A novel combined power and cooling cycle design and a modified conditional exergy destruction approach

•A new combined power and cooling cycle design with common absorber is proposed.•New scheme to address conditional nature of exergy destruction is introduced.•Dual-mode dragonfly optimization is introduced for minimizing exergy destruction.•Power, cooling capacity and exergy efficiency improve by 1....

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Bibliographic Details
Published in:Energy conversion and management 2021-04, Vol.233, p.113943, Article 113943
Main Authors: Singh, Adityabir, Das, Ranjan
Format: Article
Language:English
Subjects:
Algorithms
Condensates
Cooling
Cooling output
Design modifications
Destruction
Exergy
Exergy efficiency
Modified combined power and cooling cycle
Modified exergy destruction
Objective function
Optimization
Parameters
Temperature
Thermodynamics
Total turbine work output
Turbines
Vaporization
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Summary:•A new combined power and cooling cycle design with common absorber is proposed.•New scheme to address conditional nature of exergy destruction is introduced.•Dual-mode dragonfly optimization is introduced for minimizing exergy destruction.•Power, cooling capacity and exergy efficiency improve by 1.84, 6.74, and 1.33 times.•Exergy destruction increases by 1.35 times due to its conditional nature. This paper introduces a new combined power and cooling cycle (CPCC) formed by the integration of a modified Kalina and Goswami cycles sharing a common absorber that in turn demands for internal rectification in the former cycle. Unlike most of the conventional studies which are aimed at minimizing the overall exergy destruction of the cycle (ĖDx,OC), this work clarifies that such a practice does not ensure the optimized attainment of total turbine work output (ẆTR), cooling output (Ċcooling) and exergy efficiency (ηexergy) of the cycle. Therefore, this conditional nature of ĖDx,OC is addressed here through the optimization of an integrated objective function addressing each of the desired performance parameters using a dual-mode dragonfly algorithm. The optimization is performed for a range of strong solution concentration, boiler temperature and pressure, in which only the first two parameters are independently varying, while the third is dependent on the previous parameters to ensure partial vaporization. The temperature of the strong solution is kept below its bubble temperature while recovering heat from the hot liquid condensate so that there is no vaporization before entering the boiler. When the present optimization approach is performed for a given set of operational parameters, the values of ẆTR, Ċcooling and ηexergy are observed to improve by 1.84, 6.74, and 1.33 times, respectively with 1.35 times compromise in ĖDx,OC, with respect to the conventional practice. The temperature of the strong solution is kept below its Tbubble while recovering heat from the liquid condensate by performing pinch point calculations.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2021.113943