A recovery model for cold chain delivery of agricultural products by considering freshness

DING Qiulei, HU Xiangpei, JIANG Yang, RUAN Junhu

Systems Engineering - Theory & Practice ›› 2021, Vol. 41 ›› Issue (3) : 667-677.

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Systems Engineering - Theory & Practice ›› 2021, Vol. 41 ›› Issue (3) : 667-677. DOI: 10.12011/SETP2019-0632

A recovery model for cold chain delivery of agricultural products by considering freshness

  • DING Qiulei1, HU Xiangpei2, JIANG Yang3, RUAN Junhu4
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Abstract

It is difficult to continue with the original plan when the disruption occurs in cold chain delivery of agricultural products. In this case, continuing with the original solution may not be optimal or practicable. First of all, by analyzing the effects of freshness and service time, a recovery model to measure the deviation for cold chain delivery of agricultural products is formed on the basis of disruption management. Then, a heuristic algorithm is demonstrated based on the strategy of next node selection, solution space reduction and combination with other heuristics. Finally, the comparison result proves that our approach is more practical than the existing rescheduling because the consumption safety is taken into consideration.

Key words

cold chain delivery / agricultural products / recovery model / freshness

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DING Qiulei , HU Xiangpei , JIANG Yang , RUAN Junhu. A recovery model for cold chain delivery of agricultural products by considering freshness. Systems Engineering - Theory & Practice, 2021, 41(3): 667-677 https://doi.org/10.12011/SETP2019-0632

References

[1] Yu G, Qi X. Disruption management:Framework, models and applications[M]. Singapore:World Scientific Publishing, 2004:16-17.
[2] Mcalister J. The disruption management model[J]. Journal of Business Continuity & Emergency Planning, 2011, 5(3):231-236.
[3] Osvald A, Stirn L Z. A vehicle routing algorithm for the distribution of fresh vegetables and similar perishable food[J]. Journal of Food Engineering, 2008, 85(2):285-295.
[4] 缪小红, 周新年, 林森, 等. 第3方冷链物流配送路径优化研究[J]. 运筹与管理, 2011, 20(4):32-38. Miao X H, Zhou X N, Lin S, et al. Study on routing optimization for cold-chain logistics distribution of 3PL[J]. Operations Research and Management Science, 2011, 20(4):32-38.
[5] 杨建华, 郭继东, 马书刚. 碳税约束的城市冷链物流配送网络设计[J]. 工业工程, 2012, 15(5):86-91. Yang J H, Guo J D, Ma S G. Distribution network design for carbon tax-constrained urban cold chain logistics[J]. Industrial Engineering Journal, 2012, 15(5):86-91.
[6] 杨晓芳, 姚宇. 基于新鲜度的冷链物流配送多目标优化模型[J]. 计算机应用研究, 2016, 33(4):1050-1053. Yang X F, Yao Y. Multi-objective optimization model of cold chain logistics distribution based on freshness[J]. Application Research of Computers, 2016, 33(4):1050-1053.
[7] Hsiao Y H, Chen M C, Chin C L. Distribution planning for perishable foods in cold chains with quality concerns:Formulation and solution procedure[J]. Trends in Food Science & Technology, 2017, 61:80-93.
[8] 卢甲东, 张世斌. 基于时空相似测度的冷链物流分区配送路径优化[J]. 上海海事大学学报, 2018, 39(4):32-37. Lu J D, Zhang S B. Route optimization of partitioned distribution of cold chain logistics based on spatiotemporal similarity measure[J]. Journal of Shanghai Maritime University, 2018, 39(4):32-37.
[9] Zhang L Y, Tseng M L, Wang C H. Low-carbon cold chain logistics using ribonucleic acid-ant colony optimization algorithm[J]. Journal of Cleaner Production, 2019, 233:169-180.
[10] Wang S, Tao F, Shi Y. Optimization of location-routing problem for cold chain logistics considering carbon footprint[J]. International Journal of Environmental Research & Public Health, 2018, 15(1):86.
[11] 蒋丽, 丁斌, 臧晓宁. 基于干扰管理的车辆故障救援模型[J]. 系统工程, 2010, 28(6):111-116. Jiang L, Ding B, Zang X N. The model of vehicle breakdown rescue based on disruption management[J]. Systems Engineering, 2010, 28(6):111-116.
[12] 胡祥培, 孙丽君, 王雅楠. 物流配送系统干扰管理模型研究[J]. 管理科学学报, 2011, 14(1):50-60. Hu X P, Sun L J, Wang Y N. A model for disruption management in urban distribution systems[J]. Journal of Management Sciences in China, 2011, 14(1):50-60.
[13] Wang X, Ruan J, Shi Y. A recovery model for combinational disruptions in logistics delivery:Considering the real-world participators[J]. International Journal of Production Economics, 2012, 140(1):508-520.
[14] 杨华龙, 叶迪, 张倩, 等. 时间窗变动的车辆调度干扰管理模型与算法[J]. 运筹与管理, 2017, 26(10):56-64. Yang H L, Ye D, Zhang Q, et al. Disruption management model and algorithm for vehicle scheduling with time window changes[J]. Operations Research and Management Science, 2017, 26(10):56-64.
[15] Li N, Chen G, Govindan K, et al. Disruption management for truck appointment system at a container terminal:A green initiative[J]. Transportation Research Part D:Transport and Environment, 2018, 61:261-273.
[16] 宁涛, 王旭坪, 胡祥培. 行驶受扰延迟下配送车辆调度的干扰管理决策模型[J]. 系统工程理论与实践, 2019, 39(5):1236-1245. Ning T, Wang X P, Hu X P. Disruption management decision model for vehicle scheduling under traffic disruption delay[J]. Systems Engineering-Theory & Practice, 2019, 39(5):1236-1245.
[17] Paul S K, Asian S, Goh M, et al. Managing sudden transportation disruptions in supply chains under delivery delay and quantity loss[J]. Annals of Operations Research, 2019, 273(1-2):783-814.
[18] Stålhane M, Albjerk N, Danielsen T, et al. A variable neighbourhood search heuristic for disruption management in offshore oil and gas logistics[J]. Journal of the Operational Research Society, 2019, 70(4):588-600.
[19] Ding Q L, Hu X P, Sun L J, et al. An improved ant colony optimization and its application to vehicle routing problem with time windows[J]. Neurocomputing, 2012, 98:101-107.
[20] Solomon M M. Algorithms for the vehicle routing and scheduling problems with time window constraints[J]. Operations Research, 1987, 35(2):254-265.
[21] Chen C H, Ting C J. A hybird ant colony system for vehicle routing problem with time windows[J]. Journal of the Eastern Asia Society for Transportation Studies, 2005, 6:2822-2836.
[22] Balseiro S R, Loiseau I, Ramonet J. An ant colony algorithm hybridized with insertion heuristics for the time dependent vehicle routing problem with time windows[J]. Computers & Operations Research, 2011, 38(6):954-966.
[23] Ursani Z, Essam D, Cornforth D, et al. Localized genetic algorithm for vehicle routing problem with time windows[J]. Applied Soft Computing Journal, 2011, 11(8):5375-5390.
[24] Tan K C, Lee L H, Ou K. Artificial intelligence heuristics in solving vehicle routing problems with time window constraints[J]. Engineering Applications of Artificial Intelligence, 2001, 14(6):825-837.
[25] Xu S H, Liu J P, Zhang F H, et al. A combination of genetic algorithm and particle swarm optimization for vehicle routing problem with time windows[J]. Sensors, 2015, 15(9):21033-21053.

Funding

Major Program of the National Social Science Foundation of China (18ZDA058)
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