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LJ338ESR钢富铜纳米相引起的微应变、硬度和耐蚀性变化
引用本文:贺吉白,刘宏玉,符铎潇,刘承珊,王欣琴,李民华. LJ338ESR钢富铜纳米相引起的微应变、硬度和耐蚀性变化[J]. 钢铁研究学报, 2019, 31(9): 848-853. DOI: DOI:10.13228/j.boyuan.issn1001-0963.20190001
作者姓名:贺吉白  刘宏玉  符铎潇  刘承珊  王欣琴  李民华
作者单位:武汉科技大学理学院,湖北武汉,430065;武汉科技大学理学院,湖北武汉430065;冶金工业过程系统科学湖北省重点实验室,湖北武汉430065;湖北上大模具材料科技股份有限公司,湖北鄂州,436054
摘    要:摘要:沉淀硬化钢中纳米富Cu相的析出,使微应变(α)发生改变,这不仅影响力学性能,也对腐蚀性能产生作用。为了探索α对腐蚀性能和力学性能的影响规律,通过XRD谱型分析,对商用钢LJ338ESR 在300~600℃不同时间时效析出富铜纳米相后的α、硬度和电荷转移电阻(Rf)进行了研究。结果表明,300~450℃时效,8h前α值随时效时间延长而升高,8h后由于析出相与基体失去共格,α随着时效时间延长而降低;硬度与α变化相似。600℃时效,α在时效2h达到峰值,这归因于共格微应变和逆变奥氏体两种相反因素的共同影响;600℃逆变奥氏体生成,使硬度变化较小。析出相与基体保持共格时,Rf和α随时效时间的变化呈良好的反比关系,即Rf随α的增大而减小。

关 键 词:XRD  富铜相  微应变  硬度  耐腐蚀性

Changes in microstrain,hardness and corrosion resistance caused by Cu rich nanophases in LJ338ESR steel
HE Ji-bai,LIU Hong-yu,FU Duo-xiao,LIU Cheng-shan,WANG Xin-qin,LI Min-hua. Changes in microstrain,hardness and corrosion resistance caused by Cu rich nanophases in LJ338ESR steel[J]. Journal of Iron and Steel Research, 2019, 31(9): 848-853. DOI: DOI:10.13228/j.boyuan.issn1001-0963.20190001
Authors:HE Ji-bai  LIU Hong-yu  FU Duo-xiao  LIU Cheng-shan  WANG Xin-qin  LI Min-hua
Affiliation:1.College of Science, Wuhan University of Science and Technology, Wuhan 430065, Hubei, China; 2.Hubei Province Key Laboratory of Systems Science in Metallurgical Process, Wuhan 430065, Hubei, China;3. Hubei Shangda Mould Materials Technology Co., Ltd., Ezhou 436054, Hubei, China
Abstract:The precipitation of Cu rich nanophases in precipitation hardening steel leads to the change of microstrain (α), influencing both mechanical and corrosion properties. In order to explore the effect of α on corrosion and mechanical properties, the investigation of changes in α, hardness and charge transfer resistance (Rf) after the precipitation of Cu rich nanophases in commercial steel LJ338ESR aged at 300-600℃ for various time was performed by the XRD profile analysis. The results show that with aging at 300-450℃, the α increases with aging time less than 8h, and then α decreases with aging time due to precipitates losing coherency with the base metal, while the variation of hardness exhibits a similar trend as α. With aging at 600℃, the α peaks at 2h, which is attributed to the two opposite influences:coherent microstrain and reverted austenite. The reverted austenite forms at 600℃, making the hardness change slightly. The changing laws with aging time for the Rf and α exhibit a good polynomial correlation of inverse relationship in the coherent regime, i.e. the Rf decreases with increasing the α.
Keywords:Key words:XRD  Cu rich phase  microstrain  hardness  corrosion resistanceLJ338ESR  
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