Journal
NAVAL RESEARCH LOGISTICS
Volume 68, Issue 4, Pages 434-453Publisher
WILEY
DOI: 10.1002/nav.21971
Keywords
biomass supply chain; blending problem; decentralized supply chain; stochastic optimization
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In this study, a model is proposed to optimize the thermochemical conversion process by blending biomass materials and adjusting the quality of feedstock. The model takes into account the stochastic nature of biomass quality and ensures that process requirements are met most of the time. Results show that the identified blends consist mainly of pine and softwood residues, with the cost of the centralized supply chain being 2%-6% lower than the decentralized supply chain.
Blending biomass materials of different physical or chemical properties provides an opportunity to adjust the quality of the feedstock to meet the specifications of the conversion platform. We propose a model which identifies the right mix of biomass to optimize the performance of the thermochemical conversion process at the minimum cost. This is a chance-constraint programming (CCP) model which takes into account the stochastic nature of biomass quality. The proposed CCP model ensures that process requirements, which are impacted by physical and chemical properties of biomass, are met most of the time. We consider two problem settings, a centralized and a decentralized supply chain. We propose a mixed-integer linear program to model the blending problem in the centralized setting and a bilevel program to model the blending problem in the decentralized setting. We use the sample average approximation method to approximate the chance constraints, and propose solution algorithms to solve this approximation. We develop a case study for South Carolina using data provided by the Billion Ton Study. Based on our results, the blends identified consist mainly of pine and softwood residues. The blends identified and the suppliers selected by both models are different. The cost of the centralized supply chain is 2%-6% lower. The implications of these results are twofold. First, these results could lead to improved collaborations in the supply chain. Second, these results provide an estimate of the approximation error from assuming centralized decision making in the supply chain.
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