The equivalent low-dissipation combined cycle system and optimal analyses of a class of thermally driven heat pumps

[Display omitted] •A generic three-heat-source model of thermally driven heat pump is put forward.•A key parameter connecting two involved subsystems is introduced.•A key parameter measuring the matching deviation from reversible limit is introduced.•Bounds of coefficient of performance at maximum h...

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Bibliographic Details
Published in:Energy conversion and management 2020-09, Vol.220, p.113100, Article 113100
Main Authors: Guo, Juncheng, Yang, Hanxin, Gonzalez-Ayala, Julian, Roco, J.M.M., Medina, A., Calvo Hernández, A.
Format: Article
Language:English
Subjects:
Combined cycle
Heat
Heat exchangers
Heat pumps
Heat transfer
Low-dissipation assumption
Optimal analyses
Optimization
Parameters
Performance bound
Subsystems
Thermal energy
Thermal utilization
Thermally driven heat pump
Thermodynamic models
Three-heat-source cycle model
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Summary:[Display omitted] •A generic three-heat-source model of thermally driven heat pump is put forward.•A key parameter connecting two involved subsystems is introduced.•A key parameter measuring the matching deviation from reversible limit is introduced.•Bounds of coefficient of performance at maximum heat load are obtained.•Different performances of thermally driven heat pump from refrigerator are revealed. The performance characteristics, operation, and design strategies of a class of thermally driven heat pumps are investigated due to their important roles in the efficient utilization of low-grade thermal energy. In order to establish a more generic thermodynamic model of thermally driven heat pumps mainly including absorption, adsorption, and ejector heat pumps, low-dissipation assumption is adopted. Accordingly, the associated dissipation parameters accounting for the specific information on the irreversibilities in each heat-transfer process are introduced rather than specifying heat-transfer law. Based on the proposed model, the theoretical results of the coefficient of performance and heat load are derived with regard to two key parameters denoting the size ratio of the two involved subsystems and the matching deviation from reversible limit. The performance characteristics and the optimally operating regions of the whole system are determined and the differences between thermally driven heat pump and refrigerator are highlighted. The proposed model and obtained results further develop the low-dissipation model and may provide a useful description for the operation and design of practical thermally driven heat pumps.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2020.113100