Differential scanning calorimetry study of diffusional and martensitic phase transformations in some 9 wt-%Cr low carbon ferritic steels

Ganesh, B. Jeya; Raju, S.; Kumar, Arun; Mohandas, E.; Vijayalakshmi, M.; Rao, K. Bhanu Sankara; Raj, Baldev

doi:10.1179/026708309x12506933873260

Cited by 57 publications

(25 citation statements)

References 48 publications

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“…Figure 7 shows the dilatometric curves that account for the transformation to austenite during heating of the T91 and T9 steels when the heating rate is settled at 1, 30 and 50 ºC/s and the initial metallurgical state is the as-received one. As expected, the higher the heating rates, the more the temperatures A c1 and A c3 are shifted to higher values [26][27][28][29][30][31] . At the same time, for the 30 and 50 ºC/s cases, there is a clear change of slope in the intercritical portion of the curve at temperatures in the region of 900-925 ºC, suggesting that the transformation to austenite proceeds with two distinct regimes.…”

Section: 2supporting

confidence: 77%

“…This implies, in turn, to assume that the only precipitated phase to be found in the as-quenched condition of the T91 steel is constituted by MXtype carbides or mixed carbonitrides (M = Cr, Nb, V; X = C, N). This assumption follows from the fact that the M 23 C 6 carbides existing in the as-tempered state are dissolved during austenite holding and will not precipitate during quenching and also by noting that the solvus temperature of MX-type carbides or carbonitrides is significantly higher than that of M 23 C 6 carbides [31]. Since the T9 steel cannot form MX-type carbonitrides, there will be no carbides present in its as-quenched condition.…”

Section: Discussionmentioning

confidence: 99%

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Heterogeneous austenite grain growth in martensitic 9cr steel: Coupled influence of initial metallurgical state and heating rate

Zavaleta-Gutierrez

Luppo

Danón

et al. 2013

Materials Science and Technology

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The coupled influence of the initial metallurgical state and the heating rate to austenite on the occurrence of heterogeneous grain growth during austenitization of an ASTM A213 -T91 steel has been studied. To that aim, two-step thermal cycles were designed. In the first step, different starting metallurgical conditions were obtained by treating the as-received material at 780 C for increasing times up to 6 hours. In the second step, "in situ" austenitization was performed by heating to austenite at rates of 1, 30 and 50 ºC/s and then holding at 1050 ºC for 30'.Two types of austenite grain structures were obtained after austenitization, namely, homogeneous and heterogeneous. The homogeneous structure was characterized by a smooth size distribution of approximately equiaxed, normally grown grains. The heterogeneous structure, instead, exhibited the exaggerated growth of a few austenite grains embedded in a small to medium-sized "matrix".For the 1 ºC/s heating rate and all of the initial metallurgical states, only homogeneous grain growth was observed, whereas for the 50 ºC/s heating rate only heterogeneous grain growth was observed regardless the starting metallurgical condition. Instead, the occurrence of homogeneous or heterogeneous grain growth after heating at 30 ºC/s was observed to be a function of the time of previous tempering. Some explanations of the phenomenon are advanced taking into account the precipitation state of second phases.

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Section: 2supporting

confidence: 77%

Section: Discussionmentioning

confidence: 99%

Heterogeneous austenite grain growth in martensitic 9cr steel: Coupled influence of initial metallurgical state and heating rate

Zavaleta-Gutierrez

Luppo

Danón

et al. 2013

Materials Science and Technology

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“…DSC was used to measure the heat absorbed or liberated during heating or cooling associated with carbide precipitation and other phase changes. Ganesh et al [10] were able to find the phase transformation temperatures including temperature ranges for dissolution of various precipitates in different low carbon steels.…”

Section: Introductionmentioning

confidence: 99%

Effect of Heat Treatment on Microstructure and Hardness of Grade 91 Steel

Shrestha

Alsagabi

Charit

et al. 2015

Metals

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Grade 91 steel (modified 9Cr-1Mo steel) is considered a prospective material for the Next Generation Nuclear Power Plant for application in reactor pressure vessels at temperatures of up to 650 °C. In this study, heat treatment of Grade 91 steel was performed by normalizing and tempering the steel at various temperatures for different periods of time. Optical microscopy, scanning and transmission electron microscopy in conjunction with microhardness profiles and calorimetric plots were used to understand the microstructural evolution including precipitate structures and were correlated with mechanical behavior of the steel. Thermo-Calc™ calculations were used to support the experimental work. Furthermore, carbon isopleth and temperature dependencies of the volume fraction of different precipitates were constructed.

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“…As the predominant microstructure of high Cr ferritic creep-resistant steels, martensite formed during continuous cooling after austenization has also been studied extensively [9][10][11][12]. However, the model for nucleation and growth of martensite in high Cr ferritic steels is rarely mentioned.…”

Section: Introductionmentioning

confidence: 97%

Non-instantaneous growth characteristics of martensitic transformation in high Cr ferritic creep-resistant steel

et al. 2016

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Microstructural observation and high-resolution dilatometry were employed to investigate kinetics of martensitic transformation in high Cr ferritic creep-resistant steel upon different quenching/cooling rates. By incorporating the classical athermal nucleation and impingement correction, a non-instantaneous growth model for martensitic transformation has been developed. The developed model describes austenite/martensite interface mobility during martensite growth. The growth rate of martensite is found to be varied from 1 9 10 -6 to 3 9 10 -6 m/s. The low interface mobility suggests that it is not appropriate to presume the instantaneous growth behavior of martensite. Moreover, based on the proposed model, nucleation rate of martensite under different cooling rates is found to be nearly the same, while the growth rate of martensite is promoted by increasing the cooling rate.

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Differential scanning calorimetry study of diffusional and martensitic phase transformations in some 9 wt-%Cr low carbon ferritic steels

Cited by 57 publications

References 48 publications

Heterogeneous austenite grain growth in martensitic 9cr steel: Coupled influence of initial metallurgical state and heating rate

Heterogeneous austenite grain growth in martensitic 9cr steel: Coupled influence of initial metallurgical state and heating rate

Effect of Heat Treatment on Microstructure and Hardness of Grade 91 Steel

Non-instantaneous growth characteristics of martensitic transformation in high Cr ferritic creep-resistant steel

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