DOUBLE-EFFECT SOLAR ABSORPTION THERMAL ENERGY STORAGE

Authors

  • R.A. Rasih R.A. Rasih Faculty of Mechanical Engineering, Universiti Teknologi Mara Pulau Pinang, 13500 Permatang Pauh, Pulau Pinang
  • F.N. An F.N. An Faculty of Mechanical Engineering, Universiti Teknologi Malaysia, 81310 Johor Bahru, Johor

Keywords:

Solar absorption, lithium bromide-water, double-effect, equilibrium generator temperature, simulation.

Abstract

Solar radiation is a clean and renewable form of energy, which is required to be the main source of natural processes. Solar absorption refrigeration system (SARS) uses free source of energy when compared to the conventional electrical sources. This paper presents the SARS that is designed using meteorological data from Kuala Terengganu on 2004. The area which is located at 5°10’N latitude and 103°06’E longitude does experience a relative “dry season†from April through June, while the heaviest precipitation is seen at the end of the year, in November and December. The purpose of this project is to determine the performance of double-effect absorption chiller using solar energy through simulation approach. Initially, three types of solar collector were chosen but evacuated tube was selected as the main work due to its high efficiency. Solar energy is absorbed by the evacuated tube solar collector and then transferred to the hot water storage tank. High-pressure generator is driven by hot water storage system. The modeling and simulation of SARS is carried out using Matlab software package. Using equilibrium low-pressure generator temperature approach, the results show that minimum reference temperature of 130oC is required to run the absorption chiller because the coefficient of performance (COP) will drop sharply below this temperature. Apart from that, the maximum COP of 1.2 is achieved at high-pressure generator temperature of 15oC. 5 m3 of hot water storage tank is required to achieve continuous operation of absorption chiller. The solar collector area was designed based on the solar fraction ranging from 50% to 90% monthly. The operational system for 100kW of refrigeration load in a year consists of 250 m2 evacuated tube solar collector sloped at 2o .

References

Charles, E. B. (2002). World Energy Resources. USA: Springer.

Hussin, M. H. (2010). An Evaluation Data of Solar Irradiation and Dry Bulb Temperature at Subang Under Malaysian Climate . IEEE Control and System Graduate Research Colloquium. Photovoltaic Monitoring Centre (PVMC), Faculty of Electrical Engineering, Universiti Teknologi Mara, Malaysia.

Sid, M., Mohammed, A., Ahmed, S., & Ihtsh, S. (2010). Parametric Analysis of a Double-Effect Steam Absorption Chiller. The 4th International Meeting of Advances in Thermofluids . Melaka, Malaysia.

Mittal V, K. K. (2006). Modelling and Simulation of a Solar Absorption Cooling System for India. Journal of Energy in Southern Africa, 17 (3).

Kim, D. I. (2009). Air-cooled LiBr–Water Absorption Chillers for Solar Air Conditioning in Extremely Hot Weathers. Energy Conversion and Management, 50, 1018-1025.

Balghouthi, M., Chahbanib, M., & A., G. (2008). Feasibility of Solar Absorption Air Conditioning in Tunisia. Building and Environment, 43, 1459-1470.

Assilzadeh, F., Kalogirou, S., Ali, Y., & Sopian, K. (2005). Simulation and Optimization of a LiBr Solar Absorption Cooling System with Evacuated Tube Collectors. Renewable Energy , 1143-1159.

Florides, G., Kalogirou, S., Tassou, S., & Wrobel, L. (2002). Modelling and Simulation of an Absorption Solar Cooling System for Cyprus.

Atmaca, I., & Yigit, A. (2003). Simulation of Solar Powered Absorption Cooling System. Renewable Energy 28: 1277-1293, 2003, 28, 1277-1293.

Simonson, J. (1984). Computing methods in solar heating design. Department of Mechanical Engineering, The City University London .

Duffie, J. A., & Beckman, W. A. (2006). Solar Engineering of Thermal Process. Solar Energy Laboratory, University of Wisconsion-Madison: John Wiley and Sons.

Liu, Y., & Wang, R. (2004). Performance Prediction of a Solar/Gas Driving Double Effect LiBr–H2O Absorption System . Renewable Energy, 29, 1677-1695.

ASHRAE. (2005). Fundamental.

Muzathik, A. M., Nik, W. M., Samo, K., & Ibrahim, Z. (2010). Reference Solar Radiation Year and SOme Climatology Aspects of East Coast of West Malaysia. American J. of Engineering and Applied Sciences , 3 (2), 293-299.

Yakup, M., & Malik, A. (2001). Optimum Tilt Angle and Orientation for Solar Collector in Brunei Darussalam. Renewable Energy, 24, 223-234.

Siraki, A. G., & Pillay, P. (2012). Study of Optimum Tilt Angles for Solar Panels in Different Latitudes for Urban Applications. Solar Energy .

Lim, C., Sopian, K., & Sulaiman, Y. (2009). An Overview of Solar Assisted AirConditioning System Application in Small Office Buildings in Malaysia. Proceedings of the 4th IASME / WSEAS International Conference on Energy and Environment, (pp. 244-251). Solar Energy Research Institute, University Kebangsaan Malaysia, Malaysia.

Grossman, G. (2002). Solar Powered System for Cooling, Dehumidification, and Air-Conditioning. Solar Energy Journal, 72, 53-63.

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Published

2018-04-02

How to Cite

R.A. Rasih, R. R., & F.N. An, F. A. (2018). DOUBLE-EFFECT SOLAR ABSORPTION THERMAL ENERGY STORAGE. Jurnal Mekanikal, 35(2). Retrieved from https://jurnalmekanikal.utm.my/index.php/jurnalmekanikal/article/view/70

Issue

Issue 35: December 2012

Section

Mechanical

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Copyright of articles that appear in Jurnal Mekanikal belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions or any other reproductions of similar nature.

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