In-Situ Hydrogen Charging Effect on the Fracture Behaviour of 42CrMo4 Steel Submitted to Various Quenched and Tempering Heat Treatments

Hydrogen Pub Date : 2023-12-11 DOI:10.3390/hydrogen4040060

A. Imdad, Francisco Javier Belzunce Varela

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Abstract

Research into safer, durable steels to be used in hydrogen-rich environments has been gaining importance in recent years. In this work, 42CrMo4 steel was subjected to quenched and tempered heat treatments using different temperature and time durations, in order to obtain different tempered martensite microstructures. Tensile tests on smooth and notched specimens were then performed in the air as well as with in situ electrochemical hydrogen charging using two different hydrogenated conditions. The harmful effects of hydrogen are more evident in tensile tests performed on notched specimens. The harder (stronger) the steel, the more hydrogen embrittlement occurs. As the steel’s internal local hydrogen concentration rises, its strength must be gradually reduced in order to choose the best steel. The observed embrittlement differences are explained by modifications in the operative failure micromechanisms. These change from ductile (microvoid coalescence) in the absence of hydrogen, or under low hydrogen levels in the case of the softest steels, to brittle (cleavage or even intergranular fracture) under the most severe conditions.

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原位充氢对经过各种淬火和回火热处理的 42CrMo4 钢断裂行为的影响

近年来，在富氢环境中使用更安全、更耐用的钢材的研究越来越受到重视。在这项工作中，对 42CrMo4 钢进行了淬火和回火热处理，采用不同的温度和时间持续时间，以获得不同的回火马氏体微观结构。然后，对光滑和有缺口的试样进行拉伸试验，试验在空气中进行，并在两种不同的氢化条件下进行原位电化学充氢。在缺口试样上进行的拉伸试验中，氢的有害影响更为明显。钢的硬度（强度）越高，发生氢脆的可能性就越大。随着钢材内部局部氢浓度的升高，其强度必须逐渐降低，以便选择最佳钢材。观察到的脆性差异可以用失效微观机制的变化来解释。在无氢或氢含量较低的情况下，这些微观机制会从韧性（微空凝聚）转变为脆性（劈裂或甚至晶间断裂）。

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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