Two Novel Methods to Realize the Superplastic Forming of Ultrahigh Strength Steels

Bing Zhe Bai; Han Zhang

doi:10.4028/www.scientific.net/MSF.706-709.2699

Paper Titles

Calculation Methods to Determine Crystallographic Elements Based on Electron Diffraction Orientation Measurements by SEM/EBSD or TEM
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3D Image-Based Stereology
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Effect of Intercritical Annealing Time on Microstructure and Mechanical Behavior of Advanced Medium Mn Steels
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Influence of Rolling Temperature and Cooling Rate on Microstructure and Properties of Pipeline Steel Grades
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Thermo-Mechanical Processing of Low Manganese, Titanium Added Pipeline Steels
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HomeMaterials Science ForumMaterials Science Forum Vols. 706-709Two Novel Methods to Realize the Superplastic...

Two Novel Methods to Realize the Superplastic Forming of Ultrahigh Strength Steels

Abstract:

Two novel methods of obtaining microduplex structures, ferrite plus spherical carbides, in ultrahigh strength steels (~2000MPa) are introduced. One is through an adequate deformation just below the austenite-ferrite equilibrium transformation temperature (i.e. Ae₃ temperature, ~983K) followed by water quenching. The adequate deformation directly leads to the formation of a (ferrite plus spherical carbides) microduplex structure. The microstructure evolution during the deformation includes pearlite transformation, cementite spheroidization and ferrite recrystallization. The other is through an adequate deformation above Ae₃ temperature (~1003K) followed by water quenching to produce martensite firstly and then obtain a (ferrite plus spherical carbides) microduplex structure during warm deformation of martensite. Microstructural analysis on the microduplex structure shows that submicron carbides are located at ferrite grain boundaries while nanometer ones are dispersed inside ferrite grains. This kind of carbide distribution may suppress the coarsening of ferrite grains and form a dynamic equilibrium of ferrite grain size on a specific deformation condition. The strain rate sensitivity of the (ferrite plus spherical carbides) microduplex structures is about 0.4 at 973K and strain rate of 10^-4s^-1.

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Materials Science Forum (Volumes 706-709)

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2699-2703

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https://doi.org/10.4028/www.scientific.net/MSF.706-709.2699

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Online since:

January 2012

Authors:

Bing Zhe Bai, Han Zhang

Keywords:

Flow Stress, Steel, Strain Rate Sensitivity (SRS), Superplasticity

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[15] A.H. Chokshi: Superplasticity in Advanced Materials (Transtec, Switzerland 1997). Fig. 1 Thermomechanical processes of (a) steel A and (b) steel B Fig. 2 (a) SEM micrograph of steel A after undergoing the thermomechanical processing in Fig. 1(a), (b) stress-strain curve during the deformation at 1073K in Fig. 1(a), ferrite orientation maps of (c) steel A after undergoing the thermomechanical processing in Fig. 1(a) and (d) steel A after undergoing austenitization at 1173K for 180s followed by water quench Fig. 3 SEM micrograph of steel B after undergoing the thermomechanical processing in Fig. 1(b) Fig. 4 The warm deformation used to evaluate the superplastic behavior (at 973K) of steel A after undergoing the thermomechanical processing in Fig. 1(a) Fig. 5 (a) SEM micrograph and (b) local TEM micrograph of steel A after undergoing the warm deformation at 973K Table 1. The m value and flow stress of the (ferrite plus spherical carbides) microduplex structures Strain rate (s-1) 10-4~2×10-4 2×10-4s-1~4×10-4 4×10-4~10-3 M value 0．40 0．35 0．30 Stress (MPa) 50~66 66~84 84~110.

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