Investigation of plastic deformation heterogeneities in duplex steel by EBSD

Wroński, Sebastian; Tarasiuk, Jacek; Bacroix, Brigitte; Baczmański, Andrzej; Braham, C.

doi:10.1016/j.matchar.2012.07.016

Cited by 104 publications

(28 citation statements)

References 25 publications

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“…3(a) and3(b). The IQ factor is often used to determine the deformed and recrystallized volume fractions of material[23]. The recrystallized volume fraction of CVCDEed product is higher than original extruded bar.Fig.…”

mentioning

confidence: 99%

Investigation of microstructure characteristics of the CVCDEed AZ31 magnesium alloy

Zeng

Cao

2015

Materials Science and Engineering: A

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mentioning

confidence: 99%

Investigation of microstructure characteristics of the CVCDEed AZ31 magnesium alloy

Zeng

Cao

2015

Materials Science and Engineering: A

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“…Principles of the EBSD lattice strain assessment have been described elsewhere (e.g., in our previous works [21] , [22] ). In the present work, diffraction pattern quality deterioration and local misorientation analysis approaches [23] , [24] were chosen. EBSD microtextural analysis was conducted by orientation distribution function (ODF) calculations using the Harmonic Series Expansion method, assuming both cubic crystal symmetry and an orthonormal (for the initial material) or a triclinic (for all rolled specimens) symmetry of the sample.…”

Section: B Materials Characterizationmentioning

confidence: 99%

Electron Backscatter Diffraction Study on Microstructure, Texture, and Strain Evolution in Armco Iron Severely Deformed by the Differential Speed Rolling Method

Polkowski

Jóźwik

Bojar

2015

Metall Mater Trans A

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Results of the electron backscatter diffraction (EBSD) study on structural changes in Armco iron subjected to severe plastic deformation by differential speed rolling (DSR) with different values of roll speed mismatch (R = 1, 2, 3, and 4) are shown in the present article. Results of the EBSD microstructure evaluation reveal that a differentiation of roll speeds results in an effect of structure refinement-iron samples processed with high roll speed mismatch are characterized by a high fraction of grains with submicron size. A microtexture examination shows that the DSR process leads to an overall texture weakening effect and a displacement (a shifting to different ''stable'' positions) of the basic rolling texture components, due to an additional presence of a simple shear component in the deformation gradient imposed to the material. Despite the higher hardness of the DSR-processed samples, results of the EBSD strain analysis indicate that some part of the stored deformation energy is released during rolling with an additional presence of shear strain. This finding points toward the possibility of activating a dynamic transformation of the material structure into some more stable state. However, since the observed structural changes take place inside deformation bands and do not lead directly to the formation of a fully equiaxed grain structure, it seems to be more reasonable to call the observed structure transformation a subgrain structure evolution through accumulated shear deformation, which may be related to the dynamic recovery process.

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“…A morfologia e repartição de ambas as fases é um dos principais fatores para controlar o comportamento mecânico e suas propriedades finais. [3] Os AID são caracterizados por possuir alto teor de elementos de liga, por exemplo, molibdênio e nitrogênio os quais permitem a ocorrência de mudanças significativas na sua microestrutura como consequência de tratamentos termomecânicos [2]. Durante a deformação plástica, o refinamento de grão promovido pela estrutura duplex (δ/γ) e os elementos de liga fornecem aos AID maior resistência mecânica comparada aos aços inoxidáveis ferríticos e austeníticos (AISI 430 e 304, respectivamente) [4].…”

Section: Introductionunclassified

“…Durante a deformação plástica, o refinamento de grão promovido pela estrutura duplex (δ/γ) e os elementos de liga fornecem aos AID maior resistência mecânica comparada aos aços inoxidáveis ferríticos e austeníticos (AISI 430 e 304, respectivamente) [4]. No entanto, as duas fases presentes nos AID não apresentam o mesmo comportamento durante a deformação [3]. A fase ferrítica, com estrutura CCC, possui inúmeros sistemas de deslizamento e alta energia de falha de empilhamento, enquanto que a fase austenítica de estrutura CFC tem menos sistema de deslizamento e menor energia de falha de empilhamento [5].…”

Section: Introductionunclassified

Microestrutura E Propriedade Mecânica Dos Aços Inoxidáveis Duplex Uns S31803 E Uns S32304 Após Laminação a Frio E Recozimento

Gonçalves¹,

Oliveira²,

Alcântara³

et al. 2017

Anais Do Congresso Anual Da ABM

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ResumoA evolução da microestrutura e propriedades mecânicas de dois aços inoxidáveis duplex foram estudadas via microscopia óptica e de varredura, ensaios de dureza e tração. As amostras dos aços inoxidáveis duplex foram laminadas a frio com percentual de 18,50 e 62% para o aço S32304 e 21,52 e 64% para o aço S31803. As amostras com 62 e 64% de redução foram recozidas a uma temperatura de 1055ºC com 20 s de encharque. Os resultados mostraram o efeito da deformação a frio na espessura das lamelas de ferrita e austenita, sendo este mais pronunciado na austenita. O aço inoxidável duplex S31803 apresentou maiores valores para o limite de escoamento e dureza devido ao maior percentual de molibdênio e nitrogênio, elementos que atuam como endurecedores por solução sólida. Palavras-chave: Aço inoxidável duplex; Microestrutura; Laminação a frio; Recozimento. MICROESTRUTURE AND MECHANICAL PROPERTIES OF DUPLEX STAINLESS STEELS UNS S31803 AND UNS S32304 AFTER COLD ROLLING AND ANNEALING AbstractThe microstructural evolution and mechanical properties of two duplex stainless steel were studied by optical microscopy and scanning electron microscopy, hardness and tensile tests. Samples of duplex stainless steels were cold rolled with to 18,50 and 62% reduction for the S32304 steel, and 21,52 and 64% for the S31803 steel. Samples with 62 and 64% reduction were annealed at 1055ºC with soaking time of 20 s. The results showed the effect of cold deformation through the thickness of layers of ferrite and austenite, being more pronounced in the austenite. The S31803 duplex stainless steel presented higher values for the yield strength and hardness due to the higher percentage of molybdenum and nitrogen, elements that act as hardeners in solid solution.

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Investigation of plastic deformation heterogeneities in duplex steel by EBSD

Cited by 104 publications

References 25 publications

Investigation of microstructure characteristics of the CVCDEed AZ31 magnesium alloy

Investigation of microstructure characteristics of the CVCDEed AZ31 magnesium alloy

Electron Backscatter Diffraction Study on Microstructure, Texture, and Strain Evolution in Armco Iron Severely Deformed by the Differential Speed Rolling Method

Microestrutura E Propriedade Mecânica Dos Aços Inoxidáveis Duplex Uns S31803 E Uns S32304 Após Laminação a Frio E Recozimento

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