An exergetic performance improvement potential of a modified ejector-enhanced auto-cascade refrigeration cycle
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Date
2025
Authors
Ibrahim Karacayli
Lutfiye Altay
A. Hepbasli
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Publisher
Inderscience Publishers
Open Access Color
Green Open Access
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Abstract
This study examines both conventional and advanced exergy analyses of a modified ejector-enhanced auto-cascade refrigeration (MEACR) cycle. Conventional exergy analysis shows that the proposed model significantly improves exergy efficiency compared to similar ejector-enhanced auto-cascade refrigeration cycles in the literature. Advanced exergy analysis reveals that 63.47% of the total exergy destruction is avoidable. When the components of the MEACR cycle are investigated 56.31% of the exergy destruction is attributed to the endogenous part. The low-temperature cycle (LTC) compressor has the highest avoidable endogenous exergy destruction rate of 12.64 kW with 38.5%. © 2025 Elsevier B.V. All rights reserved.
Description
Keywords
Advanced Exergy Analysis, Auto-cascade Refrigeration, Ejector, Exergy Analysis, Refrigeration, Ejectors (pumps), Advanced Exergy Analyze, Auto-cascade Refrigeration, Ejector, Exergetic Performance, Exergy Analysis, Exergy Destructions, Exergy Efficiencies, Low Temperature Cycles, Refrigeration Cycles, Chilling, Ejectors (pumps), Advanced exergy analyze, Auto-cascade refrigeration, Ejector, Exergetic performance, Exergy Analysis, Exergy destructions, Exergy efficiencies, Low temperature cycles, Refrigeration cycles, Chilling, Advanced Exergy Analysis; Auto-cascade Refrigeration; Ejector; Exergy Analysis; Refrigeration; Ejectors (pumps); Advanced Exergy Analyze; Auto-cascade Refrigeration; Ejector; Exergetic Performance; Exergy Analysis; Exergy Destructions; Exergy Efficiencies; Low Temperature Cycles; Refrigeration Cycles; Chilling, refrigeration, auto-cascade refrigeration, advanced exergy analysis, ejector, exergy analysis
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Source
International Journal of Exergy
Volume
46
Issue
Start Page
228
End Page
243
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