Productivity Enhancement of Solar Still with PV Powered Heating Coil and Chamber Step-Wise Basin

• Autorzy: Abdallah S.

Identyfikatory

DOI

10.12911/22998993/81238

• Języki publikacji: EN

Abstrakty

EN

There is a strong need to improve the productivity of single slope solar still. PV generator powered electrical heater and chamber step-wise design were introduced to the conventional solar still. An experimental study was performed to investigate the effect of adding the above mentioned modifications on the output parameters of the modified solar still. The inclusion of PV-powered heating coil and chamber step-wise design enhanced the productivity of distiller by up to 1098%.

Słowa kluczowe

EN

solar still; chamber step-wise design; heating coil; PV

• Wydawca: Polskie Towarzystwo Inżynierii Ekologicznej ; Lublin University of Technology
• Czasopismo: Journal of Ecological Engineering
• Rocznik: 2018
• Tom: Vol. 19, nr 2
• Strony: 8--15
• Opis fizyczny: Bibliogr. 22 poz., tab., rys.

Twórcy

autor

Abdallah S.

• Mechanical and Industrial Engineering Department, Applied Science Private University, Amman, Jordan

Bibliografia

• 1. Abdallah S.M. and Badran O.O. 2008. Sun-traracking system for productivity enhancement of solar still, Desalination, 220, 669–676.
• 2. Abdallah S.M., Badran O.O. and Abu-Khader M.M. 2008. Performance evaluation of a modified design of a single slope solar still, Desalination, 219, 222–230.
• 3. Akash B.A., Mohsen M.S. and Nayfeh W. 2000. Experimental study of the basin type solar still under local climate conditions, Energy Conv. Manage., 41(9), 883–890.
• 4. Akash B.A., Mohsen M.S., Osta O. and Elayan Y. 1998. Experimental evaluation of a single-basin solar still using different absorbing materials, Renewable Energy, 14(1–4), 307–310.
• 5. Al-Hayek I. and Badran O.O. 2004. The effect of using different designs of solar stills on water distillation, Desalination, 169, 121–127.
• 6. Badran O.O. and Al-Tahaineh H.A. 2005. The effect of coupling a flat-plate collector on the solar still productivity, Desalination, 183, 137–142.
• 7. Badran O.O. and Abu-Khader M.M. 2007. Evaluating thermal performance of single slope solar stills. Heat Mass Transfer, 43(10), 985–995.
• 8. El-Agouz S.A. 2014. Experimental investigation of stepped solar still with continuous water circulation. Energy Conversion and Management 86, 186–193.
• 9. Goosen M.F.A., Sablani S.S., Shayya W.H., Paton C. and Al-Hinai H., 2000. Thermodynamic and economic considerations in solar desalination, Desalination, 129, 63–89.
• 10. Jitsuno T. and Hamabe K. 2012. Vacuum distillation system aiming to use solar-heat for desalination. Journal of Arid Land Studies, 22–1, 153–155.
• 11. Joseph J., Saravanan R. and Renganarayanan S., 2005. Studies on a single-stage solar desalination system for domestic applications, Desalination, 173, 77–82.
• 12. Kalogirou S.A., 2004. Solar thermal collectors and applications, Progr. Energy Combustion Sci., 30(3) 231–295.
• 13. Nafey A.S., Mohamad M.A., El-Helaby S.O. and Sharaf M.A., 2007. Theoretical and experimental study of a small unit for solar desalination using flashing process, Energy Conv. Manage., 48, 528–538.
• 14. Nijmeh S., Odeh S. and Akash B., 2005. Experimental and theoretical study of a single-basin solar sill in Jordan, Int Comm. Heat Mass Transfer, 32, 565–572.
• 15. Sathyamurthya R., Nagarajan P.K, Subramani J, Vijayakumar D.M., Ashraf A.K. 2014. Effect of water mass on triangular pyramid solar still using phase change material as storage medium. Energy Procedia 61, 2224–2228.
• 16. Suleiman M. and Tarawneh K. 2007. Effect of Water Depth on the Performance Evaluation of Solar Still. JJMIE. 1, 23–29.
• 17. Tanaka H. and Nakatake Y. 2006. Theoretical analysis of a basin type solar still with internal and external reflectors, Desalination, 186, 280–299.
• 18. Tiwari G.N., 2002. Solar Energy, Narosa Publishing House, New Delhi, India,.
• 19. Tiwari G.N., Kupfermann A. and Agrawal S. 1997. A new design for a double-condensing chamber solar still,Desalination, 114, 153.
• 20. Tripathi R. and Tiwari G.N. 2004. Performance evaluation of a solar still by using the concept of solar fractionation, Desalination, 169, 69–80.
• 21. Tripathi R. and Tiwari G.N. 2006. Thermal modeling of passive and active solar stills for different depths of water by using the concept of solar fraction, Int. J. Solar Energy, 80(8), 956–967.
• 22. Yadav Y.P. and Yadav S.K. 2004, Parametric studies on the transient performance of a high-temperature solar distillation system, Desalination, 170, 251–262.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).