纺织学报 ›› 2024, Vol. 45 ›› Issue (09): 146-153.doi: 10.13475/j.fzxb.20230203101

• 服装工程 • 上一篇    下一篇

速度滑冰比赛服个性化样板生成方法

肖伯祥1, 张悦1,2, 胡志远1,2, 赵欲晓1, 刘莉1,2()   

  1. 1.北京服装学院 服装艺术与工程学院, 北京 100029
    2.北京服装学院 服装科技研究院, 北京 100029
  • 收稿日期:2023-02-15 修回日期:2024-05-22 出版日期:2024-09-15 发布日期:2024-09-15
  • 通讯作者: 刘莉(1976—),女,教授,博士。主要研究方向为功能服装。E-mail: fzyll@bift.edu.cn
  • 作者简介:肖伯祥(1981—),男,教授,博士。主要研究方向为服装智能工程。
  • 基金资助:
    国家重点研发计划“科技冬奥”专项资助项目(2019YFF0302100);北京市自然科学基金面上项目(4222044);北京市高校分类发展“服装学”新兴交叉学科平台建设项目(11000024T000003073871)

Personal pattern generating method for speed skating suits

XIAO Boxiang1, ZHANG Yue1,2, HU Zhiyuan1,2, ZHAO Yuxiao1, LIU Li1,2()   

  1. 1. School of Fashion, Beijing Institute of Fashion Technology, Beijing 100029, China
    2. Research Center of Fashion Technology, Beijing Institute of Fashion Technology, Beijing 100029, China
  • Received:2023-02-15 Revised:2024-05-22 Published:2024-09-15 Online:2024-09-15

摘要:

速度滑冰比赛服是重要的运动装备,为解决速滑比赛服定制中样板与个性化体型匹配度较差和制版效率低的问题,提出一种基于质点-弹簧系统的样板生成方法。首先,扫描运动员三维体型,根据体型特征和比赛服分割线提取各主要衣片的三维模型网格;基于三维网格建立质点-弹簧模型;同时,对比赛服弹性面料进行多角度拉伸试验测量面料力学属性,以确定质点-弹簧模型的参数;然后,将衣片三维模型向二维平面投影,给定模型参数和约束条件在二维平面内对质点-弹簧模型进行迭代,在内部能量最小化目标约束下模型收敛后,获得的边界形状即认为是该衣片的样板;最后,经过服装CAD样板调整和裁剪缝纫等加工工艺步骤制作比赛服样衣,经运动员试穿评价后微调得到最终的个性化比赛服样板。试验结果表明,生成样板的测量误差在可接受范围以内,运动员主观试穿反馈样衣合体度良好,本文方法能够有效实现速度滑冰比赛服个性化样板生成,从而为速滑比赛服定制制版提供有效的技术支持和实用工具。

关键词: 速度滑冰, 比赛服, 样板制作, 个性化定制, 样板生成, 质点-弹簧系统

Abstract:

Objective Speed skating suits are an important sport equipment, where the generation of efficient and good-fit patterns are a primary challenge in customization. In order to achieve the personalized pattern, a pattern generating method for speed skating suits is proposed based on the mass-spring system. The aim of the research is to determine precise pattern shapes according to individual body build. It is helpful and significant to improve fitness of the suits and to promote the pattern-making efficiency.

Method 3-D model of athlete's body shape was obtained by scanning, and 3-D mesh models of each part of the suit were extracted based on the body shape features of athlete and the structural line distribution of suits., and the mass-spring system models were then constructed based on 3-D meshing of suit parts. Multi-angle tensile tests were carried out on the elastic fabric used in the suits to obtain the mechanical and physical properties of the fabric, and the parameters of the mass-spring model were determined by fabric properties. 3-D models of suit parts were flattened into the 2-D plane, and the mass-spring models were repeatedly used in the 2-D plane under the given model parameters and constraints. After the garment CAD pattern adjustment, accessories supplement, cutting and sewing and other processing steps, the sample suits were manufactured.

Results In experiments, 3-D body models of one male athlete and one female athlete were acquired through scanning, and their main body shape parameters were obtained. Instron 3343 material testing machine was adopted to test the mechanical properties of the elastic fabrics and the data were analyzed aiming at the making of speed skating suits. The measured properties were employed to calculate the elastic modulus of the virtual springs in the mass-spring models, which were constructed by 3-D meshes of pattern pieces extracted from scanned human models. They were used in 3-D flattening to obtain the 2-D pattern pieces' shape. The models converged under the objective constraint of internal energy minimization, and the boundary shapes obtained were considered to be the 2-D pattern of the suit components. In a typical suit, 5 pieces including front, back, arm, upper leg and lower leg were extracted and flattened. Owing to symmetry, only the left parts were selected. The mean errors of 3-D flattening algorithm were limited in a low level from 3-D to 2-D flattening. The basic shapes of pieces were obtained, and then made a series of adjustments were performed to achieve the final pattern. Flattened pattern shapes from body poses of standing and skating action were compared and the results showed obvious shape differences, indicating that the material properties constrained 3-D flattening pattern-making method. Personal body shape as well as that in designated pose could be used directly to determine the optimal pattern shapes. Furthermore, comparisons have been conducted between sample suits of our algorithm-based pattern-making and conventional manual pattern-making. After the athletes' try-on and evaluate, the final sample suits were formed to enable the personalized pattern making. The experimental results showed that the measurement errors of the generated pattern were within the acceptable range, and the athletes' subjective try-on feedback suggested that the sample suits were fitting well.

Conclusion The method can effectively facilitate the personalized pattern generation of speed skating suits, so as to provide effective technical support and practical tools for personal customized pattern making of speed skating suits. The achieved twofold advantages of proposed method are. One is that the flattening-based algorithm is helpful to determine optimal pattern shapes directly and quickly according to personal human body. Another is that the method is semi-automatically implemented by programs to promote pattern-making efficiency. The main limitations are that the method relies on the accuracy of scanned human models and the pattern structure needs to be given beforehand. The future meaningful work includes parametric pattern-making and intelligent models based on a large number of pattern-body shape practices.

Key words: speed skating, suit, pattern making, personal, generating, mass-spring system

中图分类号: 

  • TS941.26

图1

本文方法流程示意图"

图2

三维人体扫描的设备和扫描场景"

图3

面料力学性能测量试验"

图4

沿纵向不同角度的面料取样"

图5

面料不同拉伸方向的弹性模量"

图6

基于扫描模型的比赛服三维衣片提取"

图7

提取的比赛服衣片三维衣片模型"

图8

基于质点-弹簧模型的三维网格展平"

图9

三维衣片模型展平"

图10

根据方向计算的弹簧弹性系数k"

图11

展平算法生成的二维版片图形"

图12

富怡CAD样板微调与补充配件"

表1

三维衣片模型和二维衣片模型变形计算比较"

衣片 迭代收敛质点
最大位移/mm
曲线长度
变化率/%
版片面积
变化率/%
后片 0.000 608 1.04 0.10
前片 0.000 712 1.03 0.13
腿片 0.000 696 4.72 2.18

图13

不同姿态模型生成样板比较分析"

表2

生成样板与手工制版样衣实例测量尺寸比较"

实验对象 前衣长 后衣长 前裆长 后裆长 腿根围 臂根围 前胸宽 后背宽 全腰围 全身长
运动员1 2.7 -1.9 -0.6 4.4 -5 3 0.3 -3 -2 -1.4
运动员2 1.6 1.2 -0.8 4.5 -3.8 2.2 0.5 -1.8 -1.6 2.6
运动员3 -1.2 2 -1.2 4.2 -4.2 2.6 -0.2 -2.3 -0.5 1.8
运动员4 -1.8 1.7 -1.1 4.8 -2.8 1.9 -0.3 -1.2 -0.8 3.2

图14

样衣尺寸的测量位置"

图15

速滑比赛服样衣不同姿态试穿效果"

[1] YANG Chenhao, XU Yongxin, YANG Yang, et al. Effectiveness of using compression garments in winter racing sports: a narrative review[J]. Frontiers in Physiology, 2020(11):970.
[2] 李博, 刘翠佳, 杨威, 等. 滑得更快的科学:速度滑冰的运动生物学特征[J]. 体育科学, 2021, 41(8): 34-42.
LI Bo, LIU Cuijia, YANG Wei, et al. The science of skating faster:sport-biological profile of speed skating[J]. China Sport Science, 2021, 41(8): 34-42.
[3] GERARD Kuper, ELMER Sterken. Do skin suits increase average skating speed?[J]. Journal of Sports Technology, 2008, 1(4/5): 189-195.
[4] LEN Brownlie, CHESTER Kyle. Evidence that skin suits affect long track speed skating performance[J]. Procedia Engineering, 2012, 34(1): 26-31.
[5] 马杰. 短道速度滑冰运动生物学特征研究进展[J]. 体育科学, 2021, 41(8):43-52.
MA Jie. Sport-biological profile of short track speed skating[J]. China Sport Science, 2021, 41(8):43-52.
[6] 蔺世杰, 郑伟涛, 马勇, 等. 不同雷诺数下速滑运动员阻力特性研究及减阻服装建议[J]. 北京服装学院学报(自然科学版), 2021, 41(4):1-8.
LIN Shijie, ZHENG Weitao, MA Yong, et al. Resistance characteristics of speed skater under different reynolds numbers and suggestions for drag reduction clothing[J]. Journal of Beijing Institute of Fashion Technology (Natural Science Edition), 2021, 41(4):1-8.
[7] 杨宸灏, 杨洋, 胡齐, 等. 紧身服装在冬奥竞速运动项目中的研究与应用现状[J]. 中国体育科技, 2020, 56(1):24-30.
YANG Chenhao, YANG Yang, HU Qi, et al. Research and application status of compression garment in winter olympics racing sports[J]. China Sport Science and Technology, 2020, 56(1):24-30.
[8] MOON Youngjin, SONG Jooho, HWANG Jinny. Differences in rectus femoris activation among skaters wearing fabric speed skating suits with different levels of com-pression[J]. Korean Journal of Sport Biomechanics, 2016, 26(4): 421-426.
[9] CHENG Pengpeng, WANG Jianping, TAO Xuyuan. Motion comfort analysis of tight-fitting sportswear from multi-dimensions using intelligence systems[J]. Textile Research Journal, 2022, 92(11/12):1843-1866.
[10] LIU Yongjin, ZHANG Dongliang, YUEN Matthew Minfai. A survey on CAD methods in 3D garment design[J]. Computers in Industry, 2010, 61(6): 576-593.
[11] ALEXANDRA De Raeve, JORIS Cools, SIMONA Vasile. 3D body scanning as a valuable tool in a mass customization business model for the clothing indu-stry[J]. Journal of Fashion Technology & Textile Engineering, 2018. DOI: 10.4172/2329-9568.S4-009.
[12] JIANG Liguo, YE Juntao, SUN Liming, et al. Transferring and fitting fixed-sized garments onto bodies of various dimensions and postures[J]. Computer-Aided Design, 2019, 106(1): 30-42.
[13] 吴妍, 胡紫婷, 胡志远, 等. 基于速度滑冰上肢动态皮肤形变的服装结构研究[J]. 毛纺科技, 2022, 50(4):1-7.
WU Yan, HU Ziting, HU Zhiyuan, et al. Study on garment structure based on upper limb dynamic skin deformation in speed skating[J]. Wool Textile Journal, 2022, 50(4):1-7.
[14] ZHANG Yunbo, WANG Charlie. WireWarping++ robust and flexible surface flattening with length control[J]. IEEE Transactions on Automation Science and Engineering, 2011, 8(1):205-215.
[15] ARIC Bartle, ALLA Sheffer, KIM Vladimir, et al. Physics-driven pattern adjustment for direct 3d garment editing[J]. ACM Transaction on Graphics, 2016, 35(4):50.
[16] DERYA Tama, ARZU Genkilic, ZIYNET Ondogan, et al. The usability of 3D flattening in design and pattern preparation of tight-fit garments[J]. Cukurova University Journal of the Faculty of Engineering and Architecture, 2016. 31(2):169-173.
[17] KWOK Tszho, ZHANG Yanqiu, WANG Charlie, et al. Styling evolution for tight-fitting garments[J]. IEEE Transactions on Visualization and Computer Graphics, 2016, 22(5): 1580-1591.
[1] 葛苏敏, 林瑞冰, 徐平华, 吴思熠, 罗芊芊. 基于机器视觉的曲面枕个性化定制方法[J]. 纺织学报, 2024, 45(02): 214-220.
[2] 刘玉叶, 王萍. 基于纹理特征学习的高精度虚拟试穿智能算法[J]. 纺织学报, 2023, 44(05): 177-183.
[3] 肖伯祥, 刘正东, 郭昱成, 王渊霞. 基于三维人体扫描模型的衬衣版型生成方法[J]. 纺织学报, 2022, 43(12): 151-159.
[4] 张健, 徐凯忆, 赵崧灵, 顾冰菲. 基于二维照片的青年男性颈肩部形态分类与识别[J]. 纺织学报, 2022, 43(05): 143-149.
[5] 雷鸽, 李小辉. 数字化服装结构设计技术的研究进展[J]. 纺织学报, 2022, 43(04): 203-209.
[6] 冀艳波, 王玲丽, 刘凯旋. 基于数字化三维人体模型的旗袍定制设计[J]. 纺织学报, 2021, 42(01): 133-137.
[7] 朱伟明 卫杨红. 不同情景下服装个性化定制体验价值差异研究[J]. 纺织学报, 2018, 39(10): 115-119.
[8] 王永进 宋彦杰 刁杰. 排球比赛服的功能结构设计研究[J]. 纺织学报, 2014, 35(2): 71-0.
Viewed
Full text


Abstract

Cited

  Shared   
  Discussed   
No Suggested Reading articles found!