Numerical Investigation of Hot Oil Velocity Effect on Force Heat Convection and Impact of Wind Velocity on Convection Heat Transfer in Receiver Tube of Parabolic Trough Collector System
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Numerical Investigation of Hot Oil Velocity Effect on Force Heat Convection and Impact of Wind Velocity on Convection Heat Transfer in Receiver Tube of Parabolic Trough Collector System

Authors: O. Afshar

Abstract:

A solar receiver is designed for operation under extremely uneven heat flux distribution, cyclic weather, and cloud transient cycle conditions, which can include large thermal stress and even receiver failure. In this study, the effect of different oil velocity on convection coefficient factor and impact of wind velocity on local Nusselt number by Finite Volume Method will be analyzed. This study is organized to give an overview of the numerical modeling using a MATLAB software, as an accurate, time efficient and economical way of analyzing the heat transfer trends over stationary receiver tube for different Reynolds number. The results reveal when oil velocity is below 0.33m/s, the value of convection coefficient is negligible at low temperature. The numerical graphs indicate that when oil velocity increases up to 1.2 m/s, heat convection coefficient increases significantly. In fact, a reduction in oil velocity causes a reduction in heat conduction through the glass envelope. In addition, the different local Nusselt number is reduced when the wind blows toward the concave side of the collector and it has a significant effect on heat losses reduction through the glass envelope.

Keywords: Receiver tube, heat convection, heat conduction, Nusselt number.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1110091

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References:


[1] O. Afshar, R. Saidur, M. Hassanuzzaman, and M. Jameel, “A review of thermodynamics and heat transfer in solar refrigeration system,” Renewable and Sustainable Energy Reviews, vol. 16, pp.5639-5648, 10//2012.
[2] S.D. Sharma, K. Sagara, “Latent heat storage materials and systems: a review,” International Journal Green Energy, vol. 2, pp. 1-56, 2005.
[3] Q. Yu, ZF. Wang, ES> Xu, “Analysis and improvement of solar flux distribution inside a cavity receiver based on multi-focal points of heliostat field,” Apply Energy, vol. 136, pp. 417-430, 2014.
[4] JF. Lu, J. Ding, JP. Yang, XX. Yang, “Non-uniform heat transfer model and performance of parabolic trough solar receiver,” Energy, vol. 59, pp. 666-675, 2013.
[5] C. Patrice, S. Abanades, F. Lemort, G. Flamant, “Analysis of solar chemical processes for hydrogen production from water splitting thermochemical cycles,” Energy Conversion and Management, vol. 49, pp. 1547-1556, 2008
[6] XW. Song, GB. Dong. FY. Gao, XG. Diao, LQ. Zheng, FY. Zhou, “A numerical study of parabolic trough receiver with non-uniform heat flux and helical screw-tape inserts”, Energy, vol. 77, pp. 771-782, 2014.
[7] M.J. Montes, A. Rovira, J.M. Martinez-Val, and A. Ramos, “Proposal of a fluid flow layout to improve the heat transfer in the active absorber surface of solar central cavity receivers,” Applied Thermal Engineering, vol. 35, pp. 220-232, 3//2012.
[8] H.Price, “Assessment of parabolic trough and power tower solar technology cost and performance forecasts,” National Renewable Energy Laboratory, Golden, CO, 2003.
[9] L. Zhang, Z. Yu, L. Fan, W. wang, H. Chen, Y, Hu, “ An experimental investigation of the heat losses of a U-type solar heat pipe receiver of a parabolic trough collector-based natural circulation steam generation system,” Renewable Energy, vol.57, pp.1910-1914, 9//2011.
[10] S.A. Kalogirou, “A detailed thermal model of a parabolic trough collector receiver,” Energy, vol. 48, pp. 298-306, 12//2012.
[11] F.P. Incropera, Fundamentals of heat and mass transfer: John Wiley& Sons, 2011
[12] R.E. Forristall, Heat transfer analysis and modeling of a parabolic trough solar receiver implemented in engineering equation solver: National Renewable Energy Laboratory, 2003.
[13] S.M. Akbarimoosavi and M. Yaghoubi, “3D thermal structural analysis of an absorber tube of a parabolic trough collector and the effect of tube deflection on optical efficiency,” Energy Procedia, vol. 49, pp. 2433- 2443, //2014.
[14] M. Yaghoubi, and M. Akbari, “Three dimensional thermal expansion analysis of an absorber tube in a parabolic trough collector,” Solar PACES conference, Spain, 2011.
[15] S. Ghadirijafarbeigloo, A.H. Zamzamian, and M. Yaghoubi, “3D numerical simulation of heat transfer and turbulent flow in a receiver tube of solar parabolic trough concentrator with louvered twisted-tape inserts,” Energy Procedia, vol. 49, pp. 373-380,//2014.
[16] N. Naeeni and M. Yaghoubi, “Analysis of wind flow around a parabolic collector (1) fluid flow,” Renewable Energy, vol. 32, pp. 1898-1916, 9//2007.
[17] Y.S. Touloukian and D.P. Dewitt, “Thermo physical properties of matter-the TPRC data series. Volume 7. Thermal Radiative Properties- Metallic Elements and Alloys,” DTIC Document 1970.
[18] H. Al-Ansary and O. Zeitoun,” numerical study of conduction and convection heat losses from a half-insulated air-filled annulus of the receiver of a parabolic trough collector,” Solar Energy, vol. 85, pp. 3036-3045,11//2011.
[19] N. Naeeni and M. Yaghoubi, “Analysis of wind flow around a parabolic collector (2) heat transfer from receiver tube,” Renewable Energy, vol. 32, pp. 1259-1272, 7//2007.