Coolant stratification in nuclear power facilities

被引:0
|
作者
A. N. Opanasenko
A. P. Sorokin
D. G. Zaryugin
M. V. Rachkov
机构
[1] State Science Center of the Russian Federation – Leipunskii Institute for Physics and Power Engineering (GNTs RF – FEI),
来源
Atomic Energy | 2012年 / 111卷
关键词
D O I
暂无
中图分类号
学科分类号
摘要
Computational and experimental studies of the structure of the motion of stratified coolant and its temperature regime are performed on models of different elements of the circulation loops of fast and thermal reactors. The investigations have shown that in the presence of stable stratification thermogravitational forces bring about the formation of stagnant and recirculation formations with large temperature gradients and pulsations at interfaces. The data obtained show that stratification phenomena must be taken into account when validating the reliability of the control, safety, and nominal service lives of nuclear power facilities.
引用
收藏
页码:172 / 178
页数:6
相关论文
共 50 条
  • [31] Study on application of enriched boric in primary coolant of nuclear power plants
    Institute of Nuclear Science and Technology, Sichuan University, Chengdu
    610064, China
    不详
    610041, China
    [J]. Hedongli Gongcheng, 3 (110-113):
  • [32] SEISMIC RESPONSE ANALYSIS OF REACTOR COOLANT PUMP IN NUCLEAR POWER PLANT
    Ren, Zhaohui
    Ma, Hui
    Li, He
    Song, Guiqiu
    Zhou, Wenjian
    [J]. ICONE16: PROCEEDING OF THE 16TH INTERNATIONAL CONFERENCE ON NUCLEAR ENGINEERING - 2008, VOL 1, 2008, : 225 - 230
  • [33] Membrane Systems and their Use in Nuclear Power Plants - Treatment of Primary Coolant
    Kus, Pavel
    Bartova, Sarka
    Skala, Martin
    Vonkova, Katerina
    Zach, Vaclav
    Kopa, Roman
    [J]. ATW-INTERNATIONAL JOURNAL FOR NUCLEAR POWER, 2016, 61 (03): : 189 - +
  • [34] Continuous measurement of iodine concentration in the primary coolant of a nuclear power plant
    Kuroze, Y
    Yamada, M
    Shintani, H
    Nunoko, A
    Murakami, R
    [J]. 1996 IEEE NUCLEAR SCIENCE SYMPOSIUM - CONFERENCE RECORD, VOLS 1-3, 1997, : 135 - 138
  • [35] Analysis of the Polonium Hazard in Nuclear Power Systems with Lead–Bismuth Coolant
    D. V. Pankratov
    E. I. Efimov
    G. I. Toshinskii
    L. D. Ryabaya
    [J]. Atomic Energy, 2004, 97 : 559 - 563
  • [36] VERIFICATION OF REVERSE OSMOSIS FOR PRIMARY COOLANT TREATMENT IN TEMELIN NUCLEAR POWER
    Bartova, S.
    Kus, P.
    Skala, M.
    Vonkova, K.
    Zach, V
    Kopa, R.
    [J]. PROCEEDINGS OF THE 4TH INTERNATIONAL CONFERENCE ON CHEMICAL TECHNOLOGY, 1ST EDITION, 2016, : 382 - 384
  • [37] New concept for the vessel of a nuclear power reactor with supercritical coolant parameters
    Shevelev, G. N.
    Gordo, V. P.
    [J]. ATOMIC ENERGY, 2008, 105 (06) : 414 - 417
  • [38] CONTROL OF COOLANT AND MODERATOR OF A NUCLEAR POWER PLANT WITH AID OF GAS CHROMATOGRAPHY
    PIETRIK, I
    VESPALEC, R
    [J]. JOURNAL OF RADIOANALYTICAL CHEMISTRY, 1971, 8 (01): : 61 - &
  • [39] Surge Protection of the Reactor Coolant Pump Motors in Nuclear Power Plants
    Chang, Choong-koo
    Musyoka, Erastus Mwongela
    [J]. 2021 24TH INTERNATIONAL CONFERENCE ON ELECTRICAL MACHINES AND SYSTEMS (ICEMS 2021), 2021, : 437 - 442
  • [40] A METHOD OF DETERMINING PARTICLE DISPERSION IN NUCLEAR-POWER STATION COOLANT
    VIZGIN, EI
    LAZAREV, IP
    CHERNOROTOV, ES
    [J]. SOVIET ATOMIC ENERGY, 1986, 61 (04): : 781 - 784
12345