纺织学报 ›› 2023, Vol. 44 ›› Issue (06): 85-90.doi: 10.13475/j.fzxb.20220100101

• 纺织工程 • 上一篇    下一篇

多色调线横条纹织物的设计与三维仿真

郑培晓, 蒋高明(), 丛洪莲, 李炳贤   

  1. 江南大学 针织技术教育部工程研究中心, 江苏 无锡 214122
  • 收稿日期:2022-01-04 修回日期:2022-03-31 出版日期:2023-06-15 发布日期:2023-07-20
  • 通讯作者: 蒋高明
  • 作者简介:郑培晓(1996—),女,博士生。主要研究方向为数字化纺织技术。
  • 基金资助:
    国家自然科学基金项目(61772238);泰山产业领军人才项目(tscy20180224);国家留学基金项目(202106790065);江苏省研究生科研与实践创新计划项目(KYCX21_2015)

Design and three-dimensional simulation of multi-color striped fabrics

ZHENG Peixiao, JIANG Gaoming(), CONG Honglian, LI Bingxian   

  1. Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi, Jiangsu 214122, China
  • Received:2022-01-04 Revised:2022-03-31 Published:2023-06-15 Online:2023-07-20
  • Contact: JIANG Gaoming

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摘要:

为能够通过深入研究花型设计、穿纱设计可织性和三维仿真方法来提高多色调线横条纹织物的开发效率,根据调线圆纬机的编织原理和特点构建花型设计模型并生成色纱编织序列模型。计算出各成圈系统所编织的色纱种类并生成导纱模型,依据排纱原则建立了穿纱设计模型。构建了线圈几何模型和平移映射模型,并探究多色调线横条纹织物的三维仿真方法。运用上述数学模型和理论进行程序设计,以11色渐变调线横条纹为例验证其花型设计和穿纱设计在4色调线圆纬机上的编织可行性,并对比织物实物图和三维仿真图。结果表明,设计模型验证方法切实可行,仿真花色效应良好,该方法为多色调线横条纹织物的设计方案可织性分析和织物三维仿真提供了理论参考。

关键词: 纬编, 调线圆纬机, 多色调线横条纹织物, 设计模型, 三维仿真

Abstract:

Objective Multi-color striped fabrics are one of the important fashion elements in knitwear design. The development of the knitwear fashion trend reveals that fabrics with a small number of colors can no longer meet the needs of consumers. How to carry out a reasonable and feasible secondary innovative design based on multi-color striped fabrics to replace the original monotonous stripes is the challenge to the majority of designers. In this process, it is also a big problem to predict the feasibility of knitting and the color effect of multi-color striped fabrics.
Method To quickly generate a feasible design scheme and three-dimensional (3-D) simulation for multi-color striped fabrics, the pattern design models were constructed and the colored-yarn knitting sequence model was generated according to the knitting principle and characteristics of the striping circular weft knitting machine. The types of colored yarn knitted by each knitting system were calculated and the yarn guiding model was generated. According to the yarn arrangement principle, the yarn threading model was established. The loop geometry and translation mapping models were constructed, and the 3-D simulation method of multi-color striped fabrics was explored with coordinate translation mapping.
Results The design and simulation of eleven-color gradient striped fabric were taken as an example to verify the knitting feasibility for pattern and threading design on the four-color striping circular machine. The fabric design and 3-D simulation process were used to verify the feasibility of the study method (Fig. 2). The pattern model (P) and knitting model (K) were generated according to the pattern design, and the color sequence was reordered from large to small in proportion to produce colored yarn knitting sequence model (Y) (Fig. 3). According to the parameters of the knitting machine and the above pattern model, guiding instructions of yarns were assigned to the guiding devices in each knitting system to obtain guiding model (G) (Fig. 4). Based on the yarn guiding model, the codes of colored yarns in each knitting system were arranged in the yarn threading model(T). Only the number 1 to 4 thread adjusting fingers were arranged in the yarn threading model, enabling patterns of eleven-color striped fabric to be knitted normally on the four-color striping circular machine (Fig. 5). The results of the design model show that the proposed method can effectively predict the knittability of multi-color striped fabrics on the striping machine. For 3-D simulation, the coordinate model of the loop control point (L) was established. The relative position of each loop in the fabric coordinate system was achieved based on the knitting model, hence obtaining the loop translation model (t). Finally, the new spatial coordinate of each loop control point (L') at different positions was calculated. With the help of the Three.js tool, the 3-D simulation of the multi-color gradient striped fabric was achieved (Fig. 6(b)). The results show that the simulation method can visually and clearly display the color effect of multi-color striped fabrics (Fig. 6(a)), and the simulated color effect is regarded as satisfactory.
Conclusion A scientific and effective method for yarn threading design, knittability test and 3-D simulation of multi-color striped fabrics is explored. It is proved by practice that the pattern and threading design model can effectively verify the pattern knittability, so as to guide the fabric design and production. The proposed translation mapping method can effectively reduce the amount of data calculation and improve the running speed of simulation, so as to establish the 3-D simulation of fabric and predict the beauty of color quickly. This method can be applied to the design and 3-D simulation of four-color, six-color, and other multi-color striped fabrics with jacquard. It not only can automatically generate the design scheme according to the pattern, predict the knittability and aesthetics of the machine, but it can also accurately locate the wrong position in the design scheme and generate optimization suggestions, which helps improve the design production efficiency and reduce the waste of raw materials from the root.

Key words: weft knitting, striping machine, multi-color striped fabric, design model, three-dimensional simulation

中图分类号: 

  • TS186.2

图1

线圈几何建模"

图2

织物设计和三维仿真流程图"

图3

花型意匠图及其色纱序列"

图4

导纱模型示意图"

图5

穿纱模型示意图"

图6

多色渐变调线横条纹实物图和织物仿真图"

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