Journal of Textile Research ›› 2023, Vol. 44 ›› Issue (11): 113-119.doi: 10.13475/j.fzxb.20220812301

• Textile Engineering • Previous Articles     Next Articles

Three-dimensional simulation of single jacquard warp knitted shoe fabrics based on spring-mass model

YANG Meiling, JIANG Gaoming(), WANG Ting, LI Bingxian   

  1. Engineering Research Center for Knitting Technology, Ministry of Education, Jiangnan University, Wuxi, Jiangsu 214122, China
  • Received:2022-08-29 Revised:2023-03-06 Online:2023-11-15 Published:2023-12-25

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Abstract:

Objective In order to explore the mesh deformation principle in the warp knitted jacquard spacer shoe material fabric, the interaction mechanism of the loops on both sides of the mesh in the warp knitted single needle bed fabric is used to form a three-dimensional spring-mass particle tensile action geometric model between the loops of the surface layer, the bottom layer and the middle spacer layer. The tensile mechanical deformation equation and offset distance between the loops in the jacquard spacer shoe fabric are obtained to improve the three-dimensional (3-D) deformation simulation effect of single jacquard warp knitted double needle bed interval jacquard shoe fabric.

Method Aiming at the mesh area division design of warp knitted jacquard spacer shoe fabric, the jacquard principle of single jacquard comb in fabric forming is studied, and the jacquard artwork is designed and drawn. Using the quadratic Bezier curve to establish the unit loop model, and aiming at the three-dimensional structure of the spacer shoe fabric, the three-dimensional spring-mass model that conforms to the actual fabric structure is constructed, including the shearing spring, structural spring, and bending spring. The offset is worked on by the explicit integration method.

Results The single jacquard comb performs jacquard action on one side of the fabric of the spacer shoe fabric, forming a rich upper appearance through thick, thin and mesh fabric effects. The functional areas of the single jacquard warp knitted spacer vamp are divided (Fig. 1). Using red, white and green to form a single jacquard artwork, it shows fabric structures with different mesh sizes and thicknesses (Fig. 2). Using the natural transition principle of the tangent line of the quadratic Bezier curve, the motion track value of the continuous points of the loop at the tangent line is calculated. A total of 8 shape point control unit loops are adopted to build a three-dimensional geometric model of the loop, which more realistically shows the bending shape of the loop (Fig. 3, Fig. 4). On the basis of the construction principle of the two-dimensional spring-mass model adopted by the conventional warp knitted single needle bed, a three-dimensional spring-mass model based on the double needle bed spacer shoe fabric is established. Three types of spring particle systems are shown, including thick and thin mesh structures formed by spacer wire, chain knitting bottom comb and single jacquard (Fig. 6). According to the influence between spring and masses in the model, the force equation of the loop is established based on Newton's mechanical theorem, and the external force is ignored. The elastic deformation force and damping force between masses are calculated, and the explicit Euler method and midpoint method that are conducive to improving the simulation speed are selected to conduct particle velocity and displacement distance within unit time step. Three improvement measures are put forward for the easily occurring overshoot phenomenon. JavaScript and C# programming language are adopted to program the 3-D simulation of single jacquard warp knitted spacer shoe fabric, and the simulation is compared with the real picture to verify the effectiveness of the mechanical model simulation method.

Conclusion Based on the real state of the fabric, the single jacquard warp knitted shoe fabrics was simulated for deformation, Newton's laws of mechanics were adopted to establish the particle grid system. The influence range of the force of a single loop particle was sorted out, which verified the feasibility of the deformation simulation based on the three-dimensional spring-mass model, and improved the deformation simulation efficiency of the jacquard warp knitted shoe fabrics. The deformation simulation of warp knitted double jacquard spacer shoe fabric and triple jacquard spacer shoe fabric needs further research and realization.

Key words: warp knitted shoe fabric, spacer fabric, circled jacquard, jacquard principle, spring-mass model, three-dimensional simulation

CLC Number: 

  • TS186.3

Fig. 1

Design diagram of single jacquard spacer shoe material"

Fig. 2

Jacquard drafted pattern and corresponding loop structure diagram. (a) Thick tissue; (b) Thick and thin intersecting orangization; (c) Small mesh; (d) Medium mesh;(e) Large mesh"

Fig. 3

Quadratic Bezier curve"

Fig. 4

Loop model diagram"

Fig. 5

Spring-mass model and three spring types. (a) Spring-mass model; (b) Structural spring;(c) Shearing spring; (d) Bending spring"

Fig. 6

3-D spring-mass model and different structure organization. (a) 3-D spring-mass model; (b) Main view and side view of force; (c) Spacer filament tissue; (d) Chaining organization; (e) Janquard organization"

Tab. 1

Table of fabric process parameters"

梳栉 原料 线密度 垫纱数码 送经量/
(㎜·腊克-1)
GB1 涤纶
DTY		 150 dtex(48 f) 1-0-0-0/
2-3-3-3//		 2 360
GB2 涤纶
DTY		 150 dtex(48 f) 1-0-0-0/
0-1-1-1//		 1 480
GB3 涤纶
单丝		 33 dtex 1-0-2-1/
2-3-1-2//		 7 900
JB4 涤纶
DTY		 150 dtex(48 f) 1-1-1-2/
1-1-1-0//		 2 360
GB5 涤纶
DTY		 150 dtex(48 f) 1-1-1-0/
1-1-0-1//		 1 480

Fig. 7

Fabric physical picture (a) and simulation effect picture (b)"

Fig. 8

Simulation flow chart"

[1] 张爱军, 蒋高明, 李欣欣, 等. 应用弹簧-质点模型的双贾卡提花织物形变仿真[J]. 纺织学报, 2017, 38(1): 146-151.
ZHANG Aijun, JIANG Gaoming, LI Xinxin, et al. Deformation simulation of double jacquard fabric using mass-spring model[J]. Journal of Textile Research, 2017, 38(1):146-151.
[2] 顾沁婷, 李艳梅, 刘翔. 基于质点-弹簧模型的织物形象化仿真技术与展望[J]. 纺织学报, 2013, 34(3): 147-153.
GU Qinting, LI Yanmei, LIU Xiang. Visualization simulation technology of cloth deformation based on mass-spring model and its prospect[J]. Journal of Textile Research, 2013, 34(3):147 -153.
[3] 曾令玺, 邓中民, 柯薇. 基于新三针选针技术的间隔织物鞋面网孔组织研究[J]. 现代纺织技术, 2018, 26(3):38-43.
ZENG Lingxi, DENG Zhongmin, KE Wei. Research of mesh stitch of vamp of spacer fabrics based on new three-needle selection technique[J]. Advanced Textile Technology, 2018, 26(3):38-43.
[4] CONG H L, LI X X, ZHANG A J, et al. Modeling of double-layer jacquard fabrics for pattern simulation[J]. International Journal of Clothing Science and Technology, 2018, 30(5):698-709.
doi: 10.1108/IJCST-08-2017-0131
[5] 张姿叶, 蒋高明, 丛洪莲, 等. 浮纹型贾卡经编针织物的计算机仿真[J]. 纺织学报, 2011, 32(2):53-57.
ZHANG Ziye, JIANG Gaoming, CONG Honglian, et al. Computer simulation of warp knitted brochÉ fabric[J]. Journal of Textile Research, 2011, 32(2):53-57.
[6] 郭成蹊. 少梳栉经编网眼织物结构与变形研究[D]. 武汉: 武汉纺织大学, 2018:27-37.
GUO Chengxi. The study of structure and deformation of warp knitted mesh fabric with less guide bars[D]. Wuhan: Wuhan Textile University, 2018:27-37.
[7] 钟君. 经编贾卡提花鞋面织物的设计与仿真[D]. 无锡: 江南大学, 2017:26-33.
ZHONG Jun. The design and simulation of warp-knitted jacquard shoe-upper fabric[D]. Wuxi: Jiangnan University, 2017:26-33.
[8] SABRINA B, NOUR E D. Mutli-resolution cloth simulation based on particle position correction[J]. International Journal of Computer Applications, 2016, 143(6): 29-36.
[9] 吴越. 经编多贾卡提花技术及其产品工艺研究[D]. 武汉: 武汉纺织大学, 2021:45-47.
WU Yue. Research on warp knitting jacquard technology and its product process[D]. Wuhan: Wuhan Textile University, 2021:45-47.
[10] 邓文, 王田田, 邓中民. 弹簧质点模型用于经编贾卡织物仿真[J]. 武汉纺织大学学报, 2011, 24(3):74-78.
DENG Wen, WANG Tiantian, DENG Zhongmin. Mass-spring models used in jacquard fabric[J]. Journal of Wuhan Textile University, 2011, 24(3):74-78.
[11] 刘凯, 吴寒, 张纯, 等. 用于正交各向异性织物仿真的弹簧质点模型[J]. 力学季刊, 2016, 37(3):502-512.
LIU Kai, WU Han, ZHANG Chun, et al. New mass-spring model for orthotropic cloth simulation[J]. Chinese Quarterly of Mechanics, 2016, 37(3):502-512.
doi: 10.15959/j.cnki.0254-0053.2016.03.010
[12] 胡新荣, 汪卓, 刘军平, 等. 基于自适应网格划分的针织物仿真[J]. 现代纺织技术, 2022, 30(5):21-30.
HU Xinrong, WANG Zhuo, LIU Junping, et al. Knitted fabric simulation based on adaptive remeshing[J]. Advanced Textile Technology, 2022, 30(5):21-30.
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