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All issues Volume 128 (2019) E3S Web Conf., 128 (2019) 01018 References
Open Access
Issue
E3S Web Conf.
Volume 128, 2019
XII International Conference on Computational Heat, Mass and Momentum Transfer (ICCHMT 2019)
Article Number 01018
Number of page(s) 7
Section Heat and Mass Transfer in Energy Systems
DOI https://doi.org/10.1051/e3sconf/201912801018
Published online 08 November 2019
  1. R. D. Jilte, S. B. Kedare & J. K. Nayak, “Natural Convection and Radiation Heat Loss from Open Cavities of Shapes and Sizes Used with Dish Concentrator.” Mechanical Engineering Research (Canadian Center of Science and Education) 3 (1). [Google Scholar]
  2. M. Prakash, S. B. Kedare, and J. K. Nayak, “Investigations on heat losses from a solar cavity receiver.” Solar Energy 83 (2): 157–170 (2009) [CrossRef] [Google Scholar]
  3. N. Sendhil Kumar, K. S. Reddy, “Numerical investigation of natural convection heat loss in modified cavity receiver for fuzzy focal solar dish concentrator.” Solar Energy 81: 846–855 (2007) [CrossRef] [Google Scholar]
  4. T. Taumoefolau, S. Paitoonsurikarn, G. Hughes, and K. Lovegrove, “Experimental investigation of natural convection heat loss from model solar concentrator cavity receiver.” Journal of Solar Energy Engineering 126 (2): 801–807 (2004). [Google Scholar]
  5. K. Lovegrove and S. Paitoonsurikarn, “A new correlation for predicting the free convection loss from solar dish concentrating.” Solar: (ANZSES ‘06) . Canberra Australia (2006) [Google Scholar]
  6. L.L. Eyler, “Predictions of convective losses from a solar cavity receiver.” DOE/SERI/SNLL Workshop on Convective Losses from Solar Receivers Sandia Laboratory Report SAND81- 8014 . Livermore, California. 93–104 (1981). [Google Scholar]
  7. A. M. Clausing, “An analysis of convective losses from cavity solar central receivers.” Solar Energy 27 (4): 295–300 (1981). [CrossRef] [Google Scholar]
  8. P. LeQuere, F. Penot, M. Mirenayat, “Experimental study of heat loss through natural convection from an isothermal cubic open cavity” Sandia: Sandia Laboratory Report (1981). [Google Scholar]
  9. C. Balaji, S.P. Venkateshan, “Interaction of radiation with free convection in an open cavity.” Int. J. Heat Fluid Flow 15 (4): 317–324 (1994). [Google Scholar]
  10. N. Ramesh, W. Merzkirch, “Combined convective and radiative heat transfers in side-vented open cavity.” Int. J. Heat Fluid Flow 22: 180–187 (2001). [Google Scholar]
  11. N. Singh, S.P. Venkateshan “Numerical study of natural convection with surface radiation in side- vented open cavities.” Int. J. Thermal Sci. 43 (4): 865–876 (2004). [CrossRef] [Google Scholar]
  12. J.F. Hinojosa, R.E. Cabanillas, G. Alvarez, C.E. Estrada, “Nusselt number for the natural convection and surface thermal radiation in a square tilted open cavity.” Int. Comm. Heat Mass Transfer 32: 1184–1192 (2005). [CrossRef] [Google Scholar]
  13. C. Balaji, S.P. Venkateshan, “Correlations for free convection and surface radiation in a square cavity.” Int. J. Heat Fluid Flow 15 (3): 249–251 (1994). [Google Scholar]
  14. K. S. Reddy . N. Sendhil Kumar, “Study of combined natural convection and surface radiation in a modified cavity receiver for solar parabolic dish collector,” in 1st National Conference on Advances in Energy Research, AER-2006, IITB, Macmillan, New Delhi (2006). [Google Scholar]
  15. J. L . M. Jiji, Heat Convection . Verlag: Springer (2006). [Google Scholar]
  16. E. Abbasi-Shavazia, G.O. Hughes, J.D. Pye, “Investigation of heat loss from a solar cavity receiver” Energy Procedia 69: 269–275 (2015). [Google Scholar]

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