Austenite Stabilization by Quenching and Partitioning in a Low-Alloy Medium Carbon Steel

E. Paravicini Bagliani; E. Anelli; Marco Boniardi

doi:10.4028/www.scientific.net/MSF.706-709.2234

Paper Titles

Effect of Static Aging on Mechanical Properties of an 18Cr-8Ni-W-Nb-V-N Stainless Steel
p.2211

Measurement of Deformation-Induced Martensite in Stainless Steel Using Magnetic Contact Force
p.2217

Effect of Ferrite Grain Boundary on Strain Aging Behavior in Nb-Bearing Ultra-Low-Carbon Steel Sheets
p.2222

Cutting Properties of Austenitic Stainless Steel by Using Linear Polarized CO₂ Laser without Assist Gas
p.2228

Austenite Stabilization by Quenching and Partitioning in a Low-Alloy Medium Carbon Steel
p.2234

Recrystallization Behaviour of Nb and Ti+Nb Added Ferritic Stainless Steels
p.2240

Effect of Interpass Temperature on Microstructure and Mechanical Properties of Weld Metal of 690 MPa HSLA Steel
p.2246

Study of the Hydrogen Traps in a High Strength TRIP Steel by Thermal Desorption Spectroscopy
p.2253

Influence of Two-Step Austempering Process on the Fracture Toughness of a Low Carbon Low Alloy (LCLA) Steel
p.2259

HomeMaterials Science ForumMaterials Science Forum Vols. 706-709Austenite Stabilization by Quenching and...

Austenite Stabilization by Quenching and Partitioning in a Low-Alloy Medium Carbon Steel

Abstract:

Innovative treatments like quenching and partitioning (Q&P) have been recently proposed to improve the combination of strength and ductility of high strength steels by stabilization of significant fractions of retained austenite in a microstructure of tempered martensite. The decomposition of austenite into bainite and carbides precipitation are the two main competitive processes that reduce the content of retained austenite achievable at room temperature. A medium carbon low-silicon steel (0.46% C and 0.25% Si) has been studied to identify in which limits the austenite can be enriched in C and stabilized by Q&P, although a silicon content well below 1.5%, commonly used to retard cementite precipitation, is adopted; indeed, high Si contents are detrimental to the surface quality of the product due to the formation of adherent scale in high temperature manufacturing cycles. The heat treatments have been carried out with a quenching dilatometer, investigating the carbon partitioning process mainly below Ms, where cementite precipitation is not activated. The dilatometric curves show the progressive enrichment of carbon in the untransformed austenite and the occurrence of austenite phase transformation during the isothermal holding below Ms. A range of temperatures and times has been found where a content of about 10% of retained austenite can be stabilized at room temperature, a percentage much lower than the theoretical maximum achievable with the carbon content of this steel.