Prediction of radiation embrittlement of WWER-1000 reactor vessel materials considering the influence of alloying elements and high content of copper

被引:0
|
作者
Margolin B.Z. [1 ]
Yurchenko E.V. [1 ]
机构
[1] National Research Center Kurchatov Institute—Central Research Institute of Structural Materials Prometey, St. Petersburg
来源
Inorganic Materials: Applied Research | 2017年 / 8卷 / 6期
关键词
alloying elements; irradiation embrittlement; method of prediction; vessel materials; WWER-1000 reactor vessel;
D O I
10.1134/S2075113317060107
中图分类号
学科分类号
摘要
Basing on the analysis of the radiation embrittlement of RPV materials, the paper proposes a model and dependencies for description of WWER-1000 vessel material embrittlement with copper content above 0.10%. Standard dose-time trend curves have been modernized. The dose-time trend curves have been modernized. © 2017, Pleiades Publishing, Ltd.
引用
收藏
页码:936 / 943
页数:7
相关论文
共 15 条
  • [1] Radiation embrittlement (RE) of the WWER-1000 vessel materials (VM)
    Nikolaeva, A.V.
    Nikolaev, Yu.A.
    Kevorkyan, Yu.R.
    Atomnaya Energiya, 2001, 90 (05): : 359 - 366
  • [2] A new approach to description of in-service embrittlement of WWER-1000 reactor pressure vessel materials
    B. Z. Margolin
    V. A. Nikolaev
    E. V. Yurchenko
    Yu. A. Nikolaev
    D. Yu. Erak
    A. V. Nikolaeva
    Strength of Materials, 2010, 42 : 2 - 16
  • [3] Conservative estimations of irradiation embrittlement of reactor pressure vessel steels for WWER-1000 lifetime prediction
    Anosov, Nikolai Petrovich
    Skorobogatykh, Vladimir Nikolaevich
    Gordyuk, Lyubov' Yur'yevna
    Mikheev, Vasilii Anatol'evich
    Pogorelov, Egor Vasil'yevich
    Shamardin, Valentin Kuz'mich
    MULTIDISCIPLINE MODELING IN MATERIALS AND STRUCTURES, 2019, 15 (01) : 246 - 257
  • [4] A NEW APPROACH TO DESCRIPTION OF IN-SERVICE EMBRITTLEMENT OF WWER-1000 REACTOR PRESSURE VESSEL MATERIALS
    Margolin, B. Z.
    Nikolaev, V. A.
    Yurchenko, E. V.
    Nikolaev, Yu. A.
    Erak, D. Yu.
    Nikolaeva, A. V.
    STRENGTH OF MATERIALS, 2010, 42 (01) : 2 - 16
  • [5] Probabilistic analysis of mechanical properties of WWER-1000 reactor pressure vessel materials
    Gorynin I.V.
    Timofeev B.T.
    Sorokin A.A.
    Strength of Materials, 2006, 38 (2) : 117 - 127
  • [6] Prediction of irradiation embrittlement in WWER-440 reactor pressure vessel materials
    Brumovsky, M.
    Kytka, M.
    Debarberis, L.
    Gillemot, F.
    Kryukov, A.
    Valo, M.
    PROBLEMS OF ATOMIC SCIENCE AND TECHNOLOGY, 2007, (06): : 72 - 77
  • [7] Analysis of Relationship Between the Radiation Embrittlement Mechanisms and the Influence of Neutron Flux in Respect of WWER Reactor Pressure Vessel Materials
    Margolin, B. Z.
    Yurchenko, E. V.
    Morozov, A. M.
    Pirogova, N. E.
    STRENGTH OF MATERIALS, 2013, 45 (04) : 406 - 423
  • [8] Analysis of Relationship Between the Radiation Embrittlement Mechanisms and the Influence of Neutron Flux in Respect of WWER Reactor Pressure Vessel Materials
    B. Z. Margolin
    E. V. Yurchenko
    A. M. Morozov
    N. E. Pirogova
    Strength of Materials, 2013, 45 : 406 - 423
  • [9] Effect of nickel content on mechanical properties and fracture toughness of weld metal of WWER-1000 reactor vessel welded joints
    Zubchenko, AS
    Vasilchenko, GS
    Starchenko, EG
    Nosov, SI
    INTERNATIONAL JOURNAL OF PRESSURE VESSELS AND PIPING, 2004, 81 (08) : 713 - 717
  • [10] Neuronet analysis of the effect of alloying elements on the radiation embrittlement of VVER-440 vessel materials
    Obraztsov, S. M.
    Birzhevoi, G. A.
    Konobeev, Yu. V.
    Pechenkin, V. A.
    Rachkov, V. I.
    ATOMIC ENERGY, 2006, 101 (05) : 809 - 815
12