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91	Influence de la transformation martensitique induite par la déformation sur le comportement mécanique d’aciers inoxydables duplex / Influence of strain induced martensitic transformation on the mechanical behavior of duplex stainless steels Lechartier, Audrey 15 December 2015 (has links) Les aciers inoxydables duplex présentent une combinaison intéressante entre des propriétés mécaniques élevées, une faible conductivité thermique et un coût relativement faible. Ils sont couramment employés dans le domaine du bâtiment comme rond à béton, application qui requière notamment une résistance élevée (Rm > 950 MPa) et une ductilité importante (A% > 15). Cette thèse a pour objectif d’améliorer le compromis résistance / allongement, en développant de nouvelles nuances duplex présentant une transformation martensitique induite par la plasticité (effet TRIP) aux caractéristiques contrôlées. L’optimisation de ce compromis a nécessité en particulier une compréhension détaillée des mécanismes de transformation et de déformation plastique associés à chaque phase : la ferrite (BCC), l’austénite (FCC) et la martensite (BCC).L’influence de la transformation martensitique sur le comportement mécanique est étudiée pour quatre alliages duplex de stabilité variable de la phase austénitique en fonction de leur composition chimique. L’influence d’une microstructure multiphasée sur la cinétique de transformation est déterminée grâce à l’élaboration de trois nuances modèles représentant respectivement une nuance duplex et es deux compositions représentatives de ses constituants austénite et ferrite. L’utilisation de plusieurs techniques de caractérisation à différentes échelles a permis de décrire à la fois les mécanismes de transformation de phase et leur cinétique en fonction de la déformation, donnant ainsi accès à leur influence sur le comportement mécanique. L’étude des champs cinématiques a mis en évidence l’impact de la phase martensitique sur la répartition des déformations dans la microstructure multi-phasée. Finalement l’utilisation d’un modèle mécanique prenant en compte explicitement la transformation martensitique a permis de reproduire le comportement mécanique d’un alliage duplex. / Duplex stainless steels offer an attractive combination of high mechanical properties, low thermalconductivity and a relatively low cost. They are increasingly used as structural materials such as inthe construction sector as concrete reinforcement bars, where both high strength (Rm > 900 MPa)and high elongation to failure (A% > 15 %) are required. This thesis aims at improving the strength/ elongation compromise by developing new duplex stainless steel compositions experiencing a wellcontrolledmartensitic transformation induced by plasticity (TRIP effect). The optimisation of thiscompromise has required a good understanding of the transformation mechanisms and of plasticdeformation associated with each phase : ferrite (BCC), austenite (FCC) and martensite (BCC).The influence of martensitic transformation on mechanical behavior has been studied in four duplexgrades of variable austenite stability as a function of their chemical composition. The influence ofmultiphase microstructure on martensitic transformation kinetics has been determined by makingthree alloys respectively representative of a duplex grade and its two constituents (austenite andferrite). Using multiple characterization techniques at different scales has allowed determiningboth the transformation mechanisms and its kinetics as a function of strain, giving thus accessto the influence of transformation on the mechanical behavior. The study of kinematic fields hashighlighted the impact of the martensitic phase on the distribution of deformations. Finally, theuse of a mechanical model taking explicitly into account the phase transformation has allowed theduplication of the mechanical behavior of a duplex stainless steel. Aciers inoxydable duplex Comportement mécanique Corrélation d'images Martensite Duplex stainless steels Transformation induced plasticity TRIP effect Mechanical behavior Digital image correlation X-Ray diffraction Martensite 620
92	Crystallographic study on Ni-Mn-Sn metamagnetic shape memory alloys / Étude cristallographique d'alliages à mémoire de forme métamagnétiques Ni-Mn-Sn Lin, Chunqing 01 December 2017 (has links) En tant que nouveau matériau magnétique à mémoire de forme, les alliages basés sur le système Ni-Mn-Sn possèdent de multiples propriétés physiques telles que l'effet de mémoire de forme des alliages polycristallins, l'effet magnétocalorique géant, l'effet de magnétorésistance et l'effet de polarisation d'échange. Jusqu'à présent, la plupart des études ont été axées sur l'amélioration des multifonctionnalités de ces alliages, mais l'information fondamentale qui est fortement associée à ces propriétés n'est toujours pas claire. Ainsi, une étude approfondie sur les structures cristallines de la martensite et de l'austénite, les caractéristiques microstructurales et cristallographiques de la transformation martensitique a été menée dans le cadre du présent travail de doctorat. Il a été confirmé que l'austénite de Ni50Mn37.5Sn12.5 possède une structure cubique L21 (Fm3 ̅m, No.225). Le paramètre de réseau de l'austénite dans Ni50Mn37.5Sn12.5 est aA = 5.9813 Å. La martensite possède une structure orthorhombique (4O) à quatre couches (Pmma, No.51). Les paramètres de réseau de la martensite dans Ni50Mn38Sn12 et Ni50Mn37.5Sn12.5 sont a4O = 8.6068 Å; b4O = 5.6226 Å and c4O = 4.3728 Å, and a4O = 8.6063 Å, b4O = 5.6425 Å, and c4O = 4.3672Å, respectivement. La martensite 4O Ni-Mn-Sn présente une microstructure hiérarchiquement maclée. La martensite est organisée en larges plaques dans le grain d'austénite d'origine. Les plaques contiennent des colonies à forme irrégulière avec deux modèles caractéristiques de microstructures : le motif lamellaire classique et le motif en arête de poisson. Dans chaque colonie, il existe quatre variantes d'orientation (A, B, C et D) et elles forment trois types de macles (Type I, Type II et macles composées). Les interfaces entre les variantes correspondantes sont en coincidence avec leur plan de maclage K1. Les plans d'interface des paires de macles composées A-D et B-C peuvent avoir une ou deux orientations différentes, ce qui conduit aux deux modèles microstructuraux. Les variantes correspondantes dans les colonies voisines dans une même large plaque (colonies intra-plaques) possèdent des orientations proches et le joint de colonie est courbé, tandis que la limite de colonie inter-plaques est relativement droite. La relation d’orientation de Pitsch (Orientation Relation OR), spécifiée comme {1 0 1} A//{22 ̅1}4O and <1 0 1 ̅> A//<1 ̅2 2>4O, a été exclusivement déterminée à être une OR effective entre l'austénite cubique et la martensite modulée 4O. Sous cette OR, 24 variantes peuvent être générées dans un grain d'austénite. Ces 24 variantes sont organisées en 6 groupes et chaque groupe correspond à une colonie de martensite. La structure de martensite finement maclée (microstructure sandwich) est le composant microstructural de base produit par la transformation martensitique. Une telle structure assure une interface de phase invariante (plan d'habitat) pour la transformation. Au cours de la transformation, les variantes de la martensite sont organisées en clusters en forme de diamant composés de colonies de variantes et avec des structures en forme de coin au front de transformation. Chaque coin est composé de deux structures sandwich séparées par un plan de nervure médiane {1 0 1}A. Les paires de variantes dans chaque coin devraient avoir le même type de macles avec une relation de Type I ou de Type II pour garantir de bonnes compatibilités géométriques des variantes à l'interface de phase et au plan de la nervure centrale. Dans les diamants, les colonies sont séparées par des frontières présentant des marches à faible énergie interfaciale qui évoluent vers les joints des colonies intra-plaques et par des joints droits qui deviennent les joints entre les plaques. Les diamants s'allongent le long de la direction presque parallèle aux plans de la nervure centrale des coins et la forme de la plaque de la martensite est finalement formée. [...] / Being a novel magnetic shape memory material, Ni-Mn-Sn based alloy systems possess multiple physical properties, such as shape memory effect of polycrystalline alloys, giant magnetocaloric effect, large magnetoresistance effect and exchange bias effect. So far, most studies have been focused on the improvement of the multifunctionalities of these alloys, but the fundamental information which is highly associated with these properties is still unclear. Thus, a thorough study on the crystal structures of martensite and austenite, microstructural and crystallographic features of martensitic transformation has been conducted in the present PhD work. The austenite of Ni50Mn37.5Sn12.5 was confirmed to possess a L21 cubic structure (Fm"3" ̅m, No.225). The lattice parameter of austenite in Ni50Mn37.5Sn12.5 is aA=5.9813 Å. The martensite possesses a four-layered orthorhombic (4O) structure (Pmma, No.51). The lattice parameters of martensite in Ni50Mn38Sn12 and Ni50Mn37.5Sn12.5 are a4O = 8.6068 Å; b4O = 5.6226 Å and c4O = 4.3728 Å, and a4O = 8.6063 Å, b4O = 5.6425 Å, and c4O = 4.3672Å, respectively. The 4O Ni-Mn-Sn martensite exhibits a hierarchically twinned microstructure. The martensite is organized into broad plates in the original austenite grain. The plates contain irregularly shaped colonies with two characteristic microstructural patterns: classical lamellar pattern and herring-bone pattern. In each colony, there are four orientation variants (A, B, C and D) and they form three types of twins (Type I, Type II and compound twin). The interfaces between the corresponding variants are in coincidence with their twinning plane K1. The interface planes of the compound twin pairs A-D and B-C can have one or two different orientations, which leads to the two microstructural patterns. The corresponding variants in the neighboring colonies within one broad plate (intra plate colonies) possess close orientations and colony boundary is curved, whereas the inter plate colony boundary is relatively straight. The Pitsch OR, specified as "{1 0 1}" A//"{2 " "2" ̅" " "1" ̅"}" 4O and "<1 0 " "1" ̅">" A//"<" "1" ̅" " "2" ̅" 2>" 4O, was uniquely determined to be an effective OR between the cubic austenite and 4O modulated martensite. Under this OR, 24 variants can be generated within one austenite grain. Such 24 variants are organized into 6 groups and each group corresponds to a martensite colony. The finely twinned martensite structure (sandwich microstructure) is the basic microstructural constitute produced by martensitic transformation. Such a structure ensures an invariant phase interface (habit plane) for the transformation. During the transformation, martensite variants are organized into diamond shaped clusters composed of variant colonies and with wedge shaped structures at the transformation front. Each wedge is composed of two sandwich structures separating by a midrib plane {1 0 1}A. The variant pairs in each wedge should have the same twin type with either Type I or Type II relation to ensure good geometrical compatibilities of the variants at phase interface and at the midrib plane. Within the diamonds, colonies are separated by step-like boundaries with low interfacial energy that evolve into the intra plate colony boundaries and by straight boundaries that become the inter plate colony boundaries. The diamonds elongates along the direction nearly paralleled to the midrib planes of the wedges and plate shape of martensite is finally formed. Such features of the diamond structure in Ni-Mn-Sn alloys are realized by self-accommodation of transformation strains for energy minimization. The present work provides comprehensive microstructural and crystallographic information on martensite and on martensitic transforamtion of Ni-Mn-Sn alloys and it is useful for understanding their multi functionalities associated with martensitic transformation and helpful on property optimization Alliage à mémoire de forme Ni-Mn-Sn Organisation de la martensite Relation de maclage Relation d'orientation Cristallographie Transformation martensitique Self-accommodation Ni-Mn-Sn shape memory alloy Martensite organization Twin relationship Orientation relationship Crystallography Martensitic transformation Self-accommodation 669.94 620.16
93	Efeitos da temperatura de laminação na formação e na reversão de martensita induzida por deformação no aço inoxidável austenítico AISI 304L. / Effects of the rolling temperature on the formation and on the reversion of strain induced martensite in a AISI 304L stainless steel. Tiago Evangelista Gomes 14 February 2012 (has links) Objetivo principal desta dissertação foi verificar os efeitos da temperatura de laminação na formação de martensita induzida por deformação e na sua posterior reversão da martensita para austenita no aço inoxidável austenítico AISI 304L. O estudo foi predominantemente microestrutural e para análise e caracterização foram utilizadas as técnicas de microscopia óptica, microscopia eletrônica de varredura, difração de raios X, medidas de dureza Vickers e medidas de fases ferromagnéticas por ferritoscopia. As amostras foram inicialmente solubilizadas a 1100 ºC por uma hora, visando a dissolução de uma pequena quantidade residual de ferrita encontrada nas amostras na condição como recebida, depois laminadas em diferentes temperaturas, determinando-se curvas de endurecimento por deformação e de formação de martensita induzida por deformação em função do grau de deformação. Em seguida, foram realizados pré-recozimentos a 600 ºC, favorecendo apenas a reversão da martensita para austenita, de maneira que não ocorresse a recristalização. A quantidade e a temperatura de deformação apresentaram forte influência na quantidade de martensita formada, no endurecimento por deformação e na cinética de amolecimento durante o recozimento. Os pré-tratamentos realizados a 600 ºC causaram acentuada reversão da martensita, algum amolecimento e pequeno efeito no tamanho de grão recristalizado durante o posterior recozimento a 600 ºC. / The main objective of the present dissertation was to verify the effects of the rolling temperature on the formation of strain induced martensite and in its subsequent martensite reversion to austenite in a AISI 304L stainless steel. The study was predominantly microstructural and, for the analysis and characterization, several techniques have been used, namely optical microscopy, scanning electron microscopy, X-ray diffraction, Vickers hardness measurements and magnetic phase measurements, using the ferritoscope. The samples were initially solution annealed at 1100 ºC for one hour, aiming at the dissolution of a small quantity of the residual -ferrite found in the samples in the as-received condition; then rolling was performed at different temperatures, evaluating strain hardening and the strain induced martensite as a function of strain. Following, pre-annealing treatments at 600 ºC have been performed, favoring only the martensite to austenite reversion, in a way that no recrystallization would occur. Strain and temperature had a strong influence on the amount of formed martensite, on the strain hardening and on the softening kinetics during annealing. The pre-annealing treatments at 600 ºC caused an accentuated effect on the martensite reversion, some softening and a small effect on the recrystallized grain size during the subsequent annealing at 600 ºC. Aço inoxidável austenítico 304L Endurecimento por deformação Martensita induzida por deformação Recristalização Refino de grão Reversão da martensítica 304L austenitic stainless steel Grain refinement Martensite reversion Recrystallization Strain hardening Strain induced martensite
94	Estudo da evolução microestrutural e das propriedades magnéticas do aço inoxidável austenítico AISI 201 laminado a frio / Study of the microstructural evolution and magnetic properties of a cold rolled AISI 201 austenitic stainless steel Isnaldi Rodrigues de Souza Filho 20 August 2015 (has links) Nos últimos anos, devido ao elevado preço do níquel, uma nova série de aços inoxidáveis austeníticos com um menor teor de níquel foi criada. A essa nova série foi dado o nome de série 200. Dentre os aços dessa classe, o AISI 201 tem sido utilizado em aplicações onde a elevada resistência à corrosão não é tão necessária. Neste trabalho de Mestrado investigou-se a formação e a reversão da martensita induzida por deformação em um aço inoxidável austenítico AISI 201 laminado a frio em 20, 40 e 60% de redução em espessura. Das chapas laminadas foram retiradas amostras que foram recozidas em várias temperaturas (200-800oC) por 1 hora. Amostras do material laminado em 60% de redução em espessura também foram recozidas por várias temperaturas (200-800oC) e por vários tempos (5-180min). Com isso, avaliou-se a evolução microestrutural do material durante a laminação frio e durante o recozimento por meio de medidas de microdureza Vickers, microscopias óptica, eletrônica de varredura e eletrônica de transmissão, difração de elétrons retroespalhados, difração de raios X e medidas de magnetização. Além disso, foram realizados cálculos termodinâmicos para a previsão da formação de fases nesse material. Constatou-se que o material de partida não era completamente austenítico, possuindo uma pequena fração de ferrita ? residual em sua microestrutura. Com relação às medidas de magnetização, observou-se que a fração de fase ferromagnética (martensita) aumenta com o aumento da deformação, aumentando a magnetização de saturação (Ms) do material. Para pequenas deformações (20% de redução em espessura) houve a ocorrência de um pico no valor de campo coercivo do material (Hc). Com o aumento da deformação (40 e 60%) os valores de Hc diminuíram. Com relação à reversão da martensita induzida por deformação durante os recozimentos, observou-se que ela ocorre na faixa de temperatura de 500-700oC para o material laminado em 60% de redução em espessura. O comportamento do material nesse estudo corrobora o que tem sido reportado na literatura para os aços da série 300. Entretanto, pouco tem sido publicado com relação às propriedades magnéticas do aço inoxidável austenítico AISI 201, principalmente com relação ao campo coercivo. Neste trabalho também foram realizadas medidas de magnetização durante o recozimento das amostras (condição in situ). Os parâmetros obtidos desses experimentos in situ foram comparados com aqueles obtidos para as amostras recozidas isotermicamente. / In the last years, since nickel price increased, another series of austenitic stainless steel with less amount of nickel has emerged: the series 200. The AISI 201 stainless steel has been used where intermediated corrosion resistance is needed. In this work, the formation of strain-induced martensite and its reversion in an AISI 201 austenitic stainless steel were studied. The material was characterized in terms of microstructure and then cold rolled up to 20, 40 and 60% of thickness reduction. For all degree of reduction, samples were annealed at several temperatures (200-800oC) for 1 hour. Additional samples taken from the 60% cold-rolled material were also annealed at several temperatures (200-800oC) for several times (5-180minutes). The microstructural evolution during cold rolling and annealing was evaluated using microhardness Vikers testing, light optical microscopy, scanning electron microscopy, transmission electron microscopy, electron backscatter diffraction, X-Ray diffraction and magnetization measurements. Phase predictions were also performed using software Thermo-calc©. It was observed that the as-received material was not fully austenitic. It has a small fraction of ?-ferrite within its matrix. The amount of ferromagnetic phase (martensite) increases with increasing deformation. For small deformation (20%), there is a peak in the coercive field of the material (Hc). As deformation increases, Hc values decrease. It was also observed that the martensite reversion takes place at 500-700oC. The behavior of the material is in accordance with what has been reported in the literature for the 300 series. However, only few works have been reported concerning AISI 201 stainless steel and its magnetic properties. In this work, magnetic measurements were also carried out during annealing (in situ condition). The obtained parameters from the in situ magnetic measurements were compared to those ones obtained from the isothermally annealed samples. Aço inoxidável austenítico AISI 201 Evolução microestrutural Martensita induzida por deformação Propriedades magnéticas Reversão da martensita AISI 201 austenitic stainless steel Magnetic properties Martensite reversion Microstructural evolution Strain induced martensite
95	Rupture fragile des liaisons bimétalliques en acier inoxydable dans le haut de la transition fragile-ductile / Brittle fracture of Stainless Steel dissimilar metal welds in the upper shelf of the brittle-to-ductile transition temperature range Ben Salem, Ghassen 19 June 2019 (has links) Les liaisons bimétalliques en acier inoxydable (LBM inox) permettent, au sein des réacteurs nucléaires français actuels, de connecter les gros composants en acier ferritique faiblement allié (cuve, pressuriseur, générateur de vapeur) à la tuyauterie du circuit primaire en acier austénitique inoxydable. De par leurs microstructure et propriétés mécaniques hétérogènes, ces liaisons sont des zones dites "sensibles" pour l'intégrité des structures et il est donc indispensable de caractériser leur tenue mécanique dans les situations de fonctionnement nominal et accidentelles. Ce travail de thèse a pour objectif d'évaluer le risque d'amorçage fragile de la LBM inox dans le haut de la transition fragile-ductile à l'aide d'un critère adapté. Les microstructures au voisinage de l'interface entre l'acier ferritique et le beurrage austénitique ont tout d’abord été caractérisées, et un liseré martensitique d’épaisseur variable ainsi qu’une couche entièrement austénitique ont été observés. Ces deux couches, qui sont le siège d’une intense précipitation de carbures pendant le traitement thermique de détensionnement, forment ensemble une couche dure de martensite et d’austénite carburées potentiellement fragile. Le comportement mécanique de l’ensemble de la LBM inox a ensuite été étudié à 20°C et à -175°C, et des lois de comportement élasto-plastiques isotropes ont été identifiées pour les différentes couches macroscopiques à partir d’essais de traction sur des éprouvettes multi-matériaux travers-joint à diamètre variable. Le comportement mécanique de la couche dure a, quant à lui, été caractérisé à partir d’essais in-situ sur des micro-éprouvettes usinées au FIB et testées à l’aide d’une micro-machine de traction développée dans cette thèse. Une étude des mécanismes de rupture de la LBM inox dans le domaine de la transition fragile-ductile a par ailleurs été réalisée à partir d’essais sur éprouvettes CT et a mis en évidence une fragilité de l’interface MA (entre martensite et austénite) liée à un mécanisme de rupture intergranulaire amorcée sur les carbures et systématiquement activé pour des fronts de préfissure traversant la couche dure. Une modélisation par éléments finis des essais a permis d’analyser les champs de contrainte sur l’interface MA et d’identifier un modèle de Weibull linéique à 3 paramètres basé sur une contrainte seuil et une distance seuil pour les éprouvettes CT. Finalement, l’effet du vieillissement thermique sur les LBM inox a été étudié à partir d’un traitement thermique de 10 000h à 400°C et un durcissement des couches austénitiques résultant d’un mécanisme de décomposition spinodale de la ferrite résiduelle a été mis en évidence à partir d’essais de traction. L’analyse des mécanismes de rupture à l’état vieilli a également montré que ce durcissement provoque une augmentation d’environ 30°C de la température de transition associée à la rupture intergranulaire de l’interface MA. / Stainless steel dissimilar metal welds (SS DMW) are widely used within the French nuclear power plants where they connect the main components (pressure vessel, pressurisor, steam generator) made of low-alloy ferritic steel to the primary circuit pipes made of austenitic stainless steel. Because of their heterogeneous microstructure and mechanical properties, these junctions are critical components for the structure integrity and their fracture resistance has to be demonstrated for all the nominal or accidental operating conditions. This PhD work aims at building a model to evaluate the risk of brittle fracture of the SS DMW in the upper shelf of the brittle-to-ductile transition range. The observation of the microstructures around the fusion line revealed a martensitic layer and a fully austenitic zone, which undergo an important carbides precipitation during the post-weld heat treatment and form a narrow hard layer of carburized martensite and austenite. The mechanical behavior of the SS DMW was then characterized at 20°C and -175°C and isotropic elastoplastic constitutive laws were determined for each macro/mesoscopic layer of the weld from tensile tests on crossweld specimens with variable diameters. The mechanical behavior of the narrow hard layer was also studied with micro tensile tests on specimens extracted by FIB micro processing and tested using an in-situ tensile testing device developed during the PhD. Furthermore, fracture toughness tests were carried out on CT specimens in the brittle-to-ductile temperature range and helped identify the MA interface (between martensite and austenite) as the weakest region in the SS DMW because of an intergranular fracture mechanism initiated at the carbides-rich interface. This mechanism was consistently observed for specimens with fatigue precrack fronts in the hard layer. The stress distributions on the MA interface calculated from the FE numerical simulation of these tests were then analysed and a 1D 3 parameters Weibull model based on a threshold stress and a threshold length was identified for the CT specimens. Finally, the effect of thermal ageing on the SS DMW was explored with a thermal ageing treatment of 10000h at 400°C and a hardening of the austenitic layers was measured by tensile tests and was associated to a spinodal decomposition mechanism of the residual ferrite. The fracture mechanisms of the SS DMW were also analysed in the aged state and showed that this hardening caused an increase of the transition temperature associated with the intergranular fracture of the MA interface by about 30°C. Liaisons bi-métalliques Rupture fragile intergranulaire Martensite Austénite carburée Loi de Weibull Contrainte seuil Vieillissement thermique Dissimilar metal welds Intergranular brittle fracture Martensite Carburized austenite Weibull law Threshold stress Thermal ageing
96	Estudo dilatométrico das transformações de fase em aços maraging M300 e M350. / Study dilatometric of the phase transformations on maraging steels M300 and M350. Carvalho, Leandro Gomes de 09 December 2011 (has links) Os aços maraging são aços de baixo teor de carbono com estrutura martensítica (CCC), que são endurecidos pela precipitação de fases intermetálicas. O objetivo deste trabalho é estudar as transformações de fases desses aços: precipitação, reversão da martensita para a austenita e transformação martensítica. Nesse trabalho, foram caracterizadas uma corrida de aço maraging da série 300 e três corridas da série 350, usando diversas técnicas complementares: microscopia ótica, microscopia eletrônica de varredura com análise dispersiva de energia, microdurômetro, difração de raios-X, ferritoscópio e dilatometria. Os resultados obtidos mostraram que as corridas com maiores teores de cobalto e titânio apresentaram maiores valores de microdureza nos estados solubilizado e envelhecido. Por outro lado, medidas dilatométricas mostraram que há uma influência significativa tanto da composição química, quanto da taxa de aquecimento nas reações de precipitação e reversão da martensita para a austenita. No entanto, a transformação martensítica mostrou-se dependente apenas da taxa de aquecimento. / Maraging steels are steels with a low carbon martensitic structure (BCC), which are hardened by precipitation of intermetallic phases. The aim of this work is to study the phase transformations of these steels: precipitation, martensite to austenite reversion and martensitic transformation. In this study, one cast of 300 grade and three casts of 350 grade were characterized using several complementary techniques: optical microscopy, scanning el ectron microscopy with energy dispersive analysis, microhardness, X-ray diffraction, ferritoscope and dilatometry. The results showed that the casts with higher concentrations of cobalt and titanium showed higher microhardness in the solution annealed and aged states. On the other hand, dilatometry measurements showed that there is a significant influence of both the chemical composition and the heating rate on the reactions of precipitation and reversion of martensite to austenite. However, the martensitic transformation was dependent solely on the heating rate. Aços maraging Aging Austenite reversion Dilatometria Dilatometry Envelhecimento Maraging steels Martensite to austenite reversion Reversão da martensita para a austenita
97	Determinação de velocidades críticas de têmpera em aços por meio de curvas de resfriamento / Determination of critical quenching velocities in steels by means of cooling curves Patrocínio, Andrei Barban do 28 April 1999 (has links) As velocidades críticas de resfriamento necessárias à obtenção de percentuais definidos de martensita, presentes em amostras de aços temperados em óleo, foram determinadas por meio de curvas de resfriamento. As amostras constituíram-se de barras de aço AISI 4140 e 8640 com seções circulares de 25,4; 38,1 e 50,8 mm e barras quadradas com 25,4 e 38,1 mm de lado e comprimento igual a 5 vezes o diâmetro ou lado. Visando-se à obtenção de padrões de comparação para essas velocidades, foram também obtidas as curvas em U das durezas ao longo das seções transversais das barras e as curvas Jominy desses aços. Os resultados apresentaram boa coerência, o que garantiu a eficiência do processo. Os resultados concernentes ao teor específico de 50% de martensita foram comparados com os obtidos a partir de equações constantes na literatura. As equações não se mostraram diretamente adequadas, requerendo a obtenção de um fator de correção, que uma vez obtido mostrou-se eficiente na adequação dos valores empíricos de velocidade crítica aos determinados por meio das curvas de resfriamento. / The criticaI cooling velocities necessary to obtaining specific contents of martensite, present in test specimens of hardened steels in oil, were evaluated by means of cooling curves. The samples were constituted of bars of AISI 4140 and 8640 steels with 25,4; 38,1 and 50,8 mm diameter and squared bars with 25,4 and 38,1 mm in side by 5 times the diameter or side long. Aiming at obtaining comparison patterns for those velocities, they were also obtained the curves in U of the hardness along the traverse sections of the bars and the Jominy curves of those steels. The results presented good agreement, what guaranteed the efficiency of the process. The concerning results achieving a 50 pct martensitic microstructure were compared with those obtained from equations presented in the literature. The equations did not show good approaches, requesting the determination of a correction factor, that once obtained it was shown efficient in the adaptation of the empirical values of critical velocities to those determined by means of the cooling curves. Cooling curve Critical velocity Curva de resfriamento Martensite content Minimum cooling rate Taxa mínima de resfriamento Teor de martensita Velocidade crítica
98	On the interactions between strain-induced phase transformations and mechanical properties in Mn-Si-Al steels and Ni-Cr austenitic stainless steels Petein, Arnaud 20 December 2006 (has links) L'augmentation constante de la circulation automobile a travers le monde fait des effluents gazeux un des problèmes majeurs de toutes les sociétés modernes. Tant d'un point de vue économique et écologique, chacun s'accorde sur le fait que la consommation de carburants fossiles utilisés dans le transport doit baisser, principalement en réduisant le poids des véhicules. Le développement de matériaux à hautes performances et à bas prix est donc indispensable. Pour atteindre cet objectif, cette étude visait à élucider les interactions entre la déformation et les transformations de phase dans les aciers a hautes performances qui pourraient remplir les conditions de réduction de poids. En effet, une large gamme de travaux a montrer que les transformations de phase induites mécaniquement (effet TRIP) de l'austénite peuvent être à l'origine d'une amélioration des propriétés mécaniques dans de nombreuses nuances d'acier. Les transformations de phase induites par la déformation dépendent de deux paramètres : la stabilité relative et l'énergie de fautes d'empilement de l'austénite, qui sont affectes par différents facteurs. Les interactions entre les transformations de phase et les propriétés mécaniques de différentes nuances Cr-Ni et Mn-Si-Al furent examinées sous plusieurs conditions de taille de grain, de température et d'état de chargement. Des relations particulières furent établies entre les phénomènes qui se produisent a l'échelle des grains individuels et a l'échelle macroscopique. Les mécanismes cristallographiques des transformations de phase successives (austénite - martensite e - martensite a') ont été mis en évidence. Finalement, différentes techniques de raffinage de la taille de grain furent utilisées pour produire des aciers inoxydables comportant des tailles de grain variées, et l'efficacité de ces techniques a été comparée. Pour cela, les cinétiques de retransformation, recrystallisation et croissance des grains ont été étudiées. La réduction de taille des grains par cycles de transformations de phase fut établie comme plus efficace de la méthode classique par déformation - recristallisation. / The continuously increasing use of automobiles all over the world, is making of gas effluents one of the major concerns for all modern societies. From economical and ecological points of view, everyone agrees on the fact that the consumption of fossil fuels for transport must decrease, particularly by vehicle weight reduction. Development of high performance materials at low cost is therefore needed. In order to achieve this requirement, the present work aimed at investigating the interactions between straining and phase transformations in high performance steels that could meet the weight saving requirements. Indeed, a wide range of studies has shown that mechanically-induced phase transformations (TRIP effect) of the austenite may bring about improved mechanical properties in different steel grades. Strain-induced phase transformations depend on two parameters : the relative stability and the stacking fault energy of the austenite, which are affected by different factors. The interactions between the phase transformations and the mechanical properties of different Ni-Cr and Mn-Si-Al grades were examined under various conditions of grain size, temperature or stress state. Particular relationships were clearly established between the phenomena taking place at the scale of the individual grains and at the macroscopic scale. The crystallographic mechanisms of the successive strain-induced phase transformations (austenite - e-martensite - a'-martensite) has been clarified. Finally, different techniques of grain refinement were used to process stainless steels with various grain sizes, assessing the efficiency of these techniques. Therefore, the kinetics of retransformation, recrystallisation and grain growth were studied. Grain refinement by cycles of phase transformations was found more effective than the classical deformation - recrystallisation method. Martelage rotatif Martensite Traction Laminage Austenite Acier Transformation de phase Taille de grain Grain size Traction Phase transformation Steel Swaging Rolling
99	Etude du comportement thermomécanique des Alliages à Mémoire de Forme sous sollicitations multiaxiales complexes Lavernhe Taillard, Karine 11 December 2006 (has links) (PDF) Le comportement spécifique des Alliages à Mémoire de Forme (AMF) est dû à une transformation de phase appelée transformation martensitique. Cette transformation de phase peut être activée par des variations de température mais aussi par des chargements mécaniques. Si le comportement 1D de ces alliages est bien connu, la modélisation du comportement de ces alliages sous sollicitations multiaxiales complexes pose encore quelques problèmes.<br />Dans un premier temps, nous nous intéressons à la validation expérimentale directe d'une relation entre la fraction volumique de martensite et la déformation de transformation qui est utilisée dans de nombreux modèles. Pour cela des essais en traction-compression-torsion avec suivi de résistance électrique sur un AMF de type Cu-Al-Be sont réalisés. Ces essais mettent en évidence les effets de la texture de ces alliages sur leur comportement.<br />Par ailleurs, des simulations numériques de type micro-macro sont réalisées, pour différentes textures et pour différents trajets multiaxiaux proportionnels. Ces simulations complètent, d'une part, la base de données expérimentale, et permettent, d'autre part, de valider les hypothèses retenues pour la modélisation.<br />Enfin, des essais anisothermes de traction compression torsion proportionnels et non proportionnels sont réalisés sur un AMF de type Ni-Ti. Une surface de début de réorientation de phase R est ainsi mise en évidence. Pseudoélasticité multiaxiale effet mémoire simple sens multiaxial fraction volumique de martensite modèle micro-macro anisotrope anisotherme
100	Micromechancal modeling of dual-phase steel using a rate-dependent crystal plasticity model Mahmoody, Sam. January 2007 (has links) Dual-phase (DP) steels consisting of a ferrite matrix with dispersed martensite particles have attracted a significant interest due to their combination of high work hardening and ductility. A great deal of experimental work has been done to obtain a better comprehension of the relation of their mechanical behaviour to their microstructural characteristics. In the present work, a micromechanical study of ferrite-martensite DP steels is conducted. The deformation of ferrite is described by a rate-dependent crystal plasticity theory, which relates the stress-strain field equations on the grain level to the macroscopic behaviour of the material. The crystal plasticity theory assumes that slip is the only deformation mechanism. Martensite, on the other hand, is considered an elastic-plastic isotropic solid. The interfaces of the grains are taken into account through an idealized form of grain boundaries. A FORTRAN program was coupled with the finite element method to solve the stress equations of the crystal plasticity. Including the grain boundaries made it possible to examine the effect of ferrite grain size on the strength of the material. It is shown that by decreasing the grain size, the yield stress increases according to Hall-Petch equation. Additionally, the effects of the volume fraction of martensite (Vm) on the onset strain, i.e. the strain at which martensite deforms plastically, and of the distribution of martensite on the stress are studied. The former showed that the onset strain of the DP steel declines linearly with increasing Vm up to 36%, beyond which the onset strain becomes independent of V m. The latter revealed that when martensite particles are formed as islands in the ferrite grains, the material exhibits higher strength and hardening rate; compared to when martensite is distributed as large blocks among the ferrite grains. Steel -- Metallography.

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