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N. S. Ghuge, D. Mandal, M. C. Jadeja & B. K. Chougule. (2023) Estimation of effective thermal conductivity and heat transfer coefficient of lithium orthosilicate pebble bed in carbon dioxide–air medium. Experimental Heat Transfer 0:0, pages 1-16.
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Lei Chen, Youhua Chen, Kai Huang & Songlin Liu. (2016) Investigation of the packing structure of pebble beds by DEM for CFETR WCCB. Journal of Nuclear Science and Technology 53:6, pages 803-808.
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A. Abou-Sena, A. Ying & M. Abdou. (2009) Experimental Measurements of the Interface Thermal Conductance of a Lithium Metatitanate Pebble Bed. Fusion Science and Technology 56:1, pages 206-210.
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Shinji Ebara, Yasutaka Harai, Takehiko Yokomine & Akihiko Shimizu. (2009) Numerical Analysis for Thermal and Mechanical Properties of Pebble Bed. Fusion Science and Technology 56:1, pages 148-152.
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Y. Kosaku, Y. Yanagi, M. Enoeda & M. Akiba. (2002) Evaluation of Tritium Permeation in Solid Breeder Blanket Cooled by Supercritical Water. Fusion Science and Technology 41:3P2, pages 958-961.
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Yoshihiko YANAGI, Satoshi SATO, Mikio ENOEDA, Toshihisa HATANO, Shigeto KIKUCHI, Toshimasa KURODA, Yasuo KOSAKU & Yoshihiro OHARA. (2001) Nuclear and Thermal Analyses of Supercritical-water-cooled Solid Breeder Blanket for Fusion DEMO Reactor. Journal of Nuclear Science and Technology 38:11, pages 1014-1018.
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Mikio Enoeda, Yosihiro Ohara, Nicole Roux, Alice Ying, Giovanni Pizza & Siegfried Malang. (2001) Effective Thermal Conductivity Measurement of the Candidate Ceramic Breeder Pebble Beds by the Hot Wire Method. Fusion Technology 39:2P2, pages 612-616.
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M. Dalle Donne, A. Goraieb, G. Piazza & F. Scaffidi-Argentina. (2000) Measurement of the Heat Transfer Parameters in Infiltrated Binary Beryllium Beds: Comparison between the Results with PEHTRA and SUPER-PETRA. Fusion Technology 38:3, pages 310-319.
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F. Botta & C. Hellwig. (2000) SPACON—A Theoretical Model for Calculating the Heat Transport Properties in Sphere-Pac Fuel Pins. Nuclear Science and Engineering 135:2, pages 165-176.
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Mikio Enoeda, Kazuyuki Furuya, Hideyuki Takatsu, Shigeto Kikuchi & Toshihisa Hatano. (1998) Effective Thermal Conductivity Measurements of the Binary Pebble Beds by Hot Wire Method for the Breeding Blanket. Fusion Technology 34:3P2, pages 877-881.
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John W. Earnshaw, Frank A. Londry & Paul J. Gierszewski. (1998) The Effective Thermal Conductivity of a Bed of 1.2-mm-diam Lithium Zirconate Spheres in Helium. Fusion Technology 33:1, pages 31-37.
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D. R. Kingdon & A. A. Harms. (1996) Pellet Power Ratio in a Pellet-Suspension Fission Core. Nuclear Technology 116:1, pages 1-8.
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Fatollah Tehranian & Mohamed A. Abdou. (1995) Experimental Study of the Effect of External Pressure on Particle Bed Effective Thermal Properties. Fusion Technology 27:3, pages 298-313.
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A. René Raffray, Mark S. Tillack & Mohamed A. Abdou. (1993) Thermal Control of Ceramic Breeder Blankets. Fusion Technology 23:3, pages 281-308.
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W. Fundamenski & P. Gierszewski. (1992) Heat Transfer Correlations for Packed Beds. Fusion Technology 21:3P2B, pages 2123-2127.
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Articles from other publishers (55)
Pratyush Kumar, Sandip K. Saha & Atul Sharma. (2023) Experimental and CFD-DEM study on local packing distribution and thermofluidic analysis of binary packed bed. Chemical Engineering Science 282, pages 119372.
Crossref
Crossref
Shuwen Yu, Zhenze Zhang, Changhong Peng & Tianze Bai. (2023) Rapid analysis of packed pebble beds for thermal–hydraulic characteristics via reduced order models. Chemical Engineering Science 280, pages 119029.
Crossref
Crossref
Young Ah Park, Ji Won Yoo, Yi-Hyun Park & Young Soo Yoon. (2023) Li4SiO4 slurry conditions and sintering temperature for fabricating Li4SiO4 pebbles as tritium breeders for nuclear-fusion reactors. Nuclear Engineering and Technology 55:8, pages 2966-2976.
Crossref
Crossref
Chirag Sedani, Paritosh Chaudhuri & Manoj Kumar Gupta. (2023) Heat transfer and fluid flow analysis of pebble bed and its verification with artificial neural network. Nuclear Materials and Energy 35, pages 101439.
Crossref
Crossref
Chirag Sedani, Maulik Panchal, Vipul Tanna, Paritosh Chaudhuri & Manoj Kumar Gupta. (2022) Analysis of effective thermal conductivity of pebble bed by artificial neural network and its computational and experimental verification. Case Studies in Thermal Engineering 40, pages 102548.
Crossref
Crossref
Deepak Ranjan Sahoo, Paritosh Chaudhuri & Narasimhan Swaminathan. (2021) A molecular dynamics study of displacement cascades and radiation induced amorphization in Li2TiO3. Computational Materials Science 200, pages 110783.
Crossref
Crossref
Joerg Reimann, Benjamin Fretz, Ramil Gaisin, Aniceto Goraieb, Jae-Hwan Kim, Suguru Nakano, Masaru Nakamichi & Pavel Vladimirov. (2021) Thermo-mechanical behavior of titanium beryllide pebble beds at ambient temperature. Fusion Engineering and Design 165, pages 112249.
Crossref
Crossref
Yoshinori Kawamura, Hyoseong Gwon, Wenhai Guan, Hisashi Tanigawa, Takanori Hirose, Atsushi Wakasa, Seiji Yoshino, Tamon Ouchi, Kentaro Hattori, Noriaki Chiba, Takuya Kushida, Seiji Mori, Hiromasa Iida, Takumi Yamamoto, Toshihiko Yamanishi, Hiroyasu Uto, Yoji Someya, Kentaro Ochiai, Hideo Sakasegawa, Jaehwan Kim, Hirofumi Nakamura, Hiroyasu Tanigawa, Shigeru Ohira & Takumi Hayashi. (2020) Progress of water cooled ceramic breeder test blanket module system. Fusion Engineering and Design 161, pages 112050.
Crossref
Crossref
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.
Crossref
Crossref
Cong Wang, Lei Chen & Songlin Liu. (2020) Experimental measurements for the effective thermal conductivity of pebble beds with uncertainty analysis. Fusion Engineering and Design 156, pages 111707.
Crossref
Crossref
Niraj J. Kulkarni, Debapriya Mandal, Channamallikarjun S. Mathpati & Vishwanath H. Dalvi. (2020) Modeling and validation of heat transfer in packed bed with internal heat generation. Heat Transfer 49:5, pages 2961-2976.
Crossref
Crossref
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.
Crossref
Crossref
Cong Wang, Lei Chen & Songlin Liu. (2019) A DEM-CFD numerical model for the prediction of the effective thermal conductivity of pebble beds with contact conduction. Fusion Engineering and Design 147, pages 111257.
Crossref
Crossref
Lei Chen, Cong Wang, Marigrazia Moscardini, Marc Kamlah & Songlin Liu. (2019) A DEM-based heat transfer model for the evaluation of effective thermal conductivity of packed beds filled with stagnant fluid: Thermal contact theory and numerical simulation. International Journal of Heat and Mass Transfer 132, pages 331-346.
Crossref
Crossref
Manuel A. Pouchon, L.-Å Nordström & Ch Hellwig. 2019. Reference Module in Materials Science and Materials Engineering. Reference Module in Materials Science and Materials Engineering.
Mohammed Suhail, Baldev Puliyeri, Paritosh Chaudhuri, Ratnakumar Annabattula & Narasimhan Swaminathan. (2018) Molecular Dynamics Simulation of Primary Damage in β-Li2TiO3. Fusion Engineering and Design 136, pages 914-919.
Crossref
Crossref
Xuezhi Zhang & Lei Yang. 2018. Principles and Applications in Nuclear Engineering - Radiation Effects, Thermal Hydraulics, Radionuclide Migration in the Environment. Principles and Applications in Nuclear Engineering - Radiation Effects, Thermal Hydraulics, Radionuclide Migration in the Environment.
Maulik Panchal, Christopher Kang, Alice Ying & Paritosh Chaudhuri. (2018) Experimental measurement and numerical modeling of the effective thermal conductivity of lithium meta-titanate pebble bed. Fusion Engineering and Design 127, pages 34-39.
Crossref
Crossref
Yong Liu, Hongguang Yang, Qin Zhan, Shanshan Liu, Bin Zhu & Yisheng Zhang. (2017) Measurements of the effective thermal conductivity of a non-compressed Li4SiO4 pebble bed. Fusion Engineering and Design 125, pages 545-550.
Crossref
Crossref
S. Pupeschi, R. Knitter & M. Kamlah. (2017) Effective thermal conductivity of advanced ceramic breeder pebble beds. Fusion Engineering and Design 116, pages 73-80.
Crossref
Crossref
Xiang Liu, Jiming Chen, Kaiming Feng, Pengfei Zheng, Youyun Lian, Penghuai Wang, Xiaoyu Wang, Yongjin Feng, Xuru Duan & Yong Liu. 2017. Proceedings of The 20th Pacific Basin Nuclear Conference. Proceedings of The 20th Pacific Basin Nuclear Conference
825
837
.
Maulik Panchal, Paritosh Chaudhuri, Jon T Van Lew & Alice Ying. (2016) Numerical modelling for the effective thermal conductivity of lithium meta titanate pebble bed with different packing structures. Fusion Engineering and Design 112, pages 303-310.
Crossref
Crossref
Lei Chen, Youhua Chen, Kai Huang & Songlin Liu. (2016) Investigation of effective thermal conductivity for pebble beds by one-way coupled CFD-DEM method for CFETR WCCB. Fusion Engineering and Design 106, pages 1-8.
Crossref
Crossref
J.G. van der Laan, J. Reimann & A.V. Fedorov. 2016. Comprehensive Nuclear Materials. Comprehensive Nuclear Materials
114
175
.
Lei Chen, Youhua Chen, Kai Huang & Songlin Liu. (2015) Effective Thermal Property Estimation of Unitary Pebble Beds Based on a CFD-DEM Coupled Method for a Fusion Blanket. Plasma Science and Technology 17:12, pages 1083-1087.
Crossref
Crossref
Guangming Zhou, Min Li, Qianwen Liu, Shuai Wang, Zhongliang Lv, Hongli Chen & Minyou Ye. (2014) Thermal Analysis of Breeder Unit for Helium Cooled Solid Breeder Blanket of Chinese Fusion Engineering Test Reactor. Journal of Fusion Energy 34:2, pages 339-345.
Crossref
Crossref
K.M. Feng, G.S. Zhang, G. Hu, Y.J. Chen, Y.J. Feng, Z.X. Li, P.H. Wang, Z. Zhao, X.F. Ye, B. Xiang, L. Zhang, Q.J. Wang, Q.X. Cao, F.C. Zhao, F. Wang, Y. Liu & M.C. Zhang. (2014) New progress on design and R&D for solid breeder test blanket module in China. Fusion Engineering and Design 89:7-8, pages 1119-1125.
Crossref
Crossref
Hao Ran Cao, Rong Hua Huang & Jun Heng Li. (2014) Theoretical Calculation and Numerical Investigation for the Effective Thermal Conductivity of Packed Li<sub>2</sub>TiO<sub>3</sub> Pebble Bed. Advanced Materials Research 953-954, pages 627-630.
Crossref
Crossref
Manuel A. Pouchon, L.-Å Nordström & Ch Hellwig. 2012. Comprehensive Nuclear Materials. Comprehensive Nuclear Materials
436
463
.
M.A. Pouchon, L.-Å. Nordström & Ch. Hellwig. 2012. Comprehensive Nuclear Materials. Comprehensive Nuclear Materials
789
817
.
Zhou Zhao, K.M. Feng & Y.J. Feng. (2010) Theoretical calculation and analysis modeling for the effective thermal conductivity of Li4SiO4 pebble bed. Fusion Engineering and Design 85:10-12, pages 1975-1980.
Crossref
Crossref
Yixiang Gan & Marc Kamlah. (2010) Thermo-mechanical modelling of pebble bed–wall interfaces. Fusion Engineering and Design 85:1, pages 24-32.
Crossref
Crossref
Dale L. Smith, Richard F. Mattas & Michael C. Billone. 2006. Materials Science and Technology. Materials Science and Technology.
A.J. Slavin, E. Irvine & S. Penson. (2004) Analytical model for the thermal conductivity of a binary bed of packed spheroids in the presence of a static gas, with no adjustable parameters provided contact conductance is negligible. International Journal of Heat and Mass Transfer 47:5, pages 1015-1021.
Crossref
Crossref
G Piazza, M Enoeda & A Ying. (2001) Measurements of effective thermal conductivity of ceramic breeder pebble beds. Fusion Engineering and Design 58-59, pages 661-666.
Crossref
Crossref
Shigeto Kikuchi. (2001) Numerical analysis model for thermal conductivities of packed beds with high solid-to-gas conductivity ratio. International Journal of Heat and Mass Transfer 44:6, pages 1213-1221.
Crossref
Crossref
Yoshihiko YANAGI, Satoshi SATO, Mikio ENOEDA, Toshihisa HATANO, Shigeto KIKUCHI, Toshimasa KURODA, Yasuo KOSAKU & Yoshihiro OHARA. (2001) Nuclear and Thermal Analyses of Supercritical-water-cooled Solid Breeder Blanket for Fusion DEMO Reactor.. Journal of Nuclear Science and Technology 38:11, pages 1014-1018.
Crossref
Crossref
M. Dalle Donne, A. Goraieb, G. Piazza & F. Scaffidi-Argentina. (2000) Experimental investigations on the thermal and mechanical behaviour of a binary beryllium pebble bed. Fusion Engineering and Design 49-50, pages 521-528.
Crossref
Crossref
M. Dalle Donne, A. Goraieb, G. Piazza & G. Sordon. (2000) Measurements of the effective thermal conductivity of a Li4SiO4 pebble bed. Fusion Engineering and Design 49-50, pages 513-519.
Crossref
Crossref
David Krashkevich, Susan R. Loehr, Hans-Jürgen Hoffmann, Monika J. Liepmann, Norbert Neuroth, Joseph S. Hayden, Peter Naβ, Burkhard Speit, Uwe Kolberg, Ewald Hillmann, Clemens Kunisch, Thomas Schindelbeck & Thomas Westerhoff. 1998. The Properties of Optical Glass. The Properties of Optical Glass
263
402
.
M.C. Billone. (1996) Thermal and tritium transport in Li2O and Li2ZrO3. Journal of Nuclear Materials 233-237, pages 1462-1466.
Crossref
Crossref
Mingjie Xu, Mohamed A Abdou & A.Rene Raffray. (1995) Thermal conductivity of a beryllium gas packed bed. Fusion Engineering and Design 27, pages 240-246.
Crossref
Crossref
Z.R Gorbis, M.S Tillack, F Tehranian & M.A Abdou. (1995) Analysis of wall-packed—bed thermal interactions. Fusion Engineering and Design 27, pages 216-225.
Crossref
Crossref
P Gierszewski, M.Dalle Donne, H Kawamura & M Tillack. (1995) Ceramic pebble bed development for fusion blankets. Fusion Engineering and Design 27, pages 167-178.
Crossref
Crossref
N Roux, G Hollenberg, C Johnson, K Noda & R Verrall. (1995) Summary of experimental results for ceramic breeder materials. Fusion Engineering and Design 27, pages 154-166.
Crossref
Crossref
M. Ferrari, F. Di Carlo, M. Furrer, G. Simbolotti & C. Talarico. (1995) Testing of 1-PIN blanket mockup: analysis of the experimental results. Testing of 1-PIN blanket mockup: analysis of the experimental results.
E. Achenbach. (1995) Heat and flow characteristics of packed beds. Experimental Thermal and Fluid Science 10:1, pages 17-27.
Crossref
Crossref
M. Dalle Donne, A. Goraieb, R. Huber, B. Schmitt, G. Schumacher, G. Sordon & A. Weisenburger. (1994) Heat transfer and technological investigations on mixed beds of beryllium and Li4SiO4 pebbles. Journal of Nuclear Materials 212-215, pages 872-876.
Crossref
Crossref
. (1993) III.3. The NET device - Containment structures and shield. Fusion Engineering and Design 21, pages 165-212.
Crossref
Crossref
E. Achenbach. 1993. Experimental Heat Transfer, Fluid Mechanics and Thermodynamics 1993. Experimental Heat Transfer, Fluid Mechanics and Thermodynamics 1993
283
293
.
M. Dalle Donne, A. Goraieb & G. Sordon. (1992) Measurements of the effective thermal conductivity of a bed of Li4SiO4 pebbles of 0.35–0.6 mm diameter and of a mixed bed of Li4SiO4 and alu. Journal of Nuclear Materials 191-194, pages 149-152.
Crossref
Crossref
N. Roux, C. Johnson & K. Noda. (1992) Properties and performance of tritium breeding ceramics. Journal of Nuclear Materials 191-194, pages 15-22.
Crossref
Crossref
C.E. Johnson, T. Kondo, N. Roux, S. Tanaka & D. Vollath. (1991) Fabrication, properties, and tritium recovery from solid breeder materials. Fusion Engineering and Design 16, pages 127-139.
Crossref
Crossref
P.J. Gierszewski & J.D. Sullivan. (1991) Ceramic sphere-pac breeder design for fusion blankets. Fusion Engineering and Design 17, pages 95-104.
Crossref
Crossref
M.Dalle Donne, E. Günther, G. Schumacher, G. Sordon, D. Vollath, H. Wedemeyer & H. Werle. (1991) Research and development work for the lithium orthosilicate pebbles for the Karlsruhe ceramic breeder blanket. Journal of Nuclear Materials 179-181, pages 796-799.
Crossref
Crossref