考虑碳交易与实时电价的“光储充一体化”冷链物流运营优化

doi:10.12005/orms.2025.0300

运筹与管理 ›› 2025, Vol. 34 ›› Issue (9): 233-239.DOI: 10.12005/orms.2025.0300

• 管理科学 • 上一篇

考虑碳交易与实时电价的“光储充一体化”冷链物流运营优化

邵举平¹, 施瑾¹, 孙延安²

1.苏州科技大学商学院,江苏苏州 215009;
2.苏州优乐赛供应链管理有限公司,江苏苏州 215021

收稿日期:2023-12-05 出版日期:2025-09-25 发布日期:2026-01-19
通讯作者: 邵举平(1971-),男,甘肃庄浪人,博士,教授,研究方向:物流与供应链管理。Email: wlustbshao@163.com。
基金资助:
国家社会科学基金资助项目(19BGL097)

Optimizing of “Photovoltaic-Energy Storage-Charging Integration” Cold Chain Logistics Operations Considering Carbon Trading and Real-time Electricity Prices

SHAO Juping¹, SHI Jin¹, SUN Yanan²

1. School of Business, Suzhou University of Science and Technology, Suzhou 215009, China;
2. Anwood Logistics System Co. Ltd., Suzhou 215021, China

Received:2023-12-05 Online:2025-09-25 Published:2026-01-19

摘要/Abstract

摘要： 实现低碳化发展是交通运输行业转型的重要目标,针对冷链物流网络中存在的高碳排放问题,研究了“光储充一体化”冷链物流配送中心(DC)面临的光伏设施、储能设施配置决策、新能源冷链车充电时段选择等问题。首先,以最小化碳交易价格和实时电价下的经济成本和最大化售电收益为优化目标,建立了集成冷链物流车辆路径优化与“光储充一体化”设施能源管理的混合整数规划模型;其次,利用MOEA/D-IEpsilon算法进行求解;最后,以M企业在江苏省的三级冷链为例进行了实例验证,验证了模型及算法的有效性,能够为冷链物流企业的低碳行为提供决策借鉴。结果表明:新能源冷链车的充电时段选择会显著影响DC的经济成本,应合理规划新能源冷链车的充电行为;冷链物流配送中心配置光伏发电设施能为冷链物流企业带来增益,储能设施则为能量管理提供更好的灵活性。

关键词: 实时电价, 碳交易, 车辆路径, 光伏发电, 储能

Abstract: As an industry that is highly dependent on electricity and fuel, cold chain logistics faces a significant carbon emission challenge that cannot be overlooked. The consumption of these resources not only escalates operating costs but also exacerbates environmental degradation, posing a dual threat to the long-term viability of businesses and the stability of the global climate system. Thus, promoting the use of new energy logistics vehicles and renewable energy sources emerges as a crucial strategy not only to curtail carbon emissions and ease environmental pressure but also to foster a symbiotic enhancement of corporate economic gains and environmental health. This proactive approach is vital for forging a path towards sustainable industrial practices that benefit both the economy and the environment.
To rigorously investigate the potential within this sector, this study specifically targets cold chain logistics centers that are equipped with advanced “photovoltaic-energy storage-charging integration” system. The system is designed to offer clean and sustainable energy for new energy logistics vehicles, thereby significantly reducing carbon emissions. The introduction of such “photovoltaic-energy storage-charging integrated” system has undoubtedly revitalized the cold chain logistics industry and opened up new avenues for research and optimization that could lead to financial condition and environment improvements.
In this comprehensive study, the impacts of carbon trading prices and real-time electricity prices on the operations of cold chain logistics are thoroughly assessed. These pricing factors are crucial not only for their direct influence on the economic costs borne by enterprises but also for their role in shaping the deployment and operational strategies of “photovoltaic-energy storage-charging” facilities. The intricate dynamic relationships among photovoltaic installations, energy storage equipment, new energy logistics vehicle charging stations and external power grids are studied in depth. The purpose of the study is to optimize the management of these elements to maximize revenue from electricity sales while minimizing the economic costs associated with their operation. To this end, a mixed integer optimization model is constructed that combines the key aspects of cold chain logistics vehicle route optimization with “photovoltaic-energy storage-charging” energy management. This model seeks to establish an optimal operational framework that not only meets the logistical demands of transporting temperature-sensitive goods but also leverages renewable energy to its fullest potential to minimize carbon emission. In order to solve this complex model, the MOEA/D-IEpsilon algorithm is designed. This improved algorithm is capable of exploring a wider array of feasible solutions in large-scale, multi-decision scenarios compared to the traditional MOEA/D algorithm, thereby enhancing both the quantity and quality of potential solutions.
The efficacy of this model and algorithm is corroborated through a detailed case study involving the tertiary cold chain operations of Company M in Jiangsu Province. The findings reveal that: (1)it is more economical for new energy logistics vehicles to be charged between 11∶00 and 17∶00; (2)by strategically planning vehicle routes and managing the charging behaviors of new energy logistics vehicles, it is possible to significantly reduce the economic costs associated with cold chain logistics while simultaneously boosting electricity sales revenue; (3)cold chain logistics companies should make full use of the site for photovoltaic power generation and give priority to “self-use”; (4)energy storage facilities should be charged when the electricity price is low and discharged when the electricity price is high to reduce economic costs.

Key words: real-time electricity prices, carbon trading, vehicle routing, photovoltaic power generation, energy storage

中图分类号:

F272

邵举平, 施瑾, 孙延安. 考虑碳交易与实时电价的“光储充一体化”冷链物流运营优化[J]. 运筹与管理, 2025, 34(9): 233-239.

SHAO Juping, SHI Jin, SUN Yanan. Optimizing of “Photovoltaic-Energy Storage-Charging Integration” Cold Chain Logistics Operations Considering Carbon Trading and Real-time Electricity Prices[J]. Operations Research and Management Science, 2025, 34(9): 233-239.

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考虑碳交易与实时电价的“光储充一体化”冷链物流运营优化

Optimizing of “Photovoltaic-Energy Storage-Charging Integration” Cold Chain Logistics Operations Considering Carbon Trading and Real-time Electricity Prices

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