一种基于目标接触压力分布的接触轮廓设计方法

IF 2.7 3区 材料科学 Q2 ENGINEERING, MECHANICAL International Journal of Mechanics and Materials in Design Pub Date : 2023-08-30 DOI:10.1007/s10999-023-09674-5
Tianming Zhang, Jindong Ren
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引用次数: 0

摘要

有效的人机界面至关重要。然而,目前设计接触轮廓的方法并非完全无懈可击,经常依赖经验和多次设计迭代,要实现理想的目标接触压力分布具有挑战性。本研究提出了一种基于接触条件下平衡关系的新型接触轮廓设计方法,旨在实现目标接触压力。研究分析了人体组织的机械特性,并建立了人体有限元模型。利用轮椅坐垫和自行车鞍座两个设计案例,根据设计预期构建了接触压力分布。通过模拟得到了目标接触压力分布下的人体变形表面轮廓。此外,还分析了聚氨酯超弹性泡沫的机械性能及其随模型参数的变化,并建立了其数学模型。根据目标压力计算泡沫的变形并对变形体表面进行补偿,然后得到重建轮廓并与设计轮廓拟合。建立了一个对照组模型,并使用接触模拟来验证设计轮廓。两种设计情况的模拟结果表明,设计轮廓的接触压力分布与目标接触压力分布之间的差异很小,优于对照组的传统经验设计轮廓,从而验证了该方法的可行性。
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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A design method for contact contour based on the distribution of target contact pressure

An effective human–machine interface is of utmost importance. However, the current methods for designing contact contours are not entirely flawless, frequently relying on experience and multiple design iterations, and are challenging to achieve the desired distribution of target contact pressure. This study proposes a novel design method for contact contour that is based on the equilibrium relationship under contact conditions and is aimed at achieving target contact pressure. The mechanical properties of human tissue were analyzed, and a finite element model of the human body was established. Using two design cases of a wheelchair cushion and a bicycle saddle, contact pressure distribution was constructed based on design expectations. The deformed surface profile of the human body under the target contact pressure distribution was obtained through simulation. Additionally, the mechanical properties of polyurethane hyper-elastic foam and its variation with model parameters were analyzed, and a mathematical model of it was established. The deformation of foam was calculated and compensated to the deformed body surface according to the target pressure, and the reconstructed contour was then obtained and fitted to the design contour. A control group model was constructed, and contact simulation was used to validate the designed contour. The simulation results of both design cases showed that the difference between the contact pressure distribution of the design contour and the target contact pressure distribution was small, and it was better than the traditional empirical design contour of the control group, thus verifying the feasibility of this method.

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来源期刊
International Journal of Mechanics and Materials in Design
International Journal of Mechanics and Materials in Design ENGINEERING, MECHANICAL-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
6.00
自引率
5.40%
发文量
41
审稿时长
>12 weeks
期刊介绍: It is the objective of this journal to provide an effective medium for the dissemination of recent advances and original works in mechanics and materials'' engineering and their impact on the design process in an integrated, highly focused and coherent format. The goal is to enable mechanical, aeronautical, civil, automotive, biomedical, chemical and nuclear engineers, researchers and scientists to keep abreast of recent developments and exchange ideas on a number of topics relating to the use of mechanics and materials in design. Analytical synopsis of contents: The following non-exhaustive list is considered to be within the scope of the International Journal of Mechanics and Materials in Design: Intelligent Design: Nano-engineering and Nano-science in Design; Smart Materials and Adaptive Structures in Design; Mechanism(s) Design; Design against Failure; Design for Manufacturing; Design of Ultralight Structures; Design for a Clean Environment; Impact and Crashworthiness; Microelectronic Packaging Systems. Advanced Materials in Design: Newly Engineered Materials; Smart Materials and Adaptive Structures; Micromechanical Modelling of Composites; Damage Characterisation of Advanced/Traditional Materials; Alternative Use of Traditional Materials in Design; Functionally Graded Materials; Failure Analysis: Fatigue and Fracture; Multiscale Modelling Concepts and Methodology; Interfaces, interfacial properties and characterisation. Design Analysis and Optimisation: Shape and Topology Optimisation; Structural Optimisation; Optimisation Algorithms in Design; Nonlinear Mechanics in Design; Novel Numerical Tools in Design; Geometric Modelling and CAD Tools in Design; FEM, BEM and Hybrid Methods; Integrated Computer Aided Design; Computational Failure Analysis; Coupled Thermo-Electro-Mechanical Designs.
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