High Ductility and Toughness of a Micro-duplex Medium-Mn Steel in a Large Temperature Range from -196 ℃ to 200
A medium-Mn steel (0.2C5Mn) was processed by intercritical annealing at different temperatures (625 ℃ and 650 ℃ ). An ultrafine-grained micro-duplex structure consisting of alternating austenite and ferrite laths was de- veloped by austenite reverse transformation (ART) during intercritical annealin...
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| Published in: | 钢铁研究学报:英文版 no. 12; pp. 1126 - 1130 |
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| Main Author: | |
| Format: | Journal Article |
| Language: | English |
| Published: |
2015
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| Subjects: | |
| Online Access: | Get full text |
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| Summary: | A medium-Mn steel (0.2C5Mn) was processed by intercritical annealing at different temperatures (625 ℃ and 650 ℃ ). An ultrafine-grained micro-duplex structure consisting of alternating austenite and ferrite laths was de- veloped by austenite reverse transformation (ART) during intercritical annealing after forging and hot rolling. Ultra- high ductility with a total elongation higher than 30% was achieved in the temperature range from -196 ℃ to 200 ℃, and high impact toughness no less than 200 J at -40 ℃ was obtained. Based on the analysis of microstructure and mechanical properties, it was found that the enhanced ductility was determined by the phase transformation effect of austenite (TRIP effect), while the delayed ductile to brittle transition was controlled by austenite stability. |
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| Bibliography: | 11-3678/TF high strength; high ductility; intercritical annealing; medium-Mn steel; ultrafine grain size A medium-Mn steel (0.2C5Mn) was processed by intercritical annealing at different temperatures (625 ℃ and 650 ℃ ). An ultrafine-grained micro-duplex structure consisting of alternating austenite and ferrite laths was de- veloped by austenite reverse transformation (ART) during intercritical annealing after forging and hot rolling. Ultra- high ductility with a total elongation higher than 30% was achieved in the temperature range from -196 ℃ to 200 ℃, and high impact toughness no less than 200 J at -40 ℃ was obtained. Based on the analysis of microstructure and mechanical properties, it was found that the enhanced ductility was determined by the phase transformation effect of austenite (TRIP effect), while the delayed ductile to brittle transition was controlled by austenite stability. |
| ISSN: | 1006-706X 2210-3988 |