Global ETD Search

51	Potentialité de préparation de revêtements céramiques par projection plasma sous basse pression / New preparation of ceramic coatings by low-pressure plasma spray Song, Chen 25 June 2018 (has links) En tant que technologie de projection thermique avancée, la projection plasma sous basse pression (LPPS) permet d'obtenir des revêtements de haute qualité et peut combler l'écart d'épaisseur entre les technologies de projection thermique conventionnelles et les procédés de couche mince standard. En outre, LPPS permet de construire des revêtements uniformes avec diverses microstructures; le dépôt a lieu non seulement à partir des éclaboussures liquides, mais aussi à partir des amas nanométriques ainsi que de la phase vapeur en fonction des conditions opérationnelles. Afin de continuer à améliorer et à développer le procédé LPPS, cette recherche vise à le combiner avec les procédés émergents de projection plasma en suspension et de projection plasma réactif. Il devait à la fois fournir deux nouveaux processus intégrés et réaliser des revêtements à structure fine avec des microstructures uniques et des performances élevées.Une torche à plasma bi-cathode (laboratoire LERMPS, UTBM, France) à mode d'injection axiale a été conçue et construite pour le LPPS, dont la puissance maximale en entrée du plasma a pu atteindre 80 kW. En utilisant cette nouvelle torche, soit la suspension à très fines particules, soit les poudres micrométriques ont pu être injectées dans le centre du plasma à basse pression. En conséquence, le transfert de chaleur et de masse entre le jet de plasma et les matériaux pulvérisés a été amélioré.La torche à plasma bi-cathode axiale a été appliquée d'abord pour pulvériser deux types de charges de YSZ, y compris la suspension de YSZ et les poudres agglomérées de YSZ. Les résultats ont indiqué que tous les revêtements YSZ présentaient des structures relativement denses en raison de la grande vitesse des particules sous faibles pressions. Les revêtements ont été composés des particules fondues, des particules agglomérées ainsi que du dépôt en phase vapeur. Il a été constaté que le degré de vaporisation de YSZ a été augmenté en utilisant une taille de particule plus fine, une pression ambiante plus basse, une distance de pulvérisation plus longue et une puissance de plasma plus élevée. En outre, tous les revêtements YSZ ont subi une transformation de phase significative d'une phase monoclinique à une phase tétragonale, et le degré de transformation était proportionnel au degré de vaporisation. Cependant, les propriétés mécaniques des revêtements résultants ont des comportements opposés. Les revêtements YSZ préparés à partir des particules agglomérées, qui avaient une plus grande taille de gouttelettes et moins de dépôt en phase vapeur, présentaient une dureté et un module de Young plus élevés que les revêtements YSZ fabriqués à partir d'une suspension fine.Une autre torche à plasma à haute énergie O3CP (Oerlikon Metco, Suisse) a été utilisée pour synthétiser in situ les revêtements de TiN sur des alliages de Ti-6Al-4V par projection de plasma réactive à très basse pression. Les poudres de Ti pur ont été pulvérisées dans une atmosphère de N2 sous une puissance de plasma d'entrée de 120 kW. Les revêtements TiN hybrides structurés ont été synthétisés, ce qui n'était pas le cas auparavant avec d'autres procédés de projection thermique. Il est connu que la réaction de nitruration se produisait non seulement dans le jet de plasma mais aussi sur le substrat. De plus, avec l'augmentation de la distance de pulvérisation, l'effet de nitruration a été affaibli et la structure hybride du revêtement de TiN a changé de laminaire dense en colonne poreuse, en function du degré de vaporisation supérieur, de la concentration de réactive inférieure et du substrat plus froid.. Néanmoins, ils ont également permis d'améliorer les propriétés mécaniques du substrat Ti-6Al-4V. / As an advanced thermal spray technology, low-pressure plasma spray (LPPS) allows obtaining high-quality coatings and can bridge the thickness gap between conventional thermal spray technologies and standard thin film processes. Moreover, LPPS permits to build uniform coatings with various microstructures; deposition takes place not only from liquid splats but also from nano-sized clusters as well as from the vapor phase depending on operational conditions. In order to further improve and develop the LPPS process, this research aims to combine it with the emerging suspension plasma spray and reactive plasma spray processes. It was expected to both provide two novel integrated processes and achieve fine-structured coatings with unique microstructures and high performance.A bi-cathode plasma torch (LERMPS lab, UTBM, France) with an axial injection mode was designed and built for LPPS, whose maximum input plasma power was able to reach to 80 kW. By using this new torch, either the very fine-particle suspension or the micro-sized powders was able to be injected into the plasma center under low pressures. As a result, the heat and mass transfer between the plasma jet and the sprayed materials were enhanced.The axial bi-cathode plasma torch was applied firstly to spray two kinds of YSZ feedstocks, including the YSZ suspension and the YSZ agglomerated powders. The results indicated that all the YSZ coatings exhibited relatively dense structures due to the high velocity of particles under low pressures. The coatings were composed of the melted particles, the agglomerated particles as well as the vapor deposition. It was found that the vaporization degree of YSZ was increased by using smaller particle size, lower ambient pressure, longer spraying distance and higher plasma power. In addition, all the YSZ coatings undergone a significant phase transformation from a monoclinic phase to a tetragonal phase, and the transformation degree was proportional to the vaporization degree. However, the mechanical properties of the resulting coatings had the opposite behaviors. The YSZ coatings prepared from the agglomerated particles, which had a bigger droplet size and less vapor deposition, showed a higher hardness and Young's modulus than the YSZ coatings fabricated from fine suspension did.Another high-energy plasma torch O3CP (Oerlikon Metco, Switzerland) was employed to in-situ synthesize the TiN coatings on Ti-6Al-4V alloys by reactive plasma spray under very low pressure. The pure Ti powders were sprayed into an N2 atmosphere under an input plasma power of 120 kW. The hybrid structured TiN coatings were synthesized, which was not previously achieved with other thermal spraying processes. It was known that the nitriding reaction occurred not only in the plasma jet but also on the substrate. Additionally, with increasing spraying distance, the nitriding effect was weakened, and the hybrid structure of TiN coating changed from dense laminar to porous columnar, according to the higher vaporization degree, lower reactant concentration and colder substrate. Nevertheless, they also were able to improve the mechanical properties of the Ti-6Al-4V substrate. Torche à plasma bi-Cathode axiale Revêtement de nitrure de titane Suspension plasma spray at low pressure Reactive plasma spray at low pressure Axial bi-Cathode plasma torch Yttria-Stabilized zirconia coating Titanium nitride coating 530.4
52	An Experimental Study of Submerged Entry Nozzles (SEN) Focusing on Decarburization and Clogging Memarpour, Arashk January 2011 (has links) The submerged entry nozzle (SEN) is used to transport the molten steel from a tundish to a mould. The main purpose of its usage is to prevent oxygen and nitrogen pick-up by molten steel from the gas. Furthermore, to achieve the desired flow conditions in the mould. Therefore, the SEN can be considered as a vital factor for a stable casting process and the steel quality. In addition, the steelmaking processes occur at high temperatures around 1873 K, so the interaction between the refractory materials of the SEN and molten steel is unavoidable. Therefore, the knowledge of the SEN behaviors during preheating and casting processes is necessary for the design of the steelmaking processes The internal surfaces of modern SENs are coated with a glass/silicon powder layer to prevent the SEN graphite oxidation during preheating. The effects of the interaction between the coating layer and the SEN base refractory materials on clogging were studied. A large number of accretion samples formed inside alumina-graphite clogged SENs were examined using FEG-SEM-EDS and Feature analysis. The internal coated SENs were used for continuous casting of stainless steel grades alloyed with Rare Earth Metals (REM). The post-mortem study results clearly revealed the formation of a multi-layer accretion. A harmful effect of the SENs decarburization on the accretion thickness was also indicated. In addition, the results indicated a penetration of the formed alkaline-rich glaze into the alumina-graphite base refractory. More specifically, the alkaline-rich glaze reacts with graphite to form a carbon monoxide gas. Thereafter, dissociation of CO at the interface between SEN and molten metal takes place. This leads to reoxidation of dissolved alloying elements such as REM (Rare Earth Metal). This reoxidation forms the “In Situ” REM oxides at the interface between the SEN and the REM alloyed molten steel. Also, the interaction of the penetrated glaze with alumina in the SEN base refractory materials leads to the formation of a high-viscous alumina-rich glaze during the SEN preheating process. This, in turn, creates a very uneven surface at the SEN internal surface. Furthermore, these uneven areas react with dissolved REM in molten steel to form REM aluminates, REM silicates and REM alumina-silicates. The formation of the large “in-situ” REM oxides and the reaction of the REM alloying elements with the previously mentioned SEN´s uneven areas may provide a large REM-rich surface in contact with the primary inclusions in molten steel. This may facilitate the attraction and agglomeration of the primary REM oxide inclusions on the SEN internal surface and thereafter the clogging. The study revealed the disadvantages of the glass/silicon powder coating applications and the SEN decarburization. The decarburization behaviors of Al2O3-C, ZrO2-C and MgO-C refractory materials from a commercial Submerged Entry Nozzle (SEN), were also investigated for different gas atmospheres consisting of CO2, O2 and Ar. The gas ratio values were kept the same as it is in a propane combustion flue gas at different Air-Fuel-Ratio (AFR) values for both Air-Fuel and Oxygen-Fuel combustion systems. Laboratory experiments were carried out under nonisothermal conditions followed by isothermal heating. The decarburization ratio (α) values of all three refractory types were determined by measuring the real time weight losses of the samples. The results showed the higher decarburization ratio (α) values increasing for MgO-C refractory when changing the Air-Fuel combustion to Oxygen-Fuel combustion at the same AFR value. It substantiates the SEN preheating advantage at higher temperatures for shorter holding times compared to heating at lower temperatures during longer holding times for Al2O3-C samples. Diffusion models were proposed for estimation of the decarburization rate of an Al2O3-C refractory in the SEN. Two different methods were studied to prevent the SEN decarburization during preheating: The effect of an ZrSi2 antioxidant and the coexistence of an antioxidant additive and a (4B2O3 ·BaO) glass powder on carbon oxidation for non-isothermal and isothermal heating conditions in a controlled atmosphere. The coexistence of 8 wt% ZrSi2 and 15 wt% (4B2O3 ·BaO) glass powder of the total alumina-graphite refractory base materials, presented the most effective resistance to carbon oxidation. The 121% volume expansion due to the Zircon formation during heating and filling up the open pores by a (4B2O3 ·BaO) glaze during the green body sintering led to an excellent carbon oxidation resistance. The effects of the plasma spray-PVD coating of the Yttria Stabilized Zirconia (YSZ) powder on the carbon oxidation of the Al2O3-C coated samples were investigated. Trials were performed at non-isothermal heating conditions in a controlled atmosphere. Also, the applied temperature profile for the laboratory trials were defined based on the industrial preheating trials. The controlled atmospheres consisted of CO2, O2 and Ar. The thicknesses of the decarburized layers were measured and examined using light optic microscopy, FEG-SEM and EDS. A 250-290 μm YSZ coating is suggested to be an appropriate coating, as it provides both an even surface as well as prevention of the decarburization even during heating in air. In addition, the interactions between the YSZ coated alumina-graphite refractory base materials in contact with a cerium alloyed molten stainless steel were surveyed. The YSZ coating provided a total prevention of the alumina reduction by cerium. Therefore, the prevention of the first clogging product formed on the surface of the SEN refractory base materials. Therefore, the YSZ plasma-PVD coating can be recommended for coating of the hot surface of the commercial SENs. / <p>QC 20111014</p> Refractory SEN Clogging REM Coating glaze alkaline Post- Mortem industrial preheating ZrSi2 Graphite Alumina Oxidation Al2O3-C ZrO2-C MgO-C decarburization reaction mechanism Yttria Stabilized Zirconia plasma spray-PVD coating
53	Simulation numérique de dépôts céramiques plasma / Numerical simulation of ceramic plasma spray coating Sarret, Frédéric 18 June 2014 (has links) Cette thèse apporte une contribution à la simulation numérique de la construction de dépôts dans le cadre de la projection plasma type APS (Atmospheric Plasma Spraying). Ce travail est focalisé sur la construction d’un volume représentatif du revêtement en prenant en compte l’ensemble des phénomènes propres au procédé, tels que la nature de l’écoulement de gaz, la cinétique (multiphasique, mouillabilité) et la thermique (transferts thermiques, résistance thermique de contact, solidification) durant l’impact et l’empilement de particules. Une méthode numérique particulière, appelée VOF-SM (Volume Of Fluid - Sub Mesh), est développée. La simulation de l’impact d’un jet instationnaire et turbulent de plasma ArH2 sur un substrat a été réalisée pour définir la nature de l’écoulementen proche paroi et le transfert thermique entre cet écoulement et le substrat. Les phénomènes propres à l’impact de particules ont été intégrés au code de calcul Thétiset validés indépendamment par comparaison à des solutions analytiques et combinés par comparaison à un cas d’étude expérimentale millimétrique. Enfin, une étude d’impacts successifs de particules de Zircone Yttriée sur un substrat en acier a été menée, par une approche en similitudes thermique et cinétique pour pallier la difficulté de la résolution à petites échelles. / This PhD thesis is a contribution to the numerical simulation of the plasma sprayedcoating build-up by APS process (Atmospheric Plasma Spraying). This work focuses onthe build-up of a representative volume of the coat considering a great range of phenomenonappearing in APS process such as gas flow properties, kinetic (multiphase flow,wettability) and thermal (heat transfers, thermal contact resistance, solidification) duringthe impact and steaking of particles. An original numerical method, named VOF-SM(Volume Of Fluid - Sub Mesh) is developped. The simulation of the impact of an unsteadyand turbulent ArH2 plasma flow is carried out in order to define the gas flow closeto the wall and heat transferred to the substrate by the plasma. Specific phenomena of theimpact of particles were incorporated into the CFD code (Thétis) and validated independentlyby caparison with analytical solutions, then together combined by the comparisonto a millimeter size impact experimental data. Finally, a study of successive impacts ofYttria-Stabilized Zirconia particles onto a steel substrate was carried out by thermal andkinetic approach similarities to overcome the difficulty of resolving small scales. Projection plasma Dépôt Impact de particule Écoulement multi-phasique Transferts thermiques Solidification Turbulence Méthode VOF-SM Plasma spray Coating Particle impact Multiphase flow Heat transfers Solidification Turbulence VOF-SM method
54	Etude de la projection plasma sous très faible pression - torches et procédé de dépôt / Study of thermal spray for plasma torch under cery low pressure Zhu, Lin 06 December 2011 (has links) Au cours de la dernière décennie, la technologie de projection à la torche à plasmasous très faible pression (VLPPS) (inférieure à 10 mbar) a attiré l’attention denombreux chercheurs car ce procédé permet d’envisager la possibilité de réaliser desdépôts de structure voisine de celle des dépôts en phase vapeur avec une cinétiqueproche de celle de la projection thermique classique. Cette technologie vise donc àévaporer totalement ou partiellement des poudres afin de déposer des revêtementsdenses avec une structure colonnaire ou mixte.Le travail effectué dans cette étude à consisté à étudier et à développer des moyenspour assurer la fusion et l’évaporation de matériaux céramiques en vue d’élaborer desrevêtements de haute qualité et à caractériser les propriétés de ces revêtements.Dans une première approche des dépôts denses et homogènes de zircone stabilisée àl’yttrine (YSZ) ont été obtenus sur un substrat « inox » en utilisant des torches àplasma « classiques » de type F100 et F4 sous très faible pression (1 mbar) en utilisantde façon originale un principe d’injection axiale via l’alimentation en gazplasmagènes. Un spectromètre d’émission optique a été utilisé pour analyser lespropriétés du jet de plasma et notamment apprécier le taux d’évaporation du matériau.La composition et la microstructure des dépôts ont été caractérisées par diffraction desrayons X et microscopie électronique à balayage. Les résultats ont montré que lapoudre YSZ a été partiellement évaporée et que les dépôts obtenus disposent d’unemicrostructure hybride composée de « splats » formés par des particules fondues etune « matrice » (en faible quantité) résultant de la condensation de vapeurs provenantde l’évaporation des particules surchauffées.Afin de tenter d’augmenter le taux de vaporisation, l’anode de la torche F100 a étéallongée et un dispositif d’arc transféré complémentaire a été réalisé afin d’éleverl’énergie du jet de plasma et de favoriser l’échange thermique. Les effets de cedispositif sur les propriétés du jet de plasma ont été évalués par spectrométried’émission optique et calcul de la température électronique. Des dépôts de YSZ etd’alumine (Al2O3) ont été élaborés à la pression de 1 mbar. Les dépôts de YSZ ontaffiché une microstructure hybride similaire à celle obtenue précédemment alors quepour les dépôts d’alumine, seul un dépôt lamellaire « classique » a été observé. Lacapacité d’évaporation est donc restée limitée. La microstructure, les propriétésmécaniques et les propriétés de résistance aux chocs thermiques des dépôts de YSZont été étudiées plus en détail et comparées avec celle de dépôts réalisés dans desconditions plus classiques. Une tenue améliorée en termes de résistance aux cyclagesthermiques a notamment été observée.Afin de répondre aux attentes en matière de niveau de densité de puissance du jet lelaboratoire s’est équipé d’une une nouvelle torche à plasma tri-cathode expérimentaleélaborée par la société AMT. Cette torche a été modélisée et testée dans un premiertemps en conditions atmosphériques, révélant une limitation importante du rendementde projection. A partir de ces premiers résultats expérimentaux une nouvellegéométrie de buse a été proposée afin d’améliorer le rendement de projection. Il aalors été constaté que le rendement de la projection avait été considérablementaugmenté par cette modification et que la microstructure du dépôt était également plusfavorable. Ce travail devra maintenant se poursuivre par l’intégration de cette torche dans l’enceinte sous pression réduite. / During the last decade, very low pressure plasma spraying (VLPPS) technology(below 10 mbar) attracted attention because it could allow to produce coatings with astructure similar to that of vapor deposited materials (PVD) with kinetics close to thatof thermal spray. This technology aims to fully or partially evaporate the feedstockmaterials in order to build rapidly dense, thin, and columnar coatings.The work during this thesis preparation was thus devoted to the study anddevelopment of tools and techniques allowing fusion and evaporation of ceramicmaterials in order to obtain high quality deposits with new performance and then tocharacterize the properties of those deposits. In a first approach dense and homogeneous yttria-stabilized zirconia (YSZ) coatingswere deposited successfully on a stainless steel substrate using “classical” plasmaspray torches such as F100 and F4 under very low pressure (1 mbar) by means ofusing an original way of introducing the feedstock material in the core of the plasmajet via the plasma gas port. Optical emission spectroscopy was used to analyze theproperties of the plasma jet and especially to observe the feedstock materialevaporation rate. The phase composition and the microstructure of the coatings werecharacterized by X-ray diffraction and scanning electron microscopy. Results showedthat the YSZ powder was partially evaporated and that the coatings possessed aduplex microstructure which was composed of splats formed by the impingement ofmelted particles and a little amount of a matrix formed by the condensation of thevapor emitted by overheated particles.In order to try and increase the evaporation rate, a home-made transferred arc nozzlewas made and mounted on a F100 plasma torch in order to enhance the energy levelof the plasma jet and then to increase thermal exchanges. The effects of thetransferred arc nozzle on the plasma jet properties were evaluated by optical emissionspectroscopy and electron temperature calculation. YSZ and alumina (Al2O3) coatingsWere elaborated using such a nozzle below 1 mbar. It was found that the YSZ coatingsdisplayed a duplex microstructure similar to that obtained in the previous experiments.However, no vapor condensation could be observed in the case of the Al2O3 coatingsindicating that the evaporation capacity of the system remained limited.The microstructure, the mechanical properties and the thermal shock resistance of theYSZ coatings were studied in more details and compared to that of deposits madeusing classical thermal spray routes. An enhanced resistance to thermal shock couldthus be observed for the coatings with a duplex structure.In order to find a solution for a substantial increase in the energy density of theplasma jet, the laboratory commissioned a novel experimental tri-cathode plasmatorch made to the AMT Company. This new torch was modeled and first testedunder atmospheric conditions, which revealed a poor spray yield. Following thosefirst experimental results, a modified nozzle was designed. As a result, the sprayefficiency was considerably increased and the coating fabricated by the tri-cathodetorch displayed a better microstructure. Now this work has to be pursued with theintegration of this torch in the low pressure spray tank. Spectroscopie optique Revêtement de barrière thermique Torche à plasma tri-cathode Very low pressure plasma spray Optical emission spectroscopy Thermal barrier coating Tri-cathode plasma torch
55	Réalisation et caractérisation des revêtements à base de laiton. / Preparation and characterization of brass-based coatings Huang, Chunjie 30 January 2018 (has links) Le procédé Cold Spray (CS) ou projection à froid a été largement étudié en raison de son rendement de projection et de la conservation des propriétés du matériau de départ. Donc, ce procédé a montré des avantages évidents sur la fabrication de différents dépôts à base de cuivre et de ses alliages par rapport à d'autres techniques, comme l’électrodéposition, le Laser Cladding ou la projection thermique. Parmi les alliages de cuivre, le laiton s’implante dans les domaines de l'architecture ou de l'industrie. Malheureusement, aujourd’hui force est de constater qu’il n’existe que très peu de travaux sur les revêtements en laiton qui ne sont réalisés d’ailleurs que par électrodéposition et par aucune autre méthode d’élaboration limitant sérieusement leur utilisation dans de nombreuses applications.Cette thèse s’est appliquée à élaborer des revêtements de laiton et des composites à matrice laiton. La poudre d'alliage de laiton Muntz de composition Cu60Zn40, présentant une résistance à la corrosion parmi les meilleures, a été choisie comme matériau de base des revêtements. Deux méthodes de projection permettant d’éviter les phénomènes d’oxydation ont été sélectionnées : la projection à froid et la projection basse pression. La comparaison entre les deux procédés sur les microstructures, phases, textures, propriétés mécaniques, comportements à l’usure et en corrosion du revêtement Cu60Zn40 a été étudié. De plus, les recherches de ce travail ont porté sur l’optimisation du revêtement par le post-traitement de friction malaxage et par ajout de différents renforts céramiques. Les effets du post-traitement par friction malaxage sur les microstructures, phases, textures, et propriétés mécaniques et les effets des types de renfort et de leurs quantités dans les revêtements composites sur les microstructures, les phases, les propriétés mécaniques et thermiques et les comportements à la corrosion ont été analysés. Les gains de performance obtenus à la fin de cette étude sont finalement concrétisés par la réparation d’une pièce endommagée en Cu60Zn40 avec l’étude des microstructures interfaciales entre le revêtement composite Cu60Zn40 et le substrat Cu60Zn40 ainsi que la détermination des propriétés mécaniques et des comportements tribologiques. / Cold Spray (CS) has been widely investigated owing to its high deposition efficiency and retention of the properties of starting materials. Thus, this process has shown obvious advantages over the fabrication of different copper-based deposits and its alloys over other techniques, such as electroplating, Laser Cladding or thermal spraying. As one of the main copper alloys, brass is implanted in the fields of architecture or industry. Nevertheless, nowadays it is clear that there is very little work on brass coatings, and they were mainly made by electroplating and any other deposition methods, which has severely limits their uses in many applications.This study was applied to develop the brass coatings and its composites. The Muntz brass alloy powder of Cu60Zn40, which shows the best corrosion resistance, was selected to manufacture the brass coatings. Two projection methods were used, i.e. Cold Spraying and Vacuum Plasma Spraying (VPS), avoiding the oxidation. The comparison study of spraying processes on the microstructures, the phases, the textures, the mechanical properties, and the wear and corrosion behaviors of the Cu60Zn40 coatings was carried out. In addition, this work also focused on the optimization of the coatings either by applying the post-treatment of friction stir processing (FSP), or by adding different ceramic reinforcements. The effects of FSP on the microstructures, the phases, the textures and the mechanical properties of coating and the effects of reinforcement types and their amounts in composite coatings on the microstructures, the phases, the mechanical and thermal properties and the corrosion behaviors were revealed. At the end of this study, the obtained performance will ultimately be realized by repairing the damaged part of Cu60Zn40 alloy, and the studies on the interfacial microstructures between the Cu60Zn40 composite coating and the Cu60Zn40 substrate as well as the mechanical properties and the tribological behaviors between were performed. Revêtements en laiton Muntz Projection plasma sous basse pression Projection à froid Friction malaxage Résistance à la corrosion Réparation Muntz alloy coatings Vacuum plasma spray Cold spraying Friction stir processing Corrosion resistance Repairing 620.1
56	Development of Cold Gas Dynamic Spray Nozzle and Comparison of Oxidation Performance of Bond Coats for Aerospace Thermal Barrier Coatings at Temperatures of 1000°C and 1100°C Roy, Jean-Michel L. 08 February 2012 (has links) The purpose of this research work was to develop a nozzle capable of depositing dense CoNiCrAlY coatings via cold gas dynamic spray (CGDS) as well as compare the oxidation performance of bond coats manufactured by CGDS, high-velocity oxy-fuel (HVOF) and air plasma spray (APS) at temperatures of 1000°C and 1100°C. The work was divided in two sections, the design and manufacturing of a CGDS nozzle with an optimal profile for the deposition of CoNiCrAlY powders and the comparison of the oxidation performance of CoNiCrAlY bond coats. Throughout this work, it was shown that the quality of coatings deposited via CGDS can be increased by the use of a nozzle of optimal profile and that early formation of protective α-Al2O3 due to an oxidation temperature of 1100°C as opposed to 1000°C is beneficial to the overall oxidation performance of CoNiCrAlY coatings. Cold Spray APS CGDS HVOF Oxidation Thermal Barrier Coating TBC Gas Turbine Nozzle Cold Gas Dynamic Spray CoNiCrAlY MCrAlY Coating Corrosion Protection Bond Coat Air Plasma Spray High-Velocity Oxy-Fuel Aerospace 1100C 1000C
57	Development of Cold Gas Dynamic Spray Nozzle and Comparison of Oxidation Performance of Bond Coats for Aerospace Thermal Barrier Coatings at Temperatures of 1000°C and 1100°C Roy, Jean-Michel L. 08 February 2012 (has links) The purpose of this research work was to develop a nozzle capable of depositing dense CoNiCrAlY coatings via cold gas dynamic spray (CGDS) as well as compare the oxidation performance of bond coats manufactured by CGDS, high-velocity oxy-fuel (HVOF) and air plasma spray (APS) at temperatures of 1000°C and 1100°C. The work was divided in two sections, the design and manufacturing of a CGDS nozzle with an optimal profile for the deposition of CoNiCrAlY powders and the comparison of the oxidation performance of CoNiCrAlY bond coats. Throughout this work, it was shown that the quality of coatings deposited via CGDS can be increased by the use of a nozzle of optimal profile and that early formation of protective α-Al2O3 due to an oxidation temperature of 1100°C as opposed to 1000°C is beneficial to the overall oxidation performance of CoNiCrAlY coatings. Cold Spray APS CGDS HVOF Oxidation Thermal Barrier Coating TBC Gas Turbine Nozzle Cold Gas Dynamic Spray CoNiCrAlY MCrAlY Coating Corrosion Protection Bond Coat Air Plasma Spray High-Velocity Oxy-Fuel Aerospace 1100C 1000C
58	An Experimental Study of Submerged Entry Nozzles (SEN) Focusing on Decarburization and Clogging Memarpour, Arashk January 2011 (has links) The submerged entry nozzle (SEN) is used to transport the molten steel from a tundish to a mould. The main purpose of its usage is to prevent oxygen and nitrogen pick-up by molten steel from the gas. Furthermore, to achieve the desired flow conditions in the mould. Therefore, the SEN can be considered as a vital factor for a stable casting process and the steel quality. In addition, the steelmaking processes occur at high temperatures around 1873 K, so the interaction between the refractory materials of the SEN and molten steel is unavoidable. Therefore, the knowledge of the SEN behaviors during preheating and casting processes is necessary for the design of the steelmaking processes The internal surfaces of modern SENs are coated with a glass/silicon powder layer to prevent the SEN graphite oxidation during preheating. The effects of the interaction between the coating layer and the SEN base refractory materials on clogging were studied. A large number of accretion samples formed inside alumina-graphite clogged SENs were examined using FEG-SEM-EDS and Feature analysis. The internal coated SENs were used for continuous casting of stainless steel grades alloyed with Rare Earth Metals (REM). The post-mortem study results clearly revealed the formation of a multi-layer accretion. A harmful effect of the SENs decarburization on the accretion thickness was also indicated. In addition, the results indicated a penetration of the formed alkaline-rich glaze into the alumina-graphite base refractory. More specifically, the alkaline-rich glaze reacts with graphite to form a carbon monoxide gas. Thereafter, dissociation of CO at the interface between SEN and molten metal takes place. This leads to reoxidation of dissolved alloying elements such as REM (Rare Earth Metal). This reoxidation forms the “In Situ” REM oxides at the interface between the SEN and the REM alloyed molten steel. Also, the interaction of the penetrated glaze with alumina in the SEN base refractory materials leads to the formation of a high-viscous alumina-rich glaze during the SEN preheating process. This, in turn, creates a very uneven surface at the SEN internal surface. Furthermore, these uneven areas react with dissolved REM in molten steel to form REM aluminates, REM silicates and REM alumina-silicates. The formation of the large “in-situ” REM oxides and the reaction of the REM alloying elements with the previously mentioned SEN´s uneven areas may provide a large REM-rich surface in contact with the primary inclusions in molten steel. This may facilitate the attraction and agglomeration of the primary REM oxide inclusions on the SEN internal surface and thereafter the clogging. The study revealed the disadvantages of the glass/silicon powder coating applications and the SEN decarburization. The decarburization behaviors of Al2O3-C, ZrO2-C and MgO-C refractory materials from a commercial Submerged Entry Nozzle (SEN), were also investigated for different gas atmospheres consisting of CO2, O2 and Ar. The gas ratio values were kept the same as it is in a propane combustion flue gas at different Air-Fuel-Ratio (AFR) values for both Air-Fuel and Oxygen-Fuel combustion systems. Laboratory experiments were carried out under nonisothermal conditions followed by isothermal heating. The decarburization ratio (α) values of all three refractory types were determined by measuring the real time weight losses of the samples. The results showed the higher decarburization ratio (α) values increasing for MgO-C refractory when changing the Air-Fuel combustion to Oxygen-Fuel combustion at the same AFR value. It substantiates the SEN preheating advantage at higher temperatures for shorter holding times compared to heating at lower temperatures during longer holding times for Al2O3-C samples. Diffusion models were proposed for estimation of the decarburization rate of an Al2O3-C refractory in the SEN. Two different methods were studied to prevent the SEN decarburization during preheating: The effect of an ZrSi2 antioxidant and the coexistence of an antioxidant additive and a (4B2O3 ·BaO) glass powder on carbon oxidation for non-isothermal and isothermal heating conditions in a controlled atmosphere. The coexistence of 8 wt% ZrSi2 and 15 wt% (4B2O3 ·BaO) glass powder of the total alumina-graphite refractory base materials, presented the most effective resistance to carbon oxidation. The 121% volume expansion due to the Zircon formation during heating and filling up the open pores by a (4B2O3 ·BaO) glaze during the green body sintering led to an excellent carbon oxidation resistance. The effects of the plasma spray-PVD coating of the Yttria Stabilized Zirconia (YSZ) powder on the carbon oxidation of the Al2O3-C coated samples were investigated. Trials were performed at non-isothermal heating conditions in a controlled atmosphere. Also, the applied temperature profile for the laboratory trials were defined based on the industrial preheating trials. The controlled atmospheres consisted of CO2, O2 and Ar. The thicknesses of the decarburized layers were measured and examined using light optic microscopy, FEG-SEM and EDS. A 250-290 μm YSZ coating is suggested to be an appropriate coating, as it provides both an even surface as well as prevention of the decarburization even during heating in air. In addition, the interactions between the YSZ coated alumina-graphite refractory base materials in contact with a cerium alloyed molten stainless steel were surveyed. The YSZ coating provided a total prevention of the alumina reduction by cerium. Therefore, the prevention of the first clogging product formed on the surface of the SEN refractory base materials. Therefore, the YSZ plasma-PVD coating can be recommended for coating of the hot surface of the commercial SENs. Refractory SEN Clogging REM Coating glaze alkaline Post- Mortem industrial preheating ZrSi2 Graphite Alumina Oxidation Al2O3-C ZrO2-C MgO-C decarburization reaction mechanism Yttria Stabilized Zirconia plasma spray-PVD coating
59	Development of Cold Gas Dynamic Spray Nozzle and Comparison of Oxidation Performance of Bond Coats for Aerospace Thermal Barrier Coatings at Temperatures of 1000°C and 1100°C Roy, Jean-Michel L. 08 February 2012 (has links) The purpose of this research work was to develop a nozzle capable of depositing dense CoNiCrAlY coatings via cold gas dynamic spray (CGDS) as well as compare the oxidation performance of bond coats manufactured by CGDS, high-velocity oxy-fuel (HVOF) and air plasma spray (APS) at temperatures of 1000°C and 1100°C. The work was divided in two sections, the design and manufacturing of a CGDS nozzle with an optimal profile for the deposition of CoNiCrAlY powders and the comparison of the oxidation performance of CoNiCrAlY bond coats. Throughout this work, it was shown that the quality of coatings deposited via CGDS can be increased by the use of a nozzle of optimal profile and that early formation of protective α-Al2O3 due to an oxidation temperature of 1100°C as opposed to 1000°C is beneficial to the overall oxidation performance of CoNiCrAlY coatings. Cold Spray APS CGDS HVOF Oxidation Thermal Barrier Coating TBC Gas Turbine Nozzle Cold Gas Dynamic Spray CoNiCrAlY MCrAlY Coating Corrosion Protection Bond Coat Air Plasma Spray High-Velocity Oxy-Fuel Aerospace 1100C 1000C
60	Development of Cold Gas Dynamic Spray Nozzle and Comparison of Oxidation Performance of Bond Coats for Aerospace Thermal Barrier Coatings at Temperatures of 1000°C and 1100°C Roy, Jean-Michel L. January 2012 (has links) The purpose of this research work was to develop a nozzle capable of depositing dense CoNiCrAlY coatings via cold gas dynamic spray (CGDS) as well as compare the oxidation performance of bond coats manufactured by CGDS, high-velocity oxy-fuel (HVOF) and air plasma spray (APS) at temperatures of 1000°C and 1100°C. The work was divided in two sections, the design and manufacturing of a CGDS nozzle with an optimal profile for the deposition of CoNiCrAlY powders and the comparison of the oxidation performance of CoNiCrAlY bond coats. Throughout this work, it was shown that the quality of coatings deposited via CGDS can be increased by the use of a nozzle of optimal profile and that early formation of protective α-Al2O3 due to an oxidation temperature of 1100°C as opposed to 1000°C is beneficial to the overall oxidation performance of CoNiCrAlY coatings. Cold Spray APS CGDS HVOF Oxidation Thermal Barrier Coating TBC Gas Turbine Nozzle Cold Gas Dynamic Spray CoNiCrAlY MCrAlY Coating Corrosion Protection Bond Coat Air Plasma Spray High-Velocity Oxy-Fuel Aerospace 1100C 1000C

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