The Role of Hydrogen on the Separation of Interfaces of Supermartensitic Stainless Steel S13Cr

Materials Engineering eJournal Pub Date : 2020-10-13 DOI:10.2139/ssrn.3708758

Debora Lima Molter, M. L. Castro, D. D. dos Santos

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Abstract

This paper outlines experimental procedures and numerical analyses to research Hydrogen embrittlement (HE) of the supermatensitic stainless steel (SMSS) S13Cr submitted to different cathodic potentials. Hydrogen diffusion behavior was investigated by means of two electrochemical permeation techniques, namely the double potentiostatic method (DPM) and the step method (SM), and it was also performed thermal desorption spectroscopy (TDS) tests. Apparent Hydrogen diffusion coefficients vary from 1.4 x 10-13 m²/s to 4.7 x 10-12 m²/s and TDS reveals the existence of deep traps, such as interfaces of precipitates and between retained austenite and ferritic matrix. HE effects in terms of reduction of ductility were analyzed through tensile tests and fractographic analysis, where a maximum reduction of elongation of around 14% was measured and a majority of brittle fracture along entire net section was observed in test samples pre charged under -1.5 V/SCE and -1.7 V/SCE. A calculation procedure based on computational simulation via finite element method has been performed, in order to predict mentioned loss of ductility using the experimental data mentioned before. The computational model used a fracture-controlled method under static structural condition, which links reduction of elongation of tensile specimens to the decreasing of critical fracture energies, which, in turn, were achieved through a new mean field approach regarding thermodynamic excess variables. Herein presented observations make it possible to suggest, that S13Cr has good resistance to HE and that the mentioned calculation procedure is reliable, since slight deviations in the magnitude of 5% were observed.

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氢对S13Cr超马氏体不锈钢界面分离的作用

本文概述了超马氏体不锈钢(SMSS) S13Cr在不同阴极电位作用下的氢脆(HE)的实验方法和数值分析。采用双恒电位法(DPM)和步进法(SM)两种电化学渗透技术研究了氢的扩散行为，并进行了热解吸光谱(TDS)测试。表观氢扩散系数在1.4 × 10-13 m²/s到4.7 × 10-12 m²/s之间变化，TDS显示了深层圈闭的存在，如沉淀界面和残余奥氏体与铁素体基体之间的界面。通过拉伸试验和断口分析分析了HE对延性降低的影响，在-1.5 V/SCE和-1.7 V/SCE下预充的测试样品中，拉伸率的最大降低率约为14%，并且沿整个净截面观察到大部分脆性断裂。为了利用上述试验数据预测上述延性损失，采用有限元方法进行了基于计算模拟的计算程序。该计算模型采用静态结构条件下的断裂控制方法，将拉伸试样伸长率的降低与临界断裂能的降低联系起来，而临界断裂能的降低则通过考虑热力学过量变量的平均场方法来实现。本文提出的观察结果表明，S13Cr具有良好的HE抗性，并且上述计算过程是可靠的，因为观察到5%量级的轻微偏差。

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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Materials Engineering eJournal

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