运动内衣承托及其动态舒适性能的有限元分析

doi:10.13475/j.fzxb.20220706601

纺织学报 ›› 2023, Vol. 44 ›› Issue (09): 180-187.doi: 10.13475/j.fzxb.20220706601

运动内衣承托及其动态舒适性能的有限元分析

孙玥¹^,²^,³(), 周凌芳¹, 周祺旋¹, 张诗晨⁴, 易洁伦⁵

1.浙江理工大学服装学院, 浙江杭州 310018
2.浙江省服装工程技术研究中心, 浙江杭州 310018
3.服装数字化技术浙江省工程实验室, 浙江杭州 310018
4.广州美术学院工业设计学院, 广东广州 510000
5.香港理工大学时装及纺织学院, 香港 999077

收稿日期:2022-07-19 修回日期:2023-03-05 出版日期:2023-09-15 发布日期:2023-10-30
作者简介:孙玥(1988—),女,讲师,博士。主要研究方向为服装数字化仿真。E-mail:sunyue@zstu.edu.cn。
基金资助:
浙江理工大学科研启动基金项目(20072324-Y)

Finite element analysis of supportive performance and dynamic comfort of sports bra

SUN Yue¹^,²^,³(), ZHOU Lingfang¹, ZHOU Qixuan¹, ZHANG Shichen⁴, YICK Kit-lun⁵

1. School of Fashion Design & Engineering, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
2. Apparel Engineering Research Center of Zhejiang Province, Hangzhou, Zhejiang 310018, China
3. Zhejiang Provincial Engineering Laboratory of Clothing Digital Technology, Hangzhou, Zhejiang 310018, China
4. School of Innovation Design, Guangzhou Academy of Fine Arts, Guangzhou, Guangdong 510000, China
5. School of Fashion & Textiles, The Hong Kong Polytechnic University, Hong Kong 999077, China

Received:2022-07-19 Revised:2023-03-05 Published:2023-09-15 Online:2023-10-30

摘要/Abstract

摘要：

为对运动内衣的功能性和舒适性进行可量化预测及评估,缩短内衣行业的产品设计开发流程,对人体和运动内衣的动态接触关系建立有限元模型,并研究乳房在运动过程中与运动内衣的复杂相互作用机制。首先通过三维人体扫描获得人体点云数据,运用逆向工程软件进行处理,得到胸部、身体躯干和运动内衣的几何模型。利用过盈配合方法模拟人体穿着运动内衣的预紧力状态,并在重力场中加入三维运动系统捕捉的躯干动态位移作为边界条件来驱动有限元模型,从而模拟人体穿着运动内衣时的乳房运动形态。模拟结果与真实测量值的相对误差为5.15%,验证了此模型的准确性。在此模型的基础上进一步对运动内衣面料的力学属性进行参数化设计,研究了5倍初始弹性模量的运动内衣对乳房的控制性能和动态压力舒适性。结果表明,使用高弹性模量材料的运动内衣虽然能轻微增加对胸部位移的控制效果,但相应增加的人体服装压已经高于人体舒适的服装压力范围。本文提出的研究方法和结果可从功能性和舒适性角度综合指导运动内衣的面料选择,优化运动内衣的设计并缩短开发时间。

关键词: 运动内衣, 承托性能, 动态舒适性, 乳房位移, 接触压力, 有限元模型

Abstract:

Objective Without the adequate support and protection, females' breasts would suffer from troubles such as ligament rupture and mastitis during physical activities. Wearing sports bra could limit the movement of breasts, thus reducing the pain or discomfort during exercises. In order to predict and evaluate the function and comfort of sports bra, as well as to reduce the process of product design and development for intimate apparel industry, a dynamic contact finite element (FE) modeling system for human body and sports bra was constructed to evaluate the performance of sports bra with different design features from the aspects of control level and contact pressure.

Method The data of female chest was obtained by 3-D body scanner to obtain the geometric model of breasts, body torso and sports bra. The method of interference fit was adopted to simulate the pre-tension of the breasts and sports bra after wearing. The displacement of the torso obtained from the motion capture system was used as the boundary condition to drive the finite element model under the gravity field. The motion of the breasts after wearing sports bra was simulated by this FE model and a parametric study was also conducted for different material parameters of the sports bra.

Results The simulated results from the constructed FE contact model between human body and sports bra was validated with the motion capture experiment in terms of the nipple displacement. The calculated relative average absolute error was 4.13% (braless condition) and 5.15% (wearing sports bra) which denoted the accuracy of the FE method. Based on the numerical model, a parametric study was conducted to investigate different fabric materials on the control performance and wearing comfort. A virtual sports bra (SPB2) with higher Young's modulus, which was 5 times than the original tested sample SPB1, was introduced into the FE contact model. The maximum motion displacement of nipple when wearing SPB1 was 235.043 mm, while that was 228.861 mm for SPB2. The control effect of breast movement by SPB2 was increased by only 2.6% when comparing with SPB1. With regards to the contact pressure, it was revealed that in a static state, the shoulder strap has the highest contact pressure, followed by the lower under-band and the bottom of breasts (Tab. 3). It is mainly because the effects of gravity lead to the sagging of the breasts, thus the shoulder strap produces a corresponding force to support the breasts. The dynamic contact pressure extracted from different positions of human body showed that large fluctuations were detected at the bottom breasts for both SPB1 and SPB2, appearing periodically. The dynamic pressure in the position of shoulder straps, under-band and bottom breasts of SPB2 (0.30-1.19 kPa) was all higher than SPB1 (1.56-4.65 kPa) (Fig. 10), which was out the range of comfort pressure of human body (1.96-3.92 kPa). The results showed that although the higher Young's modulus of sports bra could strengthen the control performance slightly, the corresponding increase of contact pressure was higher than the comfortable clothing pressure range of the human body, which could easily cause the human body feel discomfort.

Conclusion The breast displacement and the dynamic contact pressure between breasts and bra were evaluated quantitively by the proposed numerical simulation method. The supportive performance and wearing comfort by sports bra with different material properties were compared. This model can be utilized to investigate the complicated contact mechanism between the breasts and sports bra during physical activities, thus comprehensively guiding the fabric selection of sports bra from the perspective of functionality and comfort. The intimated apparel industry will be benefited by the proposed method in terms of optimizing the design for sports bra and shortening the development duration.

Key words: sports bra, supportive performance, dynamic comfort, breast displacement, contact pressure, finite element model

中图分类号:

TS941.2

孙玥, 周凌芳, 周祺旋, 张诗晨, 易洁伦. 运动内衣承托及其动态舒适性能的有限元分析[J]. 纺织学报, 2023, 44(09): 180-187.

SUN Yue, ZHOU Lingfang, ZHOU Qixuan, ZHANG Shichen, YICK Kit-lun. Finite element analysis of supportive performance and dynamic comfort of sports bra[J]. Journal of Textile Research, 2023, 44(09): 180-187.

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参考文献 20

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有限元模型	几何类型	网格类型	网格尺寸/mm
人体软组织	实体	四面体	8
身体躯干	刚体	—	—
运动内衣	壳体	四边形	8

运动内衣部件	弹性模量E/MPa	泊松比ν
肩带	0.18	0.05
下捆带	0.19	0.10
面料(纵向)	0.14	0.22
面料(横向)	0.47	0.16

内衣类型	肩带	胸底	下捆
SPB1	1.15	0.33	0.60
SPB2	4.58	1.65	2.83

运动内衣承托及其动态舒适性能的有限元分析

Finite element analysis of supportive performance and dynamic comfort of sports bra

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