A Model to Predict the Microstructural Constituents after Quenching and Partitioning of Martensitic Stainless Steels

IF 0.3 Q4 THERMODYNAMICS

HTM-Journal of Heat Treatment and Materials Pub Date : 2021-04-01 DOI:10.1515/htm-2020-0008

S. Kresser, R. Schneider, H. Zunko, C. Sommitsch

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引用次数: 3

Abstract

Abstract The typical heat treatment of martensitic stainless steels comprises hardening and subsequent tempering. Depending on the application and size of the component, tempering is carried out either at low temperatures (< 300 °C) or at high temperatures (> 500 °C). In this paper, tempering at lower temperatures is examined. First, the austenitizing step is considered in greater detail and an optimized formula for the calculation of the MS temperature of such steel grades is created in order to enable to be modelled. For the calculations, the austenite composition is determined at different austenitizing temperatures using thermodynamic simulation. Furthermore, the transformation of austenite into martensite during quenching is described with the help of the Koistinen-Marburger equation. The second part deals with effects in the material at low holding temperatures. Here, the influence of different hardening temperatures and interception temperatures of the quenching procedure is investigated. There is no complete partitioning at temperatures of 300 °C. Certain tempering processes can also take place, such as the formation of transition carbides, so-called M3C carbides. A typical tempering with formation of stable Cr-rich carbides does not occur at this low temperature. Finally, the calculated results of the model correlate well with microstructural investigations (XRD, LOM). ◼

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马氏体不锈钢淬火及分配后组织成分预测模型

马氏体不锈钢的典型热处理包括淬火和回火。根据应用和部件的尺寸，回火可以在低温(< 300°C)或高温(> 500°C)下进行。本文对低温回火进行了研究。首先，更详细地考虑了奥氏体化步骤，并创建了用于计算此类钢牌号的MS温度的优化公式，以便能够建模。为了计算，利用热力学模拟确定了不同奥氏体化温度下的奥氏体成分。此外，还利用Koistinen-Marburger方程描述了淬火过程中奥氏体向马氏体的转变。第二部分处理在低温下对材料的影响。研究了淬火过程中不同淬火温度和淬火截留温度的影响。在300℃的温度下没有完全的分解。某些回火过程也会发生，例如形成过渡碳化物，即所谓的M3C碳化物。在这个低温下不会发生典型的回火，形成稳定的富铬碳化物。最后，模型计算结果与微观结构研究(XRD, LOM)吻合良好。◼

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

HTM-Journal of Heat Treatment and Materials THERMODYNAMICS-

CiteScore

1.50

自引率

33.30%

发文量