Efeitos das microestruturas bainíticas e multifásicas nas propriedades mecânicas de um aço AISI 4340

Ranieri, Arus [UNESP]

06 1900

Made available in DSpace on 2014-06-11T19:28:35Z (GMT). No. of bitstreams: 0 Previous issue date: 2005-06Bitstream added on 2014-06-13T18:34:54Z : No. of bitstreams: 1 ranieri_a_me_guara.pdf: 1386692 bytes, checksum: c47cd01ee98e83332bd255dbd49cadad (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Universidade Estadual Paulista (UNESP) / Os principais objetivos deste trabalho foram desenvolver estruturas bainíticas e multifásicas através de diversas rotas de tratamentos térmicos, visando as melhores combinações de propriedades mecânicas, fornecendo subsídios científicos/tecnológicos para as indústrias brasileiras. Em certos componentes de veículos aeroespaciais tem sido usado aço de baixa liga e ultra-alta resistência temperados e revenidos com elevada resistência devida a estrutura martensítica mas com baixa tenacidade. Uma melhoria na tenacidade é conseguida com redução controlada de resistência através do revenimento. O novo conceito, para aços avançados que combinam alta resistência com boa tenacidade, está simbolizado pelas microestruturas bainíticas e multifásicas. Neste projeto foi feito um estudo do efeito das microestruturas nas propriedades mecânicas de um aço AISI 4340. Foram analisadas diversas microestruturas, desde aquelas inteiramente bainíticas até microestruturas multifásicas com teores variados de ferrita, bainita, martensita e austenita retida. Os resultados foram comparados com aqueles obtidos por têmpera por resfriamento continuo e com as diversas rotas de transformação isotérmica. As combinações de propriedades mecânicas estão relacionadas com as frações volumétricas das fases e a bainita melhora significativamente a ductilidade do aço, mantendo a resistência elevada e melhorando a combinação resistência/ductilidade. O aço possui baixo coeficiente de encruamento e é possível conseguir resistências entre 1000 MPa e 1400 MPa com alongamento entre 13% e 25%, combinação esta superior aquelas encontradas para o mesmo aço quando temperado e revenido em óleo. / The main goals of this study were to develop bainitic and multiphasic structures through several routes of heat treatment, in order to reach the better combination of mechanical properties, providing scientific/technological subsidies to Brazilian industries. In some of aerospatial vehicles components have been used quenched and tempered ultra-high-strength low-alloy steel where the martensitic structure is responsible for the high-strength and low toughness levels. Toughness improvements can be achieved by strength reduction control during tempering. The new concept for advanced steels, that combine high-strength and good toughness, is correlated with the bainitic and multiphasic microstructures. In this work the effect of microstructures on the mechanical properties of AISI 4340 steel. Has been analysed several microstructures, from those totally bainitic until multiphasics microstructures with various ferrite, bainite, martensite and retained austenite content. The results were compared with those obtained by quenching through continuous cooling transformation and several routes of isothermal transformation. The combinations of mechanical properties are related with volume fraction of present phases and the bainite improved significantly the toughness steel., keeping the high strength and improving the strength/toughness combination. This steel has low coefficient of hardness and is possible to achieve strengths between 1000 MPa e 1400 MPa with percentual elongation between 13% e 25%, this combination is better than that found to the same steel when quenched and tempered in oil.

Ação Católica Operária (Brasil)

Propriedades mecanicas

Aço bainítico

Caracterização microestrutural

Aço multifásico

Bainitic steels

Mechanical properties

Microstructural characterization

Multiphasic steels

Efeitos das microestruturas bainíticas e multifásicas nas propriedades mecânicas de um aço AISI 4340 /

Ranieri, Arus.

January 2005

Resumo: Os principais objetivos deste trabalho foram desenvolver estruturas bainíticas e multifásicas através de diversas rotas de tratamentos térmicos, visando as melhores combinações de propriedades mecânicas, fornecendo subsídios científicos/tecnológicos para as indústrias brasileiras. Em certos componentes de veículos aeroespaciais tem sido usado aço de baixa liga e ultra-alta resistência temperados e revenidos com elevada resistência devida a estrutura martensítica mas com baixa tenacidade. Uma melhoria na tenacidade é conseguida com redução controlada de resistência através do revenimento. O novo conceito, para aços avançados que combinam alta resistência com boa tenacidade, está simbolizado pelas microestruturas bainíticas e multifásicas. Neste projeto foi feito um estudo do efeito das microestruturas nas propriedades mecânicas de um aço AISI 4340. Foram analisadas diversas microestruturas, desde aquelas inteiramente bainíticas até microestruturas multifásicas com teores variados de ferrita, bainita, martensita e austenita retida. Os resultados foram comparados com aqueles obtidos por têmpera por resfriamento continuo e com as diversas rotas de transformação isotérmica. As combinações de propriedades mecânicas estão relacionadas com as frações volumétricas das fases e a bainita melhora significativamente a ductilidade do aço, mantendo a resistência elevada e melhorando a combinação resistência/ductilidade. O aço possui baixo coeficiente de encruamento e é possível conseguir resistências entre 1000 MPa e 1400 MPa com alongamento entre 13% e 25%, combinação esta superior aquelas encontradas para o mesmo aço quando temperado e revenido em óleo. / Abstract: The main goals of this study were to develop bainitic and multiphasic structures through several routes of heat treatment, in order to reach the better combination of mechanical properties, providing scientific/technological subsidies to Brazilian industries. In some of aerospatial vehicles components have been used quenched and tempered ultra-high-strength low-alloy steel where the martensitic structure is responsible for the high-strength and low toughness levels. Toughness improvements can be achieved by strength reduction control during tempering. The new concept for advanced steels, that combine high-strength and good toughness, is correlated with the bainitic and multiphasic microstructures. In this work the effect of microstructures on the mechanical properties of AISI 4340 steel. Has been analysed several microstructures, from those totally bainitic until multiphasics microstructures with various ferrite, bainite, martensite and retained austenite content. The results were compared with those obtained by quenching through continuous cooling transformation and several routes of isothermal transformation. The combinations of mechanical properties are related with volume fraction of present phases and the bainite improved significantly the toughness steel., keeping the high strength and improving the strength/toughness combination. This steel has low coefficient of hardness and is possible to achieve strengths between 1000 MPa e 1400 MPa with percentual elongation between 13% e 25%, this combination is better than that found to the same steel when quenched and tempered in oil. / Orientador: Tomaz Manabu Hashimoto / Coorientador: Antonio Jorge Abdalla / Banca: Marcelo dos Santos Pereira / Banca: Jorge Otubo / Mestre

Propriedades mecanicas.

Aço bainítico.

Aço multifásico

Bainitic steels. eng

Mechanical properties. eng

Microstructural characterization. eng

Multiphasic steels. eng

Evolution microstructurale d'un acier 2.25Cr - 1Mo au cours de l'austénitisation et du revenu : croissance des grains austénitiques, séquence de précipitation des carbures et effets sur les propriétés mécaniques / Microstructural evolution of a 2.25Cr - 1 Mo steel during austenitization and temper : austenite grain growth, carbide precipitation sequence and effects on mechanical properties

Dépinoy, Sylvain

10 December 2015

Ce travail traite de l'optimisation des propriétés en traction et en résilience d'un acier 2.25 Cr – 1 Mo par le contrôle de sa microstructure via des traitements thermiques appropriés. Ainsi, les transformations de phases ayant lieu au cours de l'austénitisation, de la trempe et du revenu doivent être correctement appréhendées. Des observations en microscopies électroniques à balayage et en transmission, ainsi que des analyses par diffraction des rayons X, ont été effectuées afin de caractériser et de modéliser la microstructure de l'acier à chaque étape du traitement thermique. L'évolution de la phase austénitique lors de l'étape d'austénitisation, ainsi que son influence sur la microstructure après trempe, ont été étudiées. La croissance du grain austénitique a été modélisée afin de comprendre ses mécanismes sous-jacents, en particulier le phénomène de croissance limitée observé aux plus basses températures. L'effet des conditions d'austénitisation sur la décomposition de l'austénite ainsi que sur les propriétés mécaniques du matériau après trempe et revenu a été étudié expérimentalement. Une condition d'austénitisation optimale a été déterminée et utilisée pour étudier la précipitation au revenu. La précipitation des carbures a été étudiée pour différents temps et températures de revenu. La séquence de précipitation suivante a ainsi été mise en évidence : la cémentite M3C précipite en premier, suivie des carbures M2C et M7C3 ; les carbures à l'équilibre étant les M23C6. Enfin, l'influence de la précipitation des carbures sur les propriétés mécaniques de l'acier a été étudiée. Les propriétés en traction sont particulièrement sensibles aux conditions de revenu dans le domaine d'étude, alors que les propriétés en résilience restent stables. / This work aims at optimizing tensile and toughness properties of a 2.25Cr – 1Mo steel by controlling its microstructure through heat treatments. To this aim, phase transformations during austenitization, quenching and tempering have to be understood. Quantitative microstructural analyses were performed by means of SEM, TEM and XRD to characterize and model metallurgical evolution of the steel at each step of the heat treatment. The evolution of austenite during the austenitization stage, and its influence on the resulting as-quenched microstructure were thoroughly investigated. Austenite grain growth was modelled in order to understand its mechanisms, including the limited growth phenomenon observed at lower temperatures. The effect of austenitization conditions on further decomposition of austenite and on mechanical properties after quenching + tempering was experimentally determined. An optimal austenitization condition was selected and applied to study the tempering stage. Carbide precipitation was studied for various tempering temperatures and amounts of time. M3C carbides precipitate first, followed by M2C and M7C3; M23C6 are the equilibrium carbides. The influence of carbide precipitation on mechanical properties was studied. Tensile properties are closely linked to the tempering conditions in the range investigated, while impact toughness remains stable.

Aciers bainitiques

Précipitation

Revenu

Thermodynamique

Cinétique

Traction résilience/ténacité

Bainitic steels

Precipitation

Temper

Thermodynamique

Kinetics

Tensilte properties

620.11

Vliv mikrostruktury na hodnoty KV mikrolegované oceli 694F60 / The influence of microstructure on the KV values of microalloyed steel 694F60

Abaidullin, Ilgiz

January 2018

The subject of this master’s thesis was to find the causes of impact toughness scattering of forgings of the test disk with dimension range of 540 – 170 mm. The experimental samples were developed from steel A694 F60. To reach the main aim light microscopy, electron microscopy, EBSD technique, fractographic analysis and hardness measurement HV10 were utilized.

Entwicklung höchstfester Pipeline-Stähle mit MA-Phase für die Herstellung von Grobblechen

Kabanov, Alexander

01 July 2019

Die vorliegende Dissertation konzentriert sich auf die Untersuchung und Entwicklung hochfester Grobblechstähle mit erhöhtem Gehalt an der MA-Phase (Martensit-Austenit Phase). Dabei wurden Bildungsmechanismen der Mikrostruktur und insbesondere der MA-Phase in Abhängigkeit von der Walztechnologie an vier mikrolegierten Grobblechstählen untersucht. Zu diesem Zweck erfolgten zahlreihe Untersuchungen an verschiedenen Prüf- und Simulationsanlagen zur Charakterisierung des Werkstoffverhaltens sowie zur physikalischen Simulation der Grobblechherstellung mit der Anwendung von bekannten und neu entwickelten Wärmebehandlungstechnologien. Abschließend wurden mehrere Serien von Laborwalzversuchen auf einer Warmwalzpilotanlage durchgeführt, um die gewonnenen Erkenntnisse zu evaluieren, sowie die für Pipelinestähle relevanten mechanischen Eigenschaften zu ermitteln. Somit erstreckt sich die Arbeit über die gesamte Produktionskette zur Erzeugung der Grobblechstähle mit MA-Phase und beschreibt hierfür geeignete Herstellungsbedingungen, die in Betriebsanlagen leicht realisierbar sind.

info:eu-repo/classification/ddc/620

ddc:620

Hochfester Stahl

Grobblech

Martensit

Austenit

Warmwalzen

Simulation

Spot Welding of Advanced High Strength Steels (AHSS)

Khan, Mohammad Ibraheem

20 April 2007

Efforts to reduce vehicle weight and improve crash performance have resulted in increased application of advanced high strength steels (AHSS) and a recent focus on the weldability of these alloys. Resistance spot welding (RSW) is the primary sheet metal welding process in the manufacture of automotive assemblies. Integration of AHSS into the automotive architecture has brought renewed challenges for achieving acceptable welds. The varying alloying content and processing techniques has further complicated this initiative. The current study examines resistance spot welding of high strength and advance high strength steels including high strength low alloy (HSLA), dual phase (DP) and a ferritic-bainitic steel (590R). The mechanical properties and microstructure of these RSW welded steel alloys are detailed. Furthermore a relationship between chemistries and hardness is produced. The effect of strain rate on the joint strength and failure mode is also an important consideration in the design of welded structures. Current literature, however, does not explain the effects of weld microstructure and there are no comprehensive comparisons of steels. This work details the relationship between the joint microstructure and impact performance of spot welded AHSS. Quasi-static and impact tests were conducted using a universal tensile tester and an instrumented drop tower, respectively. Results for elongation, failure load and energy absorption for each material are presented. Failure modes are detailed by observing weld fracture surfaces. In addition, cross-sections of partially fractured weldments were examined to detail fracture paths during static loading. Correlations between the fracture path and mechanical properties are developed using observed microstructures in the fusion zone and heat-affected-zone. Friction stir spot welding (FSSW) has proven to be a potential candidate for spot welding AHSS. A comparative study of RSW and FSSW on spot welding AHSS has also been completed. The objective of this work is to compare the microstructure and mechanical properties of Zn-coated DP600 AHSS (1.2mm thick) spot welds conducted using both processes. This was accomplished by examining the metallurgical cross-sections and local hardnesses of various spot weld regions. High speed data acquisition was also used to monitor process parameters and attain energy outputs for each process.

Spot Welding

Advanced High Strength Steel (AHSS)

Resistance Spot Welding (RSW)

Friction Stir Spot Welding (FSSW)

Transformation Induces Plasticity (TRIP)

Dual Phase (DP)

High strength low alloy (HSLA)

Ferritic-Bainitic steels

Mechanical Engineering

Spot Welding of Advanced High Strength Steels (AHSS)

Khan, Mohammad Ibraheem

20 April 2007

Efforts to reduce vehicle weight and improve crash performance have resulted in increased application of advanced high strength steels (AHSS) and a recent focus on the weldability of these alloys. Resistance spot welding (RSW) is the primary sheet metal welding process in the manufacture of automotive assemblies. Integration of AHSS into the automotive architecture has brought renewed challenges for achieving acceptable welds. The varying alloying content and processing techniques has further complicated this initiative. The current study examines resistance spot welding of high strength and advance high strength steels including high strength low alloy (HSLA), dual phase (DP) and a ferritic-bainitic steel (590R). The mechanical properties and microstructure of these RSW welded steel alloys are detailed. Furthermore a relationship between chemistries and hardness is produced. The effect of strain rate on the joint strength and failure mode is also an important consideration in the design of welded structures. Current literature, however, does not explain the effects of weld microstructure and there are no comprehensive comparisons of steels. This work details the relationship between the joint microstructure and impact performance of spot welded AHSS. Quasi-static and impact tests were conducted using a universal tensile tester and an instrumented drop tower, respectively. Results for elongation, failure load and energy absorption for each material are presented. Failure modes are detailed by observing weld fracture surfaces. In addition, cross-sections of partially fractured weldments were examined to detail fracture paths during static loading. Correlations between the fracture path and mechanical properties are developed using observed microstructures in the fusion zone and heat-affected-zone. Friction stir spot welding (FSSW) has proven to be a potential candidate for spot welding AHSS. A comparative study of RSW and FSSW on spot welding AHSS has also been completed. The objective of this work is to compare the microstructure and mechanical properties of Zn-coated DP600 AHSS (1.2mm thick) spot welds conducted using both processes. This was accomplished by examining the metallurgical cross-sections and local hardnesses of various spot weld regions. High speed data acquisition was also used to monitor process parameters and attain energy outputs for each process.

Spot Welding

Advanced High Strength Steel (AHSS)

Resistance Spot Welding (RSW)

Friction Stir Spot Welding (FSSW)

Transformation Induces Plasticity (TRIP)

Dual Phase (DP)

High strength low alloy (HSLA)

Ferritic-Bainitic steels

Mechanical Engineering