Energy and exergy analyses of the diffusion absorption refrigeration system

This paper describes the thermodynamic analyses of a DAR (diffusion absorption refrigeration) cycle. The experimental apparatus is set up to an ammonia–water DAR cycle with helium as the auxiliary inert gas. A thermodynamic model including mass, energy and exergy balance equations are presented for...

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Veröffentlicht in:Energy (Oxford) 2013-10, Vol.60, p.407-415
Hauptverfasser: Yıldız, Abdullah, Ersöz, Mustafa Ali
Format: Artikel
Sprache:eng
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Zusammenfassung:This paper describes the thermodynamic analyses of a DAR (diffusion absorption refrigeration) cycle. The experimental apparatus is set up to an ammonia–water DAR cycle with helium as the auxiliary inert gas. A thermodynamic model including mass, energy and exergy balance equations are presented for each component of the DAR cycle and this model is then validated by comparison with experimental data. In the thermodynamic analyses, energy and exergy losses for each component of the system are quantified and illustrated. The systems' energy and exergy losses and efficiencies are investigated. The highest energy and exergy losses occur in the solution heat exchanger. The highest energy losses in the experimental and theoretical analyses are found 25.7090 W and 25.4788 W respectively, whereas those losses as to exergy are calculated 13.7933 W and 13.9976 W. Although the values of energy efficiencies obtained from both the model and experimental studies are calculated as 0.1858, those values, in terms of exergy efficiencies are found 0.0260 and 0.0356. •The diffusion absorption refrigerator system is designed manufactured and tested.•The energy and exergy analyses of the system are presented theoretically and experimentally.•The energy and exergy losses are investigated for each component of the system.•The highest energy and exergy losses occur in the solution heat exchanger.•The energy and the exergy performances are also calculated.
ISSN:0360-5442
DOI:10.1016/j.energy.2013.07.062