胞鞋底对跑步时足底压力的影响−实验和数值研究

本文探讨了增材制造（AM）、实验和模拟的潜力，以开发个性化鞋底，使用细胞拓扑作为插入物，最大限度地减少跑步过程中的足底压力。使用热塑性聚氨酯TPU 95长丝，采用熔融长丝制造3D打印技术制造了5种不同的拓扑结构，并在压缩条件下进行了实验和有限元分析测试。最大峰值力与吸收比能（SEA）的误差分别小于4.0%和6.0%。建立了可变形有限元足部模型，并根据平衡站立和着陆冲击试验的文献数据对该模型进行了验证。对于第一种情况，预测的最大压力（Ppeak = 0.20 MPa）位于之前论文的数据（0.16 MPa ÷ 0.30 MPa）之间。在第二种情况下，实验测量和数值预测的力峰值几乎相同，分别为1760 N和1720 N，与其他研究相似，在2.2 ÷ 2.5 BW的范围内下降。最后，提出了一种基于这些拓扑结构的鞋底设计方案，并对后足撞击进行了仿真，研究了鞋底变形及其对足底压力峰值及其分布的影响。研究结果表明，具有细胞结构的鞋底可以显著降低足底压力，提高鞋类的整体性能。本研究为使用3D打印技术制造定制鞋底的设计、建模和仿真提供了有价值的指导和见解。

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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来源期刊

Biocybernetics and Biomedical Engineering ENGINEERING, BIOMEDICAL-

CiteScore

16.50

自引率

6.20%

发文量

审稿时长

38 days

期刊介绍： Biocybernetics and Biomedical Engineering is a quarterly journal, founded in 1981, devoted to publishing the results of original, innovative and creative research investigations in the field of Biocybernetics and biomedical engineering, which bridges mathematical, physical, chemical and engineering methods and technology to analyse physiological processes in living organisms as well as to develop methods, devices and systems used in biology and medicine, mainly in medical diagnosis, monitoring systems and therapy. The Journal''s mission is to advance scientific discovery into new or improved standards of care, and promotion a wide-ranging exchange between science and its application to humans.