Effect of cyclic heat treatment on microstructure and mechanical properties of 0.6wt% carbon steel

In this work an annealed 0.6wt% carbon steel was subjected to cyclic heat treatment process that consisted of repeated short-duration (6min) holding at 810A degree C (above Ac3 temperature) followed by forced air cooling. After 8 cycles (about a total 1h and 20min duration of heating and cooling cyc...

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Veröffentlicht in:	Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2010-06, Vol.527 (16-17), p.4001-4007
Hauptverfasser:	Saha, Atanu, Mondal, Dipak Kumar, Maity, Joydeep
Format:	Artikel
Sprache:	eng
Schlagworte:	Air cooling Carbon steels Cementite Dimpling Ferrite Heat treatment Microstructure Pearlite Spheroidizing
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container_title	Materials science & engineering. A, Structural materials : properties, microstructure and processing
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creator	Saha, Atanu Mondal, Dipak Kumar Maity, Joydeep
description	In this work an annealed 0.6wt% carbon steel was subjected to cyclic heat treatment process that consisted of repeated short-duration (6min) holding at 810A degree C (above Ac3 temperature) followed by forced air cooling. After 8 cycles (about a total 1h and 20min duration of heating and cooling cycles), the microstructure mostly contained fine ferrite grains (grain size of 7I14m) and spheroidized cementite. This microstructure possessed an excellent combination of strength and ductility. The disintegration of lamellae through dissolution of cementite at preferred sites of lamellar faults during short-duration holding above Ac3 temperature, and the generation of defects (lamellar faults) during non-equilibrium forced air cooling were the main reasons of accelerated spheroidization. The strength property initially increased mainly due to the presence of finer microconstituents (ferrite and pearlite) and thereafter marginally decreased with the elimination of lamellar pearlite and appearance of cementite spheroids in the microstructure. Accordingly, the fractured surface initially exhibited the regions of wavy lamellar fracture (pearlite regions) along with dimples (ferrite regions). With increasing number of heat treatment cycles the regions of dimples gradually consumed the entire fractured surface.
doi_str_mv	10.1016/j.msea.2010.03.003
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After 8 cycles (about a total 1h and 20min duration of heating and cooling cycles), the microstructure mostly contained fine ferrite grains (grain size of 7I14m) and spheroidized cementite. This microstructure possessed an excellent combination of strength and ductility. The disintegration of lamellae through dissolution of cementite at preferred sites of lamellar faults during short-duration holding above Ac3 temperature, and the generation of defects (lamellar faults) during non-equilibrium forced air cooling were the main reasons of accelerated spheroidization. The strength property initially increased mainly due to the presence of finer microconstituents (ferrite and pearlite) and thereafter marginally decreased with the elimination of lamellar pearlite and appearance of cementite spheroids in the microstructure. Accordingly, the fractured surface initially exhibited the regions of wavy lamellar fracture (pearlite regions) along with dimples (ferrite regions). 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After 8 cycles (about a total 1h and 20min duration of heating and cooling cycles), the microstructure mostly contained fine ferrite grains (grain size of 7I14m) and spheroidized cementite. This microstructure possessed an excellent combination of strength and ductility. The disintegration of lamellae through dissolution of cementite at preferred sites of lamellar faults during short-duration holding above Ac3 temperature, and the generation of defects (lamellar faults) during non-equilibrium forced air cooling were the main reasons of accelerated spheroidization. The strength property initially increased mainly due to the presence of finer microconstituents (ferrite and pearlite) and thereafter marginally decreased with the elimination of lamellar pearlite and appearance of cementite spheroids in the microstructure. Accordingly, the fractured surface initially exhibited the regions of wavy lamellar fracture (pearlite regions) along with dimples (ferrite regions). With increasing number of heat treatment cycles the regions of dimples gradually consumed the entire fractured surface.</abstract><doi>10.1016/j.msea.2010.03.003</doi><tpages>7</tpages></addata></record>
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subjects	Air cooling Carbon steels Cementite Dimpling Ferrite Heat treatment Microstructure Pearlite Spheroidizing
title	Effect of cyclic heat treatment on microstructure and mechanical properties of 0.6wt% carbon steel
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