期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

Experimental investigation on the bursting of single molten droplet in coolant 被引量:1

Experimental investigation on the bursting of single molten droplet in coolant
下载PDF
导出
摘要 An experiment facility for observing low-temperature molten tin alloy droplet into water was es- tablished to investigate mechanisms of vapor explosion occurring in severe accidents of a fission nuclear reactor.The vapor explosion behaviors of the molten material were observed by a high-speed video cam- era and the vapor explosion pressures were recorded by a pressure transducer mounted under the water surface.The results showed that the pressure reached a peak value when the molten metal temperature was 600℃-650℃,and the coolant temperature had an obvious decreasing effect on the droplet breakups.A model for single droplet fuel/coolant interaction is proposed.It considers that in the case of Rayleigh-Taylor instability,the coolant that jets from opposite direction penetrates into the fuel and the vapor explosion occurs because of the rapid evaporation.This model explained the effect of metal droplet temperature and coolant temperature on vapor explosion. An experiment facility for observing low-temperature molten tin alloy droplet into water was established to investigate mechanisms of vapor explosion occurring in severe accidents of a fission nuclear reactor. The vapor explosion behaviors of the molten material were observed by a high-speed video cam- era and the vapor explosion pressures were recorded by a pressure transducer mounted under the water surface. The results showed that the pressure reached a peak value when the molten metal temperature was 600℃-650℃, and the coolant temperature had an obvious decreasing effect on the droplet breakups. A model for single droplet fuel/coolant interaction is proposed. It considers that in the case of Rayleigh-Taylor instability, the coolant that jets from opposite direction penetrates into the fuel and the vapor explosion occurs because of the rapid evaporation. This model explained the effect of metal droplet temperature and coolant temperature on vapor explosion.
作者 LI Tianshu YANG Yanhua YUAN Minghao HU Zhihua
机构地区 School of Mechanical Power Engineering
出处 《Nuclear Science and Techniques》 SCIE CAS CSCD 2007年第6期376-380,共5页 核技术(英文)
基金 Supported by the National Natural Science Foundation of China(No.50376036).
关键词 蒸汽爆炸 FCI 实验装置 冷却剂 Vapor explosion, FCI, Observable experimental equipment
分类号 TK12 [动力工程及工程热物理—工程热物理]
  • 相关文献

参考文献9

  • 1Yang Yanhua. Multi-phase simulations for phenomena in vapor explosions, University of Tokyo, Doctoral Dissertation, 1996.
  • 2Theofanous T G, Yuen W W. "The prediction of dynamic loads from ex-vessel steam explosions". Proceedings of the International Conference on New Trends in Nuclear System. Thermohydraulics, Pisa, 1994. 257-270.
  • 3Yutaka Abea. J Nuclear Engineering and Design, 2004, 230: 277-291.
  • 4Corradinietal M L. J Nuclear Safety, 1991, 32(3): 337-362.
  • 5Huhfiniemi I, MagaUon D. J Nuclear Engineering and Design, 2001, 204: 391-400.
  • 6Kim B, Corradini M L. J Nuclear Science and Engineering, 1988, 88: 16-28.
  • 7Nelson L S. "Steam explosion triggering phenomena; stainless steel and corium-E stimulants studied with a floodable arc melting apparatus" SAND77-998, NUREG/CR-0122, Sandia National Laboratories, May 1978.
  • 8Buchanan D J. Phys D, 1974, 7: 1441.
  • 9Henry R E. Fauske H K "Nucleation characteristics in physical explosion," Proc. 3^rd Specialists' Mtg. Sodium Fuel Interaction, Tokyo, Japan, March 1976.

同被引文献9

  • 1LUKETA-HANLIN A. A review of large-scale LNG spills: experiments and modeling[J]. Join'hal of Hazard- ous Materials,2006,132 (2 -3) :119 - 140.
  • 2CLARKE H, MARTINEZ-HERASME A, CROOKES R, et al. Experimental study of jet structure and pressuriza- tion upon liquid nitrogen injection into water[J]. Multi- phase Flow, 2010, 36(11 -12):940-949.
  • 3ZOU Yu, HUAI Xiu-lan, LIN Lin. Molecular dynamics simulation for homogeneous nucleation of water liquid ni- trogen in explosive boiling [J]. Applied Thermal Engi- neering ,2010,30(8 - 9) :895 - 863.
  • 4ZHANG Bin, WU Wan-qing, ZHANG Jian-wei. Numeri- cal study on boiling mechanism and rapid phase transfer phenomenon of LNG discharging on water[J]. Advanced Materials Research, 2012, 516-517: 97- 106.
  • 5WATANABE T, MAEHARA H, ITOH S. Explosive e- vaporating phenomena of cryogenic fluids by direct cont- racitng normal temperature [J]. International Journal of Muhiphysics, 2012,6 (2) : 107 - 114.
  • 6KHABEEV N S. Simulation of vapour explosions [J]. Applied Energy, 1999, 64 (1 -4) :317 -321.
  • 7MEISTER B J. The formation and stability of jets in im- miscible liquid systems [D]. New York : Cornell Univer- sity, 1996:30 - 50.
  • 8TENG H, YAMASAKI A. Effect of hydrates on insta- bility of liquid CO2 jets in the deep ocean [J]. Energy, 1997,22 (2 - 3 ) :273 - 278.
  • 9张彬,于桂峰,吴宛青,胡远为.液化天然气泄漏扩散数值模拟[J].大连海事大学学报,2013,39(2):99-102. 被引量:3

引证文献1

Nuclear Science and Techniques
2007年 第6期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部