Modélisation des évolutions microstructurales par changement de phases dans les alliages de titane [bêta] - métastables / Modeling microstructure evolution by phase transformation in titanium [beta]-metastable alloys

Di Napoli, Paolo

12 November 2010

Un modèle a été développé pour prédire les cinétiques de transformation de phase beta → alpha dans les alliages de titane multi constitués au cours de chemins thermiques complexes. Il repose sur : (i) une simplification de la représentation géométrique des différentes morphologies communément observées dans ces alliages (grains parents bêta, phase α(allotriomorphe) aux joints des grains parents, colonies de phase α, précipités α intragranulaires) ; (ii) des lois analytiques de germination et de croissance pour les diverses morphologies de phase α; (iii) l’hypothèse d'équilibre local aux interfaces β/α, décrite par un approche de type CalPhad ; (vi) des bilans moyens de soluté dans chaque morphologie. Nous obtenons ainsi pour chaque morphologie, les cinétiques de transformation, les évolutions de leurs tailles moyennes, et enfin les évolutions de leur composition moyenne. Nous présentons tout d’abord les calculs réalisés pour un alliage ternaire TiVO, afin de montrer les potentialités du modèle. L’analyse des résultats met en avant l’influence respective de la diffusion des solutés dans les deux phases, de la morphologie des précipités formés sur la cinétique de croissance comme sur la composition moyenne des grains formés tant pour une transformation en condition isotherme qu’au cours d’un refroidissement continu ou encore d’une séquence complexe de traitement thermique (refroidissement, chauffage, refroidissement). Le modèle a également été utilisé pour calculer les cinétiques de transformation pour l’alliage industriel Ti17 et ainsi comparer les résultats calculés aux résultats expérimentaux (cinétique et microstructures) / A model has been developed which is able to predict the kinetics of beta → alpha transformation in industrial multi component titanium alloys during complex heat treatments. The model is based on: (i) a simple geometric representations of the different morphologies commonly observed in these alloys (parent α grains, α allotriomorphs (at grain boundaries), αcolonies and intragranular α precipitates); (ii) analytical nucleation and growth laws for each morphology of α phase; (iii) the assumption of local equilibrium at interfaces, handled within the CalPhaD framework; (iv) averaged solute balances in each morphology. Diffusion of solutes in both phases is considered. We thus obtain the transformation kinetics as well as mean size parameters and mean chemical composition for each morphology of the product α phase (at grain boundaries, colonies and intragranular precipitates. Calculations performed are at first presented for a ternary TiVO alloy emphasizing the potentialities of the model. The relationships between growth conditions, role of diffusion in each phase, and chemical composition for each morphology are analyzed upon isothermal holdings, cooling from the beta phase field and more complex cooling-heating sequence. The model is further used on the Ti17 industrial and results are compared to experimental transformation kinetics and microstructures

Alliages de titane

Modélisation

Germination

Croissance

Dissolution

Calphad

Titanium alloys

Modeling

Nucleation

Growth

Dissolution

Calphad

620.189 322

Efeito da adição de oxigênio na estabilidade e metaestabilidade de fases em ligas Ti-Nb aplicadas como biomaterial / Effect of oxygen additions in the phase stability and metastability of Ti-Nb alloys applied as biomaterials

Taquire De la Cruz, Manolo Marcial

18 August 2018

Orientador: Rubens Caram Junior / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-18T19:15:30Z (GMT). No. of bitstreams: 1 TaquireDelaCruz_ManoloMarcial_M.pdf: 61740701 bytes, checksum: 1b0f2cfa983c44d13817437ff955e827 (MD5) Previous issue date: 2011 / Resumo: Em se tratando de biomateriais ortopédicos, as ligas de titânio tipo ß apresentam diversas vantagens em relação às ligas do tipo 'alfa' + ß. Ligas contendo elementos ß estabilizadores são mais interessantes em função da alta resistência mecânica específica, da elevada resistência à corrosão e da excelente biocompatibilidade. Em adição, essas ligas exibem baixo módulo de elasticidade, característica fundamental na fabricação de implantes ortopédicos. O objetivo deste trabalho é a avaliação da estabilidade e metaestabilidade de ligas de Ti tipo ß do sistema Ti-Nb com adições de oxigênio. Amostras com composições Ti-30Nb-xO e Ti-35Nb-xO (x =0,1; 0,25; 0,5) (% em peso) foram preparadas por fusão a arco voltaico, homogeneizadas quimicamente em altas temperaturas, forjadas a quente e finalmente, submetidas a diferentes taxas de resfriamento. Tais amostras foram caracterizadas em relação à microestrutura por meio de microscopia óptica e eletrônica de varredura e de difração de raios-X, enquanto o comportamento mecânico foi avaliado por meio de ensaios de dureza Vickers, de medidas de módulo de elasticidade por meio de técnicas acústicas e de nano-dureza usando a técnica de nano-indentação. Os resultados obtidos indicam que baixas taxas de resfriamento conduzem à microestrutura formada pelas fases 'alfa' e ß e eventualmente, com a precipitação da fase 'omega'. Por outro lado, altas taxas de resfriamento conduziram à formação da estrutura metaestável martensítica 'alfa'. À medida que o teor de oxigênio foi incrementado e sob resfriamento lento, obteve-se a precipitação acentuada de fase 'alfa'. Sob elevadas taxas de resfriamento, o aumento dos teores de O e Nb resultaram na estabilização da fase ß e na redução da fração volumétrica da fase metaestável 'alfa'. As medidas de módulo de elasticidade mostram que em amostras submetidas a baixas taxas de resfriamento, a adição de oxigênio levou ao aumento do módulo de elasticidade. Para todas as taxas de resfriamento estudadas, observou-se que a dureza elevou-se com o aumento do teor de oxigênio, o que está associado à formação de solução sólida intersticial e à precipitação acentuada da fase 'alfa'. / Abstract: In the case of orthopedic biomaterials, ß-type titanium alloys have several advantages compared to the 'alfa'+ß titanium alloys. Alloys containing ß-stabilizing elements are often interesting due to high mechanical strength, high corrosion resistance and superior biocompatibility. Furthermore, due to low elastic modulus, these alloys are promising candidate in the manufacturing of ortophedic implants. The main goal of this work is to study the phase stability and metastability in ß type Ti-Nb alloys with oxygen additions. Samples with concentrations Ti-30Nb-xO and Ti-35Nb-xO (x = 0,1; 0.25 and 0.5) (wt%) were prepared by using an arc melting furnace and homogenized chemically at high temperatures, hot forged and finally, submitted to different cooling rates. These samples were characterized in relation to their microstructure by applying optical microscopy and X-ray diffraction, while the mechanical behavior was evaluated by Vickers hardness tests and elastic modulus measurements using acoustic technique. These results indicate that low cooling rates lead to 'alfa' and ß phase formation and eventually, to 'omega' phase precipitation. On the other hand high cooling rates led to 'alfa' martensitic structure formation. For lower cooling rates, as the oxygen concentration increased, the volume fraction of 'alfa' precipitates increased. At higher cooling rates O and Nb additions had an effective role in enhancing the ß phase stability and in diminishing the volume fraction of 'alfa' martensite phase. It was found that samples submitted to lower cooling rates presented an increase in the elastic modulus values as the oxygen content was increased. It was possible to observe that, for all cooling rates applied, the hardness values increased as the oxygen content was increased. These results are associated with formation of interstitial solid solution and 'alfa' phase precipitation / Mestrado / Materiais e Processos de Fabricação / Mestre em Engenharia Mecânica

Ligas de titânio

Transformações de fase

Biomateriais

Propriedades mecânicas

Titanium alloys

Phase transformation

Biomaterials

Mechanical properties

Componentes com gradientes funcionais para aplicação em ortopedia obtidos por manufatura aditiva de ligas de titânio / Functional graded components for application in orthopedics obtained by additive manufacturing of titanium alloys

Lima, Dalton Daniel de, 1986-

31 July 2015

Orientador: Rubens Caram Júnior / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-28T12:00:08Z (GMT). No. of bitstreams: 1 Lima_DaltonDanielde_M.pdf: 2611996 bytes, checksum: 6f81a7094a8af1637dc4d3bda71dacd3 (MD5) Previous issue date: 2015 / Resumo: O uso de ligas do sistema Ti-Nb-Zr como biomaterial é promissor em razão de sua boa biocompatibilidade, alta resistência à corrosão, elevada resistência mecânica e baixo módulo de elasticidade. As propriedades mecânicas de ligas Ti-Nb-Zr podem ser manipuladas variando-se o teor de Nb e Zr no componente, o que é obtido aplicando-se o processo de manufatura aditiva LENS®. Tal processo é uma técnica inovadora e permite produzir componentes tridimensionais com gradientes de composição e consequentemente, com gradientes funcionais. Materiais com gradiente funcionais são exigidos, em alguns casos, no reparo de tecidos duros do corpo humano. Por exemplo, em placas de fixação de fratura óssea é interessante alto módulo de elasticidade em regiões próximas à fratura e baixo módulo de elasticidade em regiões adjacentes à fratura. O objetivo desse trabalho foi estudar, do ponto de vista metalúrgico, a possibilidade de se produzir materiais para aplicação ortopédica fabricados com ligas Ti-Nb-Zr com gradientes de composição aplicando-se o processo LENS®. Para isso foram produzidos lingotes medindo 12 x 12 x 55 mm, com extremidades com composições nominais de Ti-35Nb-10Zr (% em peso) (região de baixo módulo), a região central de Ti CP (região de alto módulo) e as regiões entre o centro e as extremidades, com composições intermediárias. Cada lingote foi cortado simetricamente no sentido longitudinal, resultando em duas amostras (placas). Uma amostra foi caracterizada no estado como solidificada e a outra, após tratamento térmico de solubilização a 1000 °C por 1 h e resfriada em água. A caracterização das amostras envolveu fluorescência de raios-X e análise de teor de O e N para determinação da composição. Microscopia eletrônica de varredura, difração de elétrons retroespalhados e difração de raios-X foram utilizadas para análise microestrutural. Nanoindentação, medida de microdureza Vickers e análise de módulo de elasticidade por ultrassom para análise do comportamento mecânico. Verificou-se que é possível obter materiais com gradientes funcionais pelo processo LENS® dentro do sistema Ti-Nb-Zr. As amostras apresentaram módulo de elasticidade variando entre 65 a 110 GPa ao longo de seu comprimento / Abstract: The use of Ti-Nb-Zr alloys system as biomaterial is promising due to its good biocompatibility, high corrosion resistance, high strength and low modulus of elasticity. The mechanical properties of Ti-Nb-Zr alloys can be manipulated varying the content of Nb and Zr in the component production. This variation is obtained by applying the additive manufacturing process LENS®. This process is a novel technique and allows the production of three-dimensional components with compositional gradients and hence with functional gradients. Functionally graded materials are required in some cases, for repair of hard tissues of human body. In bone fracture fixation plates, for example, is interesting that the closest fracture regions possess high Young's modulus while adjacent fracture regions low Young's modulus. The aim of this work was to study, of metallurgical point of view, the possibility of producing materials, for orthopedic application, manufactured with Ti-Nb-Zr alloys with composition gradients applying the LENS®. To this, ingots measuring 12 x 12 x 55 mm were produced. Its ends were produced with the nominal composition Ti-35Nb-10Zr (wt%) (low modulus region), the central region was produced with CP Ti (high modulus region) and the regions between the extremities and central, with intermediate composition. Each ingot was symmetrical cut in longitudinal way, resulting in two samples (plates). One sample was characterized as the solidified state and the other one, after solubilization heat treatment at 1000 °C for 1 h and cooled in water. The samples were characterized by X-rays fluorescence and analysis of O and N content for compositions determining. Scanning electron microscopy, electron backscattering diffraction and X-ray diffraction were used for microstructural analysis. Nanoindentation technique, Vickers microhardness measure and measurement of Young's modulus by ultrasound were used for mechanical properties analysis. It has been found that it is possible to obtain functional gradients materials by the LENS® process within Ti-Nb-Zr system. The samples had modulus ranging from 65 to 110 GPa along its length / Mestrado / Materiais e Processos de Fabricação / Mestre em Engenharia Mecânica

Ligas de titânio

Biomateriais

Prototipagem rápida

Implantes ortopédicos

Titanium alloys

Biomaterials

Rapid prototyping

Orthopedic implants

Additive Manufacturing of Metastable Beta Titanium Alloys

Yannetta, Christopher James

08 1900

Additive manufacturing processes of many alloys are known to develop texture during the deposition process due to the rapid reheating and the directionality of the dissipation of heat. Titanium alloys and with respect to this study beta titanium alloys are especially susceptible to these effects. This work examines Ti-20wt%V and Ti-12wt%Mo deposited under normal additive manufacturing process parameters to examine the texture of these beta-stabilized alloys. Both microstructures contained columnar prior beta grains 1-2 mm in length beginning at the substrate with no visible equiaxed grains. This microstructure remained constant in the vanadium system throughout the build. The microstructure of the alloy containing molybdenum changed from a columnar to an equiaxed structure as the build height increased. Eighteen additional samples of the Ti-Mo system were created under different processing parameters to identify what role laser power and travel speed have on the microstructure. There appears to be a correlation in alpha lath size and power density. The two binary alloys were again deposited under the same conditions with the addition of 0.5wt% boron to investigate the effects an insoluble interstitial alloying element would have on the microstructure. The size of the prior beta grains in these two alloys were reduced with the addition of boron by approximately 50 (V) and 100 (Mo) times.

Additive manufacturing: LENS

Engineering, Materials Science

Three-dimensional printing.

Titanium alloys.

Microstructure.

Desenvolvimento e caracterização de novas ligas do sistema Ti-Ta-Zr para aplicações biomédicas /

Kuroda, Pedro Akira Bazaglia.

January 2019

Orientador: Carlos Roberto Grandini / Resumo: Titânio e suas ligas, atualmente, são utilizados como implantes por possuírem excelente resistência à corrosão e propriedades mecânicas mais adequadas que os implantes de aço inoxidável e de Co-Cr. A liga de titânio mais utilizada para aplicações biomédicas é a liga Ti-6Al-4V, porém estudos mostraram que os elementos vanádio e alumínio são elementos nocivos à saúde humana. Assim, para contornar este problema, novas ligas de titânio sem a presença desses elementos estão sendo estudadas. O objetivo desse trabalho foi preparar ligas do sistema Ti-25Ta-Zr (onde o teor de zircônio foi variado de 0 a 75% em peso), e analisar a influência do soluto substitucional zircônio na estrutura cristalina, microestrutura, microdureza, módulo de elasticidade e biocompatibilidade das ligas. Paralelamente, diversos tratamentos de recozimento, laminação e solubilização foram realizados com o intuito de modificar as fases, microestrutura e módulo de elasticidade dos materiais. A caracterização química dos materiais foi realizada por espectroscopia de energia dispersiva, espectrometria de emissão óptica por plasma acoplado indutivamente, análise de gases e medidas de densidade. A análise estrutural foi efetuada por difração de raios X. A análise microestrutural foi realizada por microscopia ótica, microscopia eletrônica de varredura e de transmissão. Uma análise preliminar das propriedades mecânicas da liga foi obtida por intermédio de medidas de microdureza Vickers e módulo de elasticidade dinâmic... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: Titanium and alloys currently are used as implants possessing excellent corrosion resistance and mechanical properties more suited to stainless steel implants and Co-Cr. The titanium alloy used for most biomedical applications is Ti-6Al-4V, however studies showed that vanadium and aluminum are harmful to human health. The objective of this study was to prepare Ti-25Ta-Zr system alloys, where the zirconium content was varied from 0 to 75 % in weight, and to analyze the influence of zirconium substitutional solute in the structure, microstructure, hardness and elastic modulus. At the same time, several annealing, lamination and solubilization treatments were carried out to modify the phases, structures, microstructure and elastic modulus of the materials. The chemical characterization of materials was performed by energy-dispersion spectroscopy, inductively coupled plasma optical emission spectrometry, gas analysis, and density measurements. The structural analysis was performed by x-ray diffraction measurements. Microstructural analysis was performed by optical, scanning and transmission electron microscopy. To verify the initial biocompatibility of the alloys, cytotoxic tests were performed. A preliminary analysis of the mechanical properties of the alloy was obtained by means of microhardness and dynamic elastic modulus measurements. The chemical composition results showed that the samples produced are of good quality, close to proposed stoichiometry. The results showed the ... (Complete abstract click electronic access below) / Doutor

Ligas de Ti

Materiais biomédicos.

Microestrutura.

Tratamentos térmicos

Titanium alloys

Materiais biomédicos.

Microstructure

Thermomechanical

Thermomechanical treatments

Optimalizace výroby dílu pro letecký průmysl / Optimisation of a part production for aircraft industry

Filipčík, Jiří

January 2009

This thesis deals with optimization of production of "Hold-down hinge hook" component, developed from difficult-to-cut titanium alloy Ti-6Al-4V. This work is focused on the material properties of the component, current research and optimization in titanium machinability sphere. Further it contains a part dedicated to the latest trends in development of cutting tools for machining of titanium alloys. This knowledge is furthermore used for the component production optimization in Frencken Brno s.r.o. company. This project continues with analysis of the component‘s current production technology and designs the way of elimination of production bottleneck. This change is presented by component‘s clamp jig, which decreases higher percentage of scrap due to the geometric complexity. This thesis further contains drawing and technological documentation needed for implementation of the improvement suggestions into the production. There was designed a new NC program. This project is accomplished with technical-economical evaluation.

Obrábění těžkoobrobitelných materiálů / Machining of difficult machinable materials

Perončík, Martin

January 2010

Diploma thesis is specialized to solving of problems machining of diffi-cult machinable materials. There is carried out the analysis of difficult machinable materials in term of chemical composition, physical and mechanical properties. In the following it deals with analysis of machining, specification of geometry, material of cutting tools and cutting conditions.

Grain-Boundary Parameters Controlled Allotriomorphic Phase Transformations in Beta-Processed Titanium Alloys

Dixit, Vikas

21 May 2013

No description available.

Aerospace Materials

Engineering

Metallurgy

titanium alloys

grain boundary alpha

allotriomorphic alpha

variant selection, morphology

precipitate thickening

Thermo-mechanical Characterization Of High-temperature Shape Memory Ni-ti-pd Wires

Fox, Matthew

01 January 2009

Actuator applications of shape memory alloys have typically been limited by their phase transformation temperatures to around 100 degrees C. However, recently with a focus on aerospace and turbomachinery applications there have been successful efforts to increase the phase transformation temperatures. Several of these alloy development efforts have involved ternary and quaternary elemental additions (e.g., Pt, Pd, etc.) to binary NiTi alloys. Experimentally assessing the effects of varying composition and thermo-mechanical processing parameters can be cost intensive, especially when expensive, high-purity elemental additions are involved. Thus, in order to save on development costs there is value in establishing a methodology that facilitates the fabrication, processing and testing of smaller specimens, rather than larger specimens from commercial billets. With the objective of establishing such a methodology, this work compares thermo-mechanical test results from bulk dog-bone tensile Ni29.5Ti50.5Pd20 samples (7.62 mm diameter) with that of thin wires (100 μm-150 µm diameter) extracted from comparable, untested bulk samples by wire electrical-discharge machining (EDM). The wires were subsequently electropolished to different cross-sections, characterized with Scanning Electron Microscopy, Transmission Electron Microscopy and Energy Dispersive X-Ray Spectroscopy to verify the removal of the heat affected zone following EDM and subjected to Laser Scanning Confocal Microscopy to accurately determine their cross-sections before thermo-mechanical testing. Stress-strain and load-bias experiments were then performed on these wires using a dynamic mechanical analyzer and compared with results established in iv previous studies for comparable bulk tensile specimens. On comparing the results from a bulk tensile sample with that of the micron-scale wires, the overall thermomechanical trends were accurately captured by the micron-scale wires for both the constrained recovery and monotonic tensile tests. Specifically, there was good agreement between the stress-strain response in both the martensitic and austenitic phases, the transformation strains at lower stresses in constrained recovery, and the transformation temperatures at higher stresses in constrained recovery. This work thus validated that carefully prepared micron-diameter samples can be used to obtain representative bulk thermo-mechanical properties, and is useful for fabricating and optimizing composition and thermomechanical processing parameters in prototype button melts prior to commercial production. This work additionally assesses potential applications of high temperature shape memory alloy actuator seals in turbomachinery. A concept for a shape memory alloy turbine labyrinth seal is also presented. Funding support from NASA’s Fundamental Aeronautics Program, Supersonics Project (NNX08AB51A) and Siemens Energy is acknowledged.

High temperatures

Nickel titanium alloys

Shape memory alloys

Turbomachines

Engineering

Low Temperature And Reduced Length Scale Behavior Of Shape Memory And Superelastic Niti And Nitife Alloys

Manjeri, Radhakrishnan

01 January 2009

Shape memory and superelastic applications of NiTi based alloys have typically been limited to near room temperature or to bulk length scales. The objective of this work is two-fold: first, to investigate shape memory behavior at low temperatures in the context of the R-phase transformation in NiTiFe alloys by recourse to arc-melting, differential scanning calorimetry (DSC), transmission electron microscopy (TEM) and mechanical testing at low temperatures; and second, to investigate superelasticity and two-way shape memory behavior at reduced length scales in the context of NiTi by recourse to micro-compression, micro-indentation and TEM studies. Selected compositions of ternary NiTiFe shape memory alloys were arc-melted and thermomechanically processed to investigate the influence of composition and processing parameters on the formation of the R-phase. The methodology used for the processing and characterization of the alloys was established and included microprobe analysis, DSC, TEM and mechanical testing. No phase transformation was observed in alloys with Fe content in excess of 4 at.%. Thermomechanical treatments facilitated the formation of the R-phase in Ni-rich alloys. The range of the transformation between the R-phase and austenite, and the hysteresis associated with it were influenced by the distribution and size of metastable Ni4Ti3 precipitates. The investigation of the microstructural, thermal and mechanical properties of the R-phase transformation in NiTiFe alloys revealed a complex dependence of these properties on processing parameters. The present work also highlighted the hitherto unexplored competition between the two inelastic deformation modes operating in the R-phase (detwinning and stress-induced transformation) and established the preference of one mode over the other in stress-temperature space. iv The complete micromechanical response of superelastic NiTi was examined by performing careful micro-compression experiments on single crystal pillars of known orientations using a nanoindenter tip. Specifically, the orientation dependence of the elastic deformation of austenite, the onset of its transformation to martensite, the gradient and the hysteresis in the stress-strain response during transformation, the elastic modulus of the stress-induced martensite and the onset of plasticity of the stress-induced martensite were analyzed in separate experiments. A majority of the results were explained by recourse to a quantitative determination of strains associated with austenite grains transforming to martensite variants or twinning in martensite. Microstructural studies were also performed on a micro-indentation trained NiTi shape memory alloy specimen to understand the mechanisms governing the two-way shape memory effect. In situ TEM studies at temperature on specimens obtained at different depths below the indent showed the presence of retained martensite along with the R-phase. Previously, while such twoway shape memory behavior has typically been associated with large dislocation densities, this work provides evidence of the role of retained martensite and the R-phase in cases with reduced dislocation densities. Funding support for this work from NSF (CAREER DMR-0239512), NASA (NAG3-2751) and SRI is acknowledged.

Nickel titanium alloys

Shape memory alloys

Nickel titanium iron alloys

Engineering