Model for Predicting the Recrystallized Ferrite Grain Size after Annealing of Cold-Rolled Automobile Body Sheet Steels

The effects of carbon content on the crystallographic texture, plastic anisotropy, and mechanical properties of cold-rolled and annealed sheets of 0.07 percent phosphorus steels have been studied. Both vacuumand air-melted laboratory heats were used. Results show that although the strength of the sheet increased with increasing carbon content, the rm value decreased. The detrimental effect of carbon on rm value was more pronounced after annealing at an intercritical temperature of 780°C (1435℉) than at a subcritical temperature of 710°C (1310℉). These and other observations, including variations in texture, anisotropy, strength, work hardening, and grain size, are discussed.

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Microstructure and Properties of Ultrafast Annealed High Strength Steel

Materials Science Forum ◽

10.4028/www.scientific.net/msf.753.554 ◽

2013 ◽

Vol 753 ◽

pp. 554-558 ◽

Cited By ~ 1

Author(s):

Roumen H. Petrov ◽

Farideh Hajyakbari ◽

Fernando Ramos Saz ◽

Jurij Sidor ◽

Maria Jesus Santofimia ◽

...

Keyword(s):

Grain Size ◽

Phase Transformation ◽

High Strength Steel ◽

High Strength ◽

Deformation Texture ◽

Point Of View ◽

Structural Refinement ◽

Cold Rolled ◽

Ferrite Grain Size ◽

Martensite Structure

The grain size, recrystallization, phase transformation and mechanical properties of a cold-rolled high-strength steel (HSS) are studied after annealing with high (~140°C/s) and ultra-high (~1500°C/s) reheating rate, followed by subsequent water quenching without isothermal soaking. By monitoring the hardness and microstructure, it was shown that the increase of the reheating rate from 140°C/s to 1500°C/s causes grain refinement from 5 µm to 1 µm in diameter and the final ferrite grain size depends significantly on the reheating temperature and reheating rate. It was observed that after an extreme reheating rate of ~1500°C/s the α-γ phase transformation starts before the completion of recrystallization in the recovered matrix. The crystallographic texture of the ultrafast reheated and water-quenched high-strength steel inherits the cold-rolled deformation texture with well pronounced RD and ND texture fibres, even after the α-γ-α′ phase transformations. It was found that the ultrafast reheating results in a very fine non-equilibrium ferrite-martensite structure with an excellent ultimate tensile strength of ~1400 MPa and an acceptable elongation at fracture. The observed data are very promising from industrial application point of view and open up possibilities for further structural refinement and alternative texture control.

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New Approach for Multiplying the Strength and the Formability of Cold Rolled BCC Based Structure Steel through Ultra Fine Structure Technique

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.835.141 ◽

2020 ◽

Vol 835 ◽

pp. 141-148

Author(s):

Hassan Bahaa-Eldin ◽

Mamdouh Eissa ◽

Ahmed Al-Sheikh ◽

Mohamed Kamal El-Fawkhry ◽

Taha Mattar

Keyword(s):

Mechanical Properties ◽

Grain Size ◽

Carbon Steel ◽

Low Carbon Steel ◽

Low Carbon ◽

Annealing Regime ◽

Innovative Technique ◽

Subcritical Annealing ◽

Cold Rolled ◽

Ferrite Grain Size

Reduction in grain size of bcc based structure steel is still highly concerned in the cold rolled sheet to attain superior mechanical properties. As long as, the reduction of weight is much considered in the structure purposes, the strength/weight ratio of steel is highly demanded. In this study, an innovative technique was applied to attain ferrite grain size with hundreds of nanometer, in tandem with preserving the mechanical properties. In this approach, the micro-alloyed low carbon steel resulted from the thermomechanical process was followed by subcritical annealing regime prior to the first critical transformation temperature. To identify the effect of a micro-alloying element as vanadium, and the effect of subcritical annealing regime on the low carbon steel, two low carbon steel was subjected to studying in this research. The results refer that applying a subcritical annealing regime for the micro-alloyed low carbon steel after hot compression at intercritical annealing temperature can lead for attaining hundreds of nanometer ferrite grain size, which has a powerful effect on promoting the strength of the steel to exceed 1200 Mpa, in one hand with preserving the formability up to 20% as uniform elongation. Unexpectedly, the fine grain size obtained after the innovative technique promotes the impact toughness at room temperature, which is attributed to the fineness and the spheroid morphology of the secondary phase in conjugation with bcc ferrite structure.

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Grain Refinement of a Cold Rolled TRIP Assisted Steel after Ultra Short Annealing

Materials Science Forum ◽

10.4028/www.scientific.net/msf.715-716.661 ◽

2012 ◽

Vol 715-716 ◽

pp. 661-666 ◽

Cited By ~ 12

Author(s):

Roumen H. Petrov ◽

Jurij J. Sidor ◽

Wlodzimierz Kaluba ◽

Leo Kestens

Keyword(s):

Grain Size ◽

Grain Refinement ◽

Steel Sheet ◽

Intercritical Annealing ◽

Austenite Formation ◽

Rolled Steel ◽

Structural Refinement ◽

Cold Rolled ◽

Short Annealing ◽

Ferrite Grain Size

Recrystallization and austenite formation in a TRIP-assisted steel during conventional and ultra fast reheating for intercritical annealing are studied with the purpose to clarify the possibility for grain refinement. Partially recrystallized (or transformed) samples were prepared by reheating and water quenching to temperatures between 650 and 1050°C at reheating rates of 10, 50, and 3000 °C/s, respectively, without isothermal soaking from 95% cold rolled steel sheet with ferrite-pearlite microstructure. By monitoring the hardness and microstructure, it was shown that the increase of the reheating rate from 10 to 3000°C/s causes grain refinement from 5µm to 1µm in diameter and the final ferrite grain size depends significantly on both reheating temperature and reheating rate. It was observed that after an extreme reheating rate of 3000°C/s the α-γ phase transformation starts before the completion of the recrystallization. This opens up possibilities for further structural refinement and alternative texture control.

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Slip traces caused by plastic deformation during recrystallization of thin metal sheets

Proceedings, annual meeting, Electron Microscopy Society of America ◽

10.1017/s0424820100170839 ◽

1994 ◽

Vol 52 ◽

pp. 620-621

Author(s):

H. Lin ◽

D. P. Pope

Keyword(s):

Grain Size ◽

Grain Boundaries ◽

Sample Thickness ◽

List Type ◽

Metal Sheets ◽

Second Phases ◽

Slip Traces ◽

Series Of Experiments ◽

Cold Rolled ◽

Individual Grains

During a study of mechanical properties of recrystallized B-free Ni3Al single crystals, regularly spaced parallel traces within individual grains were discovered on the surfaces of thin recrystallized sheets, see Fig. 1. They appeared to be slip traces, but since we could not find similar observations in the literature, a series of experiments was performed to identify them. We will refer to them “traces”, because they contain some, if not all, of the properties of slip traces. A variety of techniques, including the Electron Backscattering Pattern (EBSP) method, was used to ascertain the composition, geometry, and crystallography of these traces. The effect of sample thickness on their formation was also investigated.In summary, these traces on the surface of recrystallized Ni3Al have the following properties:1.The chemistry and crystallographic orientation of the traces are the same as the bulk. No oxides or other second phases were observed.2.The traces are not grooves caused by thermal etching at previous locations of grain boundaries.3.The traces form after recrystallization (because the starting Ni3Al is a single crystal).4.For thicknesses between 50 μm and 720 μm, the density of the traces increases as the sample thickness decreases. Only one set of “protrusion-like” traces is visible in a given grain on the thicker samples, but multiple sets of “cliff-like” traces are visible on the thinner ones (See Fig. 1 and Fig. 2).5.They are linear and parallel to the traces of {111} planes on the surface, see Fig. 3.6.Some of the traces terminate within the interior of the grains, and the rest of them either terminate at or are continuous across grain boundaries. The portion of latter increases with decreasing thickness.7.The grain size decreases with decreasing thickness, the decrease is more pronounced when the grain size is comparable with the thickness, Fig. 4.8.Traces also formed during the recrystallization of cold-rolled polycrystalline Cu thin sheets, Fig. 5.

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Effects of Prior Austenite and Ferrite Grain Size on Fracture Properties of a Plain Carbon Steel.

10.21236/ada146276 ◽

1984 ◽

Cited By ~ 2

Author(s):

H. Couque ◽

J. Duffy ◽

R. J. Asaro

Keyword(s):

Grain Size ◽

Carbon Steel ◽

Prior Austenite ◽

Plain Carbon Steel ◽

Fracture Properties ◽

Ferrite Grain Size

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Microstructural Control in Thick-Walled Nb-Ti-V Microalloyed Linepipe Steels

Materials Science Forum ◽

10.4028/www.scientific.net/msf.467-470.223 ◽

2004 ◽

Vol 467-470 ◽

pp. 223-228

Author(s):

K.M. Banks

Keyword(s):

Grain Size ◽

Laboratory Simulation ◽

Microalloyed Steels ◽

Processing Parameter ◽

Strip Rolling ◽

Bearing Steels ◽

Simulation Results ◽

Linepipe Steels ◽

Ferrite Grain Size ◽

Microstructural Control

Various microstructure models for Nb-bearing steels were tested under industrial strip rolling conditions to establish a relationship between grain size and toughness in Ti-Nb-V microalloyed steels. For similar Nb contents, microstructure models for Nb steels were found to adequately describe recrystallisation kinetics in more complex Ti-Nb-V steels. For thick-walled linepipe (11.6mm), a minimum of 0.04%Nb is required to achieve adequate toughness. Retained strain was the dominant processing parameter factor affecting ferrite grain size. The predicted minimum amount of retained strain after the last pass required for sufficient grain refinement concurred with laboratory simulation results. For the rolling schedules investigated, metadynamic recrystallisation was predicted to occur during roughing, whilst static recrystallisation was predominant during finishing.

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Spot Weldability Assessment of Similar and Dissimilar Steel Sheets for Light Weight Automobile Body

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.306-308.899 ◽

2006 ◽

Vol 306-308 ◽

pp. 899-904

Author(s):

Dong Ho Bae ◽

Won Seok Jung ◽

J.B. Heo

Keyword(s):

Stainless Steel ◽

Fatigue Strength ◽

Lap Joints ◽

Vehicle Body ◽

Rolled Steel ◽

Cold Rolled Steel ◽

Steel Sheets ◽

Automobile Body ◽

Cold Rolled ◽

Spot Welded

An effective way to reduce the weight of vehicle body seems to be application of new materials, and such trend is remarkable. Among the various materials for automobile body, stainless steel sheets and cold rolled steel sheets are under the interests. However, in order to guarantee reliability of new material and to establish the long life fatigue design criteria for body structure, it is necessary to assess spot weldability and fatigue strength of spot welded lap joints fabricated under optimized spot welding condition. In this paper, spot weldability of stainless steel sheets, STS301L and STS304L, and cold rolled steel sheets, SPCC and SPCD. Fatigue strength of lap joints spot welded between similar and dissimilar materials were also assessed.

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A Dislocation-Based Theory for the Deformation Hardening Behavior of DP Steels: Impact of Martensite Content and Ferrite Grain Size

Journal of Metallurgy ◽

10.1155/2010/647198 ◽

2010 ◽

Vol 2010 ◽

pp. 1-16 ◽

Cited By ~ 36

Author(s):

Yngve Bergström ◽

Ylva Granbom ◽

Dirk Sterkenburg

Keyword(s):

Plastic Deformation ◽

Grain Size ◽

Deformation Process ◽

Volume Fraction ◽

High Energy ◽

Martensite Content ◽

Plastic Deformation Process ◽

Deformation Hardening ◽

Dp Steels ◽

Ferrite Grain Size

A dislocation model, accurately describing the uniaxial plastic stress-strain behavior of dual phase (DP) steels, is proposed and the impact of martensite content and ferrite grain size in four commercially produced DP steels is analyzed. It is assumed that the plastic deformation process is localized to the ferrite. This is taken into account by introducing a nonhomogeneity parameter, f(ε), that specifies the volume fraction of ferrite taking active part in the plastic deformation process. It is found that the larger the martensite content the smaller the initial volume fraction of active ferrite which yields a higher initial deformation hardening rate. This explains the high energy absorbing capacity of DP steels with high volume fractions of martensite. Further, the effect of ferrite grain size strengthening in DP steels is important. The flow stress grain size sensitivity for DP steels is observed to be 7 times larger than that for single phase ferrite.

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