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Experimental investigation of a Scheffler reflector for the medium temperature applications

Year 2021, , 1302 - 1314, 01.07.2021
https://doi.org/10.18186/thermal.978197

Abstract

This research problem reveals the experimental investigation at a pressure of 1.5 bar and temperature of 120°C for the medium thermal applications utilizing the four Scheffler reflectors with 16 m2 surface area each. The Scheffler collector associated with absorber plate of mild steel of size, 0.45 m diameter, and 0.025 m thick was assessed in June 2018. The variation in solar beam radiation over the entire day was observed from 840 W/m2 to 1278 W/m2, while, the absorber plate temperature was recorded within the extent of 116–195°C, however, the maximum heating temperature was measured 129°C at the end-use. The Scheffler collectors performed appropriately in the morning and evening time with substantial heat loss factor and lower optical efficiency factor. The energy efficiency of 59.28% has been achieved which is higher as compared to the parabolic solar concentrator. The higher concentration ratio of the Scheffler collector indicates it as an efficient substitute to replace fossil fuels. The system is viable for more than 1600 kWh/m2 yearly solar potential while the cost of heating is greater than 0.05 $/kWh for them. This paper concludes that the Scheffler reflector is the most promising solar technology for the medium-temperature applications.

References

  • [1] Scheffler, W. Introduction to the revolutionary design of Scheffler reflectors, In: SCIs International Solar Cooker Conference, Granada, Spain.
  • [2] Scheffler, W. (2006b). Development of a solar crematorium, International conference on Solar Cooker, Spain, Germany, July 15-16.
  • [3] Patil, R. J., Gajanan, K. A., & Singh, M. P. (2011). Comparison of performance analysis of Scheffler reflector and model formulation. Indian Journal of Science and Technology, 4 (10), 1335-1339.
  • [4] Ulrich, O., & Scheffler, W. (1994). The use of indigenous materials for solar conversion. Solar Energy Materials & Solar Cells, 33, 379- 438.
  • [5] Kalogirou, S. (2003). Potential of solar industrial process heat applications. Applied Energy, 76, 337–361.
  • [6] Bhirud, N., & Tandale, M. S. (2006). Field evaluation of a fixed-focus concentrators for industrial oven. Advanced in Energy Resources (AER).
  • [7] Delaney, D. (2003). Scheffler’s community solar cooker. <http://www.solar-bruecke.org>.
  • [8] Kumar, N. S., & Reddy, K. S. (2007). Numerical investigation of natural convection heat loss in modified cavity receiver for fuzzy focal solar dish concentrator. Solar Energy, 81, 846–855.
  • [9] Desale, D. C., Jain, S. C., & Sharma, P. K. (2014). Performance Analysis of Scheffler Reflector Using Approximate Generalized Model. International Journal of Emerging Trends in Engineering and Development, 4(6), 242-253.
  • [10] Chandak, A. J., & Somani, S. M. (2016). Industrial oven powered with a pair of Scheffler solar concentrators. Proceedings of International conference on Solar cooking and food process, Indore, India, 14-16.
  • [11] Chandak, A. J., Somani, S. M., & Dubey, D. (2009). Design, Development and Testing of Multi-effect Distiller/Evaporator Using Scheffler Solar Concentrators. Journal of Engineering Science and Technology, 4(3), 315-321.
  • [12] Munir, A., & Hensel, O. (2010). Investigation of optimal thermal parameters for essential oils extraction using laboratory and solar distillation systems. CIGR Journal, 12(1), 1332-1337.
  • [13] Folaranmi, J. (2009). Design, Construction and Testing of a Parabolic Solar Steam Generator. Leonardo Electronic Journal of Practices and Technology, 14, 1-7, ISSN 1583-1078.
  • [14] Afzal, A. A., Munir, A. J., Ghafoor, A. D., & Alvardo, A. A. (2017). Development of hybrid distillation system for essential oil extraction. Renewable Energy, 113, 22-29.
  • [15] Helal, O., Chaouachi, B., & Gabsi, S. (2010). Development and performance analysis of an integrated collector storage solar water heater. Proceedings of International Renewable Energy Congress Sousse, Tunisia, 87-93.
  • [16] Ouedernil, A. R. El., Salah, M. B., Askri, F., Nasrallah, M. B., & Aloui, F. (2009). Experimental study of a parabolic solar concentrator. Revue Des Energies Renouvelables 12(3), 395-404.
  • [17] Munir, A., Hensel, O., & Scheffler, W. (2010). Design Principal and Calculations of a Scheffler fixed focus concentrator for medium temperature applications. Solar Energy, 84, 1490-1502.
  • [18] Jayasimha, B. K. (2006). Application of Scheffler reflectors for process industry. In: International Solar Cooker Conference, Granada, Spain.
  • [19] J. Duffie, W. A. Beckman, Solar Engineering of Thermal Processes. Third edition, John Wiley & Sons, Inc., Hoboken, New Jersey, 2006.
  • [20] Pavlovic, S., Bellos, E., Le Roux, W. G., Stefanovic, V., & Tzivanidis, C. (2017). Experimental investigation and parametric analysis of a solar thermal dish collector with spiral absorber. Applied Thermal Engineering, 121, 126-135.
  • [21] Kumar, S., & Mullick, S. C. (2012). Glass cover temperature and top heat loss coefficient of a single glazed flat plate collector with nearly vertical configuration. Ain Shams Engineering Journal, 3, 299–304.
  • [22] Paitoonsurikarn, S., Taumoefolau, T., & Lovegrove, K. (2004). Estimation of convection loss from paraboloidal dish cavity receivers. In: Proceedings of 42nd conference of the Australia and New Zealand solar energy society (ANZSES), Perth, Australia.
  • [23] Islam, M.T., Huda, N., & Abdullah, A.B. (2018). A comprehensive review of state-of-the-art concentrating solar power (CSP) technologies: Current status and research trends. Renewable and Sustainable Energy Reviews, 91, 987–1018.
  • [24] Stefanovic, V.P., Pavlović S.R., & Bellos E. (2018). A detailed parametric analysis of a solar dish collector. Sustainable Energy Technologies and Assessments, 25, 99–110.
  • [25] Reddy, D.S., Khan, M.K., & Alam, M.Z. (2018). Design charts for Scheffler reflector. Solar Energy, 163, 104–112.
  • [26] Indora, S., & Kandpal, T. C. (2019). A framework for analyzing impact of potential financial/fiscal incentives for promoting institutional solar cooking in India. Renewable Energy, 143, 1531–1543.
  • [27] Aramesh, M., Ghalebani, M., Kasaeian, A., Zamani, H., Lorenzini, G., & Mahian, O. (2019). A review of recent advances in solar cooking technology. Renewable Energy, 140, 419–435.
  • [28] Wang, L., Yuan, Z., Zhao, Y., & Guo, Z. (2019). Review on Development of Small Point-Focusing Solar Concentrators. Journal of Thermal Science, 28 (5), 929–947.
Year 2021, , 1302 - 1314, 01.07.2021
https://doi.org/10.18186/thermal.978197

Abstract

References

  • [1] Scheffler, W. Introduction to the revolutionary design of Scheffler reflectors, In: SCIs International Solar Cooker Conference, Granada, Spain.
  • [2] Scheffler, W. (2006b). Development of a solar crematorium, International conference on Solar Cooker, Spain, Germany, July 15-16.
  • [3] Patil, R. J., Gajanan, K. A., & Singh, M. P. (2011). Comparison of performance analysis of Scheffler reflector and model formulation. Indian Journal of Science and Technology, 4 (10), 1335-1339.
  • [4] Ulrich, O., & Scheffler, W. (1994). The use of indigenous materials for solar conversion. Solar Energy Materials & Solar Cells, 33, 379- 438.
  • [5] Kalogirou, S. (2003). Potential of solar industrial process heat applications. Applied Energy, 76, 337–361.
  • [6] Bhirud, N., & Tandale, M. S. (2006). Field evaluation of a fixed-focus concentrators for industrial oven. Advanced in Energy Resources (AER).
  • [7] Delaney, D. (2003). Scheffler’s community solar cooker. <http://www.solar-bruecke.org>.
  • [8] Kumar, N. S., & Reddy, K. S. (2007). Numerical investigation of natural convection heat loss in modified cavity receiver for fuzzy focal solar dish concentrator. Solar Energy, 81, 846–855.
  • [9] Desale, D. C., Jain, S. C., & Sharma, P. K. (2014). Performance Analysis of Scheffler Reflector Using Approximate Generalized Model. International Journal of Emerging Trends in Engineering and Development, 4(6), 242-253.
  • [10] Chandak, A. J., & Somani, S. M. (2016). Industrial oven powered with a pair of Scheffler solar concentrators. Proceedings of International conference on Solar cooking and food process, Indore, India, 14-16.
  • [11] Chandak, A. J., Somani, S. M., & Dubey, D. (2009). Design, Development and Testing of Multi-effect Distiller/Evaporator Using Scheffler Solar Concentrators. Journal of Engineering Science and Technology, 4(3), 315-321.
  • [12] Munir, A., & Hensel, O. (2010). Investigation of optimal thermal parameters for essential oils extraction using laboratory and solar distillation systems. CIGR Journal, 12(1), 1332-1337.
  • [13] Folaranmi, J. (2009). Design, Construction and Testing of a Parabolic Solar Steam Generator. Leonardo Electronic Journal of Practices and Technology, 14, 1-7, ISSN 1583-1078.
  • [14] Afzal, A. A., Munir, A. J., Ghafoor, A. D., & Alvardo, A. A. (2017). Development of hybrid distillation system for essential oil extraction. Renewable Energy, 113, 22-29.
  • [15] Helal, O., Chaouachi, B., & Gabsi, S. (2010). Development and performance analysis of an integrated collector storage solar water heater. Proceedings of International Renewable Energy Congress Sousse, Tunisia, 87-93.
  • [16] Ouedernil, A. R. El., Salah, M. B., Askri, F., Nasrallah, M. B., & Aloui, F. (2009). Experimental study of a parabolic solar concentrator. Revue Des Energies Renouvelables 12(3), 395-404.
  • [17] Munir, A., Hensel, O., & Scheffler, W. (2010). Design Principal and Calculations of a Scheffler fixed focus concentrator for medium temperature applications. Solar Energy, 84, 1490-1502.
  • [18] Jayasimha, B. K. (2006). Application of Scheffler reflectors for process industry. In: International Solar Cooker Conference, Granada, Spain.
  • [19] J. Duffie, W. A. Beckman, Solar Engineering of Thermal Processes. Third edition, John Wiley & Sons, Inc., Hoboken, New Jersey, 2006.
  • [20] Pavlovic, S., Bellos, E., Le Roux, W. G., Stefanovic, V., & Tzivanidis, C. (2017). Experimental investigation and parametric analysis of a solar thermal dish collector with spiral absorber. Applied Thermal Engineering, 121, 126-135.
  • [21] Kumar, S., & Mullick, S. C. (2012). Glass cover temperature and top heat loss coefficient of a single glazed flat plate collector with nearly vertical configuration. Ain Shams Engineering Journal, 3, 299–304.
  • [22] Paitoonsurikarn, S., Taumoefolau, T., & Lovegrove, K. (2004). Estimation of convection loss from paraboloidal dish cavity receivers. In: Proceedings of 42nd conference of the Australia and New Zealand solar energy society (ANZSES), Perth, Australia.
  • [23] Islam, M.T., Huda, N., & Abdullah, A.B. (2018). A comprehensive review of state-of-the-art concentrating solar power (CSP) technologies: Current status and research trends. Renewable and Sustainable Energy Reviews, 91, 987–1018.
  • [24] Stefanovic, V.P., Pavlović S.R., & Bellos E. (2018). A detailed parametric analysis of a solar dish collector. Sustainable Energy Technologies and Assessments, 25, 99–110.
  • [25] Reddy, D.S., Khan, M.K., & Alam, M.Z. (2018). Design charts for Scheffler reflector. Solar Energy, 163, 104–112.
  • [26] Indora, S., & Kandpal, T. C. (2019). A framework for analyzing impact of potential financial/fiscal incentives for promoting institutional solar cooking in India. Renewable Energy, 143, 1531–1543.
  • [27] Aramesh, M., Ghalebani, M., Kasaeian, A., Zamani, H., Lorenzini, G., & Mahian, O. (2019). A review of recent advances in solar cooking technology. Renewable Energy, 140, 419–435.
  • [28] Wang, L., Yuan, Z., Zhao, Y., & Guo, Z. (2019). Review on Development of Small Point-Focusing Solar Concentrators. Journal of Thermal Science, 28 (5), 929–947.
There are 28 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Articles
Authors

Anil Kumar This is me 0000-0003-1681-0297

Publication Date July 1, 2021
Submission Date September 13, 2019
Published in Issue Year 2021

Cite

APA Kumar, A. (2021). Experimental investigation of a Scheffler reflector for the medium temperature applications. Journal of Thermal Engineering, 7(5), 1302-1314. https://doi.org/10.18186/thermal.978197
AMA Kumar A. Experimental investigation of a Scheffler reflector for the medium temperature applications. Journal of Thermal Engineering. July 2021;7(5):1302-1314. doi:10.18186/thermal.978197
Chicago Kumar, Anil. “Experimental Investigation of a Scheffler Reflector for the Medium Temperature Applications”. Journal of Thermal Engineering 7, no. 5 (July 2021): 1302-14. https://doi.org/10.18186/thermal.978197.
EndNote Kumar A (July 1, 2021) Experimental investigation of a Scheffler reflector for the medium temperature applications. Journal of Thermal Engineering 7 5 1302–1314.
IEEE A. Kumar, “Experimental investigation of a Scheffler reflector for the medium temperature applications”, Journal of Thermal Engineering, vol. 7, no. 5, pp. 1302–1314, 2021, doi: 10.18186/thermal.978197.
ISNAD Kumar, Anil. “Experimental Investigation of a Scheffler Reflector for the Medium Temperature Applications”. Journal of Thermal Engineering 7/5 (July 2021), 1302-1314. https://doi.org/10.18186/thermal.978197.
JAMA Kumar A. Experimental investigation of a Scheffler reflector for the medium temperature applications. Journal of Thermal Engineering. 2021;7:1302–1314.
MLA Kumar, Anil. “Experimental Investigation of a Scheffler Reflector for the Medium Temperature Applications”. Journal of Thermal Engineering, vol. 7, no. 5, 2021, pp. 1302-14, doi:10.18186/thermal.978197.
Vancouver Kumar A. Experimental investigation of a Scheffler reflector for the medium temperature applications. Journal of Thermal Engineering. 2021;7(5):1302-14.

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