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Numerical Heat Transfer, Part A: Applications
An International Journal of Computation and Methodology
Volume 68, 2015 - Issue 2
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Original Articles

Numerical Simulation of a Centrifugal Particle Receiver for High-Temperature Concentrating Solar Applications

W. WuInstitute of Solar Research, German Aerospace Centre (DLR), Stuttgart, Germany
,
R. UhligInstitute of Solar Research, German Aerospace Centre (DLR), Stuttgart, Germany
,
R. BuckInstitute of Solar Research, German Aerospace Centre (DLR), Stuttgart, GermanyCorrespondence[email protected]
&
R. Pitz-PaalInstitute of Solar Research, German Aerospace Centre (DLR), Stuttgart, Germany
Pages 133-149 | Received 17 Jul 2014, Accepted 13 Oct 2014, Published online: 31 Mar 2015

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Xinhua Xue. (2020) Daily diffuse solar radiation estimation using adaptive neuro-fuzzy inference system technique. Numerical Heat Transfer, Part B: Fundamentals 77:2, pages 138-151.
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Xinhua Xue & Hongwei Zhou. (2019) Soft computing methods for predicting daily global solar radiation. Numerical Heat Transfer, Part B: Fundamentals 76:1, pages 18-31.
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Articles from other publishers (23)

Zhang Bai, Yucheng Gu, Shuoshuo Wang, Tieliu Jiang, Debin Kong & Qi Li. (2023) Applying the solar solid particles as heat carrier to enhance the solar-driven biomass gasification with dynamic operation power generation performance analysis. Applied Energy 351, pages 121798.
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Qiang Yu, Xueyan Li, Yihui Yang, Zihao Li & Fuliang Nie. (2023) Dynamic simulation and parametric influence analysis on thermal performance of a quartz tube solid particle receiver in solar tower power plants. Particuology 79, pages 161-171.
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D.J. Erasmus, A. Sánchez-González, M. Lubkoll, K.J. Craig & T.W. von Backström. (2023) Thermal performance characteristics of a tessellated-impinging central receiver. Applied Thermal Engineering 229, pages 120529.
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Malavika V. Bagepalli, Shin Young Jeong, Joshua D. Brooks, Zhuomin M. Zhang, Devesh Ranjan & Peter G. Loutzenhiser. (2022) Experimental characterization of extreme temperature granular flows for solar thermal energy transport and storage. Solar Energy Materials and Solar Cells 248, pages 112020.
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Jikang Wang, Yuanting Zhang, Weichen Zhang, Yu Qiu & Qing Li. (2022) Design and evaluation of a lab-scale tungsten receiver for ultra-high-temperature solar energy harvesting. Applied Energy 327, pages 120135.
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Cathy Frantz, Reiner Buck & Lars Amsbeck. (2022) Design and Cost Study of Improved Scaled-Up Centrifugal Particle Receiver Based on Simulation. Journal of Energy Resources Technology 144:9.
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Muhammad M. Rafique, Graham Nathan & Woei Saw. (2022) Modelled annual thermal performance of a 50MWth refractory-lined particle-laden solar receiver operating above 1000°C. Renewable Energy 197, pages 1081-1093.
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Fuliang Nie, Fengwu Bai, Zhifeng Wang, Xiaobo Li & Ronggui Yang. (2022) Solid particle solar receivers in the next‐generation concentrated solar power plant. EcoMat 4:5.
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Kaijun Jiang, Yanqiang Kong, Chao Xu, Zhihua Ge & Xiaoze Du. (2022) Experimental performance of gas-solid countercurrent fluidized bed particle solar receiver with high-density suspension. Applied Thermal Engineering 213, pages 118661.
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Yining Tang, Zhiwei Sun, Zhao Tian, Alfonso Chinnici, Timothy Lau, Woei Saw & Graham J. Nathan. (2022) Direct measurements and prediction of the particle egress from a vortex-based solar cavity receiver with an open aperture. Solar Energy 235, pages 105-117.
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Clifford K. Ho, Brantley Mills, Jeremy Sment, Kevin Albrecht, Nathaniel Schroeder & Hendrik Laubscher. (2022) NEXT-GENERATION PARTICLE-BASED CONCENTRATING SOLAR THERMAL POWER. Annual Review of Heat Transfer 25:1, pages 1-49.
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Muhammad M. Rafique, Graham Nathan & Woei Saw. (2021) A mathematical model to assess the influence of transients on a refractory-lined solar receiver. Renewable Energy 167, pages 217-235.
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Wojciech Lipiński, Ehsan Abbasi-Shavazi, Jingjing Chen, Joe Coventry, Morteza Hangi, Siddharth Iyer, Apurv Kumar, Lifeng Li, Sha Li, John Pye, Juan F. Torres, Bo Wang, Ye Wang & Vincent M. Wheeler. (2021) Progress in heat transfer research for high-temperature solar thermal applications. Applied Thermal Engineering 184, pages 116137.
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Kaijun Jiang, Xiaoze Du, Yanqiang Kong, Chao Xu & Xing Ju. (2019) A comprehensive review on solid particle receivers of concentrated solar power. Renewable and Sustainable Energy Reviews 116, pages 109463.
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Fuliang Nie, Zhiying Cui, Fengwu Bai & Zhifeng Wang. (2019) Properties of solid particles as heat transfer fluid in a gravity driven moving bed solar receiver. Solar Energy Materials and Solar Cells 200, pages 110007.
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Liang Teng & Yimin Xuan. (2019) Design of a composite receiver for solar-driven supercritical CO2 Brayton cycle. Journal of CO2 Utilization 32, pages 290-298.
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Zhiwen Ma & Janna Martinek. (2019) Analysis of Solar Receiver Performance for Chemical-Looping Integration With a Concentrating Solar Thermal System. Journal of Solar Energy Engineering 141:2.
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Clifford K. Ho, Joshua M. Christian, Julius E. Yellowhair, Kenneth Armijo, William J. Kolb, Sheldon Jeter, Matthew Golob & Clayton Nguyen. (2019) On-Sun Performance Evaluation of Alternative High-Temperature Falling Particle Receiver Designs. Journal of Solar Energy Engineering 141:1.
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Clifford K. Ho. (2017) Advances in central receivers for concentrating solar applications. Solar Energy 152, pages 38-56.
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Clifford K. Ho, Joshua M. Christian, David Romano, Julius Yellowhair, Nathan Siegel, Laura Savoldi & Roberto Zanino. (2017) Characterization of Particle Flow in a Free-Falling Solar Particle Receiver. Journal of Solar Energy Engineering 139:2.
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C.K. Ho. 2017. Advances in Concentrating Solar Thermal Research and Technology. Advances in Concentrating Solar Thermal Research and Technology 107 128 .
Clifford K. Ho. (2016) A review of high-temperature particle receivers for concentrating solar power. Applied Thermal Engineering 109, pages 958-969.
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Clifford K. Ho, Joshua M. Christian, Julius Yellowhair, Nathan Siegel, Sheldon Jeter, Matthew Golob, Said I. Abdel-Khalik, Clayton Nguyen & Hany Al-Ansary. On-sun testing of an advanced falling particle receiver system. On-sun testing of an advanced falling particle receiver system.

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