Effect of austenite grain size on the bainitic ferrite morphology and grain refinement of a pipeline steel after continuous cooling

The effect of prior-austenite grain size (PAGS) on bainitic ferrite (BF) morphology and effective grain size in a pipeline steel under an industrial cooling condition was investigated. With PAGSs of 22.3μm and 37.0μm, BF laths with a parallel morphology could be seen, while as the PAGS is increased...

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Bibliographic Details
Published in:Materials characterization 2017-01, Vol.123, p.128-136
Main Authors: Zhao, H., Wynne, B.P., Palmiere, E.J.
Format: Article
Language:English
Subjects:
Austenite grain size
Bain group
Bainitic ferrite
Close-packed plane group
Grain refinement
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Summary:The effect of prior-austenite grain size (PAGS) on bainitic ferrite (BF) morphology and effective grain size in a pipeline steel under an industrial cooling condition was investigated. With PAGSs of 22.3μm and 37.0μm, BF laths with a parallel morphology could be seen, while as the PAGS is increased to 52.4μm or 62.8μm, more interlocking BF microstructures were observed. Detailed crystallographic analysis identified that intense BF variant selection occurs for the small-grained austenite, but due to the large austenite grain quantity, and thus the large total austenite grain boundary area per unit volume of the small-grained austenite, with the reduction of PAGS from 62.8μm to 22.3μm, the effective grain size of the transformed microstructure gradually decreases from 9.5μm to 5.6μm. The small-grained austenite transformation was dominated by one close-packed plane (CP) group, but for the larger austenite grain, different CP groups were observed to be adjacent to each other, producing the interlocking structure. A mechanism based on the carbon distribution near the BF/austenite interface is proposed to account for this difference. •Distinguishes variant selection between different starting austenite grain size.•Smaller initial austenite grains lead to a finer transformed microstructure.•Intense variant selection occurs following transformation from refined austenite.•Interlocking structure develops following transformation from coarse austenite.
ISSN:1044-5803
1873-4189
DOI:10.1016/j.matchar.2016.11.025