毛衫绞花织物的三维仿真与实现

doi:10.13475/j.fzxb.20220700901

摘要/Abstract

摘要：

为降低毛衫绞花织物的设计与研发成本,实现绞花织物的快速设计与仿真,在深入研究横编绞花织物组织结构的基础上,基于绞花组织的编织原理与编织方法,将形成绞花织物的各线圈结构与编织动作转换成具有颜色信息和编织信息的色码,提出了花型意匠图数学模型和组织结构图数学模型,并探讨这2个模型之间的展开关系得到织物的工艺编织图矩阵。再结合绞花织物各线圈结构特点,建立理想状态下的线圈结构几何模型,确定线圈各型值点的位置,并对不同移针方向、移针行数和移针线圈数的移圈线圈进行分析,得出移圈线圈型值点变化规律。借助C#编程语言实现横编绞花组织的三维结构仿真,对绞花组织的设计与开发具有理论和实际的指导意义。

关键词: 绞花织物, 花型设计, 线圈结构模型, 三维仿真, 毛衫

Abstract:

Objective The loop-transfer cable stitch is the main structure that forms the surface texture effect of the flat knitted sweater product, and its application is very extensive. Achieving the rapid design and three-dimensional structure simulation of the cable fabrics to facilitate quick prediction of the fabric effect of the cabled fabrics is of great significance to reduce the design and development cost of cable-knitted sweater fabrics.
Method Based on the knitting principle and knitting method of the cable stitch, the knitting action was parameterized, and the mathematical models for the pattern and for the knitting structure diagram were proposed. Combined with the structural characteristics of each loop of the cable fabrics, an ideal loop model was established, and the trajectory of the value point for the transfer loop was analyzed. Finally, C# and WebGL were used to program the three-dimensional structure simulation of the flat knitted cable fabric.
Results The pattern matrix model and the minimum structure unit matrix were established by the minimum pattern cycle of the cable fabric, and the block matrix F_A of the expanded pattern was established according to the color value of the pattern matrix. Then the relationship between the block matrix F_A and the structure diagram matrix in the pattern diagram matrix was obtained in combination with Equation 4, and the process knitting diagram matrix model of cable fabric was obtained by replacing the matrix elements, see Equation 5. The loop of transferred was based on the normal flat needle loop knitting, and the needle was transferred through the needle bed traversing to transfer the needle arc to form the loop tilt effect. A loop geometry model based on the normal flat needle loop geometry model showed that transfers one needle to the right, based on the establishment of the loop type value point and the loop root junction point (Fig. 4). The coordinates of the 4 type value points near the root junction point of the transfer loop remain basically unchanged, and the coordinates of the 4 type value points near the needle arc were related to the ratio between the number of needles transferred by the loop and the loop distance (g_w) and loop height (g_h). For the transfer loop with different needle transfer directions, needle transfer rows and needle transfer needle numbers showed the change law of the type value point of the transfer loop (Fig. 5). It can be seen that the coordinate values of the four type value points near the root junction point of the transfer loop are determined by the loop root junction point O₀ before the transfer loop, and the coordinate values of the four type value points near the needle arc of the transfer loop are determined by the loop root junction point O₁ at the next position of the transfer loop. Such change was reflected in Equations 7 and 8. Based on the above theory and model, the three-dimensional structure simulation diagram of the cable fabric was finally obtained, and the loop structure of the cable fabric in several weaving states was clearly presented (Fig. 6).
Conclusion Through the conversion between the pattern model and the knitting structure diagram model of the cable fabric, and based on the establishment of the fabric loop geometry model under the ideal state, the rapid design and three-dimensional simulation of the sweater cable fabric can be realized. Although the three-dimensional simulation of the fabric based on the geometric models can clearly represent the string relationship of the fabric, the realization of the cable fabric simulation requires the next step of research on the physical and mechanical model.

Key words: cable fabric, pattern design, loop structure model, three-dimensional simulation, sweater

中图分类号:

TS186.2

赵俊杰, 蒋高明, 程碧莲, 李炳贤. 毛衫绞花织物的三维仿真与实现[J]. 纺织学报, 2023, 44(12): 81-87.

ZHAO Junjie, JIANG Gaoming, CHENG Bilian, LI Bingxian. Three-dimensional simulation and realization of sweater cabled fabrics[J]. Journal of Textile Research, 2023, 44(12): 81-87.

图/表 6

图1

图2

图3

图4

图5

图6

参考文献 10

[1]	熊秋元. 横机编织绞花复合纹样的创新设计与工艺[J]. 毛纺科技, 2020, 48(1):38-42.
	XIONG Qiuyuan. Innovative design and manufacture of cable stitch composite pattern with flat knitting machine[J]. Wool Textile Journal, 2020, 48(1): 38-42.
[2]	王赪. 四针床电脑横机上毛衫绞花组织设计与三维模拟[J]. 毛纺科技, 2018, 46(6):19-21.
	WANG Zhen. Design and 3D simulation of sweater cable stitch on four needle bed computerized flat knitting machine[J]. Wool Textile Journal, 2018, 46(6):19-21.
[3]	陈钰珊, 蒋高明, 李炳贤. 纬编绕经织物设计与三维仿真[J]. 纺织学报, 2022, 43(12):62-68.
	CHEN Yushan, JIANG Gaoming, LI Bingxian. Design and 3-D simulation of weft knitted warp fabric[J]. Journal of Textile Research, 2022, 43(12):62-68.
[4]	梁佳璐, 丛洪莲, 张爱军. 纬编两面提花针织物的工艺设计模型[J]. 纺织学报, 2020, 41(1):69-74.
	LIANG Jialu, CONG Honglian, ZHANG Aijun. Technical design model of weft-knitted two-side jacquard fabric[J]. Journal of Textile Research, 2020, 41(1):69-74.
[5]	郑培晓, 蒋高明. 基于WebGL的纬编提花织物三维仿真[J]. 纺织学报, 2021, 42(5):59-65.
	ZHENG Peixiao, JIANG Gaoming. Three-dimensional simulation of weft-knitted jacquard fabric based on WebGL[J]. Journal of Textile Research, 2021, 42(5): 59-65.
[6]	张永超, 丛洪莲, 张爱军, 等. 纬编仿蕾丝织物的设计与仿真[J]. 纺织学报, 2015, 36(7):152-156.
	ZHANG Yongchao, CONG Honglian, ZHANG Aijun, et al. Design and simulation of weft knitted imitation lace fabric[J]. Journal of Textile Research, 2015, 36(7):152-156.
[7]	蒋高明, 冯勋伟. 多梳拉舍尔花边的计算机仿真[J]. 纺织学报, 2007, 28(1):40-43.
	JIANG Gaoming, FENG Xunwei. Computer simulation for multibar raschel lace[J]. Journal of Textile Research, 2007, 28(1):40-43.
[8]	张中启. 绞花组织在男式毛衫中的应用[J]. 针织工业, 2016(4):59-62.
	ZHANG Zhongqi. Application of cable stitch in men's sweaters[J]. Knitting Industries, 2016(4):59-62.
[9]	邓逸飞, 邓中民, 柯薇. 应用线圈模型的羊毛衫组织搭配与变形模拟[J]. 纺织学报, 2018, 39(4):151-157.
	DENG Yifei, DENG Zhongmin, KE Wei. Stitch design and deformation simulation of cardigan based on loop model[J]. Journal of Textile Research, 2018, 39(4):151-157.
[10]	JIANG Gaoming, LU Zhiwen, CONG Honglian, et al. Flat knitting loop deformation simulation based on interlacing point model[J]. Autex Research Journal, 2017, 17(4):361-369.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

[1]	杨美玲, 蒋高明, 王婷, 李炳贤. 基于弹簧-质点模型的单贾卡经编鞋材三维仿真[J]. 纺织学报, 2023, 44(11): 113-119.
[2]	李玉贤, 巫晓雯, 吴光军, 丛洪莲. 针织毛衫版片的参数化设计模型与实现[J]. 纺织学报, 2023, 44(09): 168-174.
[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.
[4]	郑培晓, 蒋高明, 丛洪莲, 李炳贤. 多色调线横条纹织物的设计与三维仿真[J]. 纺织学报, 2023, 44(06): 85-90.
[5]	赖安琪, 蒋高明, 李炳贤. 全成形毛衫花式结构三维仿真[J]. 纺织学报, 2023, 44(02): 103-110.
[6]	陈钰珊, 蒋高明, 李炳贤. 纬编绕经织物设计与三维仿真[J]. 纺织学报, 2022, 43(12): 62-68.
[7]	赵馨, 王彩霞, 周小皮, 丁雪梅. 基于岭回归方法的羊毛衫洗后特征感性评价[J]. 纺织学报, 2022, 43(07): 155-161.
[8]	金贵阳, 陈罡, 孙平范. 基于OPC统一架构的毛衫生产车间信息模型及其应用[J]. 纺织学报, 2022, 43(03): 185-192.
[9]	陈曦, 缪旭红, 牛丽, 韩晓雪, 蒋高明. 全成形平肩袖毛衫袖身连接工艺分段设计[J]. 纺织学报, 2020, 41(09): 76-80.
[10]	代振兴, 陈广锋, 陈革. 基于Rhino-Python的多圈高簇绒地毯三维仿真[J]. 纺织学报, 2020, 41(06): 69-75.
[11]	梁佳璐, 丛洪莲, 张爱军. 纬编两面提花针织物的工艺设计模型[J]. 纺织学报, 2020, 41(01): 69-74.
[12]	王盼, 吴志明. 全成形毛衫横向编织方式及其成形工艺[J]. 纺织学报, 2019, 40(10): 73-78.
[13]	李珂, 吴志明. 基于收针工艺的全成形毛衫分割线设计原理[J]. 纺织学报, 2019, 40(06): 85-90.
[14]	王盼, 吴志明. 全成形毛衫局部编织原理及其应用[J]. 纺织学报, 2019, 40(05): 41-46.
[15]	路丽莎, 蒋高明, 罗璇. 全成形毛衫腋下拼角编织工艺及性能[J]. 纺织学报, 2019, 40(02): 69-75.