Experimental Study Of Diffusion Absorption Refrigeration Systems Using Solar Energy
In this study, the performance of a diffusion
absorption refrigeration (DAR) system using solar energy is investigated
experimentally. For this purpose, two types of systems with/without sub-cooling
are used for the experiment. Two-phase closed thermosyphon type heat pipes
using water as the working fluid are used to utilize solar energy as heat
source. During the experiments; ambient temperature along with critical point
temperatures on DAR systems and heat pipes, DAR systems pressures and solar
radiation data are recorded from 06:00 to 16:00 and each heat pipe has
collected 82.5W of solar energy. DAR1 has achieved its lowest evaporator inlet
temperature (-14.8°C) at 14:40, and DAR2 has reached -0.9°C at 13:55. COP
values of DAR1 and DAR2 are found as 0.2362 and 0.2254. Efficiency of the heat
pipes used in DAR1 and DAR2 are 0.3677 and 0.3690, and their thermal resistance
values are 0.1154W/°C, 0.0828W/°C respectively.
Experimental Study Of Diffusion Absorption Refrigeration Systems Using Solar Energy
In this study, the performance of a diffusion
absorption refrigeration (DAR) system using solar energy is investigated
experimentally. For this purpose, two types of systems with/without sub-cooling
are used for the experiment. Two-phase closed thermosyphon type heat pipes
using water as the working fluid are used to utilize solar energy as heat
source. During the experiments; ambient temperature along with critical point
temperatures on DAR systems and heat pipes, DAR systems pressures and solar
radiation data are recorded from 06:00 to 16:00 and each heat pipe has
collected 82.5W of solar energy. DAR1 has achieved its lowest evaporator inlet
temperature (-14.8°C) at 14:40, and DAR2 has reached -0.9°C at 13:55. COP
values of DAR1 and DAR2 are found as 0.2362 and 0.2254. Efficiency of the heat
pipes used in DAR1 and DAR2 are 0.3677 and 0.3690, and their thermal resistance
values are 0.1154W/°C, 0.0828W/°C respectively.
___
- [1] Von Platen B.C., Munters C.G., “Refrigerator”, US Patent, 1: 685-764, (1928).
- [2] Sözen A., Özbaş E., Menlik T., İskender Ü., Kılınç C., Çakır M.T., “Performance investigation of a diffusion absorption refrigeration system using nano-size alumina particles in the refrigerant”, International Journal of Exergy, 18(4): 443-461, (2015).
- [3] Sözen A., Özbaş E., Menlik T., Çakır M.T., Gürü M., Boran K., “Improving the thermal performance of diffusion absorption refrigeration system with alumina nanofluids: An experimental study”, International Journal of Refrigeration, 44: 73-80, (2014).
- [4] Sözen A., Menlik T., Özbaş E., “The effect of ejector on the performance of diffusion absorption refrigeration systems: An experimental study”, Applied Thermal Engineering, 33(34): 44-53, (2012).
- [5] Zohuri B., “Heat Pipe Design and Technology”, CRC Press, (2011).
- [6] Vasiliev L.L., Kakac S., “Heat pipe and solid sorption transformation, fundamentals and practical applications”, Taylor&Francis Group, LLC, (2013).
- [7] Zohar A., Jelinek M., Levy A., Borde I., “The influence of diffusion absorption refrigeration cycle configuration on the performance”, Applied Thermal Engineering, 27(13): 2213-2219, (2007).
- [8] Faghri A., “Heat Pipe Science and Technology”, Taylor & Francis, Washington, DC, (1995).
- [9] Jafari D., Franco A., Filippeschi S., Di Marco P., “Two-phase closed thermosyphons: A review of studies and solar applications”, Renewable and Sustainable Energy Reviews, 53: 575-593, (2016).