Design, construction and operation of a solar powered ammonia–water absorption refrigeration system in Saudi Arabia

•Experimental investigation of a solar powered NH3–H2O absorption refrigerator.•Results indicated COP of 0.69 at GEN/COND/EVAP temperatures of 114/23/−2 (°C).•Results indicated COP of 0.42 at GEN/COND/EVAP temperatures of 145/45/−4 (°C). This study presents an experimental investigation of a solar t...

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Bibliographic Details
Published inInternational journal of refrigeration Vol. 62; pp. 222 - 231
Main Authors Said, S.A.M., Spindler, K., El-Shaarawi, M.A., Siddiqui, M.U., Schmid, F., Bierling, B., Khan, M.M.A.
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.02.2016
Subjects
Absorption chiller
Ammoniac-eau (NH3-H2O)
Ammonia–water (NH3–H2O)
Collecteurs solaires tubulaires à vide
Energie solaire
Evacuated tubular solar collectors
Ice storage
Refrigeration system
Refroidisseur à absorption
Solar energy
Stockage de glace
Système frigorifique
Evacuated tubular solar collectors
Stockage de glace
Ammonia–water (NH3–H2O)
Energie solaire
Ice storage
Système frigorifique
Solar energy
Refroidisseur à absorption
Collecteurs solaires tubulaires à vide
Absorption chiller
Refrigeration system
Ammoniac-eau (NH3-H2O)
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Summary:•Experimental investigation of a solar powered NH3–H2O absorption refrigerator.•Results indicated COP of 0.69 at GEN/COND/EVAP temperatures of 114/23/−2 (°C).•Results indicated COP of 0.42 at GEN/COND/EVAP temperatures of 145/45/−4 (°C). This study presents an experimental investigation of a solar thermal powered ammonia–water absorption refrigeration system. The focus of this study lies on the design of the components of the absorption chiller, the ice storages and the solar collector field as well as the integration of the data acquisition and control unit. An ammonia–water (NH3/H2O) absorption chiller was developed in the laboratory of the Institute of Thermodynamics & Thermal Engineering (ITW) at the University of Stuttgart (Germany). A demonstration plant was built in the laboratory of the CoRE-RE at King Fahd University of Petroleum & Minerals (KFUPM – Saudi Arabia). The whole system was tested successfully. The results of the experiments indicated a chiller coefficient of performance (COP) of 0.69 and a cooling capacity of 10.1 kW at 114/23/−2 (°C) representing the temperatures of the generator inlet, the condenser/absorber inlet and the evaporator outlet respectively. Even at 140/45/−4 (°C), the chiller was running with a cooling capacity of 4.5 kW and a COP of 0.42.
ISSN:0140-7007
1879-2081
DOI:10.1016/j.ijrefrig.2015.10.026