Optimal design of heat pump integrated low-grade heat utilization systems

Hu Jianqing; Fan Shanshan; Zhang BingjianHe ChangLiu ZumingChen Qinglin

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Optimal design of heat pump integrated low-grade heat utilization systems

机译：Optimal design of heat pump integrated low-grade heat utilization systems

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摘要

Recovery and utilization of low-grade heat in the process industries offers considerable economic and environmental benefits. Low-grade heat utilization employs circulating medium for heat transfer between heat sources and sinks. Thus, it is in need to synchronously integrate heat sources, circulating medium and heat sinks. It is extremely challenging for optimal design of low-grade heat utilization systems (LHUS) when considering quantity and quality of heat sources, heat sink requirements, feasible integration technologies and economic performance simultaneously. The current design methods for low-grade heat utilization integrated with upgrading technologies are simplified, narrowing down their integration domain. In this work, integration strategy of LHUS with heat pump technology is first proposed. A novel methodology for optimal design of heat pump integrated low-grade heat utilization systems (HPiLHUS) is developed subsequently for implementing the integration strategy. A modified superstructure characterized by nodes, low-low pressure steam (LLPS) generation module and a heat pump system is presented. The node acts as mixer, splitter or heat exchanger, and thus enables HPiLHUS optimization in all feasible domain. The LLPS generation module provides a promising integration possibility for heat pump technology. The heat pump system aims to upgrade low-grade heat in order to improve energy utilization efficiency. A mixed-integer non-linear programming (MINLP) model is formulated for optimal design of LHUS/HPiLHUS. Real-world case studies are employed to demonstrate our method's efficacy and applicability. The results show that integration of heat pump technology with LHUS reduces total annual cost (TAC) by 12.2%, demonstrating huge potential for reduction of energy consumption. Scenario analysis exhibit the advantages of our proposed modified method over conventional methods. Sensitivity analysis shows LLPS generation temperature and excavated heat sink duty have a great impact on TAC, which provides valuable information for implementing the heat pump integration strategy. The proposed methodology can be applied to industrial low-grade heat utilization and thus has a wide scope of applications.

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来源
《Energy conversion & management》 |2022年第5期|115619.1-115619.16|共16页
作者
Hu Jianqing; Fan Shanshan; Zhang BingjianHe ChangLiu ZumingChen Qinglin;
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作者单位

Sun Yat Sen Univ, Guangdong Engn Ctr Petrochem Energy Conservat, Sch Mat Sci & Engn, Guangzhou 510275, Guangdong, Peoples R China;

Sun Yat Sen Univ, Sch Chem Engn & Technol, Zhuhai 519082, Guangdong, Peoples R China;

Shanghai Jiao Tong Univ, Coll Smart Energy, Shanghai 200240, Peoples R China;

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收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种英语
中图分类
关键词
Low-grade heat utilization; Heat pump; Low-low pressure steam generation; Heat exchange networks; Mixed-integer non-linear programming;

Optimal design of heat pump integrated low-grade heat utilization systems

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