Thoretical Study for an Adsorption Refrigerator

Abstract

Adsorption cooling technology is one of the effctive means to convert low grade thermal energy in to effctive cooling, which improves energy effiency and lowers environmental pollution. The main objective of this study is to investigate the thermal performance of an adsorption refrigerator theoretically.The working adsorbent/adsorbate pair used is Granular Activated Carbon, GAC/R134a pair. The effct of diffrent design parameters and operating conditions on the system performance is studied and interpreted. Some assumptions and approximations are also considered. A computer program is written using Matlab. Results show that the equilibrium adsorption capacity is highly affcted by the driving temperature and equilibrium pressure. Increasing equilibrium pressure leads to a corresponding increase in the equilibrium adsorption capacity whereas it is value is decreased as the driving temperature increases. Moreover, increasing the driving and evaporator temperatures raise the values of the Specifi Cooling Effct (SCE) and Coeffient of Performance (COP). The maximum values of SCE and COP are 60 KJ/kg and 0.4 corresponding to driving and evaporator temperatures of 100 oC and 20 oC respectively. However, increasing the condenser temperature leads to a remarked decrease in SCE and COP of the cooling system. SCE and COP values are 32 KJ/kg and 0.22 at driving and condenser temperatures of 100 oC and 40 oC respectively. When comparingthe present study results with literature, there is a good agreement in general. It is clear that the adsorption cooling system can be driven effctively by low grade heat sources such as, solar energy, waste heat energy, geothermal energy…etc.