Austenitizing Temperature and Cooling Rate Effects on the Martensitic Transformation in a Microalloyed-Steel

Souza, Samuel da Silva de; Moreira, Paulo Sérgio; Faria, Geraldo Lúcio de

doi:10.1590/1980-5373-mr-2019-0570

Cited by 23 publications

(26 citation statements)

References 19 publications

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“…A significant decrease in M s temperature was observed as the step time increased. One factor that strongly influences this temperature is the austenite carbon content 34,35 , so that the higher the austenite carbon content, the lower its M s temperature. Thus, the decrease in M s temperature with the increase of step time, indicates the occurrence of carbon partition for austenite due to ferrite formation in the step stage.…”

Section: Martensite Start Temperaturementioning

confidence: 99%

“…However, the carbon partition for austenite due to the ferrite formation in an intercritical annealing, can lead to a non-homogeneous austenite carbon profile, as discussed by Tan et al 6 and Santofimia et al 36 , influencing the retained austenite morphology and the occurrence of the TRIP effect during deformation 39 . The M s temperature determination after the SQ treatment is necessary to guarantee great agreement between the thermodynamic predictions and the real Q&P heat treatments, since this M s value can be considered an indirect measurement of the austenite carbon content prior to the partial quenching in a Q&P cycle 35 .…”

Section: Martensite Start Temperaturementioning

confidence: 99%

“…Solving the equation system formed by Equation 6, Equation 7and Equation 8, the martensite and austenite carbon concentrations are known after the end of carbon diffusion during the partitioning stage. Therefore, carbon enriched austenite has, at the partitioning end, a lower M s temperature (to be mathematically determined by empirical equations available in technical literature 35 ). Thus, the final quenching up to room temperature can lead to the formation of a certain secondary martensite fraction, and can also be calculated by Equation 8.…”

Section: Thermodynamic Simulations Of Sq-qandp Heat Treatmentsmentioning

confidence: 99%

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Effect of Step Quenching Heat Treatments on the Kinetics of Ferrite Formation and Quenching & Partitioning Modeling for a Commercial C-Mn-Si Steel

2022

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Section: Martensite Start Temperaturementioning

confidence: 99%

Section: Martensite Start Temperaturementioning

confidence: 99%

Section: Thermodynamic Simulations Of Sq-qandp Heat Treatmentsmentioning

confidence: 99%

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Effect of Step Quenching Heat Treatments on the Kinetics of Ferrite Formation and Quenching & Partitioning Modeling for a Commercial C-Mn-Si Steel

2022

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“…A melhor condição de ataque foi com 1,5mL de HCl (60 segundos). Esse aço pode ser classificado como um aço de alta resistência baixa liga, comumente empregado na indústria naval [17]. Ele possui adições de Cr e Mo que são bons formadores de carbonetos.…”

Section: Avaliação Das Micrografias Obtidas Para Cada Condição De Ataqueunclassified

Avaliação da formulação de reativos à base de ácido pícrico visando a revelação do grão austenítico prévio em diferentes tipos de aços

Pimenta¹,

Moreira²,

Faria³

2021

Tecnol. Metal. Mater. Min.

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Este é um artigo publicado em acesso aberto (Open Access) sob a licença Creative Commons Attribution, que permite uso, distribuição e reprodução em qualquer meio, sem restrições desde que o trabalho original seja corretamente citado. a ResumoAs técnicas de revelação dos contornos de grãos austeníticos prévios em aços são importantes ferramentas de caracterização. O método mais usual faz uso de reativos à base de ácido pícrico, que, na maioria dos casos, não produz resultados satisfatórios. Diante disso, foram investigadas, neste trabalho, formulações de reativos à base de ácido pícrico, variando-se a concentração de ácido clorídrico, com o objetivo de propor condições de ataque eficientes para sete aços fabricados no Brasil. Para cada aço, foram avaliados reativos com cinco concentrações distintas de HCl e diferentes tempos de ataque. Foi possível revelar os contornos de grãos austeníticos eficientemente para todos os tipos de aços estudados adequando-se a concentração de HCl adicionado e o tempo de ataque. Com base nos resultados alcançados, foi possível disponibilizar uma tabela e uma equação de regressão linear múltipla que apresenta o tempo de ataque em função do carbono equivalente do aço e da concentração de HCl. Concluiu-se que a concentração de HCL utilizada no reativo é o parâmetro que exerce maior influência sobre o tempo de ataque. Palavras-chave: Grão austenítico prévio; Ácido pícrico; Ácido clorídrico; Carbono equivalente.

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“…The issue of the effect of cooling rate on T Ms in the process of quenching carbide-containing steels was discussed in a number of publications. Authors of [22] have found that in the case of low-alloy high-strength steels, lower values of T Ms corresponded to higher specimen cooling rates. They assumed that at lower values of the cooling rate, precipitation of chromium and molybdenum carbides become possible.…”

Section: Introductionmentioning

confidence: 99%

The Effect of Cooling Conditions on Martensite Transformation Temperature and Hardness of 15% Cr Chromium Cast Iron

et al. 2020

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The research reported in the paper concerned the conditions of cooling high-chromium cast iron with about 15% Cr content capable to ensure completeness of transformation of supercooled austenite into martensite in order to obtain high hardness value of the material and thus its high resistance to abrasive wear. For testing, castings were prepared with dimensions 120 mm × 100 mm × 15 mm cast in sand molds in which one of cavity surfaces was reproduced with chills. From the castings, specimens for dilatometric tests were taken with dimensions 4 mm × 4 mm × 16 mm and plates with dimensions 50 mm × 50 mm × 15 mm for heat treatment tests. The dilatometric specimens were cut out from areas subject to interaction with the chill. The austenitizing temperature and time were 1000 °C and 30 min, respectively. Dilatograms of specimens quenched in liquid nitrogen were used to determine martensite transformation start and finish temperatures TMs and TMf, whereas from dilatograms of specimens quenched in air and in water, only TMs was red out. To secure completeness of the course of transformation of supercooled austenite into martensite and reveal the transformation finish temperature, it was necessary to continue cooling of specimens in liquid nitrogen. It has been found that TMs depended strongly on the quenching method whereas TMf values were similar for each of the adopted cooling conditions. The examined cooling variants were used to develop a heat treatment process allowing to obtain hardness of 68 HRC.

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Austenitizing Temperature and Cooling Rate Effects on the Martensitic Transformation in a Microalloyed-Steel

Cited by 23 publications

References 19 publications

Effect of Step Quenching Heat Treatments on the Kinetics of Ferrite Formation and Quenching & Partitioning Modeling for a Commercial C-Mn-Si Steel

Effect of Step Quenching Heat Treatments on the Kinetics of Ferrite Formation and Quenching & Partitioning Modeling for a Commercial C-Mn-Si Steel

Avaliação da formulação de reativos à base de ácido pícrico visando a revelação do grão austenítico prévio em diferentes tipos de aços

The Effect of Cooling Conditions on Martensite Transformation Temperature and Hardness of 15% Cr Chromium Cast Iron

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