IEA Solar Heating and Cooling Programm - NachhaltigWirtschaften.at
IEA Solar Heating and Cooling Programm - NachhaltigWirtschaften.at IEA Solar Heating and Cooling Programm - NachhaltigWirtschaften.at
IEA SHC Task 38 Solar Air Conditioning and Refrigeration Subtask C1 Report, 31 October 2010 42250 Konya Turkey Researcher: H. Kursad Ersoy e-mail: kersoy@selcuk.edu.tr 7. National Taiwan University Department of Mechanical Engineering No.1 Roosevelt Rd. Sec 4 Taipei, Taiwan 106 Taiwan Researcher: Bin-Juine Huang e-mail: bjhuang@seed.net.tw 7.4 References [181] Wimolsiri Pridasawas, Solar-Driven Refrigeration Systems with Focus on the Ejector Cycle, Doctoral Thesis, School of Industrial Engineering and Management – Royal Institute of Technology KTH, Stockholm, 2006. [182] Kakabaev, A., Davletov, A., A Freon Ejector Solar Cooler, Geliotekhnika, Vol. 2, No. 5, pp. 42-48,. AS Turkmen SSR,1966. [183] Huang, B.J., Petrenko, V.A., Chang, J.M., Zhuk, K.B., A High-Performance Solar Ejector Cooling System, Department of Mechanical Engineering, National Taiwan University, Taipei, Taiwan/Odessa State Academy of Refrigeration, Odessa, Ukraine, 2000. [184] Huang, B.J., Petrenko, V.A., A combined Ejector Cooling and hot water supply system using solar and waste heat energy, Department of Mechanical Engineering, National Taiwan University, Taipei, Taiwan/Odessa State Academy of Refrigeration, Odessa, Ukraine, 2000. [185] Wolpert, J.L., Riffat, S.B., Hybrid Solar/Gas Cooling Ejector Unit for a Hospital in Mexico, http://www.kenes.com/ises.abstracts/Htm/0171.htm, Institute of Building Technology, School of the Built Environment, University of Nottingham, Great Britain, 1999. [186] Pollerberg, C. Ali, A.H.H., Dötsch, C: Solar driven steam jet ejector, Applied Thermal Engineering 29, pp. 1245–1252, 2009. [187] Pollerberg C., Jaehnig D., Doetsch C., Prototype of a Solar Driven Steam Jet Ejector Chiller, Proceedings of the 3rd International Conference on Solar Air-Conditioning, Palermo, 30.09- 2.10.09, ISBN 978-3-941758-06-9, 2009. [188] Anderson, H., Assessment of solar powered Vapor Jet Air-Conditioning Systems, Proc. Int. Solar Energy Congress and Exposition (ISES), UCLA, Los Angeles, Ca, pp. 408- 409. USA, 1975. [189] Zhadan, S., Z., Shchetinina, N., A., Selection of cycle Design Parameters for Solar Ejector Freon Refrigeration Machine (SEFRM), Geliotekhnika, Vol. 16, No.1, pp. 44-47, 1977. [190] Sokolov, M., Hershgal, D., Solar-Powered Compression-enhanced Ejector Air Conditioner, Solar Energy Vol. 51, No. 6, pp. 183-194, 1993. [191] Petrenko, V., A., Bulavin, I., V., Samofatov, I., YA., Investigation of the Methods increasing the efficiency of solar ejector cooling and refrigeration systems, Department of Mechanical Engineering, National Taiwan University, Taipei, Taiwan/Odessa State Academy of Refrigeration, Odessa, Ukraine, 2000. [192] Vidal, H., Colle, S., Pereira, G. dos S., Modelling and hourly simulation of a solar ejector cooling system, Applied Thermal Engineering 26, pp. 663-672, 2006. page 73
IEA SHC Task 38 Solar Air Conditioning and Refrigeration Subtask C1 Report, 31 October 2010 [193] Riffat, S., et al., Study of a gas-liquid ejector and its application to a solar-powered biejector refrigeration system, Applied Thermal Engineering, Vol. 25, pp. 2891-2902, 2005. [194] Khattab, N.M., Barakat, M.H., Modelling the design and performance characteristics of solar steam-jet cooling for comfort air conditioning, Solar Energy, Vol. 73, pp. 257-267, 2002. [195] Hemidi, A., et al., Designing and Rating a Tritherm Solar Ejector System for Residential Cooling, Proceedings of the EUROSUN 2008, 1 st International Conference on Solar Heating, Cooling and Buildings, 7 th to 10 th October Lisbon – Portugal, ISBN 978-972- 95854-7-0, 2008. [196] Ersoy, H.K., et al., Performance of a solar ejector cooling-system in the southern region of Turkey, Applied Energy, Vol. 84, pp. 971-983, 2007. [197] Colle, S., et al., On the validity of a design method for a solar-assisted ejector cooling system, Solar Energy, Vol. 83, pp. 139-149, 2009. [198] Vidal, H., et al., Modelling and hourly simulation of a solar ejector cooling system, Applied Thermal Engineering, Vol. 26, pp. 663-672, 2006. [199] Guo, J., Shen, H.G., Modelling solar-driven ejector refrigeration system offering air conditioning for office buildings, Energy and Building, Vol. 41, pp. 175-181, 2009. [200] Alexis, G.K., Karayiannis, E.K., A solar ejector cooling system using refrigerant R134a in the Athens area, Renewable Energy, Vol. 30, pp. 1457-1469, 2005. [201] Abdulateef, J.M., Alghoul, M.A., et al., Review on solar-driven ejector refrigeration technologies, Renewable and Sustainable Energy Review, Vol. 13, pp. 1338-1349, 2009. page 74
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<strong>IEA</strong> SHC Task 38 <strong>Solar</strong> Air Conditioning <strong>and</strong> Refriger<strong>at</strong>ion Subtask C1 Report, 31 October 2010<br />
[193] Riff<strong>at</strong>, S., et al., Study of a gas-liquid ejector <strong>and</strong> its applic<strong>at</strong>ion to a solar-powered biejector<br />
refriger<strong>at</strong>ion system, Applied Thermal Engineering, Vol. 25, pp. 2891-2902,<br />
2005.<br />
[194] Kh<strong>at</strong>tab, N.M., Barak<strong>at</strong>, M.H., Modelling the design <strong>and</strong> performance characteristics of<br />
solar steam-jet cooling for comfort air conditioning, <strong>Solar</strong> Energy, Vol. 73, pp. 257-267,<br />
2002.<br />
[195] Hemidi, A., et al., Designing <strong>and</strong> R<strong>at</strong>ing a Tritherm <strong>Solar</strong> Ejector System for Residential<br />
<strong>Cooling</strong>, Proceedings of the EUROSUN 2008, 1 st Intern<strong>at</strong>ional Conference on <strong>Solar</strong><br />
<strong>He<strong>at</strong>ing</strong>, <strong>Cooling</strong> <strong>and</strong> Buildings, 7 th to 10 th October Lisbon – Portugal, ISBN 978-972-<br />
95854-7-0, 2008.<br />
[196] Ersoy, H.K., et al., Performance of a solar ejector cooling-system in the southern region<br />
of Turkey, Applied Energy, Vol. 84, pp. 971-983, 2007.<br />
[197] Colle, S., et al., On the validity of a design method for a solar-assisted ejector cooling<br />
system, <strong>Solar</strong> Energy, Vol. 83, pp. 139-149, 2009.<br />
[198] Vidal, H., et al., Modelling <strong>and</strong> hourly simul<strong>at</strong>ion of a solar ejector cooling system,<br />
Applied Thermal Engineering, Vol. 26, pp. 663-672, 2006.<br />
[199] Guo, J., Shen, H.G., Modelling solar-driven ejector refriger<strong>at</strong>ion system offering air<br />
conditioning for office buildings, Energy <strong>and</strong> Building, Vol. 41, pp. 175-181, 2009.<br />
[200] Alexis, G.K., Karayiannis, E.K., A solar ejector cooling system using refrigerant R134a<br />
in the Athens area, Renewable Energy, Vol. 30, pp. 1457-1469, 2005.<br />
[201] Abdul<strong>at</strong>eef, J.M., Alghoul, M.A., et al., Review on solar-driven ejector refriger<strong>at</strong>ion<br />
technologies, Renewable <strong>and</strong> Sustainable Energy Review, Vol. 13, pp. 1338-1349,<br />
2009.<br />
page 74