经编间隔鞋材设计与三维仿真

doi:10.13475/j.fzxb.20220700601

摘要/Abstract

摘要：

为实现经编间隔鞋材的高效设计与简易成形,研究了鞋材织物的结构与成形原理,建立间隔鞋用织物结构的垫纱运动、穿经运动矩阵模型。根据不同组织线圈结构控制点的数量与位置,建立间隔织物面层线圈与间隔丝线圈结构的基本模型。在归纳分析这类织物结构特征的基础上,对织物编织时线圈所受张力进行力学分析并求取相应偏移量。介绍了几款具有代表性网眼结构与花纹效应间隔鞋材的结构特征与工艺设计方法,并探讨重经组织结构应用。最终借助JavaScript和C#计算机程序设计语言,对鞋材织物结构实现快速仿真,丰富网眼间隔鞋材的种类。实验证明间隔鞋材中线圈单元存在三维空间内的受力影响,采用重经组织提高了间隔鞋材中网眼的仿真效果与速度,对于重经组织的分类有利于对间隔鞋材设计仿真,可为3层结构经编鞋材设计提供新思路。

关键词: 经编鞋材, 间隔织物, 线圈模型, 线圈受力, 三维仿真

Abstract:

Objective In order to realize the efficient design and simple formation of warp knitted spacer shoe fabrics, the structure and forming principle of shoe fabrics are studied, the application benefit of spacer shoe fabrics is explored, and a design method of spacer shoe material is proposed. With the help of JavaScript and C # computer programming language, fast 3-D simulation of several types of spacer shoe fabrics is carried out with different mesh structures, enriching the choices of the mesh spacer shoe materials.

Method The functional structure of different areas of the shoe upper was divided, and the matrix model of process design was established, including the mathematical model of yarn padding number and threading cycle. 3-D loop models of 8-point unit loop, 2-point weft lining, 16-point double warp knit structure were constructed. The classification table of the retransmitted structures was listed by using the transverse displacement difference between the needle and the back of the needle. The stress analysis of the rerun loop and the spacer loop was carried out.

Results The vamp divided into different mesh areas according to functional requirements. Large mesh is used at the toe to improve breathability, small mesh is used at the toe cap and heel area, and tight structure was used at the hem to improve wear resistance (Fig. 1). The construction principle of the 3-D structure of the 4-comb spacer vamp fabric was analyzed. The re-woven weave can be applied to the top and bottom woven surfaces, and the mesh and pattern are only formed on the top or bottom (Fig. 2). The mathematical matrix was used to visually represent the padding number of the spacer shoe fabric and the warp cycle. The knitting action was expressed according to formula of the front and back needle transverse movement difference. Based on the loop control points, the basic 8-point single-needle loop, 16-point double-needle double-needle loop, and 2-point weft lining 3-D models were established, focusing on the hierarchical relationship between the double-needle loop and the two loop on the horizontal single-needle, and the classification table of the double-needle tissue was established according to the transverse movement of the needle back before the needle (Fig. 4, Tab. 1, Fig. 5). According to the formation mechanism of mesh in the spacer shoe material, stress analysis was carried out on both longitudinal lines, and the stress solution of the spacer wire loop in the 3-D space is also carried out (Fig. 6 and Fig. 7). According to different functional requirements, three types of spacer upper fabric processes with different mesh structures were designed, including raw material, knit structure, warp cycle, warp let-off and other parameters. 3-D simulation of three types of spacer mesh upper fabrics was set up using C# and JavaScript programming languages. The comparison between the physical image and the simulation image was shown (Fig. 8, Fig. 9 and Fig. 10).

Conclusion On the basis of summing up and analyzing the structural characteristics of the interval mesh shoe material, using the practical significance of the mesh structure in the shoe material fabric, the relevant technological mathematical model and geometric model are constructed, the mechanical analysis of the tension on the loop during the fabric knitting and the calculation of the corresponding offset are carried out, and the application of the warp weave structure is discussed, which provides a new idea for the design of the three-layer structure warp knitted shoe material. It provides reliable technical support for three-dimensional mesh simulation of Jacquard shoe fabric.

Key words: warp knitted shoes fabric, spacer fabric, loop model, loop force, 3-D simulation

中图分类号:

TS186.3

杨美玲, 蒋高明, 王婷, 李炳贤. 经编间隔鞋材设计与三维仿真[J]. 纺织学报, 2023, 44(08): 96-102.

YANG Meiling, JIANG Gaoming, WANG Ting, LI Bingxian. Design and three-dimensional simulation of warp knitted spacer fabrics for shoes[J]. Journal of Textile Research, 2023, 44(08): 96-102.

图/表 12

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参考文献 12

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编号	延展线绘制条件 r、t∈{1,2,…,j}	线圈形态
1	D(r)=2,且U(t)=0	右开口重编链
2	D(r)=2,且U(t)=2	左闭口重编链
3	D(r)=-2,且U(t)=0	左开口重编链
4	D(r)=-2,且U(t)=-2	右闭口重编链
5	D(r)=±2,且U(t)<-2或>2	变化重经

梳栉	原料	垫纱数码	穿经	送经量/ (㎜·腊克^-1)
GB1	涤纶 150 dtex (48 f)	(2-1-1-1/3-4-4-4) ×4/(3-2-2-2/4-5- 5-5) ×4/3-2-2-2/ (5-6-6-6/4-3-3-3)/ (4-5-5-5/3-2-2 -2)× 4/(3-4-4-4/2-1- 1-1)×4/(2-3-3-3/ 1-0-0-0)×4/3-4- 4-4//	二穿二空	1 739
GB2	涤纶 150 dtex (48 f)	(3-4-4-4/2-1-1-1) ×4/(4-5-5-5/3-2- 2-2)×4/4-5-5-5/ (4-3-3-3/5-6-6-6)/ (3-2-2-2/4-5-5-5) ×4/(2-1-1-1/3-4 -4-4)×4/(1-0-0-0/ 2-3-3-3) ×4/2-1- 1-1//	一空二穿一空	1 698
GB3	涤纶单丝 33 dtex	1-2-2-3/2-1-1-0//	满穿	7 900
GB4	涤纶单丝 33 dtex	1-2-2-3/2-1-1-0//	满穿	7 900
GB5	涤纶 76 dtex (24 f)	0-0-2-4/4-4-2-0//	满穿	4 100

梳栉	原料	垫纱数码	穿经	送经量/ (㎜·腊克^-1)
GB1	涤纶 350 dtex(72 f)	(1-0-0-0/1-2- 2-2)×3/1-2-2-2/ (2-3-3-3/2-1-1- 1)×3/2-1-1-1//	一穿一空	1 740
GB2	涤纶 350 dtex(72 f)	(2-3-3-3/2- 1-1-1)×3/2-1-1- 1/(1-0-0-0/1-2- 2-2)×3/1-2-2-2//	一穿一空	1 740
GB3	涤纶单丝 283 dtex	(1-0-1-2)×6/1- 2-2-1/(2-3-2-1) ×6/2-1-1-2//	一穿一空	6 500
GB4	涤纶单丝 283 dtex	(2-3-2-1)×6/ 2-1-1-2/(1-0-1- 2)×6 /1-2-2-1//	一穿一空	6 500
GB5	涤纶 350 dtex(72 f)	(1-0-0-0/1-2-2-2) ×3/1-2-2-2/ (2-3-3-3/2-1- 1-1)×3/2-1-1-1//	一穿一空	1 740
GB6	涤纶 350 dtex(72 f)	(2-3-3-3/2-1- 1-1)×3/2-1-1-1/ (1-0-0-0/1-2-2- 2)×3/1-2-2-2//	一穿一空	1 740

梳栉	原料	垫纱数码	穿经	送经量/ (㎜·腊克^-1)
GB1	涤纶 300 dtex(96 f)	(4-3-3-3/4-5- 5-5)×2/(1-0-0-0/ 1-2-2-2)×2//	三穿五空	1 960
GB2	涤纶 300 dtex(96 f)	(1-2-2-2/1-0-0-0)× 2/(4-5-5-5/4-3- 3-3)×2//	三穿五空	1 960
GB3	涤纶 200 dtex(48 f)	1-0-0-0/ 2-3-3-3//	一穿一空	2 350
GB4	涤纶 200 dtex(48 f)	2-3-3-3/ 1-0-0-0//	一穿一空	2 350
GB5	涤纶单丝 30 dtex	1-0-0-1//	满穿	7 800
GB6	涤纶 140 dtex(36 f)	2-2-1-0/ 0-0-1-2//	满穿	1 800
GB7	涤纶 140 dtex(36 f)	3-3-1-0/ 0-0-2-3//	满穿	2 220

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