针织毛衫版片的参数化设计模型与实现

doi:10.13475/j.fzxb.20220703701

摘要/Abstract

摘要：

为提高毛衫设计的准确性和高效性,以合体毛衫版片为例,探讨了针织毛衫版片的参数化设计方法。首先基于服装基础版型绘制毛衫样板,探讨样板与人体参数之间的关系,确定各部位关键点位置。其次基于人体工学要求拟合领口曲线、袖窿曲线及袖山曲线,研究拟合过程中存在的数学关系,提出参数约束方法,并通过合体毛衫设计实例来验证样板的准确性。结果表明:针织毛衫设计过程中,可利用圆弧拟合模型约束领口曲线和袖窿曲线,利用贝塞尔曲线模型约束袖山曲线。基于部位间数学和位置关系进行针织毛衫参数化变款式设计,再结合尺寸数据快速生成上机工艺,可节省反复计算和打样时间,提升毛衫数字化设计水平。

关键词: 针织, 毛衫, 基础版片, 数字化设计方法, 参数约束, 圆弧拟合

Abstract:

Objective Parametric platemaking is widely used in the rapid construction of clothing patterns, and the rapid design process is becoming more and more mature, but the forming process of knitted sweater is complex, and the parametric platemaking methods of existing patterns are difficult to apply. Based on the principles and methods of conventional clothing pattern design, the design of the basic patterns of knit sweaters was carried out in combination with the forming process, and the parametric platemaking method in the design process was discussed for improvement of the digital design of knit sweaters.

Method The basic patterns of knit sweaters were made based on the clothing pattern design method, the relationship between the patterns and the human body parameters was discussed, and the key points of each part were determined. The fitting constraints of the neckline curve, armhole curve and sleeve mountain curve were then carried out, the mathematical relationship existing in the fitting process was discussed, and the key data in the curve fitting process were determined. The parametric design software was utilized to constrain the basic patterns and to determine the constraint data and user parameters of the fit sweater. The feasibility of the parametric design method was verified by making the finished product on the computerized flat knitting machine.

Results Based on the principle of woven garment plate making, the data of length, bust, sleeve length and sleeve width were used as the basis to construct the basic plate of knitted sweater, taking into consideration of the sweater forming process. The curve part of the sweater needed to be set flat and retracted needle segment, and the correction factor was adopted to finely adjust the local size (Fig. 1). In the process of parametric design, the sweater curve was further decomposed by arc, and in order to match the shape of the neckline and the change trend of curvature, the curve mostly adopted a three-stage retracting needle process. For the neckline and the armhole, the curves were divided into three segments, and the formula was converted after setting the key point data of each part, and the complex spline curve was converted into a multi-terminal single arc. The arc length of the front neckline curve was related to x₁, y₁ and the angle θ₁ (Fig. 4). The arc length of the front armhole curve was related to y₂, x₂ and the angle δ₁ (Fig. 6(a)), and the arc length of the rear armhole curve is related to y₃, x₃ and the angle φ₁ (Fig. 6(b)). For the sleeve top curve, the Bezier curve model was used for parametric design, generating the required curve according to the specification of the control point coordinates (Fig. 8). Using the parametric platemaking software, the geometric constraints and annotation constraints of the basic plates of sweaters were carried out, and the expressions of each constraint object were obtained according to the platemaking principle (Tab. 2), and then the user parameters were generated according to the variable parameters, and finally the complex plate change principle was converted into simple user language. An example fitted sweater using the parametric platemaking method of sweater was used, and the size specifications of the knit sweater was shown to meet the design requirements and the loop has no bad stretching state (Fig. 13).

Conclusion In the design process of knit sweater, the arc fitting model is proved useful to constrain the neckline curve and the armhole curve, and the Bezier curve model can be adopted to constrain the sleeve curve. Based on the mathematical and position relationship between parts, the parametric variant design of knitted sweaters is carried out, and then the machine process is quickly generated in combination with dimensional data. After data processing and transformation, the size specifications of each part of the knitted sweater plate meet the requirements, and it is feasible to be produced on the computerized flat knitting machine, which can reduce repeated calculation and proofing time, and improve the digital design level of sweaters.

Key words: knitting, sweater, basic pattern, digital design method, parametric constraint, arc constraint

中图分类号:

TS184.5

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.

LI Yuxian, WU Xiaowen, WU Guangjun, CONG Honglian. Parametric design modeling and implementation of patterns for knit sweaters[J]. Journal of Textile Research, 2023, 44(09): 168-174.

图/表 16

表1

图1

图2

图3

图4

图5

图6

图7

图8

图9

图10

表2

图11

图12

图13

表3

参考文献 13

[1]	叶勤文, 张皋鹏. 基于AutoCAD参数化的个性化服装纸样生成[J]. 纺织学报, 2019, 40(4):103-110.
	YE Qinwen, ZHANG Gaopeng. Generation of personalized garment pattern based on AutoCAD parameterization[J]. Journal of Textile Research, 2019, 40(4):103-110.
[2]	娄少红. 基于AutoCAD参数化功能的A型裙样板自动化生成[J]. 纺织学报, 2020, 41(1):131-138.
	LOU Shaohong. Automatic generation of A-type skirt model based on AutoCAD parametric function[J]. Journal of Textile Research, 2020, 41(1):131-138.
[3]	卢致文, 牛梅. 基于纸样的毛衫装袖工艺计算方法[J]. 毛纺科技, 2017, 45(10):12-16.
	LU Zhiwen, NIU Mei. Study on the process calculation method of sweater sleeve based on paper pattern[J]. Wool Textile Journal, 2017, 45(10):12-16.
[4]	徐艳华, 杨婧. 纸样技术在非常规造型毛针织服装编织工艺中的应用[J]. 纺织学报, 2016, 38(8):107-113.
	XU Yanhua, YANG Jing. Application of paper pattern technology in knitting process of unconventional wool knitted apparel style[J]. Journal of Textile Research, 2016, 38(8):107-113. doi: 10.1177/004051756803800115
[5]	刘艳梅. 基于实例推理的毛衫快速变型设计方法[J]. 纺织学报, 2016, 37(5):104-109,123.
	LIU Yanmei. Rapid variant design method of sweater based on case-based reasoning[J]. Journal of Textile Research, 2016, 37(5):104-109,123.
[6]	张中启. 针织毛衫圆形领数学模型的建立[J]. 纺织学报, 2014, 35(1):102-106.
	ZHANG Zhongqi. Establishment of mathematical model of round collar of knitted woolen sweaters[J]. Journal of Textile Research, 2014, 35(1):102-106.
[7]	马燕红, 张泽军, 罗琴, 等. 基于CAD纸样技术的横编针织西装设计与实现[J]. 毛纺科技, 2021, 49(7):58-62.
	MA Yanhong, ZHANG Zejun, LUO Qin, et al. Design and realization of flat knitted suit based on CAD pattern technology[J]. Wool Textile Journal, 2021, 49(7):58-62.
[8]	范友红. 基于服装结构原理的针织毛衫板型优化探讨[D]. 上海: 东华大学, 2007:34-39.
	FAN Youhong. Base on the theory of garment pattern to study the sweater optimization[D]. Shanghai: Donghua University, 2007:34-39.
[9]	周建. 女毛衫板型设计与成品规格[J]. 毛纺科技, 2008, 36(12):32-36.
	ZHOU Jian. Principle design and product specification of female woolen sweater template[J]. Wool Textile Journal, 2008, 36(12):32-36.
[10]	周建. 羊毛衫生产工艺与设计[M]. 北京: 中国纺织出版社, 2017:5-56.
	ZHOU Jian. Wool sweater production process and design[M]. Beijing: China Textile & Apparel Press, 2017:5-56.
[11]	叶勤文, 王维杰, 陈咪, 等. 基于AutoCAD以及圆弧拟合曲线的参数化服装制版[J]. 纺织学报, 2019, 47(4):103-110.
	YE Qinwen, WANG Weijie, CHEN Mi, et al. Parametric apparel pattern-making based on AutoCAD and curve fitting with arc[J]. Wool Textile Journal, 2019, 47(4):103-110.
[12]	丛洪莲, 王迪. 针织毛衫的袖型建模与工艺实现[J]. 纺织学报, 2014, 35(8):69-75.
	CONG Honglian. WANG Di. Modeling and technology realization of knitted sweater sleeve type[J]. Journal of Textile Research, 2014, 35(8):69-75.
[13]	SONG K, ZHANG W Y. Approximation of the apparel construction curves with bezier curves[J]. Melliand China, 2001(4):76-79.

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

尺寸指标		尺寸指标	成品规格/cm
衣长L	55.0	袖口E	10.0
胸围B	84.0	袖罗H	4.0
肩宽S	34.0	后领宽N	15.8
肩斜J	3.0	前领深F	7.0
腰高Y	34.0	后领深D	2.0
腰围W	68.0	夹深A	19.0
脚高R	5.0	袖尾M	7.4
袖长C	50.0	袖山高T	15.67
袖宽K	15.5

约束对象	参数名称	表达式
F₀F₁、B₀B₁	半胸宽	B/2
F₂F₃、B₂B₃	直位	(L-Y-R-1.5)/5
F₃F₅ 、B₃B₅	腰部收针行数	4(L-Y-R-1.5)/5
F₄F₅、B₄B₅	腰部收针针数	B/2-W/4
F₆F₇、B₆B₇	胸部加针针数	B/2-W/4
F₇F₈、B₇B₈	胸部加针行数	Y-A-J-4
F₁₀F₁₂、B₁₀B₁₁	夹直位	2A/3
F₁₂F₁₃、B₁₁B₁₄	肩部收针行数	J
F₁₃F₁₄、B₁₄B₁₅	肩部收针针数	0.95S/2-N/2
F₁F₁₁	前中长	L-F
B₀B₁₂	后中长	L-D
S₀S₁	总袖口宽	2K
S₂S₄	袖加针针数	K-E
S₄S₆	袖加针行数	C-T-H-2.5
S₁₀S₁₁	袖尾	B/10-1

部位名称	样板规格/cm	成品规格/cm	样板与成品误差率/%
衣长	48.0	48.45	0.94
脚高	5.0	5.07	1.40
胸围	86.0	85.28	-0.84
腰围	78.0	76.55	-1.66
前领深	13.0	13.15	1.15
后领深	2.0	2.02	1.00
后领宽	18.0	17.53	-2.61
肩宽	30.4	31.24	2.76
袖长	24.0	24.21	0.88
袖宽	16.0	15.63	-2.31
袖口	15.0	14.76	-1.60
袖罗	5.0	5.08	1.60

[1]	任国栋, 屠佳佳, 李杨, 邱子安, 史伟民. 基于轻量化网络和知识蒸馏的纱线状态检测[J]. 纺织学报, 2023, 44(09): 205-212.
[2]	丁雪婷, 王建萍, 潘婷, 姚晓凤, 袁鲁宁. 仿蜻蜓翅膀结构的冬季针织面料研发及其性能[J]. 纺织学报, 2023, 44(09): 75-83.
[3]	李露红, 赵博宇, 丛洪莲. 复合结构经编针织电容式传感器设计及其性能[J]. 纺织学报, 2023, 44(08): 88-95.
[4]	孙园园, 张琦, 张燕婷, 左露娇, 丁宁宇. 三维通孔结构三色三贾卡提花间隔鞋材的研发[J]. 纺织学报, 2023, 44(07): 110-115.
[5]	王开, 王瑾, 牛丽, 陈超余, 马丕波. 棉/不锈钢丝包芯纱针织电路制备及其导电稳定性能[J]. 纺织学报, 2023, 44(07): 64-71.
[6]	俞旭良, 丛洪莲, 孙菲, 董智佳. 仿猪笼草口缘结构功能针织物的设计与应用[J]. 纺织学报, 2023, 44(07): 72-78.
[7]	史伟民, 简强, 李建强, 汝欣, 彭来湖. 基于非线性扩散和多特征融合的提花针织物疵点检测[J]. 纺织学报, 2023, 44(07): 86-94.
[8]	徐瑞东, 刘红, 王航, 朱士凤, 曲丽君, 田明伟. 离子型水凝胶复合织物构筑及其应变传感性能[J]. 纺织学报, 2023, 44(06): 137-143.
[9]	苏旭中, 梁巧敏, 王汇锋, 张娣, 崔益怀. 棉/生物基弹性聚酯纤维混纺针织物的服用性能[J]. 纺织学报, 2023, 44(05): 119-124.
[10]	李玉贤, 丛洪莲, 吴光军. 针织立体构型产品的全成形工艺设计[J]. 纺织学报, 2023, 44(05): 132-138.
[11]	宋洁, 蔡涛, 郑福尔, 郑环达, 郑来久. 涤纶针织鞋材超临界CO₂无水染色性能[J]. 纺织学报, 2023, 44(05): 46-53.
[12]	彭来湖, 罗昌, 戴宁, 胡旭东, 牛冲. 动态恒张力氨纶输送控制研究[J]. 纺织学报, 2023, 44(04): 194-203.
[13]	尹昂, 丛洪莲. 经编单向导湿织物设计与结构优化[J]. 纺织学报, 2023, 44(04): 86-91.
[14]	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.
[15]	牛丽, 刘青, 陈超余, 蒋高明, 马丕波. 仿生鳞片针织结构自供能传感织物的制备及其性能[J]. 纺织学报, 2023, 44(02): 135-142.