Very Fine Structured DP Steel with Tempered-Martensite Matrix Fabricated by Fast Heating

Abstract: In order to fabricate new type of low carbon dual phase steel with excellent local deformability, cold-deformed lath martensite was intercritically annealed at ferrite and austenite two phase region at very high heating rate of 500 K/s by high-frequency induction heating in a low carbon chromium-molybdenum steel (0.15%C-1.15%Cr-0.15%Mo). No recrystallization of lath martensite to ferrite took place upon heating because of the fast heating and the pinning effect of very ne M 3 C particles. Consequently, austeni… Show more

“…14,15) The ductility on the other hand is determined by the state of ferrite recrystallization and the distribution and morphology of the martensite. [16][17][18] The formability, e.g. stretch flange-ability or bendability, is often considered to be related to the elongation value.…”

Effect of the Initial Microstructure and Thermal Path on the Final Microstructure and Bendability of a High Strength Ferrite-martensite Dual Phase Steel

“…14,15) The ductility on the other hand is determined by the state of ferrite recrystallization and the distribution and morphology of the martensite. [16][17][18] The formability, e.g. stretch flange-ability or bendability, is often considered to be related to the elongation value.…”

Effect of the Initial Microstructure and Thermal Path on the Final Microstructure and Bendability of a High Strength Ferrite-martensite Dual Phase Steel

Plastic Deformation Mechanism of Dual-phase Steel at Different Strain Rates

Effect of ferrite grain shape in friction element welds on cross tension strength