Effect of Strain on Transformation Diagrams of 100Cr6 Steel

Kawulok, Rostislav; Schindler, Ivo; Sojka, Jaroslav; Kawulok, Petr; Opěla, Petr; Pindor, Lukáš; Rusz, Stanislav; Ševčák, Vojtěch

doi:10.3390/cryst10040326

Cited by 13 publications

(18 citation statements)

References 38 publications

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“…Such behavior is surprising and inconsistent with the results of many other studies on the effect of plastic deformation on the continuous cooling transformation diagrams [ 1 , 2 , 3 , 5 , 6 , 10 , 14 , 22 , 38 , 39 , 40 , 41 , 58 ]. However, less unambiguous data can be found comparing the CCT and DCCT diagrams for some steels.…”

Section: Resultscontrasting

confidence: 87%

“…The kinetics of austenite decomposition is not only fundamentally influenced by the chemical composition of the steel but also by the parameters of the structure entering the given phase transformation. The prior microstructure depends on the austenitization conditions, the parameters of the pre-deformation, and the cooling time [ 1 , 2 , 3 , 4 , 5 , 6 ]. The continuous cooling transformation (CCT) diagrams show the temperatures of the phase transformations, and the individual decomposition products of austenite depend on the cooling at different rates.…”

Section: Introductionmentioning

confidence: 99%

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Effects of Austenitization Temperature and Pre-Deformation on CCT Diagrams of 23MnNiCrMo5-3 Steel

et al. 2020

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The combined effect of deformation temperature and strain value on the continuous cooling transformation (CCT) diagram of low-alloy steel with 0.23% C, 1.17% Mn, 0.79% Ni, 0.44% Cr, and 0.22% Mo was studied. The deformation temperature (identical to the austenitization temperature) was in the range suitable for the wire rolling mill. The applied compressive deformation corresponded to the true strain values in an unusually wide range. Based on the dilatometric tests and metallographic analyses, a total of five different CCT diagrams were constructed. Pre-deformation corresponding to the true strain of 0.35 or even 1.0 had no clear effect on the austenite decomposition kinetics at the austenitization temperature of 880 °C. During the long-lasting cooling, recrystallization and probably coarsening of the new austenitic grains occurred, which almost eliminated the influence of pre-deformation on the temperatures of the diffusion-controlled phase transformations. Decreasing the deformation temperature to 830 °C led to the significant acceleration of the austenite → ferrite and austenite → pearlite transformations due to the applied strain of 1.0 only in the region of the cooling rate between 3 and 35 °C·s−1. The kinetics of the bainitic or martensitic transformation remained practically unaffected by the pre-deformation. The acceleration of the diffusion-controlled phase transformations resulted from the formation of an austenitic microstructure with a mean grain size of about 4 µm. As the analysis of the stress–strain curves showed, the grain refinement was carried out by dynamic and metadynamic recrystallization. At low cooling rates, the effect of plastic deformation on the kinetics of phase transformations was indistinct.

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Section: Resultscontrasting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Effects of Austenitization Temperature and Pre-Deformation on CCT Diagrams of 23MnNiCrMo5-3 Steel

et al. 2020

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“…The final cooling rate makes it possible to control the austenite softening processes, and phase transformations during decomposition of austenite and grain growth. The published results [4][5][6][7][8][9][10][11][12], and our experiences gained in the laboratory conditions using the hot deformation simulator Gleeble 3800 [13][14], as well as the semi-continuous hot rolling mill [15][16] prove the crucial role of the cooling parameters after hot forming. This can be deduced from the continuous cooling transformation diagrams, especially when considering the previous deformation history.…”

Section: Introductionmentioning

confidence: 99%

“…This can be deduced from the continuous cooling transformation diagrams, especially when considering the previous deformation history. Recently, thanks to two dilatometer systems available on the Gleeble simulator, the researchers of the VŠB-TUO have created continuous cooling transformation diagrams for a number of chemically very different steel grades in the traditional version (CCT), as well as after the previous deformation of austenite (DCCT) -see [17,18], for example. The effect of austenite deformation is very complex and manifests itself differently, e.g., by refining the prior austenite grains due to static recrystallization or by the modification of the austenite decomposition kinetics as a result of deformation strengthening.…”

Section: Introductionmentioning

confidence: 99%

“…The nucleation rate is high; however, the mobility of phase interfaces is severely decelerated by a high density of dislocations in austenite and that is why the final fraction of ferrite decreases. In the case of very large plastic deformation, the high nucleation rate compensates the slow growth of nuclei and the resulting ferrite fraction is approximately the same as in the case of austenite not affected by plastic deformation; however, the ferrite grains are much finer [17,[23][24][25][26][27][28].…”

Section: Introductionmentioning

confidence: 99%

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Continuous cooling transformation diagrams of HSLA steel for seamless tubes production

Schindler

Kawulok

Seillier

et al. 2019

J min metall B Metall

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The CCT and two DCCT diagrams were constructed for the HSLA steel containing Cr, V, Nb, and N microadditions, taking into account industrial processing parameters of this material in a seamless tubes rolling mill. The typical finish hot rolling temperature of 1173 K was used for the construction of the standard CCT diagram and the effect of previous austenite deformation at this temperature was evaluated in the DCCT diagram. Another DCCT diagram was developed after heating at 1553 K, followed by plastic deformation at 1173 K. The prior austenite grain size in the hot rolled material after heating at 1173 K was approx. 10 m, the heating of the as-cast material at 1553 K resulted in the prior austenite grain size over 200 m. The effect of the previous austenite deformation after low-temperature heating on the CCT diagram was negligible. The high-temperature heating showed a great influence on the austenite decomposition processes. The Ferrite-start temperature was significantly reduced at high cooling rates and the preferred decomposition of coarse grained austenite to acicular ferrite suppressed the bainite transformation at medium cooling rates. The developed DCCT diagrams can be used for the prediction of austenite decomposition products during the cooling of the seamless tubes from the finish rolling temperature. The CCT diagram can be utilized for the quality heat treatment of tubes.

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Wear of Tailored Forming Steels

et al. 2023

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This study investigates the wear behavior of additively welded cladding layers on less wear‐resistant base materials using plasma‐transferred arc welding and laser hot‐wire cladding. The cladding layers are made from atomized AISI 52100, AISI 5140, and a stainless steel with (0.52 wt% C, 0.9 wt% Si, 14 wt% Cr, 0.4 wt% Mo, 1.8 wt% Ni, 1.2 wt% V, bal. Fe) on unalloyed steel AISI 1022M as the base material. The specimens' microstructure and surface hardness are comparable with conventional specimens of monolithic AISI 52100 and AISI 4140, which is used as a reference. Tribometer tests are carried out in ball‐on‐disk configuration to investigate the wear resistance of the specimen. The multimaterial specimens show comparable wear behavior to their monolithic counterparts, and a good performance of the stainless specimen in pure sliding is proven. These findings suggest that additive manufacturing processes can be used to clad less wear‐resistant base materials and achieve high wear resistance, making it possible to exploit the advantages of surface coatings under severe wear conditions.

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Effect of Strain on Transformation Diagrams of 100Cr6 Steel

Cited by 13 publications

References 38 publications

Effects of Austenitization Temperature and Pre-Deformation on CCT Diagrams of 23MnNiCrMo5-3 Steel

Effects of Austenitization Temperature and Pre-Deformation on CCT Diagrams of 23MnNiCrMo5-3 Steel

Continuous cooling transformation diagrams of HSLA steel for seamless tubes production

Wear of Tailored Forming Steels

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