文章摘要
罗锐,程晓农,郑琦,朱晶晶,王皎,刘天,陈光,杨乔.新型含铝奥氏体耐热合金Fe-20Cr-30Ni-0.6Nb-2Al-Mo的动态再结晶行为[J].材料导报,2017,31(18):136-140
新型含铝奥氏体耐热合金Fe-20Cr-30Ni-0.6Nb-2Al-Mo的动态再结晶行为
Dynamic Recrystallization Behavior of an Alumina-forming Austenitic Alloy Fe-20Cr-30Ni-0.6Nb-2Al-Mo
  
DOI:10.11896/j.issn.1005-023X.2017.018.027
中文关键词: 含铝奥氏体耐热合金 流变应力 本构方程 动态再结晶行为 形核机制
英文关键词: alumina-forming austenitic alloy, flow stress, constitutive equation, dynamic recrystallization behavior, nucleation mechanism
基金项目:“十二五”国家高技术研究发展计划(863计划)重大资助项目(2012AA03A501);江苏省2014年度普通高校研究生科研创新计划项目(KYLY-1027)
作者单位
罗锐 江苏大学材料科学与工程学院,镇江 212013 
程晓农 江苏大学材料科学与工程学院,镇江 212013 
郑琦 江苏大学材料科学与工程学院,镇江 212013 
朱晶晶 江苏大学材料科学与工程学院,镇江 212013 
王皎 江苏大学材料科学与工程学院,镇江 212013 
刘天 江苏大学材料科学与工程学院,镇江 212013 
陈光 江苏大学材料科学与工程学院,镇江 212013 
杨乔 江苏大学材料科学与工程学院,镇江 212013 
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中文摘要:
      在Gleeble-3500热力模拟试验机上对一种新型奥氏体耐热合金(Fe-20Cr-30Ni-0.6Nb-2Al-Mo)进行单道次热压缩实验,结合OM、EBSD及TEM等表征手段,研究了该合金在950~1 100 ℃和0.01~1 s-1热变形参数下的动态再结晶行为,采用回归法确定了合金的热变形激活能和表观应力指数,并以此构建其高温本构模型。实验结果表明,新型奥氏体耐热合金的应力水平随变形温度的升高而降低,随应变速率的增大而升高;动态再结晶行为更易发生在较高变形温度或较低应变速率下。采用lnθ-ε曲线的三次多项式拟合求解临界再结晶拐点的方法,较准确地预测了合金的动态再结晶临界点。此外,归纳出该合金在动态再结晶过程中的形核机制,主要包括应变诱导晶界迁移、晶粒碎化以及亚晶的合并。
英文摘要:
      Isothermal compression tests at a temperature of 950—1 100 ℃ and strain rates ranging from 0.01 to 1 s-1 were performed on alumina-forming austenitic (AFA) alloy Fe-20Cr-30Ni-0.6Nb-2Al-Mo to reveal the hot deformation characteristics. The evolutions of microstructure and nucleation mechanisms of dynamic recrystallization (DRX) were analyzed combined with the technique of OM, EBSD and TEM. The regression method was adopted to determine the thermal deformation activation energy, apparent stress index, and to construct a thermal deformation constitutive model. The results show that the flow stress is strongly dependent on deformation temperature and strain rate, which increases with decreasing temperature and increasing strain rate. The DRX phenomenon occurred more easily at comparably higher deformation temperatures or lower strain rates. Based on the method for solving the inflection point via cubic polynomial fitting of lnθ-ε curves, the critical strain (εc) during DRX were precisely predicted. The nucleation mechanisms of DRX during thermal deformation mainly included the strain-induced grain boundary (GB) migration, grain fragmentation, and subgrain coalescence.
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