Performance Simulation of Load-based Paired-cell Overlapping Loops of Cards with Authorization

doi:10.3969/j.issn.1007-7375.2021.04.012

Abstract

Abstract: Load-based paired-cell overlapping loops of cards with authorization (LB-POLCA ) is a new type of material control system for non-repetitive manufacturing workshops, which is used to realize the load balance of processing resources in the workshop and the effective flow of materials in production. The existing research has verified the effectiveness of LB-POLCA, but most of them ignore the assembly relevance between materials, that is, the assembly process can only be started after the required materials have been completed. At this time, the core of control system is to achieve the processing coordination of related materials. In view of this, for a class of general flow shop with assembly constraints, the appropriate operation mechanism of LB-POLCA system and the key control parameters such as the card allocation rules, approaches to load accounting and dispatching rule are first given; then, a generalized simulation model is established based on the platform of simulation software eM-Plant, and a large number of experiments conducted to reveal the changes of system performance under different assembly relevance level and different combinations of system control parameters.

Key words: load-based paired-cell overlapping loops of cards with authorization (LB-POLCA), assembly products, progress coordination, workload control, simulation technology

CLC Number:

F406

LIAO Zhihua, LIU Jianjun, CHEN Qingxin, MAO Ning. Performance Simulation of Load-based Paired-cell Overlapping Loops of Cards with Authorization[J]. Industrial Engineering Journal, 2021, 24(4): 100-111.

References

[1] GERAGHTY J, HEAVEY C. A review and comparison of hybrid and pull-type production control strategies[J]. OR Spectrum, 2005, 27(2-3): 435-457
[2] FRAMINAN J M, GONZALEZ P L, RUIZ-USANO R. The CONWIP production control system: review and research issues[J]. Production Planning & Control, 2003, 14(3): 255-265
[3] 黄敏, 王兴伟, 汪定伟. 多阶段CONWIP系统流通卡分布的确定方法[J]. 控制与决策, 2000, 15(6): 686-689
HUANG Min, WANG Xingwei, WANG Dingwei. Card number distribution determination method for multi-stage CONWIP systems[J]. Control and Decision, 2000, 15(6): 686-689
[4] HUANG G, CHEN J, WANG X, et al. An approach of designing CONWIP loop for assembly system in one-of-a-kind production environment[J]. International Journal of Computer Integrated Manufacturing, 2016, 29(7): 1-16
[5] SURI R. Quick response manufacturing: a companywide approach to reducing lead times[M]. Portland: Productivity Press, 1998.
[6] FARNOUSH A, WIKTORSSON M. POLCA and CONWIP performance in a divergent production line: an automotive case study[J]. Journal of Management Control, 2013, 24(2): 159-186
[7] BRAGLIA M, CASTELLANO D, FROSOLINI M. Optimization of POLCA-controlled production systems with a simulation-driven genetic algorithm[J]. The International Journal of Advanced Manufacturing Technology, 2014, 70(1-4): 385-395
[8] 栾世超, 贾国柱, 司晓玲. 快速反应制造对偶单元授权卡片交叠循环模型[J]. 工业工程, 2013, 16(4): 85-91
LUAN Shichao, JIA Guozhu, SI Xiaoling. A modeling approach to POLCA for quick response manufacturing[J]. Industrial Engineering, 2013, 16(4): 85-91
[9] BRAGLIA M, CASTELLANO D, FROSOLINI M. A study on the importance of selection rules within unbalanced MTO POLCA-controlled production systems[J]. International Journal of Industrial and Systems Engineering, 2015, 20(4): 457-468
[10] RIEZEBOS J. Design of POLCA material control systems[J]. International Journal of Production Research, 2010, 48(5): 1455-1477
[11] 周水银, 王玮. 考虑临时订单的作业车间订单控制系统研究[J]. 工业工程与管理, 2010, 15(5): 76-81
ZHOU Shuiyin, WANG Wei. Research on order control system in Job-shop with rush orders[J]. Industrial Engineering and Management, 2010, 15(5): 76-81
[12] KRISHNAMURTHY A, SURI R. Planning and implementing POLCA: a card-based control system for high variety or custom engineered products[J]. Production Planning & Control, 2009, 20(7): 596-610
[13] FERNANDES N O, DO CARMO-SILVA S. Generic POLCA—a production and materials flow control mechanism for quick response manufacturing[J]. International Journal of Production Economics, 2006, 104(1): 74-84
[14] VANDAELE N, VAN NIEUWENHUYSE I, CLAERHOUT D, et al. Load-based POLCA: an integrated material control system for multiproduct, multimachine job shops[J]. Manufacturing & Service Operations Management, 2008, 10(2): 181-197
[15] THÜRER M, FEMANDES N O, CARMO-SILVA S, et al. Improving performance in POLCA controlled high variety shops: an assessment by simulation[J]. Journal of Manufacturing Systems, 2017, 44: 143-153
[16] BECHTE W. Theory and practice of load-oriented manufacturing control[J]. The International Journal of Production Research, 1988, 26(3): 375-395
[17] BERTRAND J W M, WORTMANN J C. Production control and information systems for component-manufacturing shops[M]. Amsterdam: Elsevier, 1981.
[18] OOSTERMAN B, LAND M, GAALMAN G. The influence of shop characteristics on workload control[J]. International Journal of Production Economics, 2000, 68(1): 107-119
[19] ENNS S T. An integrated system for controlling shop loading and work flow[J]. International Journal of Production Research, 1995, 33(10): 2801-2820
[20] FERNANDES N O, THÜRER M, STEVENSON M, et al. Load-based POLCA: an assessment of the load accounting approach[C/OL]. (2017-03-29). https://link.springer.com/chapter/10.1007%2F978-3-319-56538-5_40.
[21] THÜRER M, STEVENSON M, PROTZMAN C W. COBACABANA (control of balance by card based navigation): an alternative to kanban in the pure flow shop?[J]. International Journal of Production Economics, 2015, 166: 143-151