Influence of Deep Rolling and Induction Hardening on Microstructure Evolution of Crankshaft Sections made from 38MnSiVS5 and 42CrMo4

IF 0.3 Q4 THERMODYNAMICS
A. Fischer, B. Scholtes, T. Niendorf, M. S. A. Fischer, Dr.-Ing. habil. Berthold Scholtes, Prof. Dr.-Ing. Thomas Niendorf
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引用次数: 3

Abstract

Abstract In order to improve properties of complex automotive components, such as crankshafts, in an application-oriented way, several surface hardening treatments can be applied. Concerning the material performance the definition of adequate process parameters influences the resulting surface properties and, thus, the effectiveness of surface hardening treatments. To analyze most relevant process-microstructure-property relationships, the present paper reports results obtained by two different well-established surface hardening procedures, i. e. deep rolling as a mechanical treatment and induction hardening as a thermal treatment. For each hardening process widely used crankshaft steel grades, i. e. a medium carbon 38MnSiVS5 microalloyed steel and a quenched and tempered 42CrMo4 were selected and thoroughly characterized upon processing, using equal parameter settings. The results reveal that deep rolling in contrast to induction hardening proves to be a less sensitive surface layer treatment with regard to small differences in the initial microstructure, the chemical composition and the applied process parameters. Differences in microstructure evolution with respect to the applied surface hardening treatment are studied and discussed for the highly stressed fillet region of automotive crankshaft sections for all conditions. In this context, high-resolution SEM-based techniques such as EBSD and ECCI are proven to be very effective for fast qualitative evaluation of induced microstructural changes.
深滚和淬火对38MnSiVS5和42CrMo4曲轴型材组织演变的影响
为了提高曲轴等复杂汽车零部件的性能,可采用多种表面硬化处理方法。关于材料性能,适当的工艺参数的定义影响得到的表面性能,从而影响表面硬化处理的有效性。为了分析大多数相关的工艺-显微组织-性能关系,本文报告了两种不同的已建立的表面硬化程序所获得的结果,即深滚作为机械处理和感应淬火作为热处理。对于每一种淬火工艺,都选择了广泛使用的曲轴钢牌号,即中碳38MnSiVS5微合金钢和调质42CrMo4钢,并在加工时使用相同的参数设置进行了彻底的表征。结果表明,与感应淬火相比,深轧是一种较不敏感的表面层处理,其初始组织、化学成分和应用的工艺参数差异较小。研究和讨论了各种条件下汽车曲轴高应力圆角区域的表面硬化处理在微观组织演变方面的差异。在这种情况下,高分辨率扫描电镜技术,如EBSD和ECCI,被证明是非常有效的快速定性评价诱发的微观结构变化。
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来源期刊
CiteScore
1.50
自引率
33.30%
发文量
43
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