J Shanghai Jiaotong Univ Sci

Journal of Shanghai Jiaotong University(Science) >

2021 , Vol. 26 >Issue 2: 155 - 162

DOI: https://doi.org/10.1007/s12204-020-2209-9

Energy Engineering, Mechanics & Materials

Comparative Study on Two-Stage Absorption Refrigeration Systems with Different Working Pairs

Expand
  • (College of Mechanical and Electronic Engineering, Shandong University of Science and Technology,
    Qingdao 266590, Shandong, China)

Online published: 2021-03-24

Fold

Abstract

The objective of this paper is to present a simulation study on the two-stage absorption refrigeration systems of 2.5 kW capacity using LiBr-H2O, NH3-H2O and R124-DMAC as working pairs. Under the design condition that the generating, absorbing, evaporating and condensing temperatures are 75 °C, 45 °C, 5 °C and 40 °C, respectively, the high and low pressure side solution circulation ratios and the coefficient of performance (COP) for the systems are calculated. Then the influences of medium, generating, absorbing, evaporating and condensing temperatures on system performances are analyzed. The results show that under the design condition, the COP of the LiBr-H2O system can reach 0.49, superior to those of the NH3-H2O and R124-DMAC systems, which are 0.32 and 0.31, respectively. Furthermore, the medium temperature for higher COP lies in an interval of 64—67 °C for the LiBr-H2O, NH3-H2O and R124-DMAC systems. High generating temperature and low absorbing temperature can decrease the high and low pressure side solution circulation ratios, and can also increase the COP. High evaporating temperature can decrease the low pressure side solution circulation ratio and increase the COP. Low condensing temperature can decrease the high pressure side solution circulation ratio and increase the COP.

Key words:  absorption refrigeration; two-stage system; working pair; cycle characteristics

Cite this article

KONG Xiangqiang (孔祥强), MENG Xiangxi (孟祥熙), LI Jianbo (李见波), SHANG Yanping (尚燕平), CUI Fulin (崔福林) . Comparative Study on Two-Stage Absorption Refrigeration Systems with Different Working Pairs[J]. Journal of Shanghai Jiaotong University(Science), 2021 , 26(2) : 155 -162 . DOI: 10.1007/s12204-020-2209-9

References

[1] LEONZIO G. Solar systems integrated with absorption heat pumps and thermal energy storages: State of art[J]. Renewable and Sustainable Energy Reviews, 2017,70: 492-505.
[2] EISAVI B, KHALILARYAS, CHITSAZ A, et al. Thermodynamic analysis of a novel combined cooling, heating and power system driven by solar energy [J]. Applied Thermal Engineering, 2018, 129: 1219-1229.
[3] ZHANG X J, LI H, YANG C X. A novel solar absorption refrigeration system using the multi-stage heat storage method [J]. Energy and Buildings, 2015, 102:157-162.
[4] XU Z Y, WANG R Z, WANG H B. Experimental evaluation of a variable effect LiBr-water absorption chiller designed for high-efficient solar cooling system [J]. International Journal of Refrigeration, 2015, 59: 135-143.
[5] XU Z Y, WANG R Z. Comparison of CPC driven solar absorption cooling systems with single, double and variable effect absorption chillers [J]. Solar Energy,2017, 158: 511-519.
[6] FIT′O J, CORONAS A, MAURAN S, et al. Definition and performance simulations of a novel solar-driven hybrid absorption-thermochemical refrigeration system[J]. Energy Conversion and Management, 2018, 175:298-312.
[7] BELLOS E, TZIVANIDISC, TSIFIS G. Energetic, exergetic,economic and environmental (4E) analysis of a solar assisted refrigeration system for various operating scenarios [J]. Energy Conversion and Management,2017, 148: 1055-1069.
[8] WAN Z M, SHU S M. Refrigeration cycle of solar mixed absorption [J]. Journal of Huazhong University of Science and Technology (Nature Science Edition),2003, 31(1): 100-102 (in Chinese).
[9] CHEN Y, ZHU Y Q, GENG W, et al. SE/DL absorption refrigeration cycle driven by low temperature heat resources [J]. Acta Energiae Solaris Sinica, 2002,23(1): 102-107 (in Chinese).
[10] SUMATHY K, HUANG Z C, LI Z F. Solar absorption cooling with low grade heat source: A strategy of development in South China [J]. Solar Energy, 2002,72(2): 155-165.
[11] WU W, WANG B L, SHI W X, et al. An overview of ammonia-based absorption chillers and heat pumps[J]. Renewable and Sustainable Energy Reviews, 2014,31: 681-707.
[12] LIN P, WANG R Z, XIA Z Z. Numerical investigation of a two-stage air-cooled absorption refrigeration system for solar cooling: Cycle analysis and absorption cooling performances [J]. Renewable Energy, 2011,36(5): 1401-1412.
[13] MARYAMI R, DEHGHAN A A. An exergy based comparative study between LiBr/water absorption refrigeration systems from half effect to triple effect [J]. Applied Thermal Engineering, 2017, 124: 103-123.
[14] DU S, WANG R Z, LIN P, et al. Experimental studies on an air-cooled two-stage NH3-H2O solar absorption air-conditioning prototype [J]. Energy, 2012, 45(1):581-587.
[15] BORDE I, JELINEK M, DALTROPHE N C. Working fluids for an absorption system based on R124 (2-chloro-1,1,1,2,-tetrafluoroethane) and organic absorbents[J]. International Journal of Refrigeration,1997, 20(4): 256-266.
[16] LI J B, XU S M. The performance of absorptioncompression hybrid refrigeration driven by waste heat and power from coach engine [J]. Applied Thermal Engineering,2013, 61(2): 747-755.
[17] JIANG M N, XU S M, WU X, et al. Visual experimental research on the effect of nozzle orifice structure on R124-DMAC absorption process in a vertical bubble tube [J]. International Journal of Refrigeration, 2016,68: 107-117.
[18] ARUN M B, MAIYA M P, MURTHY S S. Optimal performance of double-effect series flow vapour absorption refrigeration systems with new working fluids[J]. International Journal of Energy Research, 1998,22(11): 1001-1017.
[19] JELINEK M, LEVY A, BORDE I. The performance of a triple pressure level absorption cycle (TPLAC) with working fluids based on the absorbent DMEU and the refrigerants R22, R32, R124, R125, R134a and R152a[J]. Applied Thermal Engineering, 2008, 28(11/12):1551-1555.
[20] HADJ AMMAR M A, BENHAOUA B, BOURAS F.Thermodynamic analysis and performance of an adsorption refrigeration system driven by solar collector[J]. Applied Thermal Engineering, 2017, 112: 1289-1296.
[21] DIXIT M, ARORA A, KAUSHIK S C. Thermodynamic and thermoeconomic analyses of two stage hybrid absorption compression refrigeration system [J].Applied Thermal Engineering, 2017, 113: 120-131.
[22] ARIVAZHAGAN S, MURUGESAN S N,SARAVANAN R, et al. Simulation studies on R134a-DMAC based half effect absorption cold storage systems [J]. Energy Conversion and Management,2005, 46: 1703-1713.
[23] MUTHU V, SARAVANAN R, RENGANARAYANAN S. Experimental studies on R134a-DMAC hot water based vapour absorption refrigeration systems [J]. International Journal of Thermal Sciences, 2008, 47(2):175-181.
[24] MEJBRI K, BELLAGI A. Modelling of the thermodynamic properties of the water-ammonia mixture by three different approaches [J]. International Journal of Refrigeration, 2006, 29(2): 211-218.
[25] KAITA Y. Thermodynamic properties of lithium bromide-water solutions at high temperatures [J]. International Journal of Refrigeration, 2001, 24(5): 374-390.
[26] LU M, LI B, LI M L. Prediction of medium pressure in two-stage absorption refrigeration system driven by low-temperature hot source [J]. Journal of University of Shanghai for Science and Technology, 2001, 23(1):79-82 (in Chinese).

Options
Outlines

/