Interacting sensitivities of alloy 600 PWSCC to stress intensity factor, yield stress, temperature, carbon concentration, and crack growth orientation Alloy 600

Hall M. M. Jr.

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Interacting sensitivities of alloy 600 PWSCC to stress intensity factor, yield stress, temperature, carbon concentration, and crack growth orientation Alloy 600

机译：合金600 PWSCC对应力强度因子，屈服应力，温度，碳浓度和裂纹扩展取向的相互作用敏感性

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Analyses of Alloy 600 primary water stress corrosion cracking data show there are interacting sensitivities of crack growth rate to applied stress intensity factor, yield stress, temperature, carbon concentration and crack growth orientation. The effects of these variables are expressed quantitatively using a crack advance model that is rate-limited by crack-tip-strain rate. Crystallographic texture and dynamic strain aging are considered to account for contrasting behavior observed for ST and LT orientation crack growth. Crack growth is conjectured to be rate-limited by "junction" pinning of mobile dislocations strengthened by interstitial carbon (ST) and "lineal" pinning by substitutional Cr and Fe (LT).

机译：合金600的一次水应力腐蚀开裂数据分析表明，裂纹扩展速率与施加的应力强度因子，屈服应力，温度，碳浓度和裂纹扩展取向之间存在相互作用的敏感性。使用受裂纹尖端应变率限制的裂纹扩展模型定量表示这些变量的影响。晶体学织构和动态应变时效被认为是ST和LT取向裂纹扩展观察到的对比行为。据推测，裂纹扩展的速率受间隙碳（ST）加强的移动位错的“接合”钉扎和由替代的Cr和Fe（LT）加强的“线性”钉扎的限制。

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来源
《Corrosion science》 |2017年第8期|152-165|共14页
作者
Hall M. M. Jr.;
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1366 Hillsdale Dr, Monroeville, PA 15146 USA;

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正文语种 eng
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Modelling studies; Stress corrosion; Effects of strain; Hydrogen embrittlement; Selective oxidation;

机译：建模研究;应力腐蚀;应变效应;氢脆;选择性氧化;

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专利

1. PWSCC Growth Assessment Model Considering Stress Triaxiality Factor for Primary Alloy 600 Components [J] . Kim Jong-Sung, Kim Ji-Soo, Jeon Jun-Young, Nuclear engineering and technology . 2016,第4期

机译：考虑三轴应力因子的合金初生600零件的PWSCC生长评估模型
2. PWSCC Growth Assessment Model Considering Stress Triaxiality Factor for Primary Alloy 600 Components [J] . Jong-Sung Kim, Ji-Soo Kim, Jun-Young Jeon, Nuclear engineering and technology . 2016,第4期

机译：考虑主要合金600分量的应力三轴性因子的PWSCC增长评估模型
3. Stress corrosion crack growth rate behaviour of Ni alloys 182 and 600 in high temperature water (part one) [J] . Peter L. Andresen, Lisa M. Young, Paul W. Emigh Stainless steel world . 2003,第5期

机译：Ni合金182和600在高温水中的应力腐蚀裂纹扩展速率行为（第一部分）
4. Stress Corrosion Crack Growth Rate Behavior of Ni Alloys 182 and 600 in High Temperature Water [C] . Peter L. Andresen, Lisa M. Young, Paul W. Emigh Corrosion Annual Conference and Exposition . 2006

机译：高温水中Ni合金182和600的应力腐蚀裂纹生长速率行为
5. Stress corrosion cracking and internal oxidation of alloy 600 in high temperature hydrogenated steam and water [D] . Lindsay, John. 2015

机译：高温氢化蒸汽和水中合金600的应力腐蚀开裂和内部氧化
6. Stress Corrosion Cracking Behavior of Alloy 600 Coupled to Magnetite under High-Temperature Caustic Conditions [O] . Geun Dong Song, Jeoh Han, Soon-Hyeok Jeon, 2019

机译：高温苛性条件下耦合磁铁矿的600合金的应力腐蚀开裂行为
7. Susceptibility to Severe PWSCC (primary water stress corrosion cracking) of LTMA (low temperature mill anneal) Alloy 600 [O] . Sung Soo Kim, Jung Jong Yeob, Young Suk Kim 2020

机译：对LTMS（低温轧机退火）合金600的严重PWSCC（初级水应激腐蚀裂解）的敏感性
8. Stress Corrosion Cracking of Alloy 600 and Alloy 690 in All Volatile Treated Water at Elevated Temperatures. Final Report (PWR) [R] . Theus, G. J., Emanuelson, R. H. 1983

机译：高温下所有挥发性处理水中合金600和合金690的应力腐蚀开裂。最终报告（pWR）

Interacting sensitivities of alloy 600 PWSCC to stress intensity factor, yield stress, temperature, carbon concentration, and crack growth orientation Alloy 600

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