Co-optimization of Low-carbon Production and Routing for Perishable Goods Considering Supply Disruptions in the Physical Internet

doi:10.3969/j.issn.1007-7375.240206

Abstract

Abstract: To address the problem of uncertainty in facility capacity and transportation distances due to unexpected disruptions in supply networks of perishable goods, this study explores the co-optimization of low-carbon production and routing for perishables in the context of the globally open and shared physical internet (PI) environment. As an innovative logistics system characterized by connections, sharing, and adaptability, PI has great potential to enhance the resilience of perishables supply networks and reduce carbon footprints. A scenario-based two-stage stochastic programming model is developed based on the unique characteristics of perishables and the features of PI. To solve the model, a hybrid solution method integrating scenario generation and reduction with improved Benders decomposition is designed. Finally, a case study is carried out in the context of Liaoning Supply and Marketing Anbang Haider Food Supply Network to verify the feasibility of the model and the effectiveness of the algorithm. Sensitivity analysis results show that PI has significant advantages in reducing carbon footprints and enhancing supply chain resilience. Additionally, this study comprehensively analyzes the impacts of carbon emission trading mechanisms, facility capacity loss, increased transportation distances, and product lifecycle effects. This study not only enriches the theoretical foundation of low-carbon production and routing co-optimization in perishables supply networks but also provides important theoretical guidance for logistics companies in coping with uncertainty and pursuing carbon neutrality goals.

Key words: physical internet, carbon reduction, co-optimization of production and routing, uncertainty, improved Benders decomposition algorithm

CLC Number:

F406
F274

ZHAO Pengyun, JI Shoufeng, LIU Hongyu, JI Yuanyuan. Co-optimization of Low-carbon Production and Routing for Perishable Goods Considering Supply Disruptions in the Physical Internet[J]. Industrial Engineering Journal, 2024, 27(4): 48-59.

References

[1] 吴瑶, 马祖军. 时变路网下带时间窗的易腐食品生产–配送问题[J]. 系统工程理论与实践，2017，37(1)：172-181.
WU Yao, MA Zujun. Perishable food production-distribution problem with time windows under time-varying road networks[J]. Systems Engineering Theory and Practice, 2017, 37(1): 172-181.
[2] 张冬梅, 施国洪, 姚冠新, 等. 碳排放约束下生鲜农产品订购与保鲜策略[J]. 工业工程与管理，2020，25(1)：144-151.
ZHANG Dongmei, SHI Guohong, YAO Guanxin, et al. Decisions of ordering and preservation for fresh agricultural products under carbon emission constraints[J]. Industrial Engineering and Management, 2020, 25(1): 144-151
[3] 冯颖, 冯仰超, 张景雄, 等. 考虑产运环节碳排放的生鲜低碳供应链运营决策[J]. 系统管理学报，2024，33(1)：1-15.
FENG Ying, FENG Yangchao, ZHANG Jingxiong, et al. Operational decision-making of fresh food low carbon supply chain considering carbon emission from production and transportation[J]. Journal of Systems Management, 2024, 33(1): 1-15.
[4] 宋丽英, 赵世超, 卞骞, 等. 低碳视角下城乡区域混合车队生鲜配送路径问题研究[J]. 交通运输系统工程与信息，2023，23(6)：250-261.
SONG Liying, ZHAO Shichao, BIAN Qian, et al. Research on the fresh food distribution path of the mixed fleet in urban and rural areas under the perspective of low carbon[J]. Transportation Systems Engineering and Information, 2023, 23(6): 250-261.
[5] 康凯, 韩杰, 普玮, 等. 生鲜农产品冷链物流低碳配送路径优化研究[J]. 计算机工程与应用，2019，55(2)：259-265.
KANG Kai, HAN Jie, PU Wei, et al. Research on optimization of low-carbon distribution path in fresh agricultural products cold chain logistics[J]. Computer Engineering and Application, 2019, 55(2): 259-265.
[6] 戚淳浩, 朱琳. 考虑满意度的团购两级混合冷链低碳路径优化[J]. 计算机工程与应用，2024，60(1)：337-347.
QI Chunhao, ZHU Lin. Low-carbon path optimization of two-stage hybrid cold chain for group purchasing considering satisfaction[J]. Computer Engineering and Applications, 2024, 60(1): 337-347.
[7] SOYSAL M, BLOEMHOF-RUWAARD J M, HAIJEMA R, et al. Modeling a green inventory routing problem for perishable products with horizontal collaboration[J]. Computers & Operations Research, 2018, 89: 168-182.
[8] SUN H, SUN S, ZHOU Y, et al. Trade-offs between economic and environmental goals of production-inventory-routing problem for multiple perishable products[J]. Computers & Industrial Engineering, 2023, 178: 109133.
[9] DIABAT A, JABBARZADEH A, KHOSROJERDI A. A perishable product supply chain network design problem with reliability and disruption considerations[J]. International Journal of Production Economics, 2019, 212: 125-138.
[10] BOTTANI E, MURINO T, SCHIAVO M, et al. Resilient food supply chain design: Modelling framework and metaheuristic solution approach[J]. Computers & Industrial Engineering, 2019, 135: 177-198.
[11] YAVARI M, ZAKER H. An integrated two-layer network model for designing a resilient green-closed loop supply chain of perishable products under disruption[J]. Journal of Cleaner Production, 2019, 230: 198-218.
[12] SHARMA M, ANTONY R, TSAGARAKIS K. Green, resilient, agile, and sustainable fresh food supply chain enablers: Evidence from India[J]. Annals of Operations Research, 2023, 18: 1-27.
[13] SARRAJ R, BALLOT E, PAN S, et al. Interconnected logistic networks and protocols: simulation-based efficiency assessment[J]. International Journal of Production Research, 2014, 52(11): 3185-3208.
[14] FAZILI M, VENKATADRI U, CYRUS P, et al. Physical Internet, conventional and hybrid logistic systems: a routing optimisation-based comparison using the Eastern Canada road network case study[J]. International Journal of Production Research, 2017, 55(9): 2703-2730.
[15] YANG Y, PAN S, BALLOT E. Mitigating supply chain disruptions through interconnected logistics services in the Physical Internet[J]. International Journal of Production Research, 2017, 55(14): 3970-3983.
[16] PENG X, JI S, THOMPSON R G, et al. Resilience planning for Physical Internet enabled hyperconnected production-inventory-distribution systems[J]. Computers & Industrial Engineering, 2021, 158: 107413.
[17] WANG X, LI D. A dynamic product quality evaluation based pricing model for perishable food supply chains[J]. Omega, 2012, 40(6): 906-917.
[18] DOLGUI A, TIWARI M K, SINJANA Y, et al. Optimising integrated inventory policy for perishable items in a multi-stage supply chain[J]. International Journal of Production Research, 2018, 56(1-2): 902-925.
[19] GHANEI S, CONTRERAS I, CORDEAU J F. A two-stage stochastic collaborative intertwined supply network design problem under multiple disruptions[J]. Transportation Research Part E: Logistics and Transportation Review, 2023, 170: 102944.