Dilatometric study of low-alloy steels with silicon carbide addition

Hebda, Marek; Dębecka, H.; Kazior, J.

doi:10.1007/s10973-016-5609-1

Cited by 6 publications

(3 citation statements)

References 18 publications

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“…Furthermore, the transformation of austenite grains at different cooling rates is of practical importance during the heat treatment of steel. [19] Although the prior austenite grain size seems to have a small effect on the phase transformation compared to the cooling rate, DOI: 10.1002/srin.202300628…”

Section: Introductionmentioning

confidence: 99%

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Effect of Austenite Grain Size on Phase Transformation Structure of Low‐Carbon Microalloyed Steel

Shi,

Hou,

Yin

et al. 2024

steel research int.

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The effect of austenite grain on the phase transformation of low‐carbon microalloyed steel during continuous cooling is investigated by using Gleeble thermal simulator. The austenite grain size is changed by altering the holding period at the peak temperature. The findings demonstrate that for a given cooling rate, the longer the holding time, the microstructure becomes finer, and bainite begins to show up in the microstructure. The critical temperature of phase transformation and the diagram of phase transformation reaction rate during continuous cooling are determined by dilatometry. The Johnson–Mehl–Avrami–Kolmogorov equation is used to fit the transformation volume fraction, and the variation of kinetic parameters k and n with prior austenite grain size under nonisothermal condition is determined. The n value is trending downward as the prior austenite grain size increases, while the kinetic parameter k barely changes at all. The activation energy of phase transition is calculated by Kissinger method. The activation energy of fine austenite grain increases from 248.6 to 286.3 kJ mol−1 with the increase of austenite grain size, while the activation energy of coarse austenite grain decreases to 176.5 kJ mol−1 due to the competitive nucleation mechanism.

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Section: Introductionmentioning

confidence: 99%

“…Furthermore, the transformation of austenite grains at different cooling rates is of practical importance during the heat treatment of steel. [ 19 ]…”

Section: Introductionmentioning

confidence: 99%

Effect of Austenite Grain Size on Phase Transformation Structure of Low‐Carbon Microalloyed Steel

Shi,

Hou,

Yin

et al. 2024

steel research int.

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“…Because, in slow cooling conditions austenite transforms to ferrite and pearlite, but in the fast-cooling condition it transforms into bainite and martensite. In the arc welding process, within the CGHAZ, austenite transforms into various product phases depending on the heat input [9]. The transformation of austenite into different phases at different cooling rates has its own importance in practical application.…”

Section: Introductionmentioning

confidence: 99%

Physical simulation on Joining of 700 MC steel: A HAZ and CCT curve study

Roshan¹,

Naik²,

Saxena³

et al. 2022

Mater. Res. Express

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In the present work, a coarse grain heat-affected zone (CGHAZ) was simulated by Gleeble 3800 thermo-mechanical simulator. A continuous cooling transformation (CCT) diagram was generated from the results of the dilatometer, hardness, and microstructure analysis. The heating rate of 100°C/s, the peak temperature of 1300°C, the holding time of one second, and thirteen different cooling conditions representing the actual welding condition were chosen here for simulation where the cooling rate was controlled by t8/3. At slow cooling rate ferrite, cementite, pearlite, and bainite were obtained. At a medium cooling rate, ferrite, bainite, and a small amount of martensite were observed. At a fast-cooling rate i.e., 100°Cs-1 fully martensite was obtained. The obtained hardness values were 225 HV, 263 HV, and 342 HV for slower, medium, and fast cooling rates respectively. The increase in hardness value shows that the amount of non-diffusional phases increases with an increase in cooling rate. The CCT curve shows the range of cooling rate and phase transformation temperature of ferrite, bainite, and martensite.

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