Avaliação comparativa da resistência à fadiga de contato para um aço ferramenta com microestruturas martensíticas e bainíticas. / Comparative study of contact fatigue for a tool steel with bainitic and martensitic microstructure.

Santos, Cláudio Eduardo Rocha dos

21 November 2011

Diversos componentes mecânicos como engrenagens, rolamentos, cilindros de laminação, trilhos e rodas de trem sofrem uma determinada solicitação conhecida por fadiga de contato, que consiste em uma solicitação causada pela tensão gerada entre o contato de dois corpos sob a ação de uma carga cíclica. Este trabalho teve como objetivo avaliar a resistência a esta solicitação para um aço ferramenta com microestruturas martensíticas e bainíticas. Para isto, foi utilizado um equipamento na configuração esfera contra plano, onde as esferas foram confeccionadas em material comercial ABNT 52100 e os discos em aço ferramenta tratados termicamente para obtenção de microestruturas martensíticas e bainíticas. Os ensaios foram realizados com a aplicação de uma pressão máxima de contato de 4,8 GPa até que ocorresse a falha por microlascamento da superfície do disco. Os resultados de vida em fadiga destes materiais foram apresentados por uma distribuição de Weibull que demonstraram uma maior resistência do material bainítico. Os resultados apresentados para ambas as microestruturas demonstraram que as falhas se iniciaram predominantemente na sub-superfície, atendendo as premissas iniciais do trabalho que buscava uma baixa ocorrência de falhas superficiais prematuras ocasionadas por possíveis inclusões, defeitos ou poros superficiais que agiriam como um concentrador de tensões, levando a uma falha antes que efetivamente as características físicas e metalúrgicas das microestruturas sejam testadas. / Several mechanical components such as gears, bearings, rolling mill rolls, rails and train wheels suffer a particular request known to contact fatigue, which consists of a request caused by the tension generated between the contact of two bodies subjected to a cyclic loading. This study aimed to evaluate the resistance to this request for tool steel with bainitic and martensitic microstructures. For this, was used a machine in the configuration ball against flat washer, where balls were made of commercial material ABNT 52100 and flat washer in tool steel heat-treated to obtain martensitic and bainitic microstructures. The tests were performed by applying a maximum contact pressure of 4.8 GPa until the failure by micro-spalling on the disk surface or subsurface. The results of the fatigue life of those materials were presented by a Weibull distribution that showed a better resistance to the bainitic material to this request. The results presented for both microstructures showed that the failures were initiated predominantly sub-surface, given the initial goals of the work, as evidenced by the low occurrence of premature superficial failures possibly caused by inclusions, pores or surface defects that would act as a stress concentrator leading to a premature failure before the physical and metallurgical microstructures characteristics were really tested.

Aço ferramenta

Bainita

Bainite

Bearing

Contact fatigue

Fadiga de contato

Martensita

Martensite

Rolamento

Tool steel

Têmpera e partição de ferros fundidos nodulares: microestrutura e cinética. / Quenching and partitioning of ductile cast irons: microstructure and kinetics.

Nishikawa, Arthur Seiji

01 October 2018

Este trabalho está inserido em um projeto que procura estudar a viabilidade técnica da aplicação de um relativamente novo conceito de tratamento térmico, chamado de Têmpera e Partição (T&P), como alternativa para o processamento de ferros fundidos nodulares com alta resistência mecânica. O processo T&P tem por objetivo a obtenção de microestruturas multifásicas constituídas de martensita e austenita retida, estabilizada em carbono. A martensita confere elevada resistência mecânica, enquanto a austenita confere ductilidade. No processo T&P, após a austenitização total ou parcial da liga, o material é temperado até uma temperatura de têmpera TT entre as temperaturas Ms e Mf para produzir uma mistura controlada de martensita e austenita. Em seguida, na etapa de partição, o material é mantido isotermicamente em uma temperatura igual ou mais elevada (denominada temperatura de partição TP) para permitir a partição de carbono da martensita para a austenita. O carbono em solução sólida diminui a temperatura Ms da austenita, estabilizando-a à temperatura ambiente. O presente trabalho procurou estudar aspectos de transformações de fases -- com ênfase na evolução microestrutural e cinética das reações -- do tratamento térmico de Têmpera e Partição (T&P) aplicado a uma liga de ferro fundido nodular (Fe-3,47%C-2,47%Si-0,2%Mn). Tratamentos térmicos consistiram de austenitização a 880 oC por 30 min, seguido de têmpera a 140, 170 e 200 oC e partição a 300, 375 e 450 oC por até 2 h. A caracterização microestrutural foi feita por microscopia óptica (MO), eletrônica de varredura (MEV), difração de elétrons retroespalhados (EBSD) e análise de microssonda eletrônica (EPMA). A análise cinética foi feita por meio de ensaios de dilatometria de alta resolução e difração de raios X in situ usando radiação síncrotron. Resultados mostram que a ocorrência de reações competitivas -- reação bainítica e precipitação de carbonetos na martensita -- é inevitável durante a aplicação do tratamento T&P à presente liga de ferro fundido nodular. A cinética da reação bainítica é acelerada pela presença da martensita formada na etapa de têmpera. A reação bainítica acontece, a baixas temperaturas, desacompanhada da precipitação de carbonetos e contribui para o enriquecimento em carbono, e consequente estabilização, da austenita. Devido à precipitação de carbonetos na martensita, a formação de ferrita bainítica é o principal mecanismo de enriquecimento em carbono da austenita. A microssegregação proveniente da etapa de solidificação permanece no material tratado termicamente e afeta a distribuição da martensita formada na etapa de têmpera e a cinética da reação bainítica. Em regiões correspondentes a contornos de célula eutética são observadas menores quantidades de martensita e a reação bainítica é mais lenta. A microestrutura final produzida pelo tratamento T&P aplicado ao ferro fundido consiste de martensita revenida com carbonetos, ferrita banítica e austenita enriquecida estabilizada pelo carbono. Adicionalmente, foi desenvolvido um modelo computacional que calcula a redistribuição local de carbono durante a etapa de partição do tratamento T&P, assumindo os efeitos da precipitação de do crescimento de placas de ferrita bainítica a partir da austenita. O modelo mostrou que a cinética de partição de carbono da martensita para a austenita é mais lenta quando os carbonetos precipitados são mais estáveis e que, quando a energia livre dos carbonetos é suficientemente baixa, o fluxo de carbono acontece da austenita para a martensita. A aplicação do modelo não se limita às condições estudadas neste trabalho e pode ser aplicada para o planejamento de tratamentos T&P para aços. / The present work belongs to a bigger project whose main goal is to study the technical feasibility of the application of a relatively new heat treating concept, called Quenching and Partitioning (Q&P), as an alternative to the processing of high strength ductile cast irons. The aim of the Q&P process is to obtain multiphase microstructures consisting of martensite and carbon enriched retained austenite. Martensite confers high strength, whereas austenite confers ductility. In the Q&P process, after total or partial austenitization of the alloy, the material is quenched in a quenching temperature TQ between the Ms and Mf temperatures to produce a controlled mixture of martensite and austenite. Next, at the partitioning step, the material is isothermally held at a either equal or higher temperature (so called partitioning temperature TP) in order to promote the carbon diffusion (partitioning) from martensite to austenite. The present work focus on the study of phase transformations aspects -- with emphasis on the microstructural evolution and kinetics of the reactions -- of the Q&P process applied to a ductile cast iron alloy (Fe-3,47%C-2,47%Si-0,2%Mn). Heat treatments consisted of austenitization at 880 oC for 30 min, followed by quenching at 140, 170, and 200 oC and partitioning at 300, 375 e 450 oC up to 2 h. The microstructural characterization was carried out by optical microscopy (OM), scanning electron microscopy (SEM), backscattered diffraction (EBSD), and electron probe microanalysis (EPMA). The kinetic analysis was studied by high resolution dilatometry tests and in situ X-ray diffraction using a synchrotron light source. Results showed that competitive reactions -- bainite reaction and carbides precipitation in martensite -- is unavoidable during the Q&P process. The bainite reaction kinetics is accelerated by the presence of martensite formed in the quenching step. The bainite reaction occurs at low temperatures without carbides precipitation and contributes to the carbon enrichment of austenite and its stabilization. Due to carbides precipitation in martensite, growth of bainitic ferrite is the main mechanism of carbon enrichment of austenite. Microsegregation inherited from the casting process is present in the heat treated material and affects the martensite distribution and the kinetics of the bainite reaction. In regions corresponding to eutectic cell boundaries less martensite is observed and the kinetics of bainite reaction is slower. The final microestructure produced by the Q&P process applied to the ductile cast iron consists of tempered martensite with carbides, bainitic ferrite, and carbon enriched austenite. Additionally, a computational model was developed to calculate the local kinetics of carbon redistribution during the partitioning step, considering the effects of carbides precipitation and bainite reaction. The model showed that the kinetics of carbon partitioning from martensite to austenite is slower when the tempering carbides are more stable and that, when the carbides free energy is sufficiently low, the carbon diffuses from austenite to martensite. The model is not limited to the studied conditions and can be applied to the development of Q&P heat treatments to steels.

Austenite

Computational model

Ductile cast iron

Ferro fundido

Heat treatments

Martensite, Bainite

Quenching and partitioning

Tratamento térmico

ON THE RELATIONSHIP BETWEEN MICROSTRUCTURE DEVELOPMENT AND MECHANICAL PROPERTIES IN Q&P STEELS

Huyghe, Pierre

08 November 2018

The Quenching and Partitioning (Q&P) heat treatment has been proposed in the early 2000s to produce cold-rolled sheets combining high-strength and formability for the automotive market. Q&P consists, first, of an interrupted quench between the martensite-start temperature (Ms) and the martensite-finish temperature (Mf) from intercritical annealing or full austenitization in order to form controlled fractions of martensite. This is followed by a partitioning step in order to stabilize the untransformed austenite through carbon enrichment. In order to maximize the carbon transfer from martensite to austenite, the use of specific alloying elements and the design of appropriate Q&P parameters are required to eliminate or minimize competing phenomena such as carbide formation and austenite decomposition. The final quenched and partitioned microstructure, using full austenitization, ideally consists of carbon-depleted lath martensite and significant fractions of retained austenite providing an improved combination of strength and ductility. Hence, the transformation of retained austenite upon straining at room temperature (TRIP effect) provides supplementary work-hardening and eventually improves the ductility. In the present work, Quenching and Partitioning (Q & P) heat treatments were carried out in a quench dilatometeron a 0.2 wt% carbon steel. The microstructure evolution of the Q & P steels was characterized usingdilatometry, SEM, EBSD and XRD. The martensitic transformation profile was analyzed in order to estimate thefraction of martensite formed at a given temperature below the martensite start temperature Ms. Q & P wasshown to be an effective way to stabilize retained austenite at room temperature. However, the measuredaustenite fractions after Q & P treatments showed significant differences when compared to the calculated valuesconsidering ideal partitioning conditions. Indeed, the measured austenite fractions were found to be less sensitiveto the quench temperature and were never larger than the ideal predicted maximum fraction. Competitivereactions such as austenite decomposition into bainite and carbide precipitation were found to occur in thepresent work.Furthermore, a broad range of mechanical properties was obtained when varying the quenching temperaturesand partitioning times. The direct contributions between Q & P microstructural constituents -such as retainedaustenite as well as tempered/fresh martensite- and resulting mechanical properties were scrutinized. This wascritically discussed and compared to quenching and austempering (QAT) which is a more conventional processingroute of stabilizing retained austenite at room temperature. Finally, Q & P steels were shown to exhibit aninteresting balance between strength and ductility. The achievement of this interesting combination of mechanicalproperties was reached for much shorter processing times compared to QAT steels. / Doctorat en Sciences de l'ingénieur et technologie / info:eu-repo/semantics/nonPublished

Sciences de l'ingénieur

Métallurgie et mines

quenching and partitioning

martensite

retained austenite

TRIP-effect

steels

Estudo das microestruturas e propriedades obtidas por tratamentos intercrí­ticos e por tratamento de estampagem a quente em um aço Dual Phase classe 600. / Study of the microstructures and properties of Dual Phase DP 600 steel after intercritical heat treatments and hot stamping.

Andrade Centeno, Dany Michell

12 November 2018

Novos tratamentos térmicos e a otimização dos processos de conformação têm contribuído para o desenvolvimento de microestruturas multifásicas com excelente combinação de ductilidade e resistência mecânica. Parte dessa melhoria depende da presença de austenita retida, de sua estabilidade e fração volumétrica. O presente trabalho tem como objetivo caracterizar a evolução da microestrutura e comportamento das propriedades mecânicas do aço dual phase classe 600 (DP 600), após tratamentos térmicos intercríticos de têmpera e partição (Q&P) e reversão da martensita, assim como tratamentos termomecânicos de simulação física da estampagem a quente (HS), variando a deformação em 10% (HS 10) e 30% (HS 30), e combinando estampagem a quente com subsequente tratamento de têmpera e partição (HSQ&P). Duas condições microestruturais de partida diferentes foram utilizadas nos tratamentos térmicos. Para os tratamentos térmicos e termomecânicos Q&P, HS e HSQ&P a microestrutura de partida foi a bifásica (ferrita e martensita). Já para o tratamento térmico de reversão a microestrutura de partida foi modificada para martensítica. Os tratamentos puramente térmicos foram realizados no dilatômetro Bähr do Laboratório de Transformações de Fase (LTF); entretanto, os tratamentos termomecânicos foram feitos no simulador termomecânico Gleeble®, acoplado à linha de difração de raios X (XTMS) do Laboratório Nacional de Nanotecnologia (LNNano). A análise microestrutural foi feita com suporte de microscopia ótica (MO) e eletrônica de varredura (MEV-FEG), EBSD, e difração de raios X in situ e convencional. Avaliaram-se as propriedades mecânicas por ensaio de tração em corpos de prova sub-size e endentação instrumentada. As amostras Q&P, HS e HSQ&P foram submetidas a ensaios exploratórios de resistência ao trincamento por hidrogênio (HIC) segundo a norma NACE TM0284. Adicionalmente, foi feita a medição de hidrogênio ancorado na microestrutura estudada, após tratamentos, utilizando a técnica de dessorção térmica disponível no LNNano. A avaliação das mudanças microestruturais e de propriedades mecânicas após tratamentos térmicos foram discutidas separadamente para cada microestrutura de partida. Os resultados dos processos Q&P, HS e HSQ&P no aço, mostraram que a evolução da microestrutura levou a formação de uma microestrutura mais complexa do que a microestrutura ferrítico-martensítica simples do material como recebido. A complexa microestrutura é dada pela formação de ferrita epitaxial durante a etapa de tratamento intercrítico, ferrita induzida por deformação (DIFT) na etapa de deformação em alta temperatura e bainita na etapa de partição. Essa mistura microestrutural levou a variações na relação das frações volumétricas de ferrita e martensita em relação às frações iniciais do aço, assim como na presença de austenita retida e sua estabilidade. Com base nos resultados é possível afirmar que o processo Q&P produz um aumento nas propriedades mecânicas do material. Por outro lado, após o ensaio de HIC todas as amostras apresentaram susceptibilidade ao trincamento; contudo, a severidade do dano foi maior nas amostras deformadas HS 30. Os ensaios preliminares de dessorção mostraram maior aprisionamento de hidrogênio em armadilhas reversíveis nas amostras HSQ&P e irreversíveis na amostra HS 30. Na segunda parte, os resultados do tratamento de reversão sugerem que, em geral, a microestrutura do aço processado compreende uma morfologia em ripas de ferrita intercrítica, martensita e filmes de austenita retida. A maior temperatura de reversão intercrítica resultou em menor fração de ferrita intercrítica. Por outro lado, a temperatura intercrítica de reversão influenciou significativamente a estabilidade da austenita retida. Uma alta fração de austenita retida foi obtida a uma temperatura ligeiramente acima da temperatura Ac1. Um segundo ciclo de reversão promoveu a difusão de C e Mn para a austenita revertida tornando-a mais estável a temperatura ambiente. / Novel Heat Treatments and the optimization of the forming processes have contributed to the development of multiphase microstructures with attractive combinations of ductility and mechanical resistance. This improvement partially depends on the presence, stability and volume fraction of retained austenite. The objective of this work is to characterize the evolution of the microstructure and mechanical properties of a class 600 dual phase steel (DP 600), as a function of the thermal and thermomechanical history. Two initial microstructures were used in this study. A ferritic-martensitic microstructure was used as the starting condition for inter-critical heat treatments followed by quenching and partitioning (Q&P) and for the thermomechanical simulations of the hot stamping (HS) process. The latter applying deformations of 10% (HS 10) and 30% (HS 30) combining hot stamping with subsequent quenching and partition (HSQ&P). The thermal cycles were performed in a Bähr dilatometer at the Laboratory of Phase Transformations (LTF), then duplicated using a Gleeble® thermomechanical simulator, coupled to the X-ray Scattering and Thermo-mechanical Simulation beamline (XTMS) at the Brazilian Nanotechnology National Laboratory (LNNano). The microstructural analysis was performed using optical microscopy (MO) and scanning electron (SEM-FEG), Electron Backscatter Diffraction (EBSD), and in situ and conventional X-ray diffraction. The mechanical properties were evaluated by tensile testing on sub-size specimens and by instrumented macro-nano indentation tests. The evolution of the microstructure and mechanical properties for each starting microstructure was discussed separately. The Q&P, HS and HSQ&P samples were submitted to exploratory tests of resistance to hydrogen induced cracking (HIC) according to NACE TM0284. Additionally, hydrogen measurements were performed for the microstructures obtained after Q&P and HDQ&P using the thermal desorption technique at LNNano. After Q&P, HS and HSQ&P, the resultant microstructure was more complex than the as-received ferritic-martensitic condition. Such complexity comes from the formation of epitaxial ferrite from the former ferritic phase during the intercritical treatment step, the deformation induced ferrite (DIFT) and the bainite formation during the partitioning step. This led to variations in the volumetric fraction of ferrite and martensite in relation to the initial fractions of the as-received condition, as well as the presence of retained austenite and its stability upon cooling. The Q&P process increased the mechanical properties of the material. On the other hand, all microstructures showed susceptibility to hydrogen cracking after 72 hours of H2S exposure tests. However, the damage was more severe for the HS samples with 30% of deformation. The preliminary desorption tests showed greater hydrogen trapping in reversible traps after HSQ&P and in irreversible traps for the HS with 30% deformation. A second set of experiments was conducted for a different microstructure consisting of a fully martensitic matrix as the initial condition. After intercritical reversion, the resultant microstructure comprised intercritical lath-like ferrite, martensite laths and retained austenite films. The higher the intercritical reversion temperature, the smaller the fraction of intercritical ferrite. On the other hand, the transformation temperature significantly influenced the stability of the retained austenite. The highest fraction of retained austenite was obtained when the transformation occurred slightly above the Ac1 temperature. A double intercritical reversion cycle promoted the diffusion of C and Mn to the reversed austenite making it more stable upon cooling to room temperature, leading to a better combination of strength and ductility.

Aço

Estampagem

Hot stamping

Martensite reversion

Physical simulation

Quenching and partitioning

Têmpera (Engenharia)

Constitutive Modelling of High Strength Steel

Larsson, Rikard

January 2007

<p>This report is a review on aspects of constitutive modelling of high strength steels. Aspects that have been presented are basic crystallography of steel, martensite transformation, thermodynamics and plasticity from a phenomenological point of view. The phenomenon called mechanical twinning is reviewed and the properties of a new material type called TWIP-steel have been briefly presented. Focus has been given on phenomenological models and methods, but an overview over multiscale methods has also been given.</p>

martensite

material modelling

TRIP

TWIP

yield criterion

multiscale methods

crystal plasticity

TECHNOLOGY

TEKNIKVETENSKAP

An Investigation of the Suitability of Using AISI 1117 Carbon Steel in a Quench and Self-tempering Process to Satisfy ASTM A 706 Standard of Rebar

Allen, Matthew

11 August 2011

Experiments were conducted to investigate the potential of using a quench and self-tempering heat treatment process with AISI 1117 steel to satisfy the mechanical properties of ASTM A 706 rebar. A series of quenching tests were performed and the resulting microstructure and mechanical properties studied using optical microscopy, microhardness measurement, and tensile tests. The presence of martensite throughout the samples contributed to the enhanced strength and strain-hardening ratio (tensile to yield strength) of the material. The experimental results showed that AISI 1117 is capable of meeting the ASTM standard. In addition to the experiments, a computer model using the finite difference method and incorporating heat transfer and microstructure evolution was developed to assist in future optimization of the heat treatment process.

AISI 1117

reinforcing steel

rebar

QST

microstructure

quench and self-tempering

tempered martensite

0794

0743

An Investigation of the Suitability of Using AISI 1117 Carbon Steel in a Quench and Self-tempering Process to Satisfy ASTM A 706 Standard of Rebar

Allen, Matthew

11 August 2011

Experiments were conducted to investigate the potential of using a quench and self-tempering heat treatment process with AISI 1117 steel to satisfy the mechanical properties of ASTM A 706 rebar. A series of quenching tests were performed and the resulting microstructure and mechanical properties studied using optical microscopy, microhardness measurement, and tensile tests. The presence of martensite throughout the samples contributed to the enhanced strength and strain-hardening ratio (tensile to yield strength) of the material. The experimental results showed that AISI 1117 is capable of meeting the ASTM standard. In addition to the experiments, a computer model using the finite difference method and incorporating heat transfer and microstructure evolution was developed to assist in future optimization of the heat treatment process.

AISI 1117

reinforcing steel

rebar

QST

microstructure

quench and self-tempering

tempered martensite

0794

0743

Constitutive Modelling of High Strength Steel

Larsson, Rikard

January 2007

This report is a review on aspects of constitutive modelling of high strength steels. Aspects that have been presented are basic crystallography of steel, martensite transformation, thermodynamics and plasticity from a phenomenological point of view. The phenomenon called mechanical twinning is reviewed and the properties of a new material type called TWIP-steel have been briefly presented. Focus has been given on phenomenological models and methods, but an overview over multiscale methods has also been given.

martensite

material modelling

TRIP

TWIP

yield criterion

multiscale methods

crystal plasticity

TECHNOLOGY

TEKNIKVETENSKAP

Effects of Martensite Tempering on HAZ-Softening and Tensile Properties of Resistance Spot Welded Dual-Phase Steels

Baltazar Hernandez, Victor Hugo

January 2010

The main purpose of this thesis is to improve the fundamental knowledge of non-isothermal tempering of martensite phase and its effects on the reduction in hardness (softening) with respect the base metal occurring at the heat affected zone (HAZ) of resistance spot welded dual-phase (DP) steels. This thesis also aims at understanding the influence of HAZ-softening on the joint performance of various DP steel grades. The tempering of martensite occurring at the sub-critical HAZ (SC-HAZ) of resistance spot welded DP600, DP780 and DP980 steels has been systematically evaluated by microhardness testing through Vickers indentation and the degree of tempering has been correlated to the HAZ-softening. From the joint performance analysis of similar and dissimilar steel grade combinations assessed through standardized testing methods, three important issues have been targeted: a) the joint strength (maximum load to failure), b) the location of failure (failure mode), and c) the physical characteristic of the weld that determines certain type of failure (weld nugget size). In addition, a partial tensile test has been conducted in order to evaluate the initiation of failure in dissimilar steel grade combinations. It has been shown that HAZ-softening lowered the weld size at which transition from interfacial to pullout failure mode takes place along with increased load-bearing capacity and higher energy absorption. Thus, it is concluded from mechanical testing that HAZ-softening benefits the lap-shear tensile joint performance of resistance spot welded DP steels by facilitating pullout failures through failure initiation at the SC-HAZ (tempered region). Instrumented nanoindentation testing was employed to further investigate HAZ-softening along the SC-HAZ by evaluating individual phases of ferrite matrix and tempered martensite islands. Although the ferrite matrix presented a slight reduction in hardness at nanoscale, higher reduction in hardness (softening) resulted for tempered martensite; thus confirming that tempered martensite is the major contributor to softening at micro-scale. A comparison between nanohardness and microhardness testing made at different distances from the line of lower critical temperature of transformation (Ac1) allowed revealing the actual extension of the SC-HAZ. In this regard, good correlation was obtained between nanohardness results along the SC-HAZ and the microstructural changes analyzed by electron microscopy (i.e., the tempering of martensite occurring at various distances far from Ac1 was correlated to low temperature tempering of dual phase steels). An in-depth analysis of the tempering of martensite phase at high temperature in DP steel subjected non-isothermal conditions i.e., rapid heating, extremely short time at peak temperature and rapid cooling (resistance spot welding), has been carried out mainly through analytical transmission electron microscopy (TEM). In addition, an isothermal tempering condition (i.e., slow heating and long time at peak temperature) in DP steel has been evaluated for complementing the analysis. Both non-isothermal and isothermal conditions have been correlated to the softening behaviour. TEM analysis of the base metal in the DP steel indicated that the morphology of the martensite phase is dependent on its carbon content, and its tempering characteristics are similar to that of equal carbon containing martensitic steel. The isothermally tempered structure is characterized by coarsening and spheroidization of cementite (θ) and complete recovery of the martensite laths; whereas precipitation of fine quasi-spherical intralath θ-carbides, coarser plate-like interlath θ-carbides, decomposition of retained austenite into elongated θ-carbides, and partial recovery of the lath structure were observed after non-isothermal tempering of DP steel. This difference in tempering behaviour is attributed to synergistic effect of delay in cementite precipitation due to higher heating rate, and insufficient time for diffusion of carbon that delays the third stage of tempering process (cementite coarsening and recrystalization) during non-isothermal. The finer size and the plate-like morphology of the precipitated carbides along with the partial recovery of the lath structure observed after non-isothermal tempering strongly influenced the softening behaviour of DP steel. The chemical analysis of θ-carbides through extraction replicas for three different DP steels revealed that the chemistry of the carbides is inherited from the parent DP steel during non-isothermal tempering at high temperature confirming that non-isothermal tempering DP steel is predominantly controlled by carbon diffusion.

Dual-Phase Steels

Martensite Tempering

Resistance Spot Welding

HAZ-Softening

Nanoindentation

Transmission Electron Microscopy

Mechanical Engineering

Effects of Martensite Tempering on HAZ-Softening and Tensile Properties of Resistance Spot Welded Dual-Phase Steels

Baltazar Hernandez, Victor Hugo

January 2010

The main purpose of this thesis is to improve the fundamental knowledge of non-isothermal tempering of martensite phase and its effects on the reduction in hardness (softening) with respect the base metal occurring at the heat affected zone (HAZ) of resistance spot welded dual-phase (DP) steels. This thesis also aims at understanding the influence of HAZ-softening on the joint performance of various DP steel grades. The tempering of martensite occurring at the sub-critical HAZ (SC-HAZ) of resistance spot welded DP600, DP780 and DP980 steels has been systematically evaluated by microhardness testing through Vickers indentation and the degree of tempering has been correlated to the HAZ-softening. From the joint performance analysis of similar and dissimilar steel grade combinations assessed through standardized testing methods, three important issues have been targeted: a) the joint strength (maximum load to failure), b) the location of failure (failure mode), and c) the physical characteristic of the weld that determines certain type of failure (weld nugget size). In addition, a partial tensile test has been conducted in order to evaluate the initiation of failure in dissimilar steel grade combinations. It has been shown that HAZ-softening lowered the weld size at which transition from interfacial to pullout failure mode takes place along with increased load-bearing capacity and higher energy absorption. Thus, it is concluded from mechanical testing that HAZ-softening benefits the lap-shear tensile joint performance of resistance spot welded DP steels by facilitating pullout failures through failure initiation at the SC-HAZ (tempered region). Instrumented nanoindentation testing was employed to further investigate HAZ-softening along the SC-HAZ by evaluating individual phases of ferrite matrix and tempered martensite islands. Although the ferrite matrix presented a slight reduction in hardness at nanoscale, higher reduction in hardness (softening) resulted for tempered martensite; thus confirming that tempered martensite is the major contributor to softening at micro-scale. A comparison between nanohardness and microhardness testing made at different distances from the line of lower critical temperature of transformation (Ac1) allowed revealing the actual extension of the SC-HAZ. In this regard, good correlation was obtained between nanohardness results along the SC-HAZ and the microstructural changes analyzed by electron microscopy (i.e., the tempering of martensite occurring at various distances far from Ac1 was correlated to low temperature tempering of dual phase steels). An in-depth analysis of the tempering of martensite phase at high temperature in DP steel subjected non-isothermal conditions i.e., rapid heating, extremely short time at peak temperature and rapid cooling (resistance spot welding), has been carried out mainly through analytical transmission electron microscopy (TEM). In addition, an isothermal tempering condition (i.e., slow heating and long time at peak temperature) in DP steel has been evaluated for complementing the analysis. Both non-isothermal and isothermal conditions have been correlated to the softening behaviour. TEM analysis of the base metal in the DP steel indicated that the morphology of the martensite phase is dependent on its carbon content, and its tempering characteristics are similar to that of equal carbon containing martensitic steel. The isothermally tempered structure is characterized by coarsening and spheroidization of cementite (θ) and complete recovery of the martensite laths; whereas precipitation of fine quasi-spherical intralath θ-carbides, coarser plate-like interlath θ-carbides, decomposition of retained austenite into elongated θ-carbides, and partial recovery of the lath structure were observed after non-isothermal tempering of DP steel. This difference in tempering behaviour is attributed to synergistic effect of delay in cementite precipitation due to higher heating rate, and insufficient time for diffusion of carbon that delays the third stage of tempering process (cementite coarsening and recrystalization) during non-isothermal. The finer size and the plate-like morphology of the precipitated carbides along with the partial recovery of the lath structure observed after non-isothermal tempering strongly influenced the softening behaviour of DP steel. The chemical analysis of θ-carbides through extraction replicas for three different DP steels revealed that the chemistry of the carbides is inherited from the parent DP steel during non-isothermal tempering at high temperature confirming that non-isothermal tempering DP steel is predominantly controlled by carbon diffusion.

Dual-Phase Steels

Martensite Tempering

Resistance Spot Welding

HAZ-Softening

Nanoindentation

Transmission Electron Microscopy

Mechanical Engineering