Simulation of Martensitic Transformation of High Strength and Elongation Steel by Cellular Automaton

Ying Zhi; Wei Jie Liu; Xianghua Liu

doi:10.4028/www.scientific.net/AMR.1004-1005.235

Paper Titles

Investigation on the Austenitic Reverse Transformation of 0.2C-3Mn-1.7Si Steel with an Ultra-Slow Heating Rate
p.214

Analysis of Orange Peel Defects on Hot-Dip Galvanized High Strength Low Alloy Steel
p.221

Deep Denitrogenization Technology of 23Co-Ni Steel in Vacuum Induction Melting Furnace
p.227

Effect of Mn Addition on Mechanical Property and Corrosion Behavior in Hot Rolled 19 % Cr Duplex Stainless Steel
p.231

Simulation of Martensitic Transformation of High Strength and Elongation Steel by Cellular Automaton
p.235

Investigation of an Isatin Schiff Base as Corrosion Inhibitor in NaCl Solution
p.239

Effect of Types of Antioxidants on Thermal and Thermo-Oxidative Degradation of Epoxidized Natural Rubber
p.245

Thermal Safety Study of One New-Type DB Propellant
p.249

Application of a Novel DOPO-Based Polymeric Phosphate Flame Retardant for Polycarbonate/Acrylonitrile-butadiene-styrene Alloy
p.253

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1004-1005Simulation of Martensitic Transformation of High...

Simulation of Martensitic Transformation of High Strength and Elongation Steel by Cellular Automaton

Abstract:

The model of cellular automaton (CA) for simulating the martensitic transformation of the high strength and elongation steel during quenching was established. The microstructure evolution of martensitic transformation of high strength and elongation steel during continuous cooling was simulated dynamically, in terms of parameters such as the volume fraction and morphology of the martensite and retained austenite were quantitatively, accurately and visually described. The simulation results could provide a theoretical reference for the control of the microstructure and property of high strength and elongation steel.