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Deformation Behaviour and Ultrafine Grained Structure Development in Steels with Different Carbon Content Subjected to Severe Plastic Deformation
The article focuses on the results from recent experimental of severe plastic deformation of low carbon (LC) steel and medium carbon (MC) steel performed at increased temperatures. The grain refinement of ferrite respectively ferrite-pearlite structure is described. While LC steel was deformed by EC...
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Published in: | Key engineering materials 2007-08, Vol.345-346, p.45-48 |
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Main Authors: | , , |
Format: | Article |
Language: | English |
Citations: | Items that this one cites Items that cite this one |
Online Access: | Get full text |
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Summary: | The article focuses on the results from recent experimental of severe plastic deformation
of low carbon (LC) steel and medium carbon (MC) steel performed at increased temperatures. The
grain refinement of ferrite respectively ferrite-pearlite structure is described. While LC steel was
deformed by ECAP die (ε = 3) with a channel angle φ = 90° the ECAP severe deformation of MC
steel was conducted with die channel angle of 120° (ε = 2.6 - 4). The high straining in LC steel
resulted in extensively elongated ferrite grains with dense dislocation network and randomly
recovered and polygonized structure was observed. The small period of work hardening appeared at
tensile deformation. On the other side, the warm ECAP deformation of MC steel in dependence of
increased effective strain resulted in more progressive recovery process. In interior of the elongated
ferrite grains the subgrain structure prevails with dislocation network. As straining increases the
dynamic polygonization and recrystallization became active to form mixture of polygonized
subgrain and submicrocrystalline structure. The straining and moderate ECAP temperature caused
the cementite lamellae fragmentation and spheroidzation as number of passes increased. The tensile
behaviour of the both steels was characterized by strength increase however the absence of strain
hardening was found at low carbon steel. The favourable effect of ferrite-pearlite structure
modification due straining was reason for extended work hardening period observed at MC steel. |
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ISSN: | 1013-9826 1662-9795 1662-9795 |
DOI: | 10.4028/www.scientific.net/KEM.345-346.45 |