Structure Refinement of Medium Carbon Steel and Deformation Properties Respond

Jozef Zrník; Sergey Dobatkin; George Raab

doi:10.4028/www.scientific.net/MSF.782.104

Paper Titles

Influence of Casting Rate on TiNb Microalloyed Steel Slab Surface Area Microstructure
p.81

Homogenization of Microstructure of Castings from the Alloy Fe-40at.%Al-Zr-B
p.87

Kinetics of Austenite Recrystallization of Selected Steels Used for Heavy Forgings
p.93

Impact of Microstructure Modification on Deformation Behaviour of Bulk TRIP Steel
p.99

Structure Refinement of Medium Carbon Steel and Deformation Properties Respond
p.104

Effect of Annealing on the Microstructure Evolution and Mechanical Properties of Dual Phase Steel
p.111

Shape Evolution of Cementite during Accelerated Carbide Spheroidisation
p.117

Microstructure Development of Bearing Steel during Accelerated Carbide Spheroidisation
p.123

Differential Scanning Calorimetry and Metallographic Analysis of Fe-Si Electrical Steel
p.129

HomeMaterials Science ForumMaterials Science Forum Vol. 782Structure Refinement of Medium Carbon Steel and...

Structure Refinement of Medium Carbon Steel and Deformation Properties Respond

Abstract:

The work presents the results on grains refinement of steel containing 0,45 wt pct carbon resulted from severe plastic deformation (SPD). Different steel structures from prior solutioning and/or thermomechanical treatment were prepared for deformation experimental. A coarse grain ferrite-pearlite structure was achieved applying solutioning. By application of thermomechanical (TM) controlled forging process, performing multistep open die forging, the refined ferrite-pearlite mixture was prepared. Final structure refinement of steel, having different initial structure, was then accomplished applying warm Equal Channel Angular Pressing (ECAP) at 400°C. Employment of this processing route resulted in extensive deformation of ferrite grains and cementite lamellae fragmentation. Applying the highest shear stress (ε_ef - 4) the mixed structure of subgrains and ultrafine grains was present within the ferrite phase. In pearlite grains, modification of cementite lamellae due to shearing, bending, twisting and breaking was found efficient. The coarse cementite lamellae spheroidization was more efficient in prior TM treated steel. The tensile deformation records confirmed strength increase and diversity in strain hardening behaviour.