Microstructure modeling of high-temperature microcrack initiation and evolution in a welded 9Cr martensitic steel
Li, Ming O'Donoghue, Padraic E. Leen, Sean B.
Li, Ming
O'Donoghue, Padraic E.
Leen, Sean B.
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Publication Date
2019-02-28
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Article
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Li, M., O’Donoghue, P., & Leen, S. (2019). Microstructure modeling of high-temperature microcrack initiation and evolution in a welded 9Cr martensitic steel. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications, 233(10), 2160–2174. https://doi.org/10.1177/1464420719833086
Abstract
Welded joints in tempered 9Cr-1Mo operating at elevated temperatures are well known to be prone to premature failure due to cracking in the heat-affected zone. This paper describes a crystal plasticity model to predict the microcrack initiation and evolution in the inter-critical heat-affected zone of 9Cr-1Mo welded steel at elevated temperature. A crystal plasticity finite element model indicates that the micro-cracks of 9Cr-1Mo steel mostly nucleate at prior austenite grain boundaries and boundary clustered regions. Inter-granular and trans-granular microcracking are shown to be the key predicted microdamage mechanisms from the current crystal plasticity model. A small amount of ferrite in the inter-critical heat-affected zone is shown to not only influence the microcrack initiation and evolution, but also significantly accentuate material degradation for a given applied load leading to premature failure at high temperature.
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SAGE Publications
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Attribution-NonCommercial-NoDerivs 3.0 Ireland