The effect of long-term creep on particle coarsening in tempered martensite ferritic steels

Acta Metallurgica Pub Date : 1989-12-01 DOI:10.1016/0001-6160(89)90194-6

G. Eggeler

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引用次数: 150

Abstract

The high creep strength of tempered martensite ferritic steels results from the presence of a dislocation network of subgrain boundaries (SGBs) which is stabilized by carbides. In these microstructures creep accelerated particle coarsening is observed at creep rates of the order of 10⁻¹⁰ s⁻¹ (long-term creep). The microstructural explanations presented in this study, are based on the close contact between particles and SGBs:

1.
(i) the difference in the thermodynamic potential on SGBs perpendicular and parallel to the stress axis results in short range pipe diffusion fluxes over distances of the order of the mean subgrain size (0.5 μm) which are not enforced during stress free ageing;
2.
(ii) at high temperatures, recovery processes can result in a decrease of the dislocation density within SGBs, which results in a decrease of pipe diffusion along SGBs. In the presence of a stress higher dislocation densities in SGBs (higher pipe diffusion fluxes) can be maintained than without stress (ageing);
3.
(iii) during primary creep carbides interrupt “knitting” reactions between “free” dislocations and SGBs. As a result carbides “come in contact” with additional pipe diffusion paths (pinned dislocations). At low stresses the “pinned” dislocations stay in contact with the “pinning” carbides throughout the creep life. These “additional” matrix/carbide pipe diffusion paths do not form during ageing (absence of primary creep). All three effects can contribute to “creep accelerated particle coarsening” in tempered martensite ferritic steels.

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长期蠕变对回火马氏体铁素体钢颗粒粗化的影响

回火马氏体铁素体钢的高蠕变强度是由于碳化物稳定的亚晶界位错网络的存在。在这些微观结构中，观察到蠕变加速颗粒粗化的蠕变速率为10−10 s−1(长期蠕变)。本研究中提出的微观结构解释是基于粒子与sgb之间的密切接触:1.(1)垂直于应力轴和平行于应力轴的sgb上的热力学势的差异导致在平均亚晶粒尺寸(0.5 μm)量级的距离上短距离的管道扩散通量，这在无应力时效过程中不会发生;2.(2)在高温下，恢复过程会导致sgb内的位错密度降低，从而导致沿sgb的管道扩散减少。在存在应力的情况下，与没有应力(时效)相比，sgb中可以保持较高的位错密度(较高的管道扩散通量);3.(iii)在初次蠕变期间，碳化物打断了"自由"位错与sgb之间的"编织"反应。结果碳化物“接触”到额外的管道扩散路径(钉位错)。在低应力下，“钉住”的位错在蠕变过程中始终与“钉住”的碳化物保持接触。这些“额外的”基体/碳化物管扩散路径不会在时效过程中形成(没有初次蠕变)。这三种作用均可导致回火马氏体铁素体钢的“蠕变加速颗粒粗化”。

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Acta Metallurgica

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