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Master's Dissertation
DOI
https://doi.org/10.11606/D.3.2008.tde-10112008-112546
Document
Author
Full name
Mario Fernando Gonzalez Ramírez
E-mail
Institute/School/College
Knowledge Area
Date of Defense
Published
São Paulo, 2008
Supervisor
Committee
Landgraf, Fernando José Gomes (President)
Gorni, Antonio Augusto
Tschiptschin, André Paulo
Title in Portuguese
Estudo da transformação durante o resfriamento continuo e da microestrutura do aço microligado X80 utilizado na construção de tubos para transporte de gás natural e petróleo.
Keywords in Portuguese
Aço microligado
Gás natural
Petróleo
Transformações de fase
Tratamento térmico
Abstract in Portuguese
O crescente consumo de energia produzida a partir do petróleo e do gás natural conduz a melhoria das propriedades mecânicas dos aços microligados empregados na construção dos oleodutos e gasodutos para incrementar o transporte dos recursos a menores custos e elevar a confiabilidade. O aumento do controle das diferentes fases, agregados eutetóides, microconstituintes e precipitados neste tipo de aço, garante a melhoria na resistência mecânica, tenacidade e soldabilidade. Dentro deste contexto foi realizado um trabalho de caracterização microestrutural do aço um microligado para tubos API 5L X80 em amostras de aço como recebido e em diferentes condições de resfriamento. Para o estudo da cinética das transformações de fase, o aço microligado foi submetido a ensaios de dilatometria onde foram identificadas as temperaturas e tempos de início e fim de transformação de fases, para varias velocidades de resfriamento. A partir das diferentes temperaturas e tempos obtidos, em função das taxas de resfriamento, foi possível extrair a curva de Transformação por Resfriamento Continuo (TRC). Os dados da curva TRC foram comparados com as microestruturas de cada corpo de prova por meio de microscopia óptica (MO), microscopia eletrônica de varredura (MEV), microscopia eletrônica de varredura com Field Emission Gun (FEG) e microdureza, caracterizando a evolução morfológica da matriz ferrítica, agregados eutetóides e microconstituinte austenita/martensita (MA). Para a caracterização microestrutural das amostras também foram utilizadas técnicas de análise microestrutural como, nanodureza, análise por difração de raios X em amostras obtidas por extração de precipitados, saturação magnética e microscopia de força atômica (AFM). A técnica de saturação magnética foi desenvolvida por médio de curvas de histerese medidas em um histeresígrafo com peças polares e anel de Rowland para diversas amplitudes de intensidade de campo magnético. Esta técnica permitiu a detecção da saturação magnética do aço sem tratamento térmico e a saturação máxima nos aços com tratamento térmico, o que indicou a total transformação da austenita retida. A relação das duas saturações permitiu determinar a fração de austenita retida no MA. Para as medidas de nanodureza foi utilizado um nanodurômetro acoplado ao microscópio de força atômica (AFM). As nanodurezas obtidas em diferentes grãos foram comparadas com os valores constantes na literatura para identificar as fases, agregados eutetóides e possíveis precipitados da microestrutura.
Title in English
Study of the transformation during the continuous cooling and the microstructure of microalloyed steel X80 used in the building of pipelines for gas and oil transport.
Keywords in English
Continuous cooling transformation (CCT)
Heat treatment
Microalloyed steel API X80
Phase transformation
Abstract in English
The continuous increase of energy generated from petroleum and natural gas created the need to improve the mechanical properties of microalloyed steels used in gas and oil pipelines, in order to increase their flow with smaller costs and higher reliability. The control of the different phases, morphology of microconstituents like ferrite plus carbide aggregates and precipitates in this kind of steels is essential to the improvement of mechanical strength, toughness and weldability. In this context, a work of microestrutural characterization of a microalloyed steel for API X80 pipelines was carried out both on an as-received steel sample as in samples submitted to different cooling conditions. The kinetics of austenite transformations was investigated using dilatometric experiments, identifying start and end of the phase transformations as well as the time spent temperatures for the phase transformations at each cooling rate. The temperature and time curves obtained as a function of the cooling rates allowed the determination of a Continuous Cooling Transformation curve (CCT). The data from the CCT curve was compared with the microstructures of each sample through optical microscopy (OM), scanning electron microscopy (SEM), scanning electron microscopy with Field Emission Gun (FEG) and microhardness, characterizing the morphologic evolution of the ferritic matrix, ferrite plus carbide eutectoid aggregates (perlite and bainite) and the microconstituent martensite/austenite (MA). The microestrutural characterization of the samples was performed also using different techniques of microestrutural analysis: precipitate extraction followed by Xrays diffraction analysis, magnetic saturation and atomic force microscopy (AFM) measurements. The magnetic saturation technique was developed through hysteresis curves measured with a hysteresigraph with polar pieces and Rowland ring for several ranges of magnetic field intensity. This technique allowed to detect the magnetic saturation of the steel without thermal treatment and the maximum saturation in the heat treated steels were the retained austenite has transformed. The relationship between those saturations curves allowed a determination of the retained austenite fraction in the MA microconstituent. The nanohardness was measured using a specific device coupled to a atomic force microscope (AFM). The nanohardness of different grains were compared with the hardness values from the literature in order to help identify phases and microconstituents, as well as possible precipitates.
 
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Publishing Date
2008-12-12
 
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