OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

核技术 2014

熔盐冷却球床堆热通道热工水力特性数值分析

DOI: 10.11889/j.0253-3219.2014.hjs.37.070602, PP. 70602-70602

牛强,宋士雄,魏泉,刘亚芬,梅龙伟,郭威,蔡翔舟

Keywords: 熔盐冷却球床堆(PebbleBedAdvancedHighTemperatureReactor,PB-AHTR),热工水力,多孔介质

Full-Text Cite this paper Add to My Lib

Abstract:

基于计算流体力学(ComputationalFluidDynamics,CFD)通用计算程序Fluent，研究了模块化熔盐冷却球床堆(PebbleBedAdvancedHighTemperatureReactor,PB-AHTR)中心热通道稳态热工水力行为。利用已开发的多孔介质流固两相局域非热平衡模型计算了球床堆中的压降、冷却剂的温场分布以及固相球床的温场分布，计算并比较了不同的多孔介质阻力因子(Ergun与KTA)对通道内的冷却剂流动以及温场分布的影响，并对丧失部分冷却剂情况下通道内的冷却剂及燃料温度进行了计算分析。结果表明使用不同的阻力因子对堆芯压降计算结果和流场的分布影响较大；而冷却剂温场及固相球床温场和球心的温度分布在不同的阻力因子下的差别较小，在PB-AHTR的设计参数下堆芯产生的热量能够被有效的输出，设计具有较大的安全裕度。计算结果对于球床堆的优化设计提供了一定的参考价值。

References

[1]	Sydney J. Ball, Charles W. Fosberg. (2004).Advanced High-Temperature Reactor (AHTR) Loss-of-Forced-Circulation Accidents.2ndInternational Topic Meeting on High Temperature Reactor Technology, Beijing, China. Paper F07
[2]	Philippe Bardet, Edward Blandford, Massimiliano Fratoni, Aurelie Niquille, Ehud Greenspan and Per F. Peterson.(2008).Design, Analysis and Development of the Modular PB-AHTR. Proceedings of ICAPP’08. Paper 8211.
[3]	Massimiliano Fratoni, Development and applications of methodologies for the neutronic design of the Pebble Bed Advanced High Temperature Reactor (PB-AHTR), Doctor Thesis.
[4]	Jorge Abejón Orzáez, Neutronics Analysis of A Modified Pebble Bed Advanced High Temperature Reactor , Master Thesis.
[5]	Fluent 6.3 User’s Guide, Fluent Inc.
[6]	Fluent 6.3 UDF Manual, Fluent Inc.
[7]	Roy C. Tew, Terry Simon, David Gedeon, Mounir Ibrahim and Wei Rong, An Initial Non-Equilibrium Porous-Media Model for CFD Simulation of Stirling Regenerators, NASA/TM—2006-214391.
[8]	Ergun S, Fluid flow through packed columns, Chemical Engineering Progress, 1952, 48(2): 89-94.
[9]	KTA 3102.3, Reactor Core Design of High-Temperature Gas-Cooled Reactors Part 3: Loss of Pressure through Friction in Pebble Bed Cores, 1981.
[10]	S.J. de Zwaan, The Liquid Salt Pebble Bed Reactor, Master Thesis.
[11]	David Samuel, MOLTEN SALT COOLANTS FOR HIGH TEMPERATURE REACTORS, IAEA Internship Report INPRO COOL, DRAFT.
[12]	P. Zehner and E.U.Schlunder, Thermal conductivity of granular materials at moderate temperatures, ChemieIngenieur Technik., 42:933–941, 1970.
[13]	宋士雄，魏泉，蔡翔舟，郭威．基于CFD方法的球床式高温气冷堆稳态热工水力分析[J].核技术．2013, 36 12。
[14]	Wakao, N., Kaguei, S., Funazkri, T., Effect of fluid dispersion coefficients on particle-to-fluid heat transfer coefficients in packed beds: correlation of Nusselt numbers, Chemical Engineering Science vol. 34, pp. 325-336, 1979.
[15]	International Atomic Energy Agency, "High temperature gas cooled reactor fuels and materials," IAEA-TECDOC-1645, VIENNA, 2010.
[16]	闫晓，肖泽军，黄彦平，王飞，多孔介质中流动换热特性的研究进展，核动力工程，2006，2，Vol. 27. No. 1(S1)。
[17]	YAN Xiao，XIAO Ze-jun，HUANG Yan-ping，Wang Fei, Research Progress on Flow and Heat Transfer in Porous Media, Nuclear Power Engineering, 2006，2，Vol. 27. No. 1(S1) (in Chinese)
[18]	杜建华, 王补宣. 带内热源多孔介质中的受迫对流换热[J]. 工程热物理学报. 1999, 20(1): 69～73.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133