TY - JOUR
T1 - An energy-efficient multi-objective integrated process planning and scheduling for a flexible job-shop-type remanufacturing system
AU - Zhang, Wenkang
AU - Zheng, Yufan
AU - Ahmad, Rafiq
N1 - Publisher Copyright:
© 2023 Elsevier Ltd
PY - 2023/4
Y1 - 2023/4
N2 - This study considers an energy-efficient multi-objective integrated process planning and scheduling (IPPS) problem for the remanufacturing system (RMS) integrating parallel disassembly, flexible job-shop-type reprocessing, and parallel reassembly shops with the goal of realizing the minimization of both energy cost and completion time. The multi-objective mixed-integer programming model is first constructed with consideration of operation, sequence, and process flexibilities in the RMS for identifying this scheduling issue mathematically. An improved spider monkey optimization algorithm (ISMO) with a global criterion multi-objective method is developed to address the proposed problem. By embedding dynamic adaptive inertia weight and various local neighborhood searching strategies in ISMO, its global and local search capabilities are improved significantly. A set of simulation experiments are systematically designed and conducted for evaluating ISMO's performance. Finally, a case study from the real-world remanufacturing scenario is adopted to assess ISMO's ability to handle the realistic remanufacturing IPPS problem. Simulation results demonstrate ISMO's superiority compared to other baseline algorithms when tackling the energy-aware IPPS problem regarding solution accuracy, computing speed, solution stability, and convergence behavior. Meanwhile, the case study results validate ISMO's supremacy in solving the real-world remanufacturing IPPS problem with relatively lower energy usage and time cost.
AB - This study considers an energy-efficient multi-objective integrated process planning and scheduling (IPPS) problem for the remanufacturing system (RMS) integrating parallel disassembly, flexible job-shop-type reprocessing, and parallel reassembly shops with the goal of realizing the minimization of both energy cost and completion time. The multi-objective mixed-integer programming model is first constructed with consideration of operation, sequence, and process flexibilities in the RMS for identifying this scheduling issue mathematically. An improved spider monkey optimization algorithm (ISMO) with a global criterion multi-objective method is developed to address the proposed problem. By embedding dynamic adaptive inertia weight and various local neighborhood searching strategies in ISMO, its global and local search capabilities are improved significantly. A set of simulation experiments are systematically designed and conducted for evaluating ISMO's performance. Finally, a case study from the real-world remanufacturing scenario is adopted to assess ISMO's ability to handle the realistic remanufacturing IPPS problem. Simulation results demonstrate ISMO's superiority compared to other baseline algorithms when tackling the energy-aware IPPS problem regarding solution accuracy, computing speed, solution stability, and convergence behavior. Meanwhile, the case study results validate ISMO's supremacy in solving the real-world remanufacturing IPPS problem with relatively lower energy usage and time cost.
KW - Energy consumption
KW - Improved spider monkey optimization algorithm
KW - Integrated process planning and scheduling
KW - Job-shop-type reprocessing shop
KW - Remanufacturing system
UR - http://www.scopus.com/inward/record.url?scp=85159628848&partnerID=8YFLogxK
U2 - 10.1016/j.aei.2023.102010
DO - 10.1016/j.aei.2023.102010
M3 - Article
AN - SCOPUS:85159628848
SN - 1474-0346
VL - 56
JO - Advanced Engineering Informatics
JF - Advanced Engineering Informatics
M1 - 102010
ER -