Influência da austenita retida no crescimento de trincas curtas superficiais por fadiga em camada cementada de aço SAE 8620 / The influence of retained austenite on short fatigue crack growth in case carburized SAE 8620 steel

Valdinei Ferreira da Silva

02 October 1997

A austenita retida está sempre presente na microestrutura de camada cementada de aços, em maior ou menor quantidade. Como é uma fase dúctil comparada à martensita, sua presença tem sido alvo de muita controvérsia. Este trabalho apresenta um estudo sobre a influência da austenita retida na propagação de trincas curtas por fadiga em camada cementada de aço SAE 8620. Foram feitos ensaios de fadiga por flexão em quatro pontos, a temperatura ambiente, em corpos de prova sem entalhe com três níveis de amplitude de tensão e razão de tensões de 0,1. Através de diferentes ciclos de cementação e tratamentos térmicos, foram obtidas camadas cementadas com quatro níveis de austenita retida na microestrutura. O teor de austenita retida foi medido através da técnica de difração de Raios-X. Trincas superficiais foram monitoradas por meio da técnica de réplicas de acetato. Como resultados foram obtidos tamanho de trinca em função do número de ciclos e taxa de crescimento de trincas curtas. Corpos de prova com maiores níveis de austenita retida apresentaram maior vida em fadiga. / The retained austenite is always present in case carburized steel microstructure in small or high percentages. Since it is a ductile phase, its presence has long been a controversial subject. The influence of retained austenite on short fatigue crack propagation in case carburized SAE 8620 steel was studied in this work. Four-point-bend fatigue tests were carried out at room temperature in specimens without notch using three levels of stress range and a stress ratio of 0.1. Four different amount of retained austenite in the case carburized microstructure were obtained through different cycles of carburizing and heat treating. The retained austenite content was measured by X-ray technique, and the surface short crack growth was monitored by means of acetate replication technique. Crack length versus number of cycles and crack growth rate versus mean crack length were obtained as results. Specimens with higher levels of retained austenite in the carburized case showed longer fatigue life.

Austenita retida

Camada cementada

Crescimento de trincas curtas por fadiga

Case carburized

Retained austenite

Short fatigue crack growth

Investigation Of Mechanical Properties And Microstructure Of Steel-Wires

Maissara, Khalifa

January 2021

Wear and friction are among the major problems faced in several industries such as mining industry. This creates challenges to select better materials with good wear behavior in order to improve the service life of the components. In the present project, three steel wire grades OH 70, OH 75 and OH 101 have been heat treated by quenching and partitioning heat treatment and tested using three wear testing methods. The wear tests performed were a pin-on-disc test, dry-pot test and slurry pot-test, and the results were compared with the conventional quenched and tempered steel. Tensile tests, hardness, impact Charpy tests, scanning electron microscope, optical microscope, X-ray diffraction and magnetic measurements were applied to characterize mechanical properties and microstructure of the steels before wear tests. The results showed that the quenched and partitioned steels with considerable amount of retained austenite had higher ductility and good impact toughness than the quenched and tempered steels. After the pin on disc tests, OH 75 grade showed the highest wear resistance, while the lowest wear resistance was obtained by OH 70 grade. The damage mechanisms identified after pin-on-disc were abrasion and oxidative wear. During erosive wear, almost no measurable wear was recorded under the dry pot conditions, while the slurry pot test owned significant wear mass loss. The main modes of the worn surfaces after erosive tests were ploughing and cutting. In addition, cracks were also observed.

steel

heat treatment

quenching and partitioning

quenching and tempering

retained austenite

wear mechanisms

wear testing

Metallurgy and Metallic Materials

Metallurgi och metalliska material

Nanostructural Evolution of Hard Turning Layers in Carburized Steel

Bedekar, Vikram

25 July 2013

No description available.

Industrial Engineering

Materials Science

Hard Turning

Nanostructure

White Layer

TEM

Glancing Angle X-ray diffraction

retained austenite transformation

Microstructure and mechanical properties of a 5 wt.% Cr cold work tool steel : Influence of heat treatment procedure.

Rehan, Arbab

January 2017

The demand for Advanced High Strength Steel (AHSS) in the automotive industry is increasing day by day. It is mainly motivated by the fact that AHSS can be used as thin sheets while having high strengths. It enables weight reduction of the automobiles which consequently increases the fuel efficiency and has proven to be less harmful to the environment. It is also expected that AHSS will have even higher strength in the near future. Cold work tools steels with 5 wt.% Cr are commonly used to process AHSS. Therefore, the tool steel must meet the challenges in the future, i.e. have even higher hardness, compressive strength and toughness. One way of increasing the mechanical properties of the tool steel is by improving the heat treatment parameters. However, it is not possible without a deeper understanding of the heat treatment process. Therefore, this work presents investigations related to phase transformations occurring in a 5 wt.% Cr cold work tool steel during heat treatment. Furthermore, the influence of austenitisation and tempering temperatures on the microstructure and mechanical properties were investigated. The studies revealed that a higher austenitisation temperature can be used to achieve a higher hardness, good compressive strength and adequate toughnessof the steel. However, too high austenitisation temperature may result inexcessive coarsening of prior austenite grains which reduced the impact toughness. It was also found that retained austenite can transform during tempering by two different mechanisms. Firstly, when tempering at 525°C, carbides precipitate in retained austenite lowering its stability and permitting a transformation to marten site on cooling. Secondly, when tempering at 600°Cfor extended holding time retained austenite isothermally transforms to ferrite and carbides. This occurs by precipitation of carbides in retained austenite followed by a final transformation to ferrite and carbides.These results were used to understand the standard tempering procedure of the 5 wt.% Cr cold work tool steel. Furthermore, alternative heat treatment procedures are discussed based on the important findings presented in this thesis.

Cold work tool steel

Heat treatment

Microstructural characterisation

Mechanical properties

Retained austenite

Bearbetnings-, yt- och fogningsteknik

Characterization of the Factors Influencing Retained Austenite Transformation in Q&P Steels

Adams, Derrik David

02 April 2020

Formable Advanced High-Strength Steels (AHSS) have a unique combination of strength and ductility, making them ideal in the effort to lightweight vehicles. The AHSS in this study, Quenched and Partitioned 1180, rely on the Transformation Induced Plasticity (TRIP) effect, in which retained austenite (RA) grains transform to martensite during plastic deformation, providing extra ductility via the transformation event. Understanding the factors involved in RA transformation, such as local strain and grain attributes, is therefore key to optimizing the microstructure of these steels. This research seeks to increase understanding of those attributes and the correlations between microstructure and RA transformation in TRIP steels. To measure local strain, the viability of using forescatter detector (FSD) images as the basis for DIC study is investigated. Standard FSD techniques, along with an integrated EBSD / FSD approach (Pattern Region of Interest Analysis System), are both analyzed. Simultaneous strain and microstructure maps are obtained for tensile deformation up to around 6% strain. The method does not give sub-grain resolution, and surface feature evolution prevents DIC analysis across large strain steps; however, the data is easy to obtain and provides a natural set of complementary information for the EBSD analysis. In-situ tensile tests combined with EBSD allow RA grain and neighboring attributes to be characterized and corresponding transformation data to be obtained. However, pseudo-symmetry of the ferrite (BCC) and martensite (BCT) phases prevents EBSD from accurately identifying all phases. Measuring the relative distortion of the crystal lattice, tetragonality, is one approach to identifying the phases. Unfortunately, small errors in the pattern center can cause significant errors in tetragonality measurement. Therefore, this research utilizes a new approach for accurate pattern center determination using a strain minimization routine and applies it to tetragonality maps for phase identification. Tetragonality maps based on dynamically simulated patterns result in the most accurate maps and can also be used to predict approximate local carbon content. Machine learning is then used on the collected data to isolate key attributes of RA grains and provide a decision tree model to predict transformation based on those attributes. Among the most relevant attributes found, RA grain area, RA grain shape aspect ratio, a “hardness” factor, and major axis orientation are included. Possible correlations between these factors and transformation improve understanding of relevant attributes and show the advantage that machine learning can have in unravelling complex material behavior.

electron backscatter diffraction (EBSD)

digital image correlation (DIC)

tetragonality

pattern center

retained austenite

Engineering

Effect of Starting Microstructure and CGL Compatible Thermal Processing Cycle on the Mechanical Properties of a Medium Mn Third Generation Advanced High Strength Steel

Bhadhon, Kazi

January 2017

Medium Mn TRIP steels are amongst the most widely researched third generation advanced high strength steels (3G-AHSSs) as they are ideal candidates for automotive light-weighting applications owing to their superior strength and ductility balance. However, the thermal processing cycles of these steels need to be compatible with the industrial continuous galvanizing line (CGL) in order to successfully employ them in the automotive manufacturing industry. The main objective of the present research was to develop a CGL compatible thermal processing cycle for a prototype medium Mn steel that would produce significant volume fractions of chemically stable retained austenite and exhibit mechanical properties consistent with established 3G-AHSS targets. In that regard, the effects of intercritical annealing (IA) time and temperature and starting microstructure were determined in the first part of this research. The as-received tempered martensite (S-TM) and heat treated martensite (S-M) were the two different starting microstructures studied in this research. In this case, the overaging temperature (OT) treatment (460°C for 20s) was kept constant. It was found that high volume fractions (≥ 0.30) of retained austenite were achieved for S-M samples intercritically annealed at 675°C for shorter times (i.e. 60 to 120s) compared to S-TM samples. TEM analysis of the S-M samples showed that most of the retained austenite was present in a film type morphology, which is known to be more stable chemically and mechanically compared to the block type morphology. The tensile test results showed that although both the S-TM and S-M samples exhibited a high strength/ductility balance, the S-M samples, particularly the S-M 675°C + 120s samples, showed more potential in terms of CGL compatibility and achieving 3G-AHSS target mechanical properties. The effect of OT holding time was determined in the second part of this research. In that regard, the OT holding time was varied form 20s to 120s for selected S-TM and S-M samples. The S-TM 710°C samples with increased OT holding times (60s and 120s) had a significant increase in retained austenite volume fraction compared to the baseline 20s OT samples. However, the retained austenite volume fractions did not change for S-M samples regardless of OT holding time. It was also found that the mechanical properties of the annealed S-TM and S-M steels depended on the OT holding time. For the S-TM samples with > 120s IA holding times, longer OT holding times (60s and 120s) produced chemically unstable retained austenite which transformed rapidly at low strain resulting in low UTS × TE products. However, although longer OT holding times significantly increased the yield strength of the annealed S-M samples, the UTS × TE product decreased significantly owing to decreased retained austenite stability. Finally, based on the results of this research, it was concluded that the prototype medium Mn TRIP steel can achieve 3G-AHSS target mechanical properties using CGL-compatible thermal processing cycles. Moreover, depending on successful reactive wetting, it may be possible to perform both thermal processing and galvanizing of this steel in the industrial CGL. / Thesis / Master of Applied Science (MASc)

Medium Mn TRIP Steel

3G-AHSS

Retained Austenite

Mechanical Properties

Overaging Temperature Holding Time

CGL Compatible Thermal Processing Cycle

[en] EFFECT OF THE AUSTENITIZATION TEMPERATURE ON THE QUENCHING AND PARTITIONING PROCESS / [pt] EFEITO DA TEMPERATURA DE AUSTENITIZAÇÃO NO PROCESSO DE TÊMPERA E PARTIÇÃO

DANIEL MASSARI DE SOUZA COELHO

11 September 2008

[pt] O processo de Têmpera e Partição (T&P) possibilita a produção de aços com frações controladas de austenita retida, a partir do enriquecimento da austenita pela partição de carbono da martensita sem a precipitação de carbonetos. A austenita retida proporciona o efeito TRIP (plasticidade induzida por transformação), que confere ao material uma deformação uniforme e uma melhor absorção de energia durante o impacto. Os aços produzidos por este processo atendem principalmente às necessidades da indústria automobilística, que busca aços com melhores propriedades para a diminuição de peso e aumento da segurança dos automóveis. Nesta dissertação, ligas de aço com diferentes composições e tamanhos de grão foram produzidos pelo processo de Têmpera e Partição e a fração de austenita retida foi medida por difração de raios-X. As ligas também foram caracterizadas por nanoindentação, microscopia ótica e microscopia eletrônica de varredura. As amostras estudadas foram produzidas com uma austenitização completa a 930°C, realizada para promover um aumento no tamanho de grão, e os resultados foram comparados com amostras estudadas anteriormente com temperatura de austenitização de 890°C. Os resultados obtidos indicaram um aumento da fração de austenita retida com o aumento do grão austenítico original. Estes resultados foram interpretados com base no modelo teórico desenvolvido para o processo T&P. / [en] The Quenching and Partitioning (Q&P) process allows the production of steels with controlled fractions of retained austenite from the enrichment of the austenite by carbon partitioning from the martensite without carbide precipitation. The retained austenite is responsible for the TRIP effect (transformation induced plasticity), which enhances the material behavior providing a uniform strain and a better energy absorption during impact. Steels produced by this process match the requirements of the automotive industry, which looks for weight reduction and safety improvements in cars. In the present dissertation, steels with different compositions and grain sizes were produced by the Quenching and Partition process and their retained austenite fraction was measured by x-ray diffraction. The steels were also characterized by nanoindentation, optical microscopy and scanning electron microscopy. The specimens studied were produced by a complete austenitization at 930°C, to promote an increase in the austenitic grain size, and the results were compared with previously studied specimens produced by a complete austenitization at 890°C. The experimental results indicate an increase of austenite fraction with an increase in grain size of the original austenite. These results were analyzed based on the theoretical model develop for the Q&P process.

[pt] TRATAMENTOS TERMICOS

[en] HEAT TREATMENTS

[pt] ACO

[en] STEEL

[pt] PARTICAO DE CARBONO

[en] CARBON PARTITIONING

[pt] AUSTENITA RETIDA

[en] RETAINED AUSTENITE

[pt] TRANSFORMACAO DE FASE

[en] PHASE TRANSFORMATION

INFLUÊNCIA DAS TEMPERATURAS DE AUSTENITIZAÇÃO E AUSTÊMPERA NA MICROESTRUTURA E PROPRIEDADES DE TRAÇÃO DE UM FERRO FUNDIDO NODULAR

Boneti, Ludiere Lucas Toldo

29 August 2014

Made available in DSpace on 2017-07-21T20:43:47Z (GMT). No. of bitstreams: 1 Ludiere Lucas Toldo Boneti.pdf: 5901766 bytes, checksum: 4f1a93e8f2d24f82e2576b7891703690 (MD5) Previous issue date: 2014-08-29 / The present study aimed to evaluate the influence of the austempering heat treatment parameters on microstructure and mechanical properties of a ductile cast iron produced in industrial conditions, containing 3.59% carbon, 2.68% silicon, 0.46% copper (in wt%) and a carbon equivalent of 4.50%. The material was produced in a foundry located in the southwest region of Parana state, Brazil. The specimens were obtained by casting the alloy into Y-block molds. The austempering heat treatments consisted of pre-heating at 500°C, followed by austenitizing step at 870°C, 900°C and 930°C during 60 minutes. Austempering was carried out in molten metal baths at temperatures of 300°C and 370°C for 30 minutes. Microstructural characterization was carried out by light optical microscopy (LOM) with image analysis, scanning electron microscopy (SEM-FEG) and X-ray diffraction with Rietveld refinement. The mechanical properties were evaluated by tensile and Vickers hardness tests. The as-cast microstructure displayed a very heterogeneous microstructure, characterized by the presence of regions with graphite flotation and carbide containing intercellular regions. The graphite nodules showed low nodularity, of 85%, which was attributed to the fading effect of magnesium alloy. Austempered samples were characterized by the presence of bainitic ferrite, interspersed with retained austenite in films and blocks. The austempering at 300°C resulted in a finer microstructure containing smaller volume fractions of retained austenite. All heat treated samples displayed transformation gradients between graphite flotation and intercellular regions. These gradients affected the mechanical properties, as well as the fracture characteristics. The best results of mechanical properties were obtained in the specimen austenitized at 900°C followed by austempering at 300°C, allowing the ADI produced to fit into a high strength class, according to ASTM A897. The study of fracture surfaces showed a sharp transition between graphite flotation and intercellular regions. The fracture at the vicinity of graphite nodules have occurred by a ductile mechanism, characterized by dimples. It was observed a rapid transition to the cleavage mode at intercellular regions, containing solidification carbides. / O presente trabalho teve como objetivo avaliar a influência dos parâmetros de tratamento térmico de austêmpera na microestrutura e nas propriedades mecânicas de tração e dureza, em uma liga de ferro fundido nodular produzida em condições industriais. A liga em estudo possui de teor de carbono de 3,59%, silício de 2,68% e adições de 0,46% de cobre, possuindo ainda um carbono equivalente de 4,50%. O material foi produzido em condições industriais, em uma fundição localizada no sudoeste do estado do Paraná. Os corpos de prova para retirada de amostras foram obtidos pelo vazamento da liga em moldes de blocos Y. Os tratamentos térmicos de austêmpera consistiram de pré-aquecimento a 500°C, seguido da etapa de austenitização a 870°C, 900°C e 930°C, por um tempo fixo de 60 minutos. A etapa de austêmpera foi realizada em banhos de metais fundidos, em temperaturas de 300°C e 370°C, durante 30 minutos. A caracterização microestrutural de amostras foi realizada pelas técnicas de microscopia ótica, com análise de imagens, microscopia eletrônica de varredura e difração de raios X, com refinamento pelo método de Rietveld. As propriedades mecânicas foram avaliadas por meio de ensaios de tração e dureza Vickers. A liga no estado bruto de fundição apresentou microestrutura bastante heterogênea, caracterizada pela presença de regiões com flotação de grafita e regiões intercelulares contendo carbetos de solidificação. Os nódulos de grafita apresentaram baixo grau de nodularização, de 85%, resultado que foi atribuído ao efeito de fadiga térmica da liga nodularizante. A microestrutura de amostras austemperadas foi caracterizada pela presença de agrupamentos de feixes de ripas de ferrita bainítica, entremeadas por austenita retida, na forma de filmes e blocos. A austêmpera a 300°C produziu microestruturas mais refinadas e com menores frações volumétricas de austenita retida. Em todas as amostras tratadas termicamente, foi observado um gradiente de transformação entre as regiões de flotação de grafita e regiões intercelulares. Estes gradientes afetaram tanto os resultados de propriedades mecânicas, como as características de fratura dos corpos de prova. Os melhores resultados de propriedades mecânicas foram obtidos para a condição de austenitização a 900°C seguida de austêmpera, permitindo enquadrar o ADI em uma classe de alta resistência, segundo a norma ASTM A897. As análises das superfícies de fratura dos corpos de prova de tração mostraram uma mudança nas características de fratura entre as regiões de flotação de grafita e as regiões intercelulares. Nas proximidades dos nódulos de grafita houve predominância do mecanismo de fratura dúctil, caracterizada pela presença de cavidades alveolares (“dimples”), com rápida transição para o modo de fratura por clivagem nas regiões com baixos números de nódulos de grafita, contendo carbetos de solidificação.

Fundição

Ferro fundido nodular austemperado

Bainita

Austenita retida

Propriedades mecânicas

Casting

Austempered ductile iron

Bainite

Retained austenite

Mechanical properties

The theory and significance of retained austenite in steels

Bhadeshia, Harshad Kumar Dharamshi Hansraj

January 1980

The processes leading to the retention of small quantities of austenite following the bainite and martensite phase transformations have been examined, together with the influence of retained austenite on the properties of low alloy steels. It was found that the upper and lower bainite transformations are separate reactions, although both involve a displacive transformation mode, Growth seems to occur by the repeated nucleation of martensitic sub-units, and this leads to an apparently slow growth rate, The partitioning of carbon from bainitic ferrite into residual austenite was thermodynamically proven to occur subsequent to transformation, and was shown to be directly responsible for the 'incomplete reaction phenomenon'. The nature of sympathetic nucleation and of the limited size of bainitic sub-units was rationalised in terms of the relatively low driving force available for bainite transformations. It was shown that the retention, stability and morphology of austenite could be directly derived from the basic transformation mechanism. Under certain circumstances, the bainitic retained austenite conferred exceptional strength/toughness properties to silicon steels; these were· shown to be superior to the properties associated with tempered martensite microstructures, Using thermodynamics, a model was established which could predict the toughness behaviour of silicon steel bainites simply from a knowledge of the composition. The tempered martensite embrittlement phenomenon was not found to be directly linked to the decomposition of retained austenite films, but to the coarsening of inter- or intra-lath carbides. In dislocated martensites, it was found that the distribution and quantity of retained austenite could be rationalised in terms of the degree of accommodation between adjacent martensite variants. The incipient twins generally observed in lath martensites were shown to be accommodation defects such that the extent of twinning was the greatest when adjacent martensite units had twin-related lattices. The thermodynamics of dislocated martensites have been briefly examined, The inhomogeneous deformation behaviour of dual-phase steels has been analysed in terms of available models.

669

Estudo das transformações de fase de aços TRIP ao Si-Mn microligados com Nb. / Phase transformations study on Nb microalloyed Mn - Si TRIP steels.

Hurtado Ferrer, Modesto

30 May 2003

Estudou-se a cinética das transformações de fase em resfriamento contínuo e em tratamentos isotérmicos de cinco ligas de aços TRIP microligados com Nb, contendo teores variáveis de Mn e Si, através de ensaios dilatométricos, de caracterização morfológica dos produtos de transformação e de cálculos termodinâmicos e simulações numéricas usando os programas Thermocalc ® e Dictra®. Foram determinados os diagramas RC para a transformação da austenita, e foi estudada a influência da precipitação de ferrita pró-eutetóide e de bainita na fração volumétrica de austenita retida. Através dos diagramas de resfriamento contínuo foi possível delimitar a extensão do campo intercrítico dos cinco aços analisados, com determinação da janela de resfriamento e seus intervalos de temperaturas. Isso permitiu projetar os ciclos de resfriamento controlado a serem aplicados durante o processamento termomecânico dos Aços TRIP-D, TRIP-E e TRIP-H. Os cálculos pelo modelo numérico de redistribuição de carbono e de elementos substitucionais na interface ferrita/austenita, bem como as medidas de microanálise química por WDS e EDS permitiram verificar que a taxa de crescimento da ferrita pró-eutetóide é controlada pela difusão do carbono na austenita. Para tempos curtos de tratamento, o modelo de crescimento que melhor se ajusta é o do equilíbrio local com partição negligível de soluto. Verificou-se através de tratamentos isotérmicos no campo bainítico, que o silício atrasa a precipitação de carbonetos durante a reação bainítica, o que justifica o aumento da estabilidade da austenita retida no aço de maior Si (TRIP-H), quando comparado com o aço de menor Si (TRIP-E). Baseado nos resultados dos estudos das transformações de fase por resfriamento contínuo foram selecionadas as ligas TRIP-D, TRIP-E e TRIP-H, para simular dois esquemas de laminação controlada por meio de ensaios de torção a quente. Nesses ensaios foram variados o grau de deformação e a temperatura de acabamento, de modo a estudar os efeitos dos parâmetros de deformação mecânica na fração transformada dos diferentes constituintes microestruturais, e em particular na fração volumétrica de austenita retida. O primeiro ensaio refere-se à laminação controlada por recristalização estática (LCRE) e o segundo à laminação convencional (LCC), com temperatura de acabamento de 1030°C e 850°C, respectivamente. O resfriamento consistiu em dois tratamentos isotérmicos consecutivos: o primeiro no campo intercrítico (austenita + ferrita), e o segundo no campo bainítico. O aumento do grau de deformação na simulação por torção a quente da laminação controlada por recristalização estática, levou a um aumento da porcentagem de austenita retida obtida durante o resfriamento controlado (de 9 a 14,0 %). O acúmulo de energia de deformação abaixo da TNR na simulação do processo de laminação controlada convencional provocou uma diminuição da fração volumétrica de austenita retida bem como da concentração de carbono contido nela. Os perfis de Mn e C obtidos a partir de análises químicas com EDS e WDS em amostras do aço TRIP-E, deformadas com deformação total de 2,1 e deformação total de 2,8, mostram a contribuição do refinamento de grão para a difusão destes elementos na frente da interface ferrita/austenita, durante a precipitação de ferrita pró-eutetóide. / The phase transformation kinetics of five Nb microalloyed Si-Mn TRIP steels was studied under continuous cooling and isothermal treatments, using dilatometric techniques, morphologic characterization, Thermocalc computational thermodynamics and Dictra numerical simulation. WDS and EDS X-ray microanalysis and Dictra numerical modeling of C, Mn and Si distribution during transformation showed that the reaction is carbon diffusion controlled and growth occurs under local equilibrium with negligible partition. CCT diagrams for austenite transformation were determined and the effect of the amount of proeutectoid ferrite and bainite precipitation on the volume fraction of retained austenite was also estimated. The CCT diagrams allowed determining the boundaries of the critical zone and the processing window to obtain bainite plus austenite microstructures. Based on this information cooling cycles were selected to perform thermomechanical treatments. Three TRIP steels were selected to simulate, in a hot torsion testing machine, two different controlled rolling sequences: Recrystallization Controlled Rolling and Conventional Controlled Rolling. The influence of the degree of deformation and the finishing temperature on the amount of retained austenite was studied. After rolling the cooling cycle comprised two isothermal treatments, one in the austenite + ferrite field and the other in the bainitic field. Increasing the strain during simulation of Recrystallization Controlled Rolling led to an increase in the volume fraction of retained austenite to the range 9 to 14 %. The energy stored during simulation bellow TNR of the Conventional Controlled Rolling led to a decrease in the volume fraction and in the carbon content of retained austenite. The Mn and C contents measured by EDS and WDS analysis of TRIP-E steel, showed that grain refinement due to recrystallization contributes to diffusion of these elements in front of the ferrite/austenite interface during precipitation.

aços de baixa liga e alta resistência

aços TRIP

austenita retida

bainitic transformation

continuous cooling diagrams

intercritical treatment

laminação controlada

phase transformations

retained austenite

transformações de fase

TRIP-steels