• International Journal of Technology (IJTech)
  • Vol 6, No 4 (2015)

Numerical Simulation of a Two-bed Solar-driven Adsorption Chiller in a Tropical Climate

Numerical Simulation of a Two-bed Solar-driven Adsorption Chiller in a Tropical Climate

Title: Numerical Simulation of a Two-bed Solar-driven Adsorption Chiller in a Tropical Climate
Nasruddin , Lemington , Muhammad Idrus Alhamid

Corresponding email:


Published at : 27 Oct 2015
Volume : IJtech Vol 6, No 4 (2015)
DOI : https://doi.org/10.14716/ijtech.v6i4.1333

Cite this article as:

Nasruddin, Lemington, Alhamid, M.I., 2015. Numerical Simulation of a Two-bed Solar-driven Adsorption Chiller in a Tropical Climate. International Journal of Technology. Volume 6(4), pp. 594-603



821
Downloads
Nasruddin Department of Mechanical Engineering, Faculty of Engineering, Universitas Indonesia, Kampus Baru UI Depok, Depok 16424, Indonesia
Lemington Department of Mechanical Engineering, Faculty of Engineering, Universitas Indonesia, Kampus Baru UI Depok, Depok 16424, Indonesia
Muhammad Idrus Alhamid Department of Mechanical Engineering, Faculty of Engineering, Universitas Indonesia, Kampus Baru UI Depok, Depok 16424, Indonesia
Email to Corresponding Author

Abstract
Numerical Simulation of a Two-bed Solar-driven Adsorption Chiller in a Tropical Climate

Cooling systems in tropical countries consume a large part of energy usage in a building, especially in a tropical climate, which places a high demand on cooling systems throughout the year. This paper presents a simulation of a two-bed silica gel-water adsorption chiller, utilizing solar energy based in the tropical climate of Indonesia. The adsorption chiller is being mathematically modelled and calculated numerically using MATLAB®. The simulation is used to show the performance of the chiller during the working hours, based on maximum and minimum inputs of solar irradiation in Indonesia Furthermore, mass recovery and heat recovery is also applied in the adsorption cycle in order to increase the cooling capacity. The adsorption chiller is based on the most recent chiller developed by Shanghai Jiao Tong University (SJTU). The simulation results generally demonstrated the running characteristics of the chiller under a range of different values of solar radiation. Furthermore, the simulation results in detail showed that during the maximum value of irradiation, the average value of COP can reach 0.26, while during the minimum value of irradiation the COP is 0.15. At the same time, the cooling capacity is also varied which can reach up to the maximum value of 37.8 kW, whereas in the minimum range of irradiation values, the cooling capacity dropped to 5.3 kW.

Adsorption chiller, Indonesia climate, Silica gel

References

Chua, H.T., Ng, K.C., Malek, A., Kashiwagi, T., Akisawa, A., Saha, B.B., 1999. Modelling the Performance of Two-bed, Silica Gel-water Adsorption Chillers. International Journal of Refrigeration, Volume 22, pp. 194-204

Di, J., Wu, J.Y., Xia, Z.Z., Wang, R.Z., 2007. Theoretical and Experimental Study on Characteristics of Novel Silica Gel-water Chiller under the Conditions of Variable Heat Source Temperature. International Journal of Refrigeration, Volume 30, pp. 515?526

Fernandes, M.S., Brites, G.J.V.N., Costa, J.J., Gaspar, A.R., Costa, V.A.F., 2014. Review and Future Trends of Solar Adsorption Refrigeration System. Renewable and Sustainable Energy Reviews, Volume 39, pp. 102-123

Jacobs, G., 2010. Training Course on Renewable Energy Part II, MEMR-CASINDO, Jakarta 14-18 June 2010

Miyazaki, T., Akisawa, A., Saha, B.B., El-Sharkawy, I.I., Chakraborty, A., 2009. A New Cycle Time Allocation for Enhancing the Performance of Two-bed Adsorption Chillers. International Journal of Refrigeration, Volume 32, pp. 864-853

Pan, Q.W., Wang, R.Z., Wang, L.W., Liu, D., 2014. Design and Experimental Study of Adsorption Chiller with Module Type Adsorber. In: Proceedings of the International Conference of Solar Heating and Cooling for Building and Industry, SHC 2014, Beijing, 13-15 October 2014

Saha, B.B., Boelman, E.C., Kashiwagi, T., 1995. Computational Analysis of an Advance Adsorption- refrigeration Cycle. Energy, Volume 10, pp. 983-994

Wang, D., Zhang, J., Tian, X., Liu, D., Sumathy, K., 2013. Progress in Silica Gel–water Adsorption Refrigeration Technology. Renewable and Sustainable Energy Reviews, Volume 30, pp. 85–104

Wang, D.C., Xia, Z.Z., Wu, J.Y., Wang, R.Z., Zhai, H., Dou, W.D., 2005. Study of a Novel Silica Gel-water Adsorption Chiller. Part I: Design and Performance Prediction. International Journal of Refrigeration, Volume 28, pp. 1073-1083

Wang, R., Wang, L., Wu, J., 2006. Adsorption Refrigeration – An Efficient Way to Make Good Use of Waste Heat and Solar Energy. Progress in Energy and Combustion Science, Volume 32, pp. 424-458

Wang, R., Wang, L., Wu, J., 2014. Adsorption Refrigeration Technology Theory and Application, Singapore: John Wiley and Sons Pte. Ltd

Zhang, G., Wang, D.C., Zhang, J.P., Han, Y.P., Sun, W., 2011. Simulation of Operating Characteristic of the Silica Gel-water Adsorption Chiller Powered by Solar Energy. Solar Energy, Volume 85, pp. 1469-1478