Boosting energy return using 3D printed midsoles designed with compliant constant force mechanisms

IF 2.9 3区工程技术 Q2 ENGINEERING, MECHANICAL Journal of Mechanical Design Pub Date : 2023-11-30 DOI:10.1115/1.4064164

Haihua Ou, S. Johnson

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Abstract

The enhancement of midsole compressive energy return is associated with improved running economy. Traditional midsole materials such as EVA, TPU, and PEBA foams typically exhibit hardening force-displacement characteristics. On the other hand, a midsole with softening properties, which can be achieved through Compliant Constant Force Mechanisms (CFMs), can provide significant benefits in terms of energy storage and return. This study presents the development of such a midsole, incorporating 3D printed TPU CFM designs derived through structural optimization. The mechanical properties under cyclic loading were evaluated and compared with those of commercially available running shoes with state-of-the-art PEBA foam midsoles, specifically the Nike ZoomX Vaporfly Next% 2 (NVP). Our custom midsole demonstrated promising mechanical performance. At similar deformation levels, the new design increased energy storage by 58.1% and energy return by 47.0%, while reducing the peak compressive force by 24.3%. As per our understanding, this is the first study to prove that the inclusion of CFMs in the structural design of 3D printed midsoles can significantly enhance energy return.

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利用 3D 打印鞋垫提高能量回馈，鞋垫设计采用顺应性恒力机制

中底压缩能量回馈的增强与跑步经济性的提高有关。EVA、TPU 和 PEBA 泡沫等传统中底材料通常具有硬化力-位移特性。另一方面，具有软化特性的中底（可通过顺应恒力机制（CFM）实现）可在能量存储和回馈方面提供显著优势。本研究介绍了这种中底的开发情况，其中采用了通过结构优化获得的 3D 打印热塑性聚氨酯 CFM 设计。研究人员评估了循环载荷下的机械性能，并将其与采用最先进 PEBA 泡沫中底的市售跑鞋（特别是耐克 ZoomX Vaporfly Next% 2 (NVP)）进行了比较。我们的定制中底表现出了良好的机械性能。在类似的变形水平下，新设计的能量储存增加了 58.1%，能量回流增加了 47.0%，同时峰值压缩力降低了 24.3%。据我们了解，这是第一项证明在 3D 打印中底的结构设计中加入 CFM 可显著提高能量回馈的研究。

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来源期刊

Journal of Mechanical Design 工程技术-工程：机械

CiteScore

8.00

自引率

18.20%

发文量

139

审稿时长

3.9 months

期刊介绍： The Journal of Mechanical Design (JMD) serves the broad design community as the venue for scholarly, archival research in all aspects of the design activity with emphasis on design synthesis. JMD has traditionally served the ASME Design Engineering Division and its technical committees, but it welcomes contributions from all areas of design with emphasis on synthesis. JMD communicates original contributions, primarily in the form of research articles of considerable depth, but also technical briefs, design innovation papers, book reviews, and editorials. Scope: The Journal of Mechanical Design (JMD) serves the broad design community as the venue for scholarly, archival research in all aspects of the design activity with emphasis on design synthesis. JMD has traditionally served the ASME Design Engineering Division and its technical committees, but it welcomes contributions from all areas of design with emphasis on synthesis. JMD communicates original contributions, primarily in the form of research articles of considerable depth, but also technical briefs, design innovation papers, book reviews, and editorials.