Developing a full-body finite element model and its preliminary validation for seating comfort

Proceedings of the 7th International Digital Human Modeling Symposium (DHM 2022) and Iowa Virtual Human Summit 2022 - Pub Date : 2022-08-23 DOI:10.17077/dhm.31775

S. Liu, P. Beillas, Li Ding, Xuguang Wang

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Abstract

Human body finite element (FE) models can be used for seating comfort assessment by providing biomechanical related parameters such as internal loads and soft-tissue deformations. However, most of the published models were only validated under a condition far from a real seating situation. Their ability to be repositioned may also be limited. In recent years, an open-source PIPER software package has been developed to help personalize and position Human Body Models (HBMs) for crash simulation. We have morphed the PIPER Child model into an adult FE model. In this paper, we present how the initially morphed adult FE model was adapted for assessing seating comfort and validated for different seating conditions. Experimental data was collected using a reconfigurable experimental seat and pressure mats. Four seat configurations were defined with the seat pan angle (SPA) from 0° to 15° (5° in steps) and seat pan to seat backrest angle (SP2BA) kept to 100°. Simulated results in terms of seat contact area (ContactA), peak pressure (PeakP), mean pressure (MeanP), and pressure profiles showed good agreement with experimental observations. The full-body FE model developed and validated in this work will be used as a reference for further development of scalable and positionable models using the PIPER software framework. The model will be open source to facilitate reuse and further improvements.

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建立了座椅舒适性的全身有限元模型并进行了初步验证

人体有限元(FE)模型可以通过提供内部载荷和软组织变形等生物力学相关参数，用于座椅舒适性评估。然而，大多数已发布的模型仅在远离真实座位情况的条件下进行了验证。它们重新定位的能力也可能有限。近年来，一个开源的PIPER软件包被开发出来，以帮助个性化和定位人体模型(HBMs)进行碰撞模拟。我们已经将PIPER儿童模型转变为成人FE模型。在本文中，我们介绍了如何将最初变形的成人有限元模型用于评估座位舒适性，并在不同的座位条件下进行验证。实验数据采集采用可重构实验座椅和压力垫。确定了4种座椅配置，其中座椅盘面角(SPA)为0°~ 15°(5°为阶梯)，座椅盘面与座椅靠背角(SP2BA)为100°。座座接触面积(ContactA)、峰值压力(PeakP)、平均压力(MeanP)和压力分布的模拟结果与实验结果吻合较好。在这项工作中开发和验证的全身有限元模型将作为使用PIPER软件框架进一步开发可扩展和可定位模型的参考。该模型将是开源的，以促进重用和进一步改进。

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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Proceedings of the 7th International Digital Human Modeling Symposium (DHM 2022) and Iowa Virtual Human Summit 2022 -

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