Design and optimization of sustainable closed-loop supply chain networks under uncertainty

不确定性下可持续闭环供应链网络的设计与优化

• 批准号: RGPIN-2021-02912
• 负责人: MohamadpourTosarkani, Babak
• 金额: $ 1.89万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=761771
• 关键词: Design; optimization; sustainable; closed; loop

Most materials from end-of-life (EOL) and end-of-use (EOU) products can be recycled and used to produce new products. A great number of benefits are associated with recycling plans such as reducing the consumption of raw materials, saving energy, and diverting waste from landfills. In this regard, closed-loop supply chain networks (CLSCNs) are designed for creating value over the entire life cycle of products. A CLSCN is an integration of a forward supply chain (i.e., suppliers, producers, retailers, and customer zones) and a reverse logistics network (i.e., collection depots, recovery centers, remanufacturing plants, and disposal centers). Forward supply chains consist of several activities to convert raw materials to finished products, while reverse logistics networks include some activities (e.g., refurbishing and remanufacturing) to recover the EOL and EOU products. Nowadays, CLSCN design is experiencing growing attention due to customer awareness and government policies regarding recovery options to protect the environment. According to the recycling regulations in British Columbia, producers are responsible for the life cycle management (i.e., collection and recycling) of their products. To this aim, producers need to collaborate with other parties involved in reverse logistics networks to manage a sequence of operations (e.g., collection, transportation, refurbishing, and remanufacturing). Although social development and environmental protection should be considered for planning sustainable CLSCNs, most existing studies have focused on economic aspects of recycling plans. Similarly, a very small amount of research has focused on resiliency in CLSCNs. However, there are many uncertain parameters (e.g., quantity and quality of returned products) that affect the performance of the entire network (e.g., higher overtime and transportation costs). My long-term research objective is to advance state-of-the-art methods to support industries and communities to establish efficient recycling mechanism in which several facilities cooperate effectively over the entire life cycle of products. Therefore, over the next five years, optimal CLSCNs will be designed for products containing non-biodegradable substances (e.g., e-waste and plastics) in Canada by focusing on three short-term objectives:(1) To develop data-driven decision-making processes using big data analytics in the configuration of CLSCNs, (2) To design sustainable CLSCNs using multi-objective models (i.e., social development, environmental protection, and economic benefits), (3) To propose novel optimization models to configure CLSCNs that are resilient against the impact of operational and disruption risks. In this research program, CLSCNs will be configured to improve the performance of existing recycling plans related to e-waste and plastics. This research will have significant outcomes, such as saving costs, conserving natural resources, and protecting the environment in Canada.

大多数来自寿命终止（EOL）和使用结束（EOU）产品的材料都可以回收并用于生产新产品。大量的好处与回收计划有关，如减少原材料的消耗，节约能源，并将废物从垃圾填埋场转移。在这方面，闭环供应链网络（CLSCN）旨在为产品的整个生命周期创造价值。CLSCN是前向供应链（即，供应商、生产商、零售商和客户区）和逆向物流网络（即，收集站、回收中心、再制造厂和处置中心）。正向供应链包括将原材料转化为成品的若干活动，而逆向物流网络则包括一些活动（例如，翻新和再制造）以回收EOL和EOU产品。如今，由于客户意识和政府关于恢复选项以保护环境的政策，CLSCN设计正受到越来越多的关注。根据不列颠哥伦比亚省的回收条例，生产商负责生命周期管理（即，收集和回收）。为此，生产商需要与逆向物流网络中的其他各方合作，以管理一系列操作（例如，收集、运输、翻新和再制造）。虽然社会发展和环境保护应考虑规划可持续的CLSCN，大多数现有的研究集中在回收计划的经济方面。同样，很少有研究关注CLSCN的弹性。然而，存在许多不确定的参数（例如，返回产品的数量和质量）影响整个网络的性能（例如，加班费和运输费较高）。 我的长期研究目标是推进最先进的方法，以支持行业和社区建立有效的回收机制，其中几个设施在产品的整个生命周期有效合作。因此，在未来五年内，最佳的CLSCN将被设计用于含有不可生物降解物质的产品（例如，电子废物和塑料）在加拿大通过专注于三个短期目标：（1）在CLSCN的配置中使用大数据分析来开发数据驱动的决策过程，（2）使用多目标模型（即，社会发展、环境保护和经济效益），（3）提出新的优化模型来配置CLSCN，以抵御运营和中断风险的影响。 在这项研究计划中，CLSCN将被配置为改善与电子废物和塑料相关的现有回收计划的性能。这项研究将产生重大成果，如节省成本，保护自然资源，保护加拿大的环境。