International Journal of Renewable Energy Research-IJRER

This paper proposes a design of receiver of a scheffler dish solar concentrator which uses the phase change material to store the thermal energy. For this, water is used for direct steam generation from the receiver. The proposed model consists of a phase change material (PCM) present in between the inner and outer cylinder of the copper receiver. A binary mixture commonly known as solar salt (60% NaNO₃-40% KNO₃) is used as PCM for analysis. It helps to get rid of fluctuations due to sudden weather changes. Scheffler solar concentrator of 16 m² area with a fixed focus is used to concentrate the solar radiations to the receiver. The purpose of this study is to see the effect of PCM on steam generation and compare it with the results obtained without the use of solar salt in the receiver experimentally as well as numerically using Finite Element Method. Numerical analysis was performed using Transient thermal analysis in Ansys-16 and experimental investigations were performed. Results showed that the use of PCM in the receiver not only increases the mass flow rate of the steam but also  the duration of steam generation by storing the thermal energy.

George W. Crabtree and Nathan S. Lewis, Physics Today Online vol. 60, March 2007, pages 37-42.

Malayeri, M.R & Zunft, S & Eck, M, 2004. "Compact field separators for the direct steam generation in parabolic trough collectors: An investigation of models," Energy, Elsevier, vol. 29(5), pages 653-663.

Kabir, Ehsanul, et al., 2018, “Solar energy: Potential and future prospectsâ€, Renewable and Sustainable Energy Reviews 82 (2018), pp. 894–900.

P. A. Galione, C. D. Perez-Segarra, I. Rodriguez, O. Lehmkuhl and J. Rigola, “A new thermocline-PCM thermal storage concept for CSP plants. Numerical analysis and perspectives,†Energy Procedia, no. 49, pp. 790–799, 2013.

Cristina Prieto, Alfonso Rodríguez, David Patiño, Luisa F, Cabeza, "Thermal energy storage evaluation in direct steam generation solar plants", Solar Energy, Volume 159, 1 January 2018, Pages 501-509.

Anita A. Nene, S. Ramachandran," Numerical and Experimental Investigation of Scheffler Concentrator Receivers for Steam Generation Rate Under Different Operating Conditions "IJRER, Vol.7, No.4, 2017.

Lan Xiao, Shung Ying,Wu, You Rong Li†Effect of cavity wall temperature and opening ratio on the natural convection Heat loss characteristics of a solar cavity receiver†Computer Distributed control and intelligent Environmental monitoring (CDCIEM), Changsha, china,1112-1115, 19-20 Feb 2011.

Jianbin Fang,JinJia Wei, XunWei Dong “Acalculation Method for evaluating Thermal loss for cavity receiver†Power and Energy Engineering conference, Wuhan, China, 27-31 March 2009.

Sarihassoun Zakaria, Aliune Khaled, Henaoui Mustapha “Experimental study of a flat plate solar collector equipped with concentratorsâ€, International Journal of Renewable Energy Research, vol7, no3, pp.1028-1031,2017.

MOSBAH charaf Abdelkarim, TAD JINE Mohmed, CHAKIR Messaond, BOUCHERIT Mohmad seghir “On the control of parabolic solar concentrator : The zipper approach †International Journal of Renewable Energy Research, vol6, no3, pp.1101-1108,2016.

Kearney D., Herrmann U., Nava P., Kelly B., Mahoney R., Pacheco J., Cable R., Potrovitza N., 2 D., Price H.: Assessment of a molten salt heat transfer fluid in a parabolic trough solar field, J. of Solar Energy Eng., Vol. 121 (2003), pp. 170–176.

Peng Zhang, Jinhui Cheng, Yuan Jin, Xuehui An," Evaluation of thermal physical properties of molten nitrate salts with low melting temperature" Elsevier ,Solar Energy Materials and Solar Cells, Volume 176, March 2018, Pages 36-41.

Nexant Inc., 2001, ‘‘USA Trough Initiative: Nitrate Salt HTF Rankine Cycle, Steam Generator, and Thermal Storage Analyses,’’ prepared for NREL.

Pacheco, J. E., Showalter, S., and Kolb, W., 2001, ‘‘Development of a Molten Salt Thermocline Thermal Storage System for Parabolic Trough Plants,’’ Solar Forum 2001, Washington, DC.

A. Munir , O. Hensel ,W. Scheffler, Design Principle and Calculations of A Scheffler Fixed Focus Concentrator For Medium Temperature Applications, Solar Energy 84 (2010) 1490–1502.