Integrated and sustainable forest biomass supply chain planning

综合可持续的森林生物质供应链规划

• 批准号: RGPIN-2014-04758
• 负责人: Sowlati, Taraneh
• 金额: $ 1.75万
• 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: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=587997
• 关键词: Integrated; sustainable; forest; biomass; supply

There is a growing interest in using forest biomass to generate bioenergy in Canada. Forest biomass is a renewable and clean source of energy. Its utilization for energy production reduces dependency on fossil fuels and their negative environmental impacts, creates jobs and provides sustainable and domestic energy for communities. Moreover, utilizing forest biomass has the benefit of providing a new revenue stream for the forest industry in Canada, which despite its significant impact on our economy has been facing many challenges during the past two decades. Canada and especially British Columbia have large amount of forest biomass. The recent infestation of mountain pine beetle within the forests of interior BC has resulted in a cumulative total of 723 million cubic meters of dead wood. One proposed solution for the forest industry to remain competitive is to utilize the large amount of available forest biomass to produce bioenergy and bioproducts. The feasibility of bioenergy/ bioproducts projects depends on the long-term availability of forest biomass at a competitive cost and desired quality. There is variability in the amount and quality (moisture content and heating value) of forest biomass supply over time. Its transportation is costly and it has a complex supply chain. Mathematical models that consider and optimize the entire forest biomass supply chain are helpful to ensure consistent delivery of desired feedstock is possible at a low cost. A few studies have modeled and optimized the economic benefits of forest biomass supply chain for bioenergy production. In addition to economic benefits, social and environmental objectives have to be considered in the supply chain models in order to have sustainable development. Another key aspect is to make sure that the long-term decisions from multi-objective models are attainable at the operational level. The review of literature reveals the key attempts by researchers to use deterministic mathematical programming approaches to optimize the supply chains, stochastic programming and simulation to incorporate uncertainties, and multi-objective optimization to consider social and environmental objectives in addition to economic benefits in the models for sustainable development. It is a challenge to incorporate variations in biomass quality as biomass moves through the supply chain in optimization models. In addition, there are computational complexities associated with solving optimization models for real case scenarios as they are usually very large sized problems. To date, there is no published work on modeling and optimizing the design and management of forest biomass supply chains considering sustainability factors (economic, social and environmental impacts) as well as uncertainties, especially those related to the quality of forest biomass, in the supply chains. Moreover, there is no integrated study to ensure that the prescribed design of forest biomass supply chains by optimization models is practical and attainable at the operational level. Due to variability and uncertainty in parameters, decisions prescribed by strategic or tactical models may not be feasible or achievable at the operational level. Therefore, it is timely to focus on forest biomass supply chain and develop integrated and sustainable optimization models. The proposed proposal will address this gap and challenging problem. The objectives of the proposed research are 1) to optimize the design of forest biomass supply chains that are achievable at the operational level considering uncertainties in the parameters and sustainability factors (this will be done by developing new integrated simulation and optimization models), 2) solve the integrated models, and 3) apply them to real case scenarios in Canada.

在加拿大，人们对利用森林生物量生产生物能源的兴趣越来越大。森林生物质是一种可再生的清洁能源。将其用于能源生产，减少了对化石燃料的依赖及其对环境的负面影响，创造了就业机会，并为社区提供了可持续的家庭能源。此外，利用森林生物质的好处是为加拿大的林业提供新的收入来源，尽管它对我国经济产生了重大影响，但在过去二十年中，加拿大林业一直面临着许多挑战。加拿大，特别是不列颠哥伦比亚省有大量的森林生物量。最近，不列颠哥伦比亚省内陆森林中的山松甲虫肆虐，累计造成7.23亿立方米的枯木。森林工业保持竞争力的一个拟议解决办法是利用大量现有森林生物质生产生物能源和生物产品。生物能源/生物产品项目的可行性取决于能否以具有竞争力的成本和理想的质量长期获得森林生物量。森林生物量供应的数量和质量（含水量和热值）随时间变化。它的运输成本很高，而且有一个复杂的供应链。考虑和优化整个森林生物质供应链的数学模型有助于确保以低成本持续交付所需原料。一些研究已经模拟和优化了用于生物能源生产的森林生物质供应链的经济效益。除了经济效益外，供应链模型还必须考虑社会和环境目标，以实现可持续发展。另一个关键方面是确保多目标模型的长期决策可以在操作层面上实现。文献回顾揭示了研究人员的主要尝试，使用确定性数学规划方法来优化供应链，随机规划和模拟，以纳入不确定性，多目标优化，以考虑社会和环境目标，除了经济效益的可持续发展模型。随着生物质在优化模型中通过供应链移动，将生物质质量的变化纳入其中是一个挑战。此外，存在与求解用于真实的情况场景的优化模型相关联的计算复杂性，因为它们通常是非常大尺寸的问题。到目前为止，还没有出版的工作，建模和优化森林生物质供应链的设计和管理，考虑到可持续性因素（经济，社会和环境影响）以及不确定性，特别是那些与森林生物质的质量，在供应链。此外，没有综合研究，以确保规定的设计森林生物质供应链的优化模型是切实可行的，可在业务层面。由于参数的可变性和不确定性，战略或战术模型所规定的决策在作战层面可能不可行或无法实现。因此，关注森林生物质供应链并开发集成的可持续优化模型是及时的。拟议提案将解决这一差距和挑战性问题。拟议的研究的目标是1）优化森林生物质供应链的设计，可实现在操作层面上考虑参数和可持续性因素的不确定性（这将通过开发新的集成模拟和优化模型来完成），2）解决集成模型，和3）将其应用到加拿大的真实的案例场景。