纺织学报 ›› 2024, Vol. 45 ›› Issue (10): 95-102.doi: 10.13475/j.fzxb.20230901601

• 纺织工程 • 上一篇    下一篇

基于双扎口的纬编管状无缝织物三维仿真

陈钰珊1,2, 蒋高明1(), 李炳贤1   

  1. 1.江南大学 针织技术教育部工程研究中心, 江苏 无锡 214122
    2.广东职业技术学院 纺织学院, 广东 佛山 528041
  • 收稿日期:2023-09-08 修回日期:2024-05-21 出版日期:2024-10-15 发布日期:2024-10-22
  • 通讯作者: 蒋高明(1962—),男,教授,博士。主要研究方向为纺织数字化技术与纺织结构材料。E-mail: jgm@jiangnan.edu.cn
  • 作者简介:陈钰珊(1999—),女,硕士生。主要研究方向为纬编针织物的设计与三维仿真。
  • 基金资助:
    江苏省自然科学青年基金项目(BK20221094);中央高校基本科研业务费专项资金资助项目(JUSRP123005)

Three-dimensional simulation of weft-knitted tubular seamless fabric based on welt tucks

CHEN Yushan1,2, JIANG Gaoming1(), LI Bingxian1   

  1. 1. Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi, Jiangsu 214122, China
    2. Textile School, Guangdong Polytechnic, Foshan, Guangdong 528041, China
  • Received:2023-09-08 Revised:2024-05-21 Published:2024-10-15 Online:2024-10-22

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摘要:

为在设计过程中能够实时查看纬编管状无缝织物不同部位的线圈结构与织物的三维效果,避免反复打样,缩短设计流程,通过分析扎口特殊结构的编织原理,分别建立下扎口、衣身和上扎口编织图模型。结合线圈几何模型和织物实际测量的参数,分别建立上下扎口、衣身和扎口线线圈网格模型。将无缝管状产品的不同组织结构数字化存储为编织图,判断其中编织动作对应的线圈网格类型,代入线圈型值点与线圈网格点间的数学关系式,求得线圈型值点的三维坐标;结合穿纱模型中设计的对应纱线参数,采用WebGL技术渲染线圈型值点路径,实现纬编管状无缝织物的三维仿真。将扎口部位的仿真结果与实际织物对比,结果表明:将线圈分方向建模的方法对实现双扎口结构的仿真是科学可行的,以典型无缝抹胸为例,可对简单的纬编管状无缝产品进行三维平面、筒状和曲面仿真,为进一步研究复杂的纬编无缝产品仿真奠定基础。

关键词: 扎口结构设计, 线圈几何模型, 线圈网格模型, 纬编无缝内衣, 三维结构仿真

Abstract:

Objective Due to their snug fit, versatile fabric functionalities and other characteristics, seamless warp-knitted products are gaining gradual applications across various fields such as apparel, healthcare, and interior decoration. With the improvement of computer-assisted technology, the demand for online design and real-time simulation of seamless fabrics is becoming increasingly significant. This research mainly explores the knitting principle of seamless warp-knitted fabrics, discusses the special loop structure at the welt stitch locations, and focuses on the simulation research of simple seamless fabrics with double welt stitches.

Method Based on the principle of welt knitting in weft-knitted fabrics, the structure of double-layer welt was analyzed, and a knitting diagram model was established. To deal with the opposite directions of double-layer loops, a top-down grid division and a bottom-up grid division were proposed, and the corresponding loop grid model was established based on the relationship between model points and grid points. Combining the corresponding yarn parameters in the threading model, the three-dimensional loop structure was drawn using WebGL technology.

Results Based on an in-depth study of the loop structure of weft-knitted tubular seamless products a loop geometric model, an upper tuck loop geometric model and a lower welt loop geometric model have been established based on the classic Pierce loop model and the actual shape of the loops. Considering the unique double-layer loop structure of the welt in weft-knitted tubular seamless products two loop mesh models of the same size but opposite directions and a welt loop mesh model were constructed. By combining the loop geometric models, the mathematical relationship between the type value points and the mesh points was constructed to obtain the loop mesh parameters, and the z-direction of the special transverse row loop type value points was adjusted.

An upper welt knitting pattern model, a garment body knitting pattern model, and a lower welt knitting pattern model were established. Through the process, the corresponding loop mesh model was determined using an algorithm, where the direction of loops in the front half of the lower welt and the back half of the upper welt runs from top to bottom, utilizing the welt loop mesh model. For the garment body and the back half of the lower welt and the front half of the upper tuck, the direction of loops runs from bottom to top, using the gridf loop mesh model. By integrating the yarn parameters from the threading model, the three-dimensional loop structure was rendered using WebGL technology.

Examples were presented to demonstrate the simulation effects of typical weft-knitted seamless products in both tubular and flat unfolded forms, clearly showing the interlocking relationship of loops and the double-layer structure characteristics at the welt stitch areas. Examples also showcased the effect of the garment on a human body, with the simulation image of a tube top closely fitting the surface curves of the body, hiding the back welt stitch structure in a way consistent with the actual fabric.

Conclusion The implementation of three-dimensional simulation for seamless warp-knitted products bypasses processes such as machine trials, directly obtaining the finished fabric effect from the pattern design, reducing product development steps, and improving product development efficiency. By comparing the simulation results with the actual fabric, it is demonstrated that using this method to simulate seamless warp-knitted products with double welt stitches is scientifically feasible. It can perform three-dimensional planar, cylindrical, and curved simulations for simple seamless warp-knitted tube tops, laying a foundation for further research into the simulation of complex seamless warp-knitted products.

Key words: welt structure design, loop geometry model, loop grid-based model, weft knitted seamless underwear, three-dimensional structure simulation

中图分类号: 

  • TS186.3

图1

起口工艺"

图2

扎口编织过程"

图3

扎口结构"

图4

成圈线圈"

图5

实际织物扎口线线圈"

图6

扎口线线圈几何模型"

图7

成圈线圈网格模型"

图8

扎口成圈线圈网格模型"

图9

扎口线线圈网格模型"

表1

成圈线圈网格模型参数"

型值点 bm,1 bm,2 bm,3 bm,4 Rz Pz
P0/R0 0.577 0.163 0.203 0.057 -N×r-Tn -N×r
P1/R1 0.246 0.181 0.329 0.244 -(1.N×3)×
r-Tn		 r-N×
1.r
P2/R2 0.593 0.060 0.315 0.032 -(1.N×3)×
r-Tn		 r-N×
1.r
P3/R3 0.190 0.077 0.520 0.213 -N×r-Tn -N×r
P4/R4 0.077 0.190 0.213 0.520 -N×r-Tn -N×r
P5/R5 0.060 0.593 0.032 0.315 -(1.N×3)×
r-Tn		 r-N×
1.r
P6/R6 0.181 0.246 0.244 0.329 -(1.N×3)×
r-Tn		 r-N×
1.r
P7/R7 0.163 0.577 0.057 0.203 -N×r-Tn -N×r

图10

扎口侧面结构示意图及对应模型调整结果"

图11

仿真流程图 注:%代表计算机语言中的除余运算。"

图12

纬编无缝产品筒状仿真"

图13

平板三维仿真图"

图14

抹胸产品穿着效果展示"

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