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A novel experimental investigation of a solar cooling system in Madrid
Authors:A. Syed, M. Izquierdo, P. Rodrí  guez, G. Maidment, J. Missenden, A. Lecuona,R. Tozer,
Affiliation:a Cundall Johnston and Partners LLP Consulting Engineers, 13-17 Long Lane, EC1A 9RH London, UK
b London South Bank University, Faculty of Engineering, Science and the Built Environment, 103 Borough Road, SE1 0AA London, UK
c Waterman Gore Consulting Engineers, Versailles Court, 3 Paris Garden, SE1 8ND London, UK
d Instituto de Ciencias de la Construcción Eduardo Torroja (CSIC), c/ Serrano Galavache S/no. 28033, Madrid, España
e Universidad Carlos III de Madrid, Escuela Politécnica Superior, Avenida de la Universidad 30, 28911 Leganés, Madrid, España
Abstract:This paper reports novel experimental results derived through field testing of a part load solar energized cooling system for typical Spanish houses in Madrid during the summer period of 2003. Solar hot water was delivered by means of a 49.9 m2 array of flat-plate collectors to drive a single-effect (LiBr/H2O) absorption chiller of 35 kW nominal cooling capacity. Thermal energy was stored in a 2 m3 stratified hot water storage tank during hours of bright sunshine. Chilled water produced at the evaporator was supplied to a row of fan coil units and the heat of condensation and absorption was rejected by means of a forced draft cooling tower. Instantaneous, daily and period energy flows and energy balance in the installation is presented. System and absorption machine temperature profiles are given for a clear, hot and dry day's operation. Daily and period system efficiencies are given. Peak insolation of 969 W m−2 (at 12:30 solar time on 08/08/03) produced 5.13 kW of cooling at a solar to cooling conversion efficiency of 11%. Maximum cooling capacity was 7.5 kW. Cooling was provided for 8.67 h and the chiller required a threshold insolation of 711 W m−2 for start-up and 373 W m−2 for shut-down. A minimum hot water inlet temperature to the generator of 65 °C was required to commence cold generation, whereas at 81 °C, 6.4 kW of cooling (18.3% of nominal capacity) was produced. The absorption refrigeration machine operated within the generation and absorption temperature ranges of 57–67 and 32–36 °C, respectively. The measured maximum instantaneous, daily average and period average COP were 0.60 (at maximum capacity), 0.42 and 0.34, respectively. Energy flows in the system are represented on a novel area diagram. The results clearly demonstrate that the technology works best in dry and hot climatic conditions where large daily variations in relative humidity and dry bulb temperature prevail. This case study provides benchmark data for the assessment of other similar prototypes and for the validation of mathematical models.
Keywords:Air conditioning   Residential building   Spain   Experiment   Absorption system   Water-lithium bromide   Solar collector   Thermal storageMots clé  s: Conditionnement d'air   Immeuble ré  sidentiel   Espagne   Expé  rimentation   systè  me à   absorption   Eau-bromure de lithium   Capteur solaire   Accumulation thermique
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