Correlation of isothermal bainite transformation and austenite stability in quenching and partitioning steels

IF 3.1 2区 材料科学 Q1 METALLURGY & METALLURGICAL ENGINEERING Journal of Iron and Steel Research(International) Pub Date : 2017-11-01 DOI:10.1016/S1006-706X(17)30159-0
Shan Chen, Guang-zhen Wang, Chun Liu, Chen-chong Wang, Xian-ming Zhao, Wei Xu
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引用次数: 16

Abstract

The possible decomposition of metastable austenite during the partitioning process in the high-end quenching and partitioning (Q&P) steels is somewhat neglected by most researchers. The effects of primary martensite and alloying elements including manganese, cobalt and aluminum on the isothermal decomposition of austenite during typical Q&P process were studied by dilatometry. The transformation kinetics was studied systematically and resulting microstructures were discussed in details. The results suggested that the primary martensite decreased the incubation period of isothermal decomposition by accelerating the nucleation process owing to dislocations especially on phase and grain boundaries. This effect can be eliminated by a flash heating which recovered dislocations. Co addition significantly promoted the bainite transformation during partitioning while Al and Mn suppressed the isothermal bainite transformation. The bainite transformation played an important role in carbon distribution during partitioning, and hence the amount and stability of austenite upon final quenching. The bainite transformation during partitioning is an important factor in optimizing the microstructure in Q&P steels.

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淬火配分钢等温贝氏体相变与奥氏体稳定性的关系
在高端淬火配分(Q&P)钢中,亚稳奥氏体在配分过程中可能发生的分解在一定程度上被大多数研究者所忽视。采用膨胀法研究了典型Q&过程中初生马氏体和锰、钴、铝等合金元素对奥氏体等温分解的影响。系统地研究了相变动力学,并详细讨论了相变后的微观结构。结果表明,初生马氏体主要是由于位错(尤其是在相界和晶界上的位错)的存在,加速了合金的成核过程,从而缩短了等温分解的潜伏期。这种影响可以通过闪光加热来消除,从而恢复位错。Co的加入显著促进了等温贝氏体的转变,而Al和Mn的加入抑制了等温贝氏体的转变。贝氏体相变对分配过程中的碳分布起重要作用,从而影响最终淬火时奥氏体的数量和稳定性。分配过程中贝氏体相变是优化Q&钢组织的重要因素。
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CiteScore
4.30
自引率
0.00%
发文量
2879
审稿时长
3.0 months
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