Designing a Novel DQ&P Process through Physical Simulation Studies

Mahesh Chandra Somani; David A. Porter; L. Pentti Karjalainen; R.D.K. Misra

doi:10.4028/www.scientific.net/MSF.762.83

Paper Titles

Control of Microstructure by MaxStrain Device
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Novel Physical Simulation Technique Development for Multistage Metal Plastic Deformation Processing
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Physical Simulation of Hot Rolling Steel Plate and Coil Production for Pipeline Applications
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Physical Simulation of Thermomechanical Processing of Multiphase Mn-Al Steels with Retained Austenite
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Designing a Novel DQ&P Process through Physical Simulation Studies
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Achieving High Tensile Properties in a C-Mn-Si Structural Steel by Simulating Hot Rolling and Heat Treatment Schedules
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The Development of Interphase Precipitated Nanometre-Sized Carbides in the Advanced Low-Alloy Steels
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Effect of Heating Process on Retained Austenite of Mn-TRIP Steel
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Crystallographic Features of Low-Carbon Bainite Formed under Non-Isothermal Conditions
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HomeMaterials Science ForumMaterials Science Forum Vol. 762Designing a Novel DQ&P Process through Physical...

Designing a Novel DQ&P Process through Physical Simulation Studies

Abstract:

This study presents the use of physical and laboratory rolling simulations for the development of a novel direct quenching and partitioning (DQ&P) process for the development of tough ductile ultra-high strength structural steels with yield strengths ~1100 MPa and reasonable ductility and toughness. Suitable compositions were designed based on high silicon and/or aluminium content. The DQ&P parameters were established with the aid of physical simulation on a Gleeble simulator. Two types of dilatation tests were carried out: with or without prior straining in the no-recrystallization regime to establish the influence of controlled deformation on subsequent transformation structures and properties. Based on dilatation results, simulated rolling trials were conducted on a laboratory rolling mill and the rolled samples were direct quenched in water to the desired quench stop temperatures followed by partitioning in a furnace held at this temperature. Detailed microstructural examination confirmed that the desired martensite-austenite microstructures were achieved. Besides high strengths, the ductility (including uniform elongation) and impact toughness were quite improved in comparison to that of a direct quenched carbon steel in the same strength class.

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Periodical:

Materials Science Forum (Volume 762)

Pages:

83-88

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.762.83

Citation:

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Online since:

July 2013

Authors:

Mahesh Chandra Somani, David A. Porter, L. Pentti Karjalainen, R.D.K. Misra

Keywords:

Direct Quenching, EBSD, Electron Microscopy, Finish Rolling Temperature, Martensite, Quenching and Partitioning, Retained Austenite, THERMOMECHANICAL PROCESSING, X-Ray Diffraction (XRD)

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