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21	Etude des effets des préparations de surface avant projection thermique : application barrière thermique / Effects on adhesion mechanisms of prior-surface treatments before thermal spraying : Thermal barrier coating Kromer, Robin 05 December 2016 (has links) L'adhésion des revêtements est l'objectif premier de tout système afin de pouvoir apporter les propriétés de surface voulues par projection thermique. De façon conventionnelle, des traitements de sablage sont régulièrement employés afin de promouvoir des phénomènes d'ancrage mécanique entre les deux matériaux mis en contact.Néanmoins, selon la nature même des matériaux, un certain nombre de limitations peuvent être observées aussi bien d'un point de vue usage que tenue. Une fragilisation des surfaces peut en effet être remarquée dès lors qu'ils'agit du traitement de matériaux ductiles. Pour palier certaines de ces contraintes, des traitements palliatifs sont alors recherchés parmi lesquels les traitements laser apparaissent particulièrement bénéfiques dont la texturation laser. Les revêtements barrière thermique sont l'application visée de cette étude avec comme objectif une optimisation de leur durabilité à chaud (oxydation, fluage). Une sous-couche d'accroche est habituellement déposée mais les modes d'endommagement recensés semblent se concentrer autour de cette dernière. L'objectif de c etravail a donc visé à remplacer la sous-couche par une topographie de surface spécifique du substrat générée partexturation laser et permettant un ancrage mécanique suffisant aux chargement mécaniques et thermiques subis par les aubes de turbines hautes températures.Lors de l'interaction laser-matière, une élévation en température de l'extrême surface jusqu'à la température defusion et de vaporisation du matériau peut être observée et permettre la formation de motifs. Les dimensions de tels motifs sont donc liées à l¿énergie par impulsion et au nombre d¿impulsions. Pour valider de tels effets, les mécanismes de perçage ont donc été étudiés grâce à une modélisation thermo hydraulique et une validation postmortem des échantillons. Les dimensions des motifs alors contrôlées, le remplissage des surfaces texturées par des particules fondues projetées par le procédé APS a été étudié afin de minimiser le nombre de défauts proche de l'interface. Deux modes de rupture ont pu être identifiés en fonction de la morphologie de surface pour descontraintes de traction et de cisaillement. Les fissures se propagent à l'interface jusqu'à avoir des changements dedirection. L'énergie de propagation de la fissure augmente donc jusqu'à atteindre une valeur limite correspondant àla ténacité du revêtement. Dans ce cas, la tenue n'est pas fonction de la surface totale en contact mais de larépartition spatiale et l'ouverture des motifs, la seule limite de la tenue du revêtement restant la cohésion du dépôt.D'un point de vue applicatif, le but de cette étude a été de caractériser les modes d'endommagements de systèmes barrière thermique sans sous-couche pour des conditions rencontrées en service. Les mécanismes d'endommagement dus à l'oxydation et à l'allongement viscoplastique à 1100C ont donc été isolés par des essais àdes flux thermiques isothermes et cyclés, de fluage et de fatigue thermomécanique. Le traitement laser modifiant localement la microstructure des surfaces, une modification des couches d'oxydes a tout d'abord pu être identifiée.En effet, contrairement aux traitements conventionnels où la croissance d'oxyde n'est pas constante (point limitant de la durée de vie du système), l'apparition de spinelles et d'une couche dense d'alumine protectrice en surface des matériaux texturés a pu être observée. L'ancrage mécanique ainsi créé a démontré alors une durée de vie nettement améliorée face à des conditions extrêmes. / Coating adhesion is requiered to rpomote specific surface properties by thermal spraying. Conventional prior-surface treatments have been developed to create anchoring zones but the adhesion strenght and their applications are limited. Laser surface texturing increases and adapts the adhesion surface. Therefore, two interface failure modes have been related to texture morphologies for tensile and shear stresses. The energy released rate at the interface increases up to coating toughness when the crack path is sharp. Mixed-mode failures have been observed with adhesive and cohesive cracks around and above pattern respectively. So, the adhesion stengyh is function of the contact aera precisely linked to pattern distribution and morphology. Thermal barrier coating system without bond coat life-span has been evaluated for thermomechanical stresses (YSZ coating on single crystal based Nickel). The bond coat has been remplaced by an adapted substrate surface topography. According ti the laser parameters (energy per pulse, pulse numbers) pattern morphology can be created. Therefore, textured surface filling by melted particles has been studies to minimize interface defaults and created mixed-mode failures for during plasma spray coatings. The drilling mechanisms have been evaluated by numerical modeling and experimental analysis. The pattern dimensions and heat affected zones has been identified. The laser treatment changes the microstructure locally.Oxydation tests have been performed to study the surface pre-tratments effects on oxide nature and mass gain rate. The damaging mechanisms ave been studied under isotherm and cyclic high temperature tests and also under creeping and thermo-mechanical fatigue tests. Grit-blasting change the natural oxides, limits life-span and bucking failure mode have been obeserved. Natural oxides have been analyzed for the textured substraes also but anchoring mechanism enables large life-span under high temperature tests. Mechanical applied stresses (constant and cyclic) validate the beneficial effects of patterned surfaces. The interface is stronger than the coating toughness and the patterns do not create early cracks under thermo-mechanical solicitations. Texturation laser Projection thermique Système barrière thermique Adhérence Durée de vie Laser surface texturing Thermal spray Thermal barrier coating Adhesion Life-span 629
22	Refusão superficial a laser da liga com memória de forma Cu-11,8Al-3,2Ni-3Mn (% Peso) / Laser surface remelting of a Cu-11.8Al-3.2Ni-3Mn (wt. %) shape memory alloy Silva, Murillo Romero da 10 February 2017 (has links) Submitted by Alison Vanceto (alison-vanceto@hotmail.com) on 2017-08-30T12:06:28Z No. of bitstreams: 1 DissMRS.pdf: 7292710 bytes, checksum: b518987951bcfa31933df3cece2f16cf (MD5) / Approved for entry into archive by Ronildo Prado (ronisp@ufscar.br) on 2017-09-06T18:24:26Z (GMT) No. of bitstreams: 1 DissMRS.pdf: 7292710 bytes, checksum: b518987951bcfa31933df3cece2f16cf (MD5) / Approved for entry into archive by Ronildo Prado (ronisp@ufscar.br) on 2017-09-06T18:33:14Z (GMT) No. of bitstreams: 1 DissMRS.pdf: 7292710 bytes, checksum: b518987951bcfa31933df3cece2f16cf (MD5) / Made available in DSpace on 2017-09-06T18:34:27Z (GMT). No. of bitstreams: 1 DissMRS.pdf: 7292710 bytes, checksum: b518987951bcfa31933df3cece2f16cf (MD5) Previous issue date: 2017-02-10 / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / Shape memory alloys (SMA) are alloys that undergo martensitic transformation due to an external solicitation (temperature, stress, strain or magnetic field) and are capable of recovering permanent deformation when heated above a critical temperature. The most used shape memory alloys are Ti-Ni- and Cu-based. Cu-based SMA have some advantages due to better thermal and electrical conductivity, lower production cost and are easier to process. The main disadvantage of Cu-based SMA is its low ductility. This property is improved by decreasing the grain size and by a reduction of microstructural heterogeneities. This can be achieved at the surface of structural components after LASER remelting, through which the surface of the material is remelted by a LASER beam and solidifies under extremely high cooling rates. In this context, the aim of the present work is to investigate the influence of LASER surface remelting in the microstructure, thermal stability and mechanical properties of Cu-11.8Al-3.2Ni-3Mn (wt. %) SMA plates obtained by suction casting. The samples were characterized by optical and scanning electron microscopy, energy dispersive X-ray spectroscopy, electron backscatter diffraction, X-ray computed tomography, X-ray diffraction, differential scanning calorimetry as well as by tensile and microhardness tests. The results show that small shifts in the transformation temperatures occur due to the LASER treatment. It was observed that only the monoclinic β’1 martensitic phase formed in the as cast and LASER treated samples. The LASER treatment provided an improvement in mechanical properties with an increase of up to 162 MPa in fracture stress, up to 2.2% in fracture strain and up to 21 HV in microhardness when compared with the as-cast sample. This makes the surface remelting treatment a promising method for improving the mechanical properties of Cu-based SMA. / Ligas com memória de forma (LMF) sofrem transformação martensítica devido a uma solicitação externa (temperatura, tensão, deformação ou campo magnético) e são capazes de recuperar deformações permanentes quando aquecidas acima de uma temperatura crítica. Dentre as LMF mais utilizadas se destacam aquelas à base de Ti e Ni e aquelas à base de Cu. As à base de Cu apresentam vantagens devido a melhor condutividade térmica e elétrica, menor custo de produção e maior facilidade de processamento. A principal desvantagem das LMF à base de cobre é a baixa ductilidade. Uma forma de melhorar essa propriedade é promovendo uma diminuição no tamanho de grão e uma redução das heterogeneidades microestruturais. Isso pode ser obtido no tratamento de refusão superficial a LASER, no qual a superfície do material é refundida por um feixe de LASER e solidificada sob altas taxas de resfriamento. Nesse contexto, o objetivo da presente dissertação de mestrado é analisar a influência do tratamento de refusão superficial a LASER na microestrutura, na estabilidade térmica e nas propriedades mecânicas de placas da LMF Cu-11,8Al-3,2Ni-3Mn (% peso) obtidas através de fundição por sucção. As amostras foram caracterizadas por microscopia óptica e eletrônica de varredura, espectometria de energia dispersiva de raios X, difração de elétrons retroespalhados, tomografia computacional por raios X, calorimetria diferencial de varredura, difração de raios X, ensaio de tração e microdureza. A análise dos resultados mostrou que as temperaturas de transformação sofreram pequenas variações e nenhuma nova fase foi observada após o tratamento de refusão a LASER, sendo observada apenas a presença da fase monoclínica martensítica β’1. O tratamento propiciou uma melhoria nas propriedades mecânicas das placas obtidas por fundição por sucção, com um aumento em até 162 MPa na tensão de fratura, em até 2,2 % na deformação de fratua e em até 21 HV na microdureza, fazendo deste tratamento um método promissor para melhorar as propriedades mecânicas das LMF à base de Cu. / CNPq: 132132/2015-0 / FAPESP: 2015/04134-7 Ligas com memória de forma Refusão superficial a laser Transformação martensítica Resfriamento rápido Shape memory alloys Laser surface remelting Martensitic transformation Rapid cooling
23	Tratamento superficial por refusão a laser em aços AISI H13 e AISI 420 / Laser surface melting of steels AISI H13 and AISI 420 Pereira, Elaine Cristina 17 February 2006 (has links) Orientador: Maria Clara Filippini Ierardi / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecanica / Made available in DSpace on 2018-08-06T10:03:07Z (GMT). No. of bitstreams: 1 Pereira_ElaineCristina_M.pdf: 3869413 bytes, checksum: b9bfe02035758d11f3c1b43e411db4d4 (MD5) Previous issue date: 2006 / Resumo: A refusão superficial a laser é uma técnica muito promissora para a melhoria das propriedades mecânicas dos aços ferramentas através da homogeneização química e refino da estrutura. O tratamento a laser promove o aquecimento e resfriamento rápidos da camada superficial resultando em transformações microestruturais que promovem a melhoria do desempenho sem envolver o reprocessamento do material como um todo. Neste trabalho foram analisadas, além da microestrutura resultante do tratamento de refusão a laser, a resistência à corrosão e a resistência à flexão dos aços ferramenta para trabalho a quente AISI H13 e inoxidável martensítico AISI 420. Os resultados experimentais foram comparados com os mesmos aços sem tratamento. Observou-se que a microestrutura resultante do tratamento de refusão a laser é formada de martensita e austenita residual. A estrutura refinada e a presença de martensita resultaram em um aumento da dureza, apesar do grande volume de austenita residual. A dissolução de carbonetos e incorporação dos elementos de liga na matriz, como por exemplo o cromo, promoveu uma melhoria no comportamento em corrosão / Abstract: Laser surface melting is a very promising technique to improve the mechanical properties of tool steel by the chemical homogenization and refinement of the microstructure. Laser treatment promotes the rapid heating and cooling of the superficial layer resulting in microstructure transformations, which improve material performance without involving the reprocessing of the bulk material. In this work, besides the microstructure resulting from laser surface melting, corrosion resistance and deflection of hot-work tool steel AISI H13 and martensitic stainless steel AISI 420 were analyzed. The experimental results were compared to the same steels without treatment. The microstructure of the laser surface melting is formed by martensite and retained austenite. The refined structure and the presence of martensite increased hardness, despite the large volume of retained austenite. The carbides dissolution and incorporation of alloying elements into the matrix, for example chrome, improve the corrosion behavior / Mestrado / Materiais e Processos de Fabricação / Mestre em Engenharia Mecânica Fusão a laser Aço inoxidável Aço-ferramenta Aço - Corrosão Corrosão Laser surface melting Stainless steel Tool-steel Corrosion resistance Rapid solidification
24	Corrosion And Wear Behaviour of Plasma Electrolytic Oxidation And Laser Surface Alloy Coatings Produced on Mg Alloys Rapheal, George January 2016 (has links) (PDF) In the present investigation, surface coatings employing laser surface alloying (LSA) and plasma electrolytic oxidation (PEO) processes have been prepared on Mg alloys. The coatings have been investigated for corrosion and wear behaviour. Two important Mg alloys based on Mg–Al system were selected namely, MRI 230D and AM50 as substrates. LSA coatings have been prepared employing Al and Al2O3 as precursors using different laser scan speeds. PEO coatings were prepared in standard silicate and phosphate based electrolytes employing unipolar, pulsed DC. Hybrid coatings using a combination of the two processes were also produced and investigated for corrosion and wear behaviour. Hybrid coatings of LSA followed by PEO (LSA+PEO) were investigated for effectiveness of sealing the cracks in the LSA coatings by subsequent PEO process and consequent improvement in the corrosion resistance. Hybrid coatings of PEO followed by LSA (PEO+LSA) were prepared with an objective of sealing the pores in the PEO coating LSA treatment. In an attempt to produce more compact PEO coatings, electrolyte containing montmorillonite clay additives was employed for the PEO process of AM50 Mg alloy. The coatings were produced employing different current densities and the effect of current density on the microstructure and corrosion behaviour of coating was investigated. Electrochemical corrosion tests of uncoated and coated alloys were carried out in 3.5 wt.% (0.6M)NaCl, neutral pH, solution with an exposed area of 0.5 cm2 for a time duration of 18.5 h. For the PEO coatings with clay additives, corrosion tests were conducted additionally in 0.5 wt.% (0.08 M) NaCl, neutral pH, solution for a time duration of 226.1 h. Wear behaviour of LSA coatings was analyzed by employing a pin on disc tribo–tester conforming to ASTM G–99 standard at ambient conditions with ground EN32 steel disc of hardness Rc 58 as the counterface. Tests were conducted under dry sliding conditions for a sliding distance of 1.0 km at a sliding velocity of 0.837 m/s employing normal loads of 10, 20, 30 and 40 N. Friction and wear behavior of PEO and PEO+LSA coatings were analyzed at ambient conditions by employing a ball−on−flat linearly oscillating tribometer conforming to ASTM G–133 standard. AISI 52100 steel ball of diameter 6 mm was employed as the friction partner. Wear tests were conducted under dry sliding conditions for a total sliding distance of 100 m at normal loads of 2 N and 5 N with oscillating amplitude of 10 mm and mean sliding speed of 5 mm/s. LSA coatings could not improve the corrosion resistance of MRI 230D Mg alloy. This was attributed to the presence of cracks in the LSA coating, which resulted in the accelerated galvanic corrosion of the substrate. LSA coatings improved the wear resistance at all loads. The improved wear resistance was attributed to β (Mg17Al12) phase and Al2O3 particles in the coating which increased the hardness of the LSA layer. No trend in corrosion and wear resistance with laser scan speed was observed for LSA coatings. PEO coatings improved the corrosion resistance of the MRI 230D Mg alloy significantly. The improved corrosion resistance was attributed to the enhanced barrier protection provided by dense barrier layer formed at the substrate/coating interface and to the insoluble phase constituents in the coatings. PEO coating was effective in improving the wear resistance at low loads/contact pressures. At higher loads, the coating underwent micro–fracture as a result of the porosity in the coatings. Hybrid coatings of LSA followed by PEO (LSA+PEO) in silicate based electrolyte improved the corrosion resistance of LSA coatings. However, the corrosion resistance was not improved to the extent of PEO coatings on as–cast alloy as a result of cracks in the primary coatings, which were not fully sealed by the plasma conversion products. No trend in corrosion resistance with laser scan speed was observed for LSA+PEOcoatings. In hybrid coatings of PEO followed by LSA (PEO+LSA), primary PEO coating was completely melted and mixed with applied precursor to form a single composite LSA layer. The corrosion resistance of the hybrid coatings was observed to be lower than that of the as–cast alloy. The presence of solidification cracks reduced the barrier properties and resulted in the accelerated galvanic corrosion of the substrate similar to LSA coatings. Hybrid (PEO+LSA) coatings exhibited improved wear resistance as compared to as–cast alloy at lower loads as a result of increase in the hardness due to β (Mg17Al12) phase and oxide/ceramic particles in the hybrid layer. At higher loads, hybrid coatings exhibited higher wear rate as compared to as–cast alloy and PEO coatings. This was attributed to three–body abrasive wear as a result of dislodged hard oxide/ceramic particles in the wear tracks. No trend in corrosion and wear resistance with laser scan speed was observed for PEO+LSA coatings. PEO coatings on AM50 Mg alloy by employing clay additives in the electrolyte resulted in the reactive uptake of clay particles producing a predominantly amorphous coating at low current density. Clay additives were effective in improving the compactness of the coating at lower current density. At higher current densities, the porosity of the coatings increased. The clay particles got re–constituted producing increasing amount of crystalline phases with increase in current density. Long term impedance measurements showed that clay addition as well as increased current density employed for the PEO process was not effective in improving the corrosion resistance of the coatings. At low current density, even though the coating with clay additives was more compact, it was deficient in MgO and consisted predominantly of an amorphous phase, which underwent fast dissolution in electrolyte thereby resulting in an early loss of barrier properties. At higher current densities, even though the coatings consisted of increased amount of MgO and crystalline phases, which resist dissolution in the electrolyte, the increased porosity and defective barrier layer resulted in easy permeation of the electrolyte into the substrate/coating interface, which resulted in much earlier loss of barrier properties and inferior corrosion resistance. Magnesium Alloys Plasma Electrolytic Oxidation (PEO) Laser Surface Alloying Magnesium Alloy Plating Mg Alloys Hybrid Coatings Magnesium Alloy Coatings Electrochemical Corrosion PEO Coatings Materials Engineering
25	Nanokristalline und laserpuls-strukturierte Ni-Elektroden für die alkalische Wasserelektrolyse Rauscher, Thomas 08 November 2021 (has links) Das Ziel der vorliegenden Arbeit ist es, nanokristalline und laserpuls-strukturierte Elektroden für die alkalische Wasserelektrolyse zu untersuchten und hinsichtlich ihrer elektrokatalytischen Eigenschaft zu bewerten. Dabei besteht die Hauptaufgabe in der Aufklärung der Zusammenhänge zwischen der elektrokatalytischen Aktivität und der Struktur der Elektroden. Es soll der Effekt der nanokristallinen Kristallstruktur auf die Elektrodenaktivität aufgeklärt werden. Zudem stellt die elektrokatalytische Wirkung von Mo in Ni-Elektroden für die Wasserstoffentwicklungsreaktion eine zentrale Untersuchung in der vorliegenden Arbeit dar. Für die Sauerstoffentwicklungsreaktion soll der Einfluss von Fe in nanokristallinen Ni-Materialien näher analysiert und unter industriell relevanten Betriebsbedingungen bewertet werden. Zum anderen richtet sich der Fokus auf die Nutzung eines Ultrakurzpulslasers zur Strukturierung von Ni-Elektrodenoberflächen. Besonderes Augenmerk wird auf die Korrelation zwischen den individuellen Strukturmerkmalen, der erzielten Oberflächenvergrößerung und der elektrokatalytischen Aktivität bezüglich der Wasserstoffentwicklung gelegt. Zudem werden Langzeituntersuchungen bei Stromdichten von bis 1 A/cm² durchgeführt, um die Stabilität zu bewerten und Degradationsmechanismen aufzuklären. info:eu-repo/classification/ddc/620 ddc:620
26	A cfd design of engineered surface for tribological performance improvements in hydraulic pumps Casoli, Paolo, Scolari, Fabio, Rossi, Carlo, Rigosi, Manuel 25 June 2020 (has links) In the present paper the preliminary results of the potentialities that surface texturing has in improving the coupling of lubricated surfaces in relative motion is presented. This kind surface engineering requires careful design of the geometry to obtain relevant improvements; therefore, it is useful to study in detail the behavior of the fluid confined between the coupled surfaces by means of CFD analysis. The purpose of this research is to study the effect of dimples created on one of the two coupled surfaces and to observe the variation of tribological properties as their principal design parameters vary, such as dimple shape, size and spatial distribution. Furthermore, simulations have been carried out with different sliding velocities and fluid temperatures to analyze the effects that these variables have on the tribological performance of the textured surface. The simulations also consider the presence of cavitation and the influence of this phenomenon on the overall behavior of the textured surface is evaluated. info:eu-repo/classification/ddc/620 ddc:620
27	Desarrollo de aleaciones ß Ti-Nb-Mo mediante pulvimetalurgia para aplicaciones biomédicas Viera Sotillo, Mauricio 27 November 2020 (has links) [ES] Dentro del sector biomédico, el titanio y sus aleaciones han desplazado a otros materiales como el acero inoxidable 316L y las aleaciones Co-Cr por ofrecer un módulo elástico más cercano al hueso cortical, lo que reduce sustancialmente el efecto de apantallamiento de tensiones. Una manera de disminuir aún más el módulo elástico es estabilizando la fase cúbica beta (bcc) del titanio a temperatura ambiente mediante la adición de elementos como el Nb y Mo, cuya biocompatibilidad ha sido comprobada en numerosos estudios. La ruta convencional para el procesado de estas aleaciones es la fundición y/o forja, pero en esta investigación se ha optado por la pulvimetalurgia ya que el desperdicio de material es mínimo y se reducen las etapas posteriores de tratamientos térmicos y mecanizado, facilitando el procesado en general y reduciendo los costos. Además, el carácter refractario de los elementos estabilizadores beta justifica aún más el empleo de un método de consolidación en estado sólido como la pulvimetalurgia donde no es necesario alcanzar temperaturas tan elevadas. Por tanto, en una primera aproximación se han procesado aleaciones de Ti-xNb-yMo (x = 13, 20, 27, 35 ; y = 12, 10, 8, 6; % en peso) mediante pulvimetalurgia convencional para estudiar el efecto del Nb y Mo en la microestructura y propiedades mecánicas de las aleaciones. A fin de atacar otros problemas inherentes del proceso como la porosidad y la falta de homogeneidad en la microestructura se ha acudido a la mezcla mecánica de polvos de la aleación Ti-35Nb-6Mo, evaluando también el efecto de diferentes agentes controladores de proceso en la molienda. Por último, se ha tratado la superficie de las aleaciones Ti-27Nb-8Mo y Ti-35Nb-6Mo mediante fusión por láser con diferentes parámetros para estudiar la capacidad del proceso de cerrar la porosidad abierta, mejorar la homogeneidad superficial, y evaluar su efecto en la microestructura y propiedades mecánicas de las aleaciones. Pese a aumentar la porosidad en función del contenido de Nb, las aleaciones Ti-27Nb-8Mo y Ti-35Nb-6Mo de las obtenidas por mezcla elemental exhibieron las mejores propiedades en general, con una microestructura casi beta en su totalidad y un módulo de elasticidad de 67 - 74 GPa, que se acerca más al presentado por el hueso cortical en comparación con la aleación comercial Ti-6Al-4V ELI. Por su parte, la mezcla mecánica mejoró considerablemente la homogeneidad química de la aleación Ti-35Nb-6Mo, pero promovió la formación de la fase alfa y deterioró la resistencia y deformación mecánica debido a la ganancia en acritud del polvo y el aumento de la porosidad. No obstante, la microdureza de las aleaciones aumentó significativamente. En cuanto al agente controlador de proceso, el cloruro de sodio (NaCl) exhibió los mejores resultados en términos de rendimiento y distribución de tamaño de partícula, mientras que el ácido esteárico indujo la contaminación del polvo mediante la formación de la fase no deseada TiC. El tratamiento de fusión superficial por láser consiguió cerrar efectivamente la porosidad abierta de las aleaciones y mejorar la homogeneidad microestructural. Adicionalmente, promovió un aumento de la resistencia y la deformación mecánica y una leve disminución del módulo elástico en ambas aleaciones. Por último, la aleación Ti-27Nb-8Mo tratada superficialmente a 1000W y 6,67 mm/s exhibió una microestructura beta casi en su totalidad y las mejores propiedades mecánicas desde un punto de vista biomédico, con una resistencia de 1467 MPa, una deformación de 7% y un módulo de elasticidad de 67 - 72 GPa. / [CA] Dins del sector biomèdic el titani i els seus aliatges han desplaçat a altres materials com l'acer inoxidable 316L i els aliatges Co-Cr per oferir un mòdul elàstic inferior i més pròxim a l'os cortical, la qual cosa redueix substancialment l'efecte d'apantallament de tensions. Una manera de disminuir encara més el mòdul elàstic és estabilitzant la fase cúbica beta; (bcc) del titani a temperatura ambient mitjançant l'addició d'elements altament biocompatibles com el Nb i Mo. La ruta convencional per al processament d'aquests aliatges és la fosa i/o forja, però en aquesta recerca s'ha optat per la pulvimetalurgia ja que el desaprofitament de material és mínim i es redueixen les etapes posteriors de tractament tèrmics i mecanitzat, facilitant el processament en general i reduint els costos. A més, el caràcter refractari dels elements estabilitzadors beta justifica encara més l'ús d'un mètode de consolidació en estat sòlid com la pulvimetalurgia on no és necessari aconseguir temperatures tan elevada. Per tant, en una primera aproximació s'han processat aliatges de Tu-xNb-yMo (x = 13, 20, 27, 35 ; i = 12, 10, 8, 6; % en pes) mitjançant pulvimetalurgia convencional per a estudiar l'efecte del Nb i Mo en la microestructura i propietats mecàniques dels aliatges. A fi d'atacar altres problemes inherents del procés com la porositat i la falta d'homogeneïtat en la microestructura s'ha acudit a la mescla mecànica de pólvores de l'aliatge Tu-35Nb-6Mo, avaluant també l'efecte de diferents agents antiadherentes en la mòltaa. Finalment, s'ha tractat la superfície dels aliatges Tu-27Nb-8Mo i Tu-35Nb-6Mo mitjançant fusió per làser amb diferents paràmetres per a estudiar la capacitat del procés per a tancar la porositat oberta, millorar l'homogeneïtat superficial, i avaluar el seu efecte en la microestructura i propietats mecàniques dels aliatges. Malgrat augmentar la porositat en funció del contingut de Nb, els aliatges Tu-27Nb-8Mo i Tu-35Nb-6Mo van exhibir les millors propietats en general. La mescla mecànica va millorar l'homogeneïtat química de l'aliatge Tu-35Nb-6Mo però va deteriorar les propietats mecàniques amb excepció de la microdureza. El tractament de fusió superficial per làser va aconseguir tancar efectivament la porositat oberta dels aliatges i va millorar l'homogeneïtat microestructural i les propietats mecàniques. Finalment, l'aliatge Tu-27Nb-8Mo tractada superficialment a 1000W i 6,67 mm/s va exhibir una microestructura beta gairebé íntegrament i les millors propietats mecàniques des d'un punt de vista biomèdic. / [EN] Within the biomedical sector, titanium and its alloys have replaced other materials such as 316L stainless steel and Co-Cr alloys due to a lower elastic modulus, closer to the cortical bone, which significantly reduces the stress shielding effect. An alternative to decrease the elastic modulus even more is to stabilize the cubic beta phase (bcc) of titanium at room temperature by adding highly biocompatible elements such as Nb and Mo. These alloys are normally processed by casting and/or forging, but in this work powder metallurgy was conducted due to lower material waste and less subsequent stages of heat treatments and machining, reducing costs significantly. Moreover, the refractory nature of beta stabilizing elements justifies even more the use of a solid-state consolidation method such as powder metallurgy where it is not necessary to reach meting point temperatures. Therefore, in a first approach, Ti-xNb-yMo alloys (x = 13, 20, 27, 35; y = 12, 10, 8, 6;% by weight) were processed by conventional powder metallurgy to study the effect of Nb and Mo in the microstructure and mechanical properties of the alloys. In order to attack other powder metallurgy inherent problems, such as porosity and inhomogeneity in the microstructure, mechanical mixing was carried out for the Ti-35Nb-6Mo powder, evaluating the effect of different non-stick agents on the milling process. Finally, the surface of Ti-27Nb-8Mo and Ti-35Nb-6Mo alloys were treated by laser surface melting under different parameters to reduce open porosity, improve surface homogeneity, and evaluate its effect. in the microstructure and mechanical properties of alloys. Despite increasing porosity with the increase of Nb content, Ti-27Nb-8Mo and Ti-35Nb-6Mo alloys exhibited the best overall properties, consisting of a beta phase microstructure. Mechanical mixing improved the chemical homogeneity of the Ti-35Nb-6Mo alloy but deteriorated the mechanical properties with the exception of microhardness. The laser surface melting treatment effectively closed the open porosity in the alloys and improved the microstructural homogeneity and mechanical properties. Lastly, the Ti-27Nb-8Mo alloy which surface was treated at 1000W and 6.67 mm/s exhibited a beta microstructure and the best mechanical properties from a biomedical point of view. Despite increasing porosity with Nb addition, Ti-27Nb-8Mo and Ti-35Nb-6Mo alloys exhibited the best overall properties, both consisting of a beta phase microstructure and an elastic modulus of 67 - 74 GPa, which is closer to the cortical bone in comparison to the commercial Ti-6Al-4V ELI alloy. On the other hand, the mechanical mixing significantly improved the chemical homogeneity of the Ti-35Nb-6Mo alloy, but induced the formation of alfa phase and deteriorated the resistance and mechanical deformation due to the increase in porosity and the hardening effect produced during the milling process. Therefore, the microhardness increased significantly. Regarding the process control agent, sodium chloride (NaCl) exhibited the best results in terms of powder yield and particle size distribution, while stearic acid induced contamination by the formation of the undesired TiC phase. The laser surface melting treatment was able to effectively close the open porosity of the alloys and improve microstructural homogeneity. Moreover, it promoted an increase in strength and mechanical deformation and a slight decrease in the elastic modulus in both alloys. Finally, the surface-treated Ti-27Nb-8Mo alloy at 1000W and 6.67 mm/s exhibited almost an entirely beta phase microstructure and the best mechanical properties from a biomedical point of view, with a resistance of 1467 MPa, a deformation of 7% and a modulus of elasticity of 67 - 72 GPa. / El trabajo se realizó en el Instituto de Tecnología de Materiales y en el Departamento de Ingeniería Mecánica y de Materiales de la Universitat Politècnica de València, bajo la ayuda del proyecto MAT2014-53764-C3-1-R del Ministerio de Economía y Competitividad de España, y la subvención 2016/020 del programa SANTIAGO GRISOLIA, enmarcada en la convocatoria del 2015 de la Conselleria de Educación, Cultura y Deporte de la Generalitat Valenciana. / Viera Sotillo, M. (2020). Desarrollo de aleaciones ß Ti-Nb-Mo mediante pulvimetalurgia para aplicaciones biomédicas [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/156194 Laser surface melting Mechanical alloying Powder metallurgy Titanium alloys Aleaciones de titanio Ti-Nb-Mo Pulvimetalurgia Fusión superficial por láser Aleado mecánico
28	Resistência à corrosão e simulação numérica da temperatura e tensões induzidas na refusão superficial a laser da liga aerospacial Al–1,5% Fe Teleginski, Viviane 31 August 2012 (has links) Made available in DSpace on 2017-07-21T20:42:38Z (GMT). No. of bitstreams: 1 VIVIANE TELEGINSKI.pdf: 4135573 bytes, checksum: d862e0fdfd063afd1dec2d86b22b4031 (MD5) Previous issue date: 2012-08-31 / Conselho Nacional de Desenvolvimento Científico e Tecnológico / In this work, the aerospace alloy Al–1.5wt.%Fe was submitted to laser surface remelting (LSR). This process occurs thought the application of a localized laser radiation with high power density, causing fast heating and melting of the irradiated material, following with high rates of cooling causing the non-equilibrium solidification of the treated layer. In the present work a broad experimental survey was made in relation to microstructure, composition of the resulting phases, morphology characterization, microhardness and corrosion resistance of the treated layer and the results were compared with the untreated sample. Predictions through the numerical simulation were done relative to the thermal history, heating and cooling cycles, the depth of the treated layer and the thermal stress caused by sudden heating and cooling of the treated layer. The results indicate that the high cooling rates of the order of 104 K/s promoted the formation of metastable intermetallic phases and oxides. Due to the laser treatment there was an increase in microhardness, reduction in surface roughness and there was an increase in corrosion resistance about fourteen times on the studied electrolyte. These results indicate that laser surface remelting is an effective tool for upgrade the surface quality of parts that require high level performances. The RSL technique is a modern technology for surface processing and it is being applied in industry such as automotive, aerospace and energy. / Neste trabalho a liga aeroespacial Al–1,5%Fe foi submetida ao tratamento de refusão superficial a laser (RSL). O processo ocorre através da aplicação localizada da radiação laser com alta densidade de potência, acontecendo um rápido aquecimento e fusão do material irradiado, seguido de um resfriamento com taxas elevadas sendo que a solidificação da camada tratada ocorre em condições fora de equilíbrio. No presente trabalho realizou-se um amplo levantamento experimental quanto à microestrutura, composição das fases resultantes, característica da morfologia, microdureza e resistência à corrosão da camada tratada e os resultados foram comparados com a amostra não tratada. Através da simulação numérica foram previstos o histórico térmico, ciclos de aquecimento, resfriamento, profundidade da camada tratada e as tensões termicamente induzidas pelo brusco aquecimento e resfriamento provocado pelo processamento. Os resultados indicam que em consequência do resfriamento com taxas da ordem de 104 K/s houve a formação de fases intermetálicas metaestáveis e óxidos. Houve um aumento da dureza, redução da rugosidade superficial e aumento da resistência à corrosão em torno de quatorze vezes no eletrólito de ácido sulfúrico 0,1 mol/L. Estes resultados indicam que o tratamento de refusão superficial a laser é uma eficiente ferramenta para aprimorar a qualidade superficial de peças que exigem alto nível de desempenho. A técnica de RSL é uma tecnologia moderna de processamento superficial e vem sendo aplicada nas indústrias como automobilística, aeroespacial e de energia. Ligas Al–Fe Refusão superficial a laser Estudo da corrosão Modificação superficial Simulação numérica Rugosidade Al–Fe alloys Laser Surface Remelting Corrosion study Surface modification Numerical simulation Roughness
29	ESTUDO DA CAMADA TRATADA GERADA POR REFUSÃO SUPERFICIAL A LASER DA LIGA AL-1,5%FE Bertoni, Jean Cleber 30 January 2015 (has links) Made available in DSpace on 2017-07-21T20:43:46Z (GMT). No. of bitstreams: 1 Jean Cleber Bertoni.pdf: 7862049 bytes, checksum: 4c77f7ebc3fc211aac8ad8a7de58ccad (MD5) Previous issue date: 2015-01-30 / There are currently extensive research on aluminum alloys, mainly due to its wide application in the automotive and aerospace industries, due to the following characteristics, among them, low density, high thermal conductivity and high corrosion resistance at room temperature. Al-Fe alloys have a high degree of microstructural change due to changes in their properties when appropriate techniques are applied. The Al-Fe alloy was studied in the composition of 1.5% Fe by weight, which was subjected to the treatment laser surface remelting in order to enhance its surface characteristics. The characterization of these alloys in order to determine the variation of the chemical composition at different depths was performed by Grazzing incidence x-ray diffraction (GIXRD). In this technique, the angle of incidence of the X-ray beam was fixed and the detector moved in 2θ, it is possible to obtain the XRD patterns at different depths by varying the angle of incidence. In this work, the characterizations the micro and nano structural sample of alloy Al-1.5wt.%Fe treated by laser surface remelting (LSR) were performed, on the treated surface, as well as the transverse section, this study was performed at treated samples surface and at the isolated weld fillet on samples, where were applied laser beam speeds of 20, 40 and 60 mm / s. In this study we used different characterization techniques, such as, optical microscopy, scanning electron microscopy, energy dispersive spectroscopy, together with atomic force microscopy, and the Vickers hardness. Also in this work the technique of GIXRD was used to obtain depth profiles of near the surface chemical composition of the alloy. The analysis was performed in the micrometer range varying the angle of incidence between 0.5° to 6° in steps of 0.5° and analysis with incident angles 3° and 6° in steps of 0.02° for each 10 sec. As a result by examining the microstructure was characterized melted zone, the heat affected zone and the substrate, a particular features were found for each velocity of the laser beam, generally the treated area showed a more homogenous microstructure consisting of grains smaller feature, with low roughness and high hardness. The heat affected zone was more notorious the morphology of grains elongated feature in the treated and untreated interface for low laser beam scanning velocities. By means of the technique of X-ray diffraction various metastable phases were found, such as aluminum oxide, nitrides, etc., with different intensities of peaks as a consequence of the variation of angle of incidence. / Atualmente há uma ampla investigação sobre ligas de alumínio, principalmente devido a sua larga aplicação na indústria automotiva e aeroespacial, devido as seguintes características, entre elas, a baixa densidade, alta condutividade térmica e elevada resistência à corrosão a temperatura ambiente. Ligas de Al-Fe possuem um alto grau de modificação microestrutural, devido a mudanças em suas propriedades quando técnicas adequadas forem aplicadas. A liga Al-Fe foi estudada na composição de 1,5% de Fe em peso, a qual foi submetida ao tratamento de refusão superficial a laser de modo a aprimorar suas características superficiais. A caracterização dessas ligas com a finalidade de determinar à variação de composição química em diferentes profundidades foi realizado mediante a difração de raios X com ângulo de incidência rasante (DRXIR). Nesta técnica, o ângulo de incidência do feixe de raios X foi fixado e o detector moveu-se em 2θ, sendo possível obter os difratogramas em diferentes profundidades com a variação do ângulo de incidência. Neste trabalho, as caracterizações a nível micro e nano estrutural das amostras da liga Al-1,5%Fe tratadas por refusão superficial a laser (RSL) foram realizadas, tanto na superfície tratada e bem como na parte transversal, este estudo foi realizado nas amostras tratadas em toda a superfície, quanto nas amostras com trilhas isoladas que foram aplicadas as velocidades de feixe laser de 20, 40 e 60 mm/s. Para isso foram utilizados diferentes técnicas de caracterização, tais como, microscópio ótico, microscópio eletrônico de varredura, espectroscopia por energia dispersiva, acompanhada da microscopia de força atômica, bem como da microdureza Vickers. Também neste trabalho a técnica de DRXIR foi utilizada para obtenção de perfis de profundidade da composição química próxima à superfície da liga. A análise foi realizada em escala micrométrica por meio da variação do ângulo de incidência entre 0,5° a 6° com passos de 0,5°, bem como as análises com ângulos incidentes de 3º e 6º com passos de 0,02º a cada 10 s. Como resultado mediante o estudo microestrutural foram caracterizados a zona fundida, a zona afetada termicamente e o substrato, sendo encontradas características particulares para cada velocidade do feixe de laser, de modo geral a zona tratada mostrou ter uma característica microestrutural mais homogênea formada por grãos menores, com baixa rugosidade e de alta dureza. A zona afetada termicamente mostrou ser mais notória a morfologia de grãos com característica alongada na interface tratada e não tratada para baixas velocidades de varredura do feixe laser. Por meio da técnica de difração de raios X diferentes fases metaestáveis foram encontradas, tais como, óxido de alumínio, nitretos, etc, com diferentes intensidades de picos como consequência da variação do ângulo de incidência. ligas Al-Fe refusão superficial a laser caracterização microestrutural MEV EDS microdureza Al-Fe alloys laser surface remelting GIXRD microstructural characterization SEM FEG EDS microhardness
30	Contribution à l'étude des propriétés physico-chimiques des surfaces modifiées par traitement laser : application à l'amélioration de la résistance à la corrosion localisée des aciers inoxydables / Contribution to the study of physico-chemical properties of surfaces modified by last treatment : application to the enhancement of localized corrosion resistance of stainless stells Pacquentin, Wilfried 25 November 2011 (has links) Les matériaux métalliques sont utilisés dans des conditions de plus en plus sévères et doivent présenter une parfaite intégrité sur des périodes de plus en plus longues. L’objectif de ce travail de thèse est d’évaluer le potentiel d'un traitement de refusion laser pour améliorer la résistance à la corrosion d'un acier inoxydable de type 304L ; l’utilisation du laser dans le domaine des traitements de surface constituant un procédé en pleine évolution à cause des changements récents dans la technologie des lasers. Dans le cadre de ce travail, le choix du laser s’est porté sur un laser nano-impulsionnel à fibre dopée ytterbium dont les caractéristiques permettent la fusion quasi-instantanée sur quelques microns de la surface traitée, immédiatement suivie d'une solidification ultra-rapide avec des vitesses de refroidissement pouvant atteindre 1011 K/s. La combinaison de ces processus favorise l'élimination des défauts surfaciques, la formation de phases hors équilibre, la ségrégation d’éléments chimiques et la formation d’une nouvelle couche d’oxyde dont les propriétés sont gouvernées par les paramètres laser. Afin de les corréler avec la réactivité électrochimique de la surface, l’influence de deux paramètres laser sur les propriétés physico-chimiques de la surface a été étudiée : la puissance du laser et le taux de recouvrement des impacts laser. Pour clarifier ces relations, la résistance à la corrosion par piqûration des surfaces traitées a été déterminée par des tests électrochimiques. Pour des paramètres laser spécifiques, le potentiel de piqûration d'un acier inoxydable de type 304L augmente de plus de 500 mV traduisant ainsi une meilleure tenue à la corrosion localisée en milieu chloruré. L’interdépendance des différents phénomènes résultant du traitement laser a rendu complexe la hiérarchisation de leur effet sur la sensibilité de l’alliage testé. Cependant, il a été montré que la nature de l’oxyde thermique formé au cours de la refusion laser et ses défauts sont du premier ordre pour l’amorçage des piqûres. / Metallic materials are more and more used in severe conditions with particularly strong request for improving their behavior in aggressive environment and especially over long periods. The objective of this PhD work is to estimate the potentiality of a laser surface melting treatment on the improvement of the stainless steel 304L corrosion resistance, surface treatments by laser can be revisited on the basis of a recent change in the laser technology. In the frame of this work, a nano-pulsed laser fiber was chosen : it allows the treated surface to be melted for few microns in depth, followed by an ultra-fast solidification occuring with cooling rates up to 1011 K/s. The combination of these processes leads to the elimination of the surface defects, the formation (trapping) of metastable phases, the segregation of chemical elements and the growth of a new oxide layer which properties are governed by the laser parameters. To correlate these latter to the electrochemical reactivity of the surface, the influence of two laser parameters on the physico-chemical properties of the surface was studied : the laser power and the overlap of the laser impacts. To support this approach, the pitting corrosion resistance of the samples was determined by standard electrochemical tests. For specific laser parameters, the pitting potential of a 304L stainless steel was increased by more than 500 mV corresponding to an important enhancement in localized corrosion resistance in chloride environment. The interdependence of the different phenomena resulting from the laser treatment lead to a quite complex prioritization of their role on the sensibility of the 304L. However, it was demonstrated that the nature of the thermal oxide formed during the laser surface melting and the induced defects are first-order parameters for the initiation of pits. Traitement de surface Refusion de surface Laser impulsionnel nanoseconde Acier inoxydable 304L Aciers inoxydables Corrosion localisée Piqûration Couche d’oxyde Caractérisations physico-chimiques Surface treatment Laser surface melting Nano-pulsed laser Stainless steel 304L Stainless steels Localized corrosion Pitting resistance Oxide layer Physico-chemical characterizations 620.16

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