COMPARATIVE STUDY AND ANALYSIS OF PERFORMANCE REFRIGERATION SYSTEM DRIVEN BY DIFFERENT ENERGY SOURCES
DOI:
https://doi.org/10.4314/jfas.v11i2.27Keywords:
Refrigeration system; Energy; Cost;Cop.Abstract
The present work concerns a study on mechanical compression refrigeration machines that based on the electric compressor, and absorption machine, were this work is focused on choosing natural gas as a direct source in the refrigeration space; this logic was present general thermodynamic calculations of the two machines. The results show that quite good values of the coefficient of performance of the new configuration of the absorption refrigeration machine and the study of the cost of each one, we can consider it encouraging for the development of this device, which promises to be an alternative one hand to eliminate the pressure in the electricity sector, and promises to be quite powerful economic and energy point of view and side environment.
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References
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[6] Mancin, S., Diani, A., Doretti, L., Rossetto, L. R134a and R1234ze(E) liquid and flow boiling heat transfer in a high porosity copper foam, International Journal of Heat and Mass Transfer, 74 (2014) 77–87.
[7] Navarro-Esbri, J., Moles, F., Barragan-Cervera, A. Experimental analysis of the internal heat exchanger influence on a vapour compression system performance working with R1234yf as a drop-in replacement for R134a, Applied Thermal Engineering, 59 (2013) 153-161.
[8] Navarro-Esbrí, J., Molés F., Peris, B., Barragán-Cervera, A., Mendoza-Miranda, J.M., Mota-Babiloni, A., Belman, J.M. Shell-and-tube evaporator model performance with different two-phase flow heat transfer correlations. Experimental analysis using R134a and R1234yf, Applied Thermal Engineering, 62 (2014) 80-89.
[9] R. Ventas, A. Lecuona, A. Zacarías, M. Venegas, Ammonia-lithium nitrate absorption chiller with an integrated low-pressure compression booster cycle for low driving temperatures, Applied Thermal Engineering, 30 (2010), 11-12, pp. 1351-1359
[10] Yongqing Wang, Noam Lior, Proposal and analysis of a high-efficiency combined desalination and refrigeration system based on the LiBr–H2O absorption cycle—Part 1: System configuration and mathematical model, Energy Conversion and Management, 52 (2011), 1, pp. 220-227
[11] A. Zacarías, M. Venegas, R. Ventas, A. Lecuona, Experimental assessment of ammonia adiabatic absorption into ammonia–lithium nitrate solution using a flat fan nozzle, Applied Thermal Engineering, 31 (2011), 16, pp. 3569-3579.
[2] Berhane H. Gebreslassie, Marc Medrano, Dieter Boer, Exergy analysis of multi-effect water–LiBr absorption systems: From half to triple effect, Renewable Energy, 35 (2010), 8, pp. 1773-1782
[3] J. Cerezo, R. Best, R.J. Romero, A study of a bubble absorber using a plate heat exchanger with NH3–H2O, NH3–LiNO3 and NH3–NaSCN, Applied Thermal Engineering, 31 (2011), 11-12, pp. 1869-1876
[4] M.I. Karamangil, S. Coskun, O. Kaynakli, N. Yamankaradeniz, A simulation study of performance evaluation of single-stage absorption refrigeration system using conventional working fluids and alternatives, Renewable and Sustainable Energy Reviews, 14 (2010), 7, pp. 1969-1978
[5] Mota-Babiloni A., Navarro-Esbrı J., Barraga A., Moles F., Peris B., Theoretical comparison of low GWP alternatives for different refrigeration configurations taking R404A as baseline, International Journal of Refrigeration, 44 (2014) 81-90.
[6] Mancin, S., Diani, A., Doretti, L., Rossetto, L. R134a and R1234ze(E) liquid and flow boiling heat transfer in a high porosity copper foam, International Journal of Heat and Mass Transfer, 74 (2014) 77–87.
[7] Navarro-Esbri, J., Moles, F., Barragan-Cervera, A. Experimental analysis of the internal heat exchanger influence on a vapour compression system performance working with R1234yf as a drop-in replacement for R134a, Applied Thermal Engineering, 59 (2013) 153-161.
[8] Navarro-Esbrí, J., Molés F., Peris, B., Barragán-Cervera, A., Mendoza-Miranda, J.M., Mota-Babiloni, A., Belman, J.M. Shell-and-tube evaporator model performance with different two-phase flow heat transfer correlations. Experimental analysis using R134a and R1234yf, Applied Thermal Engineering, 62 (2014) 80-89.
[9] R. Ventas, A. Lecuona, A. Zacarías, M. Venegas, Ammonia-lithium nitrate absorption chiller with an integrated low-pressure compression booster cycle for low driving temperatures, Applied Thermal Engineering, 30 (2010), 11-12, pp. 1351-1359
[10] Yongqing Wang, Noam Lior, Proposal and analysis of a high-efficiency combined desalination and refrigeration system based on the LiBr–H2O absorption cycle—Part 1: System configuration and mathematical model, Energy Conversion and Management, 52 (2011), 1, pp. 220-227
[11] A. Zacarías, M. Venegas, R. Ventas, A. Lecuona, Experimental assessment of ammonia adiabatic absorption into ammonia–lithium nitrate solution using a flat fan nozzle, Applied Thermal Engineering, 31 (2011), 16, pp. 3569-3579.
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Published
2019-04-30
How to Cite
GUERMIT, T.; SETTOU, N. COMPARATIVE STUDY AND ANALYSIS OF PERFORMANCE REFRIGERATION SYSTEM DRIVEN BY DIFFERENT ENERGY SOURCES. Journal of Fundamental and Applied Sciences, [S. l.], v. 11, n. 2, p. 966–977, 2019. DOI: 10.4314/jfas.v11i2.27. Disponível em: https://jfas.info/index.php/JFAS/article/view/431. Acesso em: 30 jan. 2025.
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