基于服装吊挂系统协同的车间混合流水线布局优化

doi:10.13475/j.fzxb.20221204501

纺织学报 ›› 2024, Vol. 45 ›› Issue (03): 169-176.doi: 10.13475/j.fzxb.20221204501

基于服装吊挂系统协同的车间混合流水线布局优化

童锡宇¹, 郑路², 杨金昌², 胡觉亮³, 韩曙光³()

1.浙江理工大学经济管理学院, 浙江杭州 310018
2.达利(中国)有限公司, 浙江杭州 311200
3.浙江理工大学理学院, 浙江杭州 310018

收稿日期:2023-01-19 修回日期:2023-10-10 出版日期:2024-03-15 发布日期:2024-04-15
通讯作者: 韩曙光
作者简介:童锡宇(1997—),男,硕士。主要研究方向为物流系统建模与优化。
基金资助:
国家自然科学基金项目(12071436)

Optimization of mixed production line layout for collaborative clothing suspension system

TONG Xiyu¹, ZHENG Lu², YANG Jinchang², HU Jueliang³, HAN Shuguang³()

1. School of Economics and Management, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
2. High Fashion (China) Co., Ltd., Hangzhou, Zhejiang 311200, China
3. School of Science, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China

Received:2023-01-19 Revised:2023-10-10 Published:2024-03-15 Online:2024-04-15
Contact: HAN Shuguang

摘要/Abstract

摘要：

为适应服装生产企业转型,针对服装制造车间混合流水线生产存在吊挂系统的物料传输路径耗时耗能、各工作台作业负荷时间不均、加工周期长及加工设备资源浪费等问题,根据服装生产工艺流程、工作台资源和加工设备数量受限、理性生产节拍等约束条件,建立物料传输总距离极小化及平滑系数极小化的双目标数学规划模型;设计非支配遗传(NSGA-Ⅱ)算法,对多款式服装生产具体实例进行编程仿真求解,并与多目标粒子群(MOPSO)算法进行优化对比。研究结果表明:NSGA-Ⅱ算法拥有更好的寻优能力,实验得到最优总距离为82 m、最优平滑系数为21.977、最优编制效率为90.2%、最少只需要打开10个工作台和使用18台加工设备,企业可根据不同目标的需要择优选出相应的布局编排方案。

关键词: 双目标布局优化, 服装吊挂, 服装车间, 混合流水线, NSGA-Ⅱ算法, 节能增效

Abstract:

Objective In order to adapt to the transformation and upgrading of clothing manufacturing enterprises, and quickly respond to market demand, most clothing manufacturing enterprises had introduced many intelligent production equipment such as clothing suspension systems to replace conventional backward bundled assembly line production. In order to apply new production equipment in the actual production, some problems were identified for the mixed assembly line in the clothing manufacturing workshop such as unreasonable suspension system material transmission path, time consumption and energy consumption, uneven workload time of each workbench, long processing cycle, and waste of processing equipment resources. The optimization of workshop assembly line layout considering the collaboration of clothing suspension systems was carried out aiming to effectively solve the above-mentioned problems of clothing production lines.

Method Because of the involvement of multiple disciplines such as clothing, logistics, and operations research, as well as the complexity of the production process, it was necessary to conduct on-site investigations, observe the production line process of clothing production, analyze the production process diagram of clothing production enterprises and the raw data in MES systems. Based on the constraints of the clothing production process, limited workbench resources and processing equipment quantity, and rational production rhythm, a dual objective mathematical programming model was established to minimize material transmission distance and smoothness coefficient. The non-dominant sorting genetic(NSGA-II) algorithm was designed and applied to solve the production lines of multi-style clothing.

Results From the optimization objective iteration curve generated using NSGA-II algorithm, it was found that the algorithm had a good optimization effect on the green mixed clothing assembly line, and the total distance and smoothness coefficient of material transmission had converged to a stable level in over 300 generations. Based on the production data examples, the Pareto optimal solution set was obtained. Because of the two objectives of the total distance of material transmission and the smoothing coefficient, a non-dominated solution with the best total distance and the non-dominated solution with the best smoothing coefficient were extracted from the solution set for analysis. When 12 workstations are operational and 21 processing devices are utilized, the average idle time per workstation amount to 42.2 s, resulting in an optimal total distance of material transport measuring 82 m. However, the smoothness coefficient stands at 55.86 and the compilation efficiency is merely 75.2%. Conversely, when operating with only 10 workstations and utilizing 18 processing devices, each workstation experiences an average idle time of approximately 16.6 s while achieving a smoother coefficient of 24.104. This leads to an improved compilation efficiency of up to 90.2%, albeit at the expense of increased material transport distance reaching a value of approximately 100 m. The total distance of material transmission in the minimum production cycle was 82 m, with a smoothness coefficient of 55.86, and 12 workstations were needed with 21 processing equipment. The average idle time of each workbench was 42.2 s, and the staffing efficiency was 75.2%. The total transmission distance of the material was 100 m, and the smoothness coefficient was 21.977. It was necessary to operate 10 workstations with 18 processing equipment. The idle time of each workbench was 16.6 s, and the staffing efficiency was 90.2%. The Gantt chart of the work tasks for each workstation in the mixed clothing assembly line were generated according to the scheme. In order to verify the effectiveness of the model, NSGA-II algorithm and multi-objective particle swarm optimization(MOPSO) algorithm were compared, and the result showed that NSGA-II algorithm produced closer simulation results.

Conclusion Faced with the transformation of the clothing industry structure, the design of the entire production line plays a crucial role in intelligent clothing manufacturing. The optimization of workshop assembly line layout considering the synergistic effect of clothing suspension system helps promote the transformation and it is useful for upgrading of China's clothing and textile industry from labor-intensive to less labor intensive or unmanned production. This study provides some theoretical reference for the promotion of green and intelligent manufacturing in the clothing enterprises.

Key words: two-objective layout optimization, clothing hanging, clothing workshop, mixing assembly line, NSGA -Ⅱ algorithm, energy saving and efficiency improvement

中图分类号:

TS941

童锡宇, 郑路, 杨金昌, 胡觉亮, 韩曙光. 基于服装吊挂系统协同的车间混合流水线布局优化[J]. 纺织学报, 2024, 45(03): 169-176.

TONG Xiyu, ZHENG Lu, YANG Jinchang, HU Jueliang, HAN Shuguang. Optimization of mixed production line layout for collaborative clothing suspension system[J]. Journal of Textile Research, 2024, 45(03): 169-176.

图/表 9

表1

符号说明"

参数	符号含义
N	工序总数, $i = 1,2, …, N$
K	工作台总数, $k = 1,2, …, K$
E	加工设备种类总数, $e = 1,2, …, E$
R	服装种类总数, $r = 1,2, …, R$
C	平均生产节拍
Y	目标日产量
Q	目标日加工时间
$α$	有效加工系数, $α ∈ (0,1)$
$β$	在制品传递时间系数, $β ∈ (0,1)$
Z	生产传输总距离
M	能使用的最大加工设备总数
$S I$	平滑系数
$t i r$	款式r服装在工序i的加工时间
$d k l$	工作台k和工作台l之间的距离
$T k$	工作台k上的加工时间
$y i j r$	款式r服装的工艺工序从工序i到工序j则为1,否则为0
$x i r k$	款式r服装的第i道工艺工序在工作台k上加工时则为1,否则为0
$z k$	使用第k个工作台则为1,否则为0
$B e k$	在工作台k上使用e种加工设施则为1,否则为0

表1

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图3

图4

表2

表3

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表4

参考文献 16

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工作台	工艺工序编号	资源设备	空闲时间/s
1	1、2、6、19、29、30	熨烫机、缝纫机	6	82	55.86
2	19、22、25、27、31、32、34	熨烫机、缝纫机	13
3	3、6、7、28	拷边机、缝纫机	90
4	2、20、21、22、29、34	熨烫机、缝纫机	10
5	3、4、8	拷边机、缝纫机	81
6	9、23、24、25、26、35	缝纫机、钉扣机	52
7	5、7	熨烫机、拷边机	123
8	10、11、12	缝纫机	4
9	8、9、10、11、14、15	拷边机、缝纫机	19
10	13、14、15、16	缝纫机	28
11	16、17、18	缝纫机、钉扣机	28
12	17、18	钉扣机	52

工作台	工艺工序编号	资源设备	空闲时间/s
1	1、2、3、19、22	熨烫机、拷边机	28	110	21.977
2	4、5、25、27、29、33、34	熨烫机、缝纫机	1
3	2、6、19、20、21、22、29	熨烫机、缝纫机	31
4	3、6、7、8、28	拷边机、缝纫机	11
5	23、24、25、30、31、32	钉扣机、缝纫机	1
6	7、8、9、10、11、34、35、36	拷边机、缝纫机	2
7	9、10、11、26	缝纫机、钉扣机	39
8	12、13、14、15	缝纫机	13
9	14、15、16	缝纫机	28
10	16、17、18	缝纫机、钉扣机	12

算法类型	最优总距离/m	最优平滑系数	最优编制效率/%	平均运行时间/s
NSGA-Ⅱ	82	21.977	90.2	209.333
MOPSO	202	38.523	82.0	151.295

基于服装吊挂系统协同的车间混合流水线布局优化

Optimization of mixed production line layout for collaborative clothing suspension system

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