[1]谢 红,刘星辰,沈云萍.弹性护膝防护效果预测模型的分析[J].服装学报,2023,8(02):108-117.
 XIE Hong,LIU Xingchen,SHEN Yunping.Analysis of Protective Effect Prediction Models of Elastic Knee Pads[J].Journal of Clothing Research,2023,8(02):108-117.
点击复制

弹性护膝防护效果预测模型的分析()
分享到:

《服装学报》[ISSN:2096-1928/CN:32-1864/TS]

卷:
第8卷
期数:
2023年02期
页码:
108-117
栏目:
服装人体工学
出版日期:
2023-05-01

文章信息/Info

Title:
Analysis of Protective Effect Prediction Models of Elastic Knee Pads
作者:
谢 红;  刘星辰;  沈云萍
上海工程技术大学 纺织服装学院,上海 201620
Author(s):
XIE Hong;  LIU Xingchen;  SHEN Yunping
School of Textiles and Fashion, Shanghai University of Engineering Science, Shanghai 201620, China
分类号:
TS 941.7
文献标志码:
A
摘要:
通过构建人体膝关节-护膝有限元模型,模拟人体站立和高度屈曲两种姿势,从应力、位移两个维度分析穿着不同弹性护膝对膝关节韧带的影响; 采用最大位移差作为弹性护膝防护效果仿真模拟的评判指标,通过有限元法对膝关节内部组织结构间的作用机理进行定量化研究,进而对弹性护膝的防护效果进行预判。经模型测试,得到:1#样本弹性护膝对膝关节的防护效果最差,5#样本最好,样本1#~5#防护效果呈递增趋势,与护膝样本的实际防护效果一致。实验证明,模型可用于弹性护膝防护效果的预测,为弹性护膝的设计提供技术支持。
Abstract:
In this chapter, finite element method is used to simulate the protective effect of elastic knee pads, and the influence of different elastic knee pads on knee ligament is analyzed from two dimensions of stress and displacement. The maximum displacement difference was used to evaluate the protective effects of elastic knee pads simulation, in order to predict the protective effect of knee pads made of different fabrics, so as to improve the functional design and production of elastic knee pads. The results showed that the elastic knee pads made by 1# had the worst protective effects, while pads made by 5# had the best effects. The protective effects showed increasing trends from 1# to 5# consistent with the actual protective effect of the knee pads samples. It was proved that the model could be used to predict the protective effects of elastic knee pads. And the study could provide suggestions for elastic knee pads design.

参考文献/References:

[1] 季立云. 磁共振成像在膝关节半月板损伤中的诊断价值分析[J]. 中文科技期刊数据库(文摘版)医药卫生, 2022(1): 187-189.
JI Liyun.Analysis of the diagnostic value of magnetic resonance imaging in knee joint and meniscal injuries[J]. Chinese science and technology journal database(abstract edition)medicine and health, 2022(1): 187-189.(in Chinese)
[2] 王嘉瑛, 李令岭, 马梁, 等. 跑步爱好者运动损伤的调查与分析[J]. 昆明医科大学学报, 2020, 41(1): 151-157.
WANG Jiaying, LI Lingling, MA Liang, et al. Investigation and analysis of sports injury of runners[J]. Journal of Kunming Medical University, 2020, 41(1): 151-157.(in Chinese)
[3] 刘青青, 阎玉秀. 不同款式的篮球护膝防护性能的研究[J]. 消费导刊, 2017(21): 8-9.
LIU Qingqing, YAN Yuxiu. Study on the protective performance of different styles of basketball knee pads[J]. Consume Guide, 2017(21): 8-9.(in Chinese)
[4] HERBAUT A, DELANNOY J, FOISSAC M. Injuries in French and Chinese regular badminton players[J]. Science and Sports, 2018, 33(3): 145-151.
[5] 魏巍, 裴仁明, 孙喆. 用磁共振影像为膝关节检查者建立膝关节三维有限元模型的效果[J]. 当代医药论丛, 2019, 17(6): 46- 47.
WEI Wei, PEI Renming, SUN Zhe. Effect of establishing three-dimensional finite element model of knee joint for knee joint examiners with magnetic resonance imaging[J]. Contemporary Medical Symposium, 2019, 17(6): 46-47.(in Chinese)
[6] 高艳芳, 豆贺, 韩盛松, 等. 基于Mimics软件的股骨的提取与三维模型重建[J]. 中国科技信息, 2017(17): 99-101.
GAO Yanfang, DOU He, HAN Shengsong, et al. Femoral extraction and 3D model reconstruction based on Mimics software[J]. China Science and Technology Information, 2017(17): 99-101.(in Chinese)
[7] 刘星辰, 谢红. 基于有限元建模技术的下肢着袜舒适性分析[J]. 上海纺织科技, 2021, 49(11): 18-21.
LIU Xingchen, XIE Hong. Analysis of the comfortability of lower limb socks based on finite element modeling technology[J]. Shanghai Textile Science and Technology, 2021, 49(11): 18-21.(in Chinese)
[8] 黎蒙. 女性羽毛球运动员头顶球单腿落地动作的膝关节生物力学有限元分析[D]. 上海: 上海体育学院, 2020.
[9] 苏工兵, 陈海英, 张露, 等. 人体下肢有限元模型构建及着袜舒适性分析[J]. 天津工业大学学报, 2013, 32(6): 32-35.
SU Gongbing, CHEN Haiying, ZHANG Lu, et al. Building of finite element model of lower limbs and analysis of socks’ comfort[J]. Journal of Tianjin Poly-technic University, 2013, 32(6): 32-35.(in Chinese)
[10] 陈文栋, 杨光. 不同载荷条件下半月板动态仿真生物力学分析[J]. 中国组织工程研究, 2017, 21(11): 1742-1747.
CHEN Wendong, YANG Guang. Biomechanical analysis of dynamic simulation of meniscus under different loading conditions[J]. Chinese Journal of Tissue Engineering Research, 2017, 21(11): 1742-1747.(in Chinese)
[11] SUN P C, SHIH S L, CHEN Y L, et al. Biomechanical analysis of foot with different foot arch heights: a finite element analysis[J]. Computer Methods in Biomechanics and Biomedical Engineering, 2012, 15(6): 563-569.
[12] 鲍春雨, 郭宝川, 孟庆华. 人体膝关节有限元模型建立及其有效性验证[J]. 应用力学学报, 2017, 34(3): 559-563, 615.
BAO Chunyu, GUO Baochuan, MENG Qinghua. A finite element model of human knee joint and its validation[J]. Chinese Journal of Applied Mechanics, 2017, 34(3): 559-563, 615.(in Chinese)
[13] PE?A E, CALVO B, MARTíNEZ M A, et al. A three-dimensional finite element analysis of the combined behavior of ligaments and menisci in the healthy human knee joint[J]. Journal of Biomechanics, 2006, 39(9): 1686-1701.
[14] GABRIEL M T, WONG E K, WOO S L Y, et al. Distribution of in situ forces in the anterior cruciate ligament in response to rotatory loads[J]. Journal of Orthopaedic Research, 2004, 22(1): 85-89.
(责任编辑:卢 杰)

更新日期/Last Update: 2023-05-08