Analysis of a simulated flat plate solar collector system using solidworks flow simulator interface
Year 2020,
Volume: 2 Issue: 2, 121 - 128, 26.06.2020
Eghosa Omo-oghogho
,
Godwin Sadjere
Abstract
Abstract: One of the promising source of renewable energy is solar energy. Water heating by solar energy for domestic use is one of the most successful and feasible applications of solar energy. Other areas of application of solar energy include solar drying, electricity generation using photovoltaic cells, solar cooling and refrigeration, solar still (or solar distillation) and solar cooking. In this study flat plate solar collector was simulated, a temperature of 58^o C and an efficiency of 51% was achieved respectively. Solar radiation being abundantly present in Nigeria is one area of focus among the renewable energy resources and this can be harnessed for heating water for both domestic and industrial purposes.
References
- 5.0 REFERENCE
[1] Dimitrios P. (2001): Solar water heating systems study reliability, quantitative survey and life cost method, MSC. Thesis, Department of Mechanical Engineering, University of Strathelyde in Glasgow.
[2] Sopian, K., Syahri, M., Abdullah, S., Othman, M.Y. and B. Yatim, B (2004)” Performance of a non-metallic unglazed solar water heater with integrated storage system”, Renewable Energy, volume 29: pp 1421–1430.
- [3] Selmi, M., Al-Khawaja, M.J., and Marafia, A. (2008) “Validation of CFD simulation for flat plate solar energy collector” Renewable Energy, volume 33: pp 383-387.
- [4] Vettrivel, H and Mathiaragan, P (2013) Experimental Study on a Flat Plate Solar Collector, International Journal of Mechanical Engineering and Research, volume 3(6): pp 641-646.
- [5] Farahat, S., Sarhaddi, F. and Ajam H., (2009) "Exergetic optimization of flat plate solar collectors",Renewable Energy, volume 34, pp1169–1174.
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- [7] Garg, H.P. and Rani, U. (2016) Loss Coefficients from Solar Flat-Plate applied Energy, volume 7, pp 109 -117.
- [8]Agarwal, V.K. and Larson D.C. (200) Calculation of top heat loss coefficient of a flat-plate solar collector. Solar Energy, volume 27, pp 69-71.
- [9]. Anderson T., Duke M., and Carson J. (2010) The effect of color on the thermal performance of building integrated solar collectors, Solar Energy Materials and solar cells, volume 94, pp 350-354.
- [10] Duffie J. and Beckmann W. (2013) solar engineering of thermal processes, 3rd edition (Wiley
Interscience, New York).
Year 2020,
Volume: 2 Issue: 2, 121 - 128, 26.06.2020
Eghosa Omo-oghogho
,
Godwin Sadjere
References
- 5.0 REFERENCE
[1] Dimitrios P. (2001): Solar water heating systems study reliability, quantitative survey and life cost method, MSC. Thesis, Department of Mechanical Engineering, University of Strathelyde in Glasgow.
[2] Sopian, K., Syahri, M., Abdullah, S., Othman, M.Y. and B. Yatim, B (2004)” Performance of a non-metallic unglazed solar water heater with integrated storage system”, Renewable Energy, volume 29: pp 1421–1430.
- [3] Selmi, M., Al-Khawaja, M.J., and Marafia, A. (2008) “Validation of CFD simulation for flat plate solar energy collector” Renewable Energy, volume 33: pp 383-387.
- [4] Vettrivel, H and Mathiaragan, P (2013) Experimental Study on a Flat Plate Solar Collector, International Journal of Mechanical Engineering and Research, volume 3(6): pp 641-646.
- [5] Farahat, S., Sarhaddi, F. and Ajam H., (2009) "Exergetic optimization of flat plate solar collectors",Renewable Energy, volume 34, pp1169–1174.
- [6] Chamoli, S., (2013) Exergy analysis of a flat plate solar collector, Journal energy South. Afr., vol.24 no.3 Cape Town.
- [7] Garg, H.P. and Rani, U. (2016) Loss Coefficients from Solar Flat-Plate applied Energy, volume 7, pp 109 -117.
- [8]Agarwal, V.K. and Larson D.C. (200) Calculation of top heat loss coefficient of a flat-plate solar collector. Solar Energy, volume 27, pp 69-71.
- [9]. Anderson T., Duke M., and Carson J. (2010) The effect of color on the thermal performance of building integrated solar collectors, Solar Energy Materials and solar cells, volume 94, pp 350-354.
- [10] Duffie J. and Beckmann W. (2013) solar engineering of thermal processes, 3rd edition (Wiley
Interscience, New York).