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Fusion Technology Volume 33, 1998 - Issue 1
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Technical Paper

The Effective Thermal Conductivity of a Bed of 1.2-mm-diam Lithium Zirconate Spheres in Helium

John W. EarnshawTrent University, Physics Department, Peterborough, Ontario, Canada
,
Frank A. LondryTrent University, Physics Department, Peterborough, Ontario, Canada
&
Paul J. GierszewskiCanadian Fusion Fuels Technology Project, Toronto, Canada
Pages 31-37 | Published online: 09 May 2017

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Rahman S. Almusafir, Ahmed A. Jasim & Muthanna H. Al-Dahhan. (2023) Review of the Fluid Dynamics and Heat Transport Phenomena in Packed Pebble Bed Nuclear Reactors. Nuclear Science and Engineering 197:6, pages 1001-1037.
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M. Moscardini, S. Pupeschi, Y. Gan, F. A. Hernández & M. Kamlah. (2019) Discrete Element Analysis of Heat Transfer in the Breeder Beds of the European Solid Breeder Blanket Concept. Fusion Science and Technology 75:4, pages 283-298.
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A. Abou-Sena, A. Ying & M. Abdou. (2005) Effective Thermal Conductivity of Lithium Ceramic Pebble Beds for Fusion Blankets: A Review. Fusion Science and Technology 47:4, pages 1094-1100.
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Articles from other publishers (24)

Maulik Panchal, Vrushabh Lambade, Vimal Kanpariya, Harsh Patel & Paritosh Chaudhuri. (2021) Measurement of effective thermal conductivity of lithium metatitanate pebble beds by steady-state radial heat flow method. Fusion Engineering and Design 172, pages 112854.
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Hao Wu, Houjian Zhao, Zulong Hao, Fang Liu & Fenglei Niu. (2021) A non-linear transform approach for conduction-radiation heat transfer in the extended thermal discrete element method. International Journal of Heat and Mass Transfer 176, pages 121432.
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Limin Liu, Jian Deng, Dalin Zhang & Hanyang Gu. (2020) Review of the experimental research on the thermal‐hydraulic characteristics in the pebble bed nuclear reactor core and fusion breeder blankets. International Journal of Energy Research 45:8, pages 11352-11383.
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Shengyao Jiang, Jiyuan Tu, Xingtuan Yang & Nan GuiShengyao Jiang, Jiyuan Tu, Xingtuan Yang & Nan Gui. 2021. Multiphase Flow and Heat Transfer in Pebble Bed Reactor Core. Multiphase Flow and Heat Transfer in Pebble Bed Reactor Core 237 399 .
Shengyao Jiang, Jiyuan Tu, Xingtuan Yang & Nan GuiShengyao Jiang, Jiyuan Tu, Xingtuan Yang & Nan Gui. 2021. Multiphase Flow and Heat Transfer in Pebble Bed Reactor Core. Multiphase Flow and Heat Transfer in Pebble Bed Reactor Core 1 42 .
Raghuram Karthik Desu, Akhil Reddy Peeketi & Ratna Kumar Annabattula. (2020) Influence of bed conditions on the effective thermal conductivity of ceramic breeder pebble beds using thermal DEM (TDEM). Fusion Engineering and Design 159, pages 111767.
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Maulik Panchal, Abhishek Saraswat, Shrikant Verma & Paritosh Chaudhuri. (2020) Measurement of effective thermal conductivity of lithium metatitanate pebble bed by transient hot-wire technique. Fusion Engineering and Design 158, pages 111718.
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Hao Wu, Nan Gui, Xingtuan Yang, Jiyuan Tu & Shengyao Jiang. (2020) Analysis of Clumped-Pebble Shape on Thermal Radiation and Conduction in Nuclear Beds by Subcell Radiation Model. Journal of Heat Transfer 142:3.
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D. Mandal, P.A. Dabhade & N. Kulkarni. (2020) Estimation of effective thermal conductivity of packed bed with internal heat generation. Fusion Engineering and Design 152, pages 111458.
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Hao Wu, Nan Gui, Xingtuan Yang, Jiyuan Tu & Shengyao Jiang. (2020) Analysis and evaluations of four models of thermal radiation for densely packed granular systems. Chemical Engineering Science 211, pages 115309.
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Hao Wu, Nan Gui, Xingtuan Yang, Jiyuan Tu & Shengyao Jiang. (2020) An approximation function model for solving effective radiative heat transfer in packed bed. Annals of Nuclear Energy 135, pages 107000.
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Akhil Reddy Peeketi, Marigrazia Moscardini, Simone Pupeschi, Yixiang Gan, Marc Kamlah & Ratna Kumar Annabattula. (2019) Analytical estimation of the effective thermal conductivity of a granular bed in a stagnant gas including the Smoluchowski effect. Granular Matter 21:4.
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Jian Yang, Yingxue Hu & Qiuwang Wang. (2019) Investigation of Effective Thermal Conductivity for Ordered and Randomly Packed Bed with Thermal Resistance Network Method. Energies 12:9, pages 1666.
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S. Pupeschi, R. Knitter & M. Kamlah. (2017) Effective thermal conductivity of advanced ceramic breeder pebble beds. Fusion Engineering and Design 116, pages 73-80.
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D. Mandal, N. Kulkarni, S. Gosavi & C.S. Mathpati. (2017) Experimental investigation of effective thermal conductivity of packed lithium-titanate pebble bed with external heat source and flow of helium. Fusion Engineering and Design 115, pages 56-66.
Crossref
Shahram Sharafat, Brian Williams, Nasr Ghoniem, Adam Ghoniem, Masashi Shimada & Alice Ying. (2016) Development of a new cellular solid breeder for enhanced tritium production. Fusion Engineering and Design 109-111, pages 119-127.
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Xiaoliang Wang, Jie Zheng & Hongli Chen. (2016) Application of a model to investigate the effective thermal conductivity of randomly packed fusion pebble beds. Fusion Engineering and Design 106, pages 40-50.
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Xiaoliang Wang, Jie Zheng & Hongli Chen. (2016) A prediction model for the effective thermal conductivity of mono-sized pebble beds. Fusion Engineering and Design 103, pages 136-151.
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D. Mandal, D. Sathiyamoorthy & M. Vinjamur. (2012) Experimental measurement of effective thermal conductivity of packed lithium-titanate pebble bed. Fusion Engineering and Design 87:1, pages 67-76.
Crossref
Galit Weidenfeld, Yeshayahu Weiss & Haim Kalman. (2004) A theoretical model for effective thermal conductivity (ETC) of particulate beds under compression. Granular Matter 6:2-3, pages 121-129.
Crossref
G. Widenfeld, Y. Weiss & H. Kalman. (2003) The effect of compression and preconsolidation on the effective thermal conductivity of particulate beds. Powder Technology 133:1-3, pages 15-22.
Crossref
A.J. Slavin, V. Arcas, C.A. Greenhalgh, E.R. Irvine & D.B. Marshall. (2002) Theoretical model for the thermal conductivity of a packed bed of solid spheroids in the presence of a static gas, with no adjustable parameters except at low pressure and temperature. International Journal of Heat and Mass Transfer 45:20, pages 4151-4161.
Crossref
Alan J. Slavin. (2001) Test of a new model for the temperature and pressure dependence of the thermal conductivity of a packed pebble bed in gas: lithium zirconate in helium. Fusion Engineering and Design 54:1, pages 87-95.
Crossref
Alan J. Slavin, Frank A. Londry & Joy Harrison. (2000) A new model for the effective thermal conductivity of packed beds of solid spheroids: alumina in helium between 100 and 500°C. International Journal of Heat and Mass Transfer 43:12, pages 2059-2073.
Crossref

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