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Influence of Martensite–Austenite constituents formed at different intercritical temperatures on toughness
Highlights Impact toughness improves with increasing temperature within intercritical region. Coarse necklace M–A formed at 760°C resulted in the lowest toughness (42J). Samples reheated to 800°C/840°C had better toughness, respectively 80J and 105J. Notable difference in toughness is due to size/distribution/carbon content of M–A.
Abstract The objective of the present study is to elucidate the impact of Martensite–Austenite (M–A) constituents formed at different intercritical temperatures on toughness. Gleeble thermal simulation technique has been used to produce different intercritically reheated coarse grained heat affected zone (ICCGHAZ) microstructures corresponding to different reheating temperatures between Ac1 and Ac3. The instrumental Charpy impact test results of dual pass thermal simulation showed that Charpy impact toughness improved with the increasing of second peak temperature. The fraction of M–A constituent was similar at each temperature. Near-connected coarse necklacing M–A constituents (2.4μm) formed at 760°C (near to Ac1) led to the worst toughness (42J) while those formed at 800°C and 840°C (near to Ac3) resulted in better toughness, respectively 80J and 105J. M–A constituents formed at 800°C were still coarse (2.2μm) but had larger interspace compared to 760°C. And those formed at 840°C were refined (1.9μm) and well dispersed by matrix. Notable difference in toughness values is attributed to the size and distribution of M–A constituents formed at different intercritical temperatures. It is possible to achieve better toughness if M–A constituents are well controlled: smaller in size and larger in interspacing.
Influence of Martensite–Austenite constituents formed at different intercritical temperatures on toughness
Highlights Impact toughness improves with increasing temperature within intercritical region. Coarse necklace M–A formed at 760°C resulted in the lowest toughness (42J). Samples reheated to 800°C/840°C had better toughness, respectively 80J and 105J. Notable difference in toughness is due to size/distribution/carbon content of M–A.
Abstract The objective of the present study is to elucidate the impact of Martensite–Austenite (M–A) constituents formed at different intercritical temperatures on toughness. Gleeble thermal simulation technique has been used to produce different intercritically reheated coarse grained heat affected zone (ICCGHAZ) microstructures corresponding to different reheating temperatures between Ac1 and Ac3. The instrumental Charpy impact test results of dual pass thermal simulation showed that Charpy impact toughness improved with the increasing of second peak temperature. The fraction of M–A constituent was similar at each temperature. Near-connected coarse necklacing M–A constituents (2.4μm) formed at 760°C (near to Ac1) led to the worst toughness (42J) while those formed at 800°C and 840°C (near to Ac3) resulted in better toughness, respectively 80J and 105J. M–A constituents formed at 800°C were still coarse (2.2μm) but had larger interspace compared to 760°C. And those formed at 840°C were refined (1.9μm) and well dispersed by matrix. Notable difference in toughness values is attributed to the size and distribution of M–A constituents formed at different intercritical temperatures. It is possible to achieve better toughness if M–A constituents are well controlled: smaller in size and larger in interspacing.
Influence of Martensite–Austenite constituents formed at different intercritical temperatures on toughness
Li, Xueda (Autor:in) / Fan, Yuran (Autor:in) / Ma, Xiaoping (Autor:in) / Subramanian, S.V. (Autor:in) / Shang, Chengjia (Autor:in)
13.10.2014
7 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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