Optimization framework of clean heat and CO2 supply for agricultural greenhouses exploiting industrial symbiosis

IF 7.9 2区 工程技术 Q1 ENERGY & FUELS
Farzaneh Rezaei , Vanessa Burg , Stephan Pfister , Stefanie Hellweg , Ramin Roshandel
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引用次数: 0

Abstract

The rising demand for greenhouse cultivation poses a challenge in providing environmentally friendly energy to maintain favorable greenhouse indoor conditions. This research presents an optimization model to identify cost-optimal symbiotic pathways to replace the import of three key greenhouse crops (tomato, cucumber, lettuce) with local greenhouse production. The proposed solutions involve greenhouses that can meet these crops' heat and CO2 demands via industrial symbiosis. Switzerland is investigated as the case study, and the (waste) heat suppliers are municipal solid waste incinerators, cement production plants and biogas plants. Upgrading biomethane production plants are also considered potential CO2 suppliers. The objective is to minimize the discounted cost when replacing 25%–100 % of vegetable imports with local agricultural greenhouses, considering availability of suitable land as well as waste heat and CO2 suppliers. Optimization results suggest prioritizing northeast and west Switzerland for greenhouse development, due to the availability of suitable land and proximity of waste heat and CO2 suppliers. Waste incinerators could provide 50%–70 % of the necessary heat, while Organic Rankine cycle in cement plants could generate 63 % of the electricity of supplementary lighting demand of greenhouses. While tailored for Switzerland, the optimization framework's general formulation can be adapted also to other regions to optimize greenhouses' heat and CO2 demands. The optimization code is provided open source for associated applications.

利用工业共生为农业温室提供清洁供热和二氧化碳的优化框架
温室种植的需求不断增加,这对提供环保能源以维持良好的温室室内条件提出了挑战。本研究提出了一个优化模型,以确定成本最优的共生途径,用本地温室生产替代三种主要温室作物(番茄、黄瓜和莴苣)的进口。所提出的解决方案涉及通过工业共生来满足这些作物对热量和二氧化碳需求的温室。瑞士被作为案例进行研究,(废)热供应方是城市固体废物焚化炉、水泥生产厂和沼气厂。升级生物甲烷生产厂也被视为潜在的二氧化碳供应方。目标是在考虑到合适土地的可用性以及废热和二氧化碳供应商的情况下,将本地农业温室取代 25%-100% 蔬菜进口的贴现成本降至最低。优化结果表明,由于瑞士东北部和西部有合适的土地,且靠近废热和二氧化碳供应商,因此应优先发展温室。垃圾焚烧炉可提供 50%-70%的必要热量,而水泥厂的有机郎肯循环可产生 63%的温室补充照明用电。虽然该优化框架是为瑞士量身定做的,但其一般表述也可适用于其他地区,以优化温室的热量和二氧化碳需求。优化代码已开放源代码,可供相关应用使用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Energy Strategy Reviews
Energy Strategy Reviews Energy-Energy (miscellaneous)
CiteScore
12.80
自引率
4.90%
发文量
167
审稿时长
40 weeks
期刊介绍: Energy Strategy Reviews is a gold open access journal that provides authoritative content on strategic decision-making and vision-sharing related to society''s energy needs. Energy Strategy Reviews publishes: • Analyses • Methodologies • Case Studies • Reviews And by invitation: • Report Reviews • Viewpoints
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