Root Cause of Degradation in the Creep Strength of Martensitic Steel

M. Tamura
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引用次数: 1

Abstract

Creep curves of Grade 91 and 92 steels were analyzed by applying an exponential law to the temperature, stress, and time parameters to investigate the formation process of the Z-phase, which lowers the long-term rupture strength of high-Cr martensitic steel. The activation energy (Q), activation volume (V), and Larson–Miller constant (C) were obtained as functions of creep strain. At the beginning of creep, sub-grain boundary strengthening occurs because of dislocations that are swept out of the sub-grains, and this is followed by strengthening owing to the rearrangement of M23C6 and the precipitation of the Laves phase. Heterogeneous recovery and subsequent heterogeneous deformation start at an early stage of transient creep near several of the weakest boundaries because of the coarsening of the precipitates; this results in the simultaneous decreases in Q, V, and C even in transient creep. Further, this activity triggers an unexpected degradation in strength because of the accelerated formation of the Z-phase even in transient creep. The stabilization of M23C6 and the Laves phase is important to mitigate the degradation of the long-term rupture strength of high-strength martensitic steel. The stabilization of the Laves phase is especially important for Cr-Mo systems because Fe2Mo is easily coarsened at approximately 600 °C compared to Fe2W in Grade 92 steel.
马氏体钢蠕变强度下降的根本原因
通过对温度、应力和时间参数的指数规律分析了91级和92级钢的蠕变曲线,探讨了降低高铬马氏体钢长期断裂强度的z相的形成过程。得到了活化能Q、活化体积V和Larson-Miller常数C随蠕变应变的变化规律。在蠕变开始时,亚晶界的强化是由于位错从亚晶中扫出,随后的强化是由于M23C6的重排和Laves相的析出。由于析出相的粗化,非均质恢复和随后的非均质变形开始于瞬态蠕变的早期阶段,靠近几个最弱的边界;这导致即使在瞬态蠕变中Q、V和C也同时降低。此外,即使在瞬态蠕变中,这种活性也会加速z相的形成,从而引发意想不到的强度下降。M23C6和Laves相的稳定化是减缓高强马氏体钢长期断裂强度下降的重要因素。Laves相的稳定对于Cr-Mo体系尤为重要,因为与92级钢中的Fe2W相比,Fe2Mo在大约600℃时容易粗化。
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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