The effect of hydrogen charging on the mechanical properties and fracture mechanisms of high-nitrogen chromium-manganese steels after age-hardening

M. Panchenko, A. Mikhno, I. Tumbusova, G. Maier, V. Moskvina, E. Melnikov, S. Astafurov, E. Astafurova
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Abstract

: Currently, many technical problems require a comprehensive study of the properties of materials operating in hydrogen-containing environments. The authors investigated the effect of age-hardening on the hydrogen embrittlement and fracture micromechanisms of high-nitrogen austenitic Fe-23Cr-17Mn-0.1C-0.6N (wt. %) steel. For this purpose, using heat treatments, the authors formed in specimens of Fe-23Cr-17Mn-0.1C-0.6N steel the structural phase states characte-rized by different distribution and content of dispersed phases. The experiment determined that the accumulation of hydrogen atoms occurs predominantly in the grains in solution-treated specimens without dispersed phases. This causes the effects of solid solution hardening and leads to a change in the micromechanism of steel fracture from a ductile dimple fracture in the absence of hydrogen to a transgranular fracture by the quasi-cleavage mechanism in hydrogen-charged specimens. It was established that the discontinuous decomposition of austenite with the formation of Cr 2 N cells and austenite depleted in nitrogen, predominantly along the grain boundaries causes the formation of a large fraction of interphase (aus-tenite/Cr 2 N particles) boundaries. Cells of discontinuous decomposition promote hydrogen accumulation along the grain boundaries and cause brittle intergranular fracture of hydrogen-charged specimens during plastic deformation. The study showed that in specimens with the discontinuous decomposition of austenite both along the grain boundaries and spreading into the grain body, plenty of intragranular interphase boundaries (Cr 2 N plates in austenite) are formed, which causes the formation of a transgranular brittle fracture in the hydrogen-charged specimens.
充氢对高氮铬锰钢时效硬化后力学性能及断裂机制的影响
当前,许多技术问题需要对材料在含氢环境下的性能进行全面的研究。研究了时效硬化对高氮奥氏体Fe-23Cr-17Mn-0.1C-0.6N (wt. %)钢氢脆及断裂微观机制的影响。为此,通过热处理,在Fe-23Cr-17Mn-0.1C-0.6N钢试样中形成了分散相分布和含量不同的组织相态。实验确定,在溶液处理的样品中,氢原子的积累主要发生在晶粒中,没有分散相。这导致了固溶硬化效应,导致钢的断裂微观机制由无氢时的韧性韧窝断裂转变为含氢试样的准解理穿晶断裂。结果表明,奥氏体的不连续分解(cr2n细胞的形成)和贫氮奥氏体主要沿晶界形成了大量的间相(奥氏体/ cr2n颗粒)晶界。不连续分解细胞促进氢沿晶界积累,导致充氢试样在塑性变形过程中发生脆性晶间断裂。研究表明,在奥氏体沿晶界不连续分解并向晶体扩散的试样中,形成了大量的晶内相界面(奥氏体中的cr2n板),导致充氢试样形成穿晶脆性断口。
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