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Effect of operating variables on modified compression-absorption refrigeration system

Navneet Kumar Pandey*, V.K. Bajpai**

* Assistant Professor, Department of Mechanical Engineering, JSSATE, Noida, U.P., India.

** Professor, Department of Mechanical Engineering, N.I.T, Kurukshetra, Haryana, India.

Periodicity:February - April'2014
DOI : https://doi.org/10.26634/jme.4.2.2684

Abstract

The vapour-absorption refrigeration cycle is a traditional and well-established technique, particularly with ammonia/water and water/LiBr (Lithium Bromide). Energy management has further enhanced its possibilities in day-today applications. Modifications have been suggested in compression–absorption refrigeration system which offers numerous advantages compared to conventional absorption systems. A detailed thermodynamic analysis and parametric study of NH -H O based compression absorption system has been carried out with an objective to get an 3 2 insight into the performance and feasibility of this system under varying operating conditions. The operating parameters studied are the effects of concentration of weak solution leaving the desorber on COP and variation of saturation pressure with respect to concentration keeping in view certain assumptions.

Keywords

Energy Management, Compression-Absorption System, Ammonia – Water, Concentration, COP.

How to Cite this Article?

Pandey, N. K., & Bajpai, V. K. (2014). Effect of Operating Variables on Modified Compression absorption Refrigeration System. i-manager's Journal on Mechanical Engineering, 4(2), 38-43. https://doi.org/10.26634/jme.4.2.2684

References

[1]. Pratihar A.K, Kaushik S.C and Agarwal R.S. (2010). “Simulation of an ammonia-water compression-absorption refrigeration system for water chilling application”. International Journal of Refrigeration, 33, pp. 1386-1394.

[2]. Jin Soo, Kim, Felix Ziegler, Huen Lee. (2002). “Simulation of the compressor-assisted triple-effect H O/LiBr absorption 2 cooling cycles”, Applied Thermal Engineering 22, pp. 295–308.

[3]. Jose Fernandez Seara, Jaime Sieres, Manuel Vazquez, (2006). “Compression–absorption cascade refrigeration system”, Applied Thermal Engineering, 26, pp. 502–512.

[4]. Magnus Hulten, Thore Berntsson, (1999). “The compression/absorption cycle – influence of some major parameters on COP and a comparison with the compression cycle”, International Journal of Refrigeration, 22, pp. 91–106.

[5]. Herold K.E, Howe. L.A., Radermacher, R. (1991). “Analysis of a hybrid compression absorption cycle using lithium bromide and water as working fluid”, International Journal of Refrigeration, 14, pp. 264-272

[6]. Levy A; Jelinek.M; Borde. I; Ziegler. F. (2004). “Performance of an advanced absorption cycle with R-125 and different absorbents”, Energy, 29, pp. 2501-2515.

[7]. Best, R; Islas. J. and Martinez. M, (1993). “Energy efficiency of an ammonia-water absorption system for ice production”, Applied energy 45, pp. 243-256

[8]. Arzu Sencan, Kemal. A. Yakut, Soteris. A. Kalogirou, (2005). “Exergy analysis of lithium bromide/water absorption systems”, Renewable energy 30, pp. 645-657.

[9]. Ziegler, B., Trepp, Ch. (1984). “Equation of states for ammonia water mixtures”, International journal of Refrigeration 7, pp. 101-106

[10]. Mejbri. Kh, Bellagi, A. (2006). “Modelling of the thermodynamic properties of the water ammonia mixture by three different approaches”, International journal of Refrigeration 29, pp. 211-218.

[11]. Yokozeki A, (2005). “Theoretical performances of various refrigerant–absorbent pairs in a vapour-absorption refrigeration cycle by the use of equations of state”, Applied Energy 80, pp. 383-399.

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Effect of operating variables on modified compression-absorption refrigeration system

Abstract

Keywords

How to Cite this Article?

References

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