基于男性腰臀裆部NURBS曲面模型的内裤数字化制版

doi:10.13475/j.fzxb.20220701101

摘要/Abstract

摘要：

为解决男士内裤版型因前裆凸起量规定模糊而导致内裤裆部不合体的问题,对男性人体建立腰臀裆部曲面仿真模型,依据曲面模型生成合体的数字化内裤版型。运用三维人体扫描仪获取实验对象腰臀裆部点云数据,使用逆向工程软件提取点云数据中能表征腰臀裆部形态的点云坐标集,按照NURBS曲线曲面原理在Solidworks软件中建立腰臀裆部曲面模型并对7块曲面进行展平,以ET服装CAD软件为版片编辑平台生成合体的男士内裤版型。结果表明:从点云数据中提取7个特征截面的点云坐标集构建的曲面模型能够表征腰臀裆部体表形态,数字化男士内裤版型在虚拟试衣和真实试穿中十分贴合男性腰臀裆部形态,内裤服装压强范围在0~2.4 kPa之间,可满足人体舒适性要求,验证显示采用腰臀裆部曲面模型生成数字化内裤版型是合理的,数字化内裤版型更符合人体腰臀裆部形态特征,为合体和贴体服装版型的快速获取提供一种新的方法。

关键词: 数字化服装制版, 男士内裤版型, 腰臀裆部曲面模型, NURBS曲面, 曲面展平

Abstract:

Objective In order to solve the problem of ambiguity in the amount of front crotch bulge in men's underwear pattern and the problem of ill-fitting crotch of underwear, a surface simulation model of waist, hip and crotch of male human body was established by extracting point cloud data, and a well-fitting men's underwear pattern was generated based on the surface model to improve the comfort of wearing men's underwear by improving the underwear pattern, and also to broaden the new idea of fast access to the fit and body-fitting clothing pattern.

Method A 3-D body scanner was used to obtain the point cloud data of the waist, hip and crotch of the experimental subject, and the point cloud coordinate set was extracted from the point cloud data using reverse engineering software to describe the waist, hip and crotch morphology. NURBS curve and surface principle were used to construct the waist, hip and crotch surface model, the 3-D surface was developed into a 2-D plane in Solidworks software, and the developed plane was processed using ET software to generate a fitted digital underwear pattern.

Results Using the 3-D body scanner to obtain the point cloud data of the male mannequin, 7 feature sections characterizing the morphology of the waist, hip and crotch were selected, and 50 equidistant points of each feature section were extracted from the point cloud data to form a point cloud coordinate set as indicated in Fig. 2(b) for the point cloud coordinate set imported into Solidworks software. The male waist, hip and crotch were reasonably divided into 16 areas, and NURBS curves and surfaces were constructed based on the information of point coordinates in the point cloud coordinates set (Fig. 4). The waist, hip and crotch surface models were established in Solidworks software by using common connecting lines of adjacent surfaces, and the surface models were made to accurately describe the body surface morphology of the waist, hip and crotch. The surface flattening tool was used to flatten the three-dimensional surface into a two-dimensional plane, and the area error ≤1 cm² and the boundary length error ≤1 cm during the flattening process were within the acceptable range of dimensional error. The 2-D plane was exported into the ET software for 4 simple steps (Fig. 7): curve point optimization, plate alignment and shape docking, front and back crotch line adjustment and waist adjustment, and the final digital men's underwear pattern was generated. Based on the virtual fitting of 3-D scanned mannequins in CLO3D software and the actual garment fitting on the male mannequin, the fitting effect was verified for the underwear pattern. Using an air bag contact pressure tester, the pressure test was conducted on seven key parts of the underwear wear. The garment pressure generated by the underwear ranged from 0 to 2.4 kPa (Tab. 4), verifying that the digital underwear version met the garment pressure comfort requirements.

Conclusion For the study of fitted men's underwear patterns, a method is proposed to establish a surface model of the waist and hip crotch and generate a digital men's underwear pattern through the surface model, which solves the problem of ill-fitting men's underwear crotch and provides a new approach for the rapid generation of fitted men's underwear patterns. The digital pattern-making method can be applied to the acquisition of fitted and close-fitting garment patterns by establishing a simulated surface model of the human body form to generate a fitted garment pattern, and the structure of the garment pattern is more in line with the detailed morphological characteristics of the human body.

Key words: digital clothing pattern making, men's underwear pattern, surface model of male waist, hip and crotch, NURBS surface, surface flattening

中图分类号:

TS941.2

任泽, 钟安华. 基于男性腰臀裆部NURBS曲面模型的内裤数字化制版[J]. 纺织学报, 2023, 44(08): 167-173.

REN Ze, ZHONG Anhua. Digital pattern making of underwear based on NURBS surface model of male waist, hip and crotch[J]. Journal of Textile Research, 2023, 44(08): 167-173.

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曲面编号	曲面面积/cm²	平面面积/cm²	差值/cm²
1	103.11	103.11	0
2	57.97	57.96	0.01
3	341.17	341.06	0.11
4	187.66	187.86	0.20
5	431.22	431.75	0.53
6	257.42	257.44	0.02
7	11.48	11.48	0

曲面编号	曲面边界长度/cm	平面边界长度/cm	差值/cm
1	50.40	50.44	0.04
2	34.09	34.23	0.14
3	73.86	74.01	0.15
4	62.24	62.40	0.16
5	83.17	83.09	0.08
6	72.29	73.06	0.77
7	31.53	31.53	0