Modeling study on the thermal performance of a modified cavity receiver with glass window and secondary reflector
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Yuting Liu | Chen Duan | Zhongmin Wan | Wen Ke | Shuiming Shu | Changwei Jing | Huawei Chang | Can Xiang | Sinian He | Huawei Chang | Z. Wan | S. Shu | Chen Duan | W. Ke | Yuting Liu | Changwei Jing | Can Xiang | Sinian He
[1] Terry G. Lenz,et al. Thermal performance of solar concentrator/cavity receiver systems , 1985 .
[2] Sendhil Kumar Natarajan,et al. Comparison of receivers for solar dish collector system , 2008 .
[3] V. Bǎdescu. Optimum operation of a solar converter in combination with a Stirling or Ericsson heat engine , 1992 .
[4] Yuting Tan,et al. Experimental investigation on heat loss of semi-spherical cavity receiver , 2014 .
[5] Tao Guo,et al. Comparative analysis of natural and conventional working fluids for use in transcritical Rankine cycle using low‐temperature geothermal source , 2011 .
[6] Sendhil Kumar Natarajan,et al. Experimental performance investigation of modified cavity receiver with fuzzy focal solar dish concentrator , 2015 .
[7] Wang Fuqiang,et al. Effects of glass cover on heat flux distribution for tube receiver with parabolic trough collector system , 2015 .
[8] Abraham Kribus,et al. A Multistage Solar Receiver , 1999 .
[9] Xinggang Wang,et al. Thermodynamic design of Stirling engine using multi-objective particle swarm optimization algorithm , 2014 .
[10] K. S. Reddy,et al. Convection and surface radiation heat losses from modified cavity receiver of solar parabolic dish collector with two-stage concentration , 2009 .
[11] Jinjia Wei,et al. Numerical investigation on uniformity of heat flux for semi-gray surfaces inside a solar cavity receiver , 2015 .
[12] Luis M. Serra,et al. Environmental evaluation of dish-Stirling technology for power generation , 2012 .
[13] Liang Yingchun,et al. Radiative properties of a solar cavity receiver/reactor with quartz window , 2011 .
[14] Sendhil Kumar Natarajan,et al. Combined laminar natural convection and surface radiation heat transfer in a modified cavity receiver of solar parabolic dish , 2008 .
[15] M. Pinar Mengüç,et al. Thermal Radiation Heat Transfer , 2020 .
[16] Joshua M. Christian,et al. Numerical Simulation of Natural Convection in Solar Cavity Receivers , 2015 .
[17] N. D Kaushika,et al. Viability aspects of paraboloidal dish solar collector systems , 1993 .
[18] V. Badescu. Different tracking error distributions and their effects on the long-term performances of parabolic dish solar power systems , 1994 .
[19] Sendhil Kumar Natarajan,et al. Numerical investigation of natural convection heat loss in modified cavity receiver for fuzzy focal solar dish concentrator , 2007 .
[20] V. Badescu. Optimizing of Stirling and Ericsson cycles using solar radiation , 1992 .
[21] Alan W. Weimer,et al. A cavity-receiver containing a tubular absorber for high-temperature thermochemical processing using concentrated solar energy , 2008 .
[22] Ali Al-Mohamad,et al. Efficiency improvements of photo-voltaic panels using a Sun-tracking system , 2004 .
[23] G. Flamant,et al. Effect of directional dependency of wall reflectivity and incident concentrated solar flux on the efficiency of a cavity solar receiver , 2014 .
[24] C. Balaji,et al. Interaction of radiation with free convection in an open cavity , 1994 .
[25] Josua P. Meyer,et al. Numerical modelling and optimisation of natural convection heat loss suppression in a solar cavity receiver with plate fins , 2015 .
[26] Ricardo Beltran,et al. Mathematical model for the study and design of a solar dish collector with cavity receiver for its application in Stirling engines , 2012 .
[27] Xiaoqing Zhang,et al. Working fluid selection for an Organic Rankine Cycle utilizing high and low temperature energy of an LNG engine , 2015 .
[28] Kefa Cen,et al. Simulation and experimental study of an air tube-cavity solar receiver , 2015 .
[29] Yuqiang Li,et al. Field synergy principle analysis for reducing natural convection heat loss of a solar cavity receiver , 2015 .
[30] Chen Duan,et al. Similarity design and experimental investigation of a beta‐type Stirling engine with a rhombic drive mechanism , 2015 .
[31] Ya-Ling He,et al. Study on combined heat loss of a dish receiver with quartz glass cover , 2013 .
[32] V. Badescu. OPTIMIZATION OF A SOLAR SPACE POWER SYSTEM BASED ON THERMODYNAMIC CYCLES , 1995 .
[33] Josua P. Meyer,et al. Three-dimensional analysis and numerical optimization of combined natural convection and radiation heat loss in solar cavity receiver with plate fins insert , 2015 .
[34] Ibrahim Dincer,et al. Hybrid solar–fuel cell combined heat and power systems for residential applications: Energy and exergy analyses , 2013 .