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51	Processamento e caracterização de rotores automotivos da superliga MAR-M247 / Processing and characterization of nickel based superalloy MARM247 turbine wheels Renato Baldan 13 April 2009 (has links) A superliga policristalina à base de níquel MAR-M247 foi desenvolvida na década de 70. Sua ótima composição, estabilidade microestrutural, excelente resistência à fluência e à oxidação e boa resistência à corrosão a quente faz dessa superliga uma das mais utilizadas em rotores durante os últimos 20 anos. Os objetivos do presente trabalho são a produção e caracterização microestrutural e mecânica de rotores da superliga MARM247 (10% peso Co, 10W, 8.25Cr, 5.5Al, 3Ta, 1.5Hf, 1Ti, 0.7Mo, 0.15C, 0.05Zr, 0.015B, Ni balanço). Os rotores foram obtidos pela técnica de microfusão por cera perdida na empresa Açotécnica S.A. (Jandira/SP) em diferentes temperaturas de vazamento e isolamento do molde cerâmico. Os materiais foram analisados por microscopia ótica e eletrônica de varredura (MEV/EDS), análise térmica diferencial (DTA), macro/microdureza e ensaios de tração convencional a 25oC e a 760oC. Além disso, os materiais passaram por tratamentos térmicos de solubilização e envelhecimento em diferentes temperaturas e tempos a fim de avaliar as mudanças microestruturais. Com a ajuda do software de cálculo termodinâmico Thermocalc foram feitas simulações das relações de fases utilizando a composição média da superliga MAR-M247. Os resultados permitiram obter uma condição de processamento (temperatura de vazamento e condição de isolamento) com maior quantidade de peças sem defeitos. Além disso, os experimentos permitiram definir uma condição ideal para o tratamento térmico de solubilização da superliga MAR-M247. / The polycrystalline nickel-based superalloy MAR-M247 was developed in the 1970s. Its optimal alloy composition, microstructural stability, excellent resistance to creep and oxidation and good resistance to hot corrosion make the MAR-M247 superalloy one of the alloys widely used in turbine rotors during the last 20 years. The aims of the present work are the production and the microstructural and mechanical characterization of rotors made of MAR-M247 superalloy (10 wt. % Co, 10W, 8.25Cr, 5.5Al, 3Ta, 1.5Hf, 1Ti, 0.7Mo, 0.15C, 0.05Zr, 0.015B, Ni balance). The rotors were produced by using the lost-wax technique at different pouring temperatures and isolation of the shell mold at the Açotécnica S.A. company (Jandira/SP). The materials were analyzed by optical and scanning electron microscopy (SEM/EDS), differential thermal analysis (DTA), macro/microhardness and tensile tests at 25oC and 760oC. Besides, the materials were submitted to solution and ageing treatments at different temperatures and times in order to evaluate de microstructural changes. With the aid of the thermodynamic calculation software Thermocalc, simulations of phase relations were made using the average composition of the MAR-M247 superalloy. The results allowed to obtain a processing condition (pouring temperature and isolation condition) with larger amount of rotors without defects. Moreover, the experiments allowed to define an ideal solution heat treatment condition of MAR-M247 superalloy. Fundição por cera perdida MAR-M247 Superligas de níquel Thermocalc Tratamento térmico MAR-M247 Investment casting MAR-M247 MAR-M247 heat treatment nickel based superalloys Thermocalc
52	Simulação termodinâmica e caracterização da superliga a base de níquel Inconel 713LC / Thermodynamic simulation and microstructural characterization of a nickel based superalloy Inconel 713LC Alvaro Guilherme Junqueira dos Santos 09 March 2012 (has links) O uso do cálculo termodinâmico e consequentemente base de dados desenvolvidas para esse propósito é hoje uma das ferramentas fundamentais para o aprimoramento e desenvolvimento de superligas a base de níquel. A proposta deste trabalho foi avaliar a confiabilidade de uma base de dados comercial, específica para superligas a base de níquel, utilizada em softwares de cálculos termodinâmicos computacionais. Comparou-se os dados experimentais da superliga Inconel 713LC com informações obtidas através do calculo termodinâmico para a composição química específica da superliga estudada. As amostras da superliga comercial Inconel 713LC foram retiradas de barras da liga fundida a vácuo (VIM). Os tratamentos térmicos foram realizados sob atmosfera de argônio em cápsulas de quartzo nas temperaturas de 600?C, 900?C e 1250 ?C nos tempos de 10h, 24h, 50h, 100h, 250h, 500h, 1000h e 2000 horas, de acordo com a temperatura de tratamento utilizada, visando acompanhar o desenvolvimento microestrutural até alcançar a condição de equilíbrio termodinâmico. Previamente, a amostra no estado bruto de fusão e as amostras após os tratamentos de equilíbrio foram caracterizadas microestruturalmente via microscopia eletrônica de varredura (MEV) e a composição das fases medidas por microanálise de energia dispersiva (EDS). As temperaturas das transformações de fases foram medidas por analise térmica diferencial (DTA). Nas amostras também foram realizadas medidas de microdureza para acompanhar indiretamente a evolução microestrutural da fase gama prime. Para os cálculos termodinâmicos foram utilizados o software Thermo-Calc® e a base de dados TTNi8 da empresa Thermotech Ltd®. / The computational thermodynamic simulation and the databases designed for this purpose are today one the most important tools to develop new nickel based superalloys. The aim of this work was to check the reliability of a commercial database, designed specifically for Ni-based superalloys. The experimental phase diagram data of Inconel 713LC, such as, liquidus and solidus temperatures as well as chemical phase compositions were compared with thermodynamic information extracted from computational simulations. Samples of a commercial superalloy Inconel 713LC were extracted from an ingot produced by Vacuum Induction Melting (VIM) and heat treated under argon in quartz capsules at 600?C, 900 ?C and 1250?C for 10h, 24h, 50h, 100h, 250h, 500h, 1000h and 2000h, according to the treatment temperature used, aiming at reaching the thermodynamic equilibrium conditions. The as-cast and all heat-treated samples were characterized by Scanning Electron Microscopy (SEM) and the chemical compositions of the phases were measured via Energy Dispersive X-ray Spectroscopy (EDS). Temperatures of phase transformations were determined by Differential Thermal Analysis (DTA). Microhardness measurements were performed to indirectly follow the microstructural evolution of gamma prime. The Thermo-Calc® software and the TTNi8 database from Thermotech Ltd® were used for thermodynamic calculations. Diagrama de Fase Inconel 713LC Superligas Termodinâmica computacional Thermo-Calc Tratamento térmico TTNi8 computational thermodynamic heat treatment Inconel 713LC nickel based superalloy phase diagram Thermo-Calc TTNi8
53	Influence de l'eau (vapeur, liquide) et du régime d'oxydation sur la dégradation de revêtements alumino-formeurs sur superalliage à base nickel / Influence of water (vapour, liquid) and of the oxidation regime on the high temperature degradation of alumina-forming coatings on Ni-based superalloys Brossard, Maxime 29 September 2014 (has links) En service, les matériaux constituant les aubes de turbine aéronautique (superalliages à base nickel) sont soumis à des environnements agressifs susceptibles d’altérer leurs propriétés structurales. Les atmosphères oxydantes impliquées sont en général complexes (O2, H2O, CO2, SO2, NOx…), la quantité d’eau présente pouvant en particulier varier selon le régime moteur et les conditions environnantes (nuages, précipitations, humidité de l’air). Pour apporter une protection contre l’oxydation à haute température, on met en œuvre des revêtements alumino-formeurs sur lesquels une barrière thermique peut, de plus, être déposée. Le présent travail se proposait donc d’étudier l’influence de l’eau, sous forme vapeur et/ou liquide, sur le comportement de revêtements alumino-formeurs de référence, ou développés au LaSIE (barbotine d’aluminium, électrodéposition de CeO2), selon différents régimes d’oxydation (isotherme et cyclique). Afin de se rapprocher des conditions en service, une démarche scientifique originale a été proposée avec la mise en œuvre de conditions de vieillissement et post-vieillissement variées, à haute température, lors des phases de refroidissement, ou encore à température ambiante. Les expériences menées ont montré qu’une introduction de vapeur d’eau n’a que peu d’effet en régime isotherme à 1100°C, notamment lorsqu’une couche d’alumine alpha s’est développée en surface. L’ajout d’eau à froid (humidité relative,gouttes d’eau) accroît l’écaillage des couches d’oxydes, au-delà d’un temps d’oxydation critique, alors que l’apport d’eau lors de la phase de refroidissement des cycles thermiques conduit à une dégradation catastrophique des aluminures de nickel par un mécanisme combinant fatigue thermique et piqûration. / Upon service, aero-turbine blades (nickel-based superalloys) are submitted to high temperature degradation that may alter their structural properties. The oxidizing atmospheres are particularly complex (O2, H2O, CO2, SO2, NOx…) with variable water vapour contents as function of the engine regime and the atmospheric conditions (clouds, rain, relative humidity of air). These substrate materials are protected by alumina-forming coatings to improve their oxidation resistance, while additional thermal barrier coatings insulate the hottest parts. This PhD project aims at studying the effect of water (vapour, liquid) on the degradation of conventional and new coatings (Al slurry, electrodeposited CeO2) developed at the LaSIE laboratory under different oxidation regimes (isothermal and cyclic). An approximation to service conditions was proposed through an original methodology in which several oxidation and post-ageing conditions for different oxidation ranges (hot, upon cooling, at room temperature) were performed. The experiments showed little effect of water vapour mixed with air at 1100°C in isothermal conditions, in particular when the alumina scale grew over the surface. In contrast, water-containing environments at room temperature (relative humidity, water drops) increased the spallation of the oxide scales above a critical threshold time. Cyclic oxidation with water cooling provoked in turn, a catastrophic failure of the aluminide coatings by a mechanism involving thermal fatigue and pitting corrosion. Eau Vapeur d'eau Oxydation à haute température Revêtements alumino-formeurs Superalliages à base nickel Water Water vapour High temperature oxidation Alumina-forming coatings Nickel-based superalloys
54	Dissolution sélective de produits de corrosion et revêtements sur matériaux de turbine aéronautique par méthodes électrochimiques / Selective dissolution of corrosion products and coatings from aero-turbine materials by electrochemical methods Le Guevel, Yves 11 February 2016 (has links) Les superalliages à base nickel des turbines aéronautiques sont susceptibles de subir des phénomènes de corrosion et/ou d’oxydation à haute température par les environnements agressifs rencontrés en service. Aussi, des revêtements d’aluminure sont appliqués par dépôt chimique afin d’assurer la protection des pièces contre ces phénomènes. La dégradation progressive de ces revêtements mène à la nécessité de les enlever afin d’en appliquer des nouveaux. Les bains chimiques industriels pour enlever les revêtements et les oxydes sont très toxiques, polluants et plutôt empiriques. Ainsi, ce travail de thèse se proposait d’étudier une méthode alternative et originale, par voie électrochimique permettant de contrer les limitations des approches chimiques. La voie électrochimique par application d’un potentiel (mode potentiostatique) a été étudiée afin de procurer la sélectivité entre le substrat et le revêtement lors de la dissolution, ainsi que le contrôle in-situ du procédé à l’aide d’une cellule à 3 électrodes. La faisabilité de la méthode a d’abord été démontrée, puis différentes procédures (par cycles cathodique/anodique, en continu et, parfois, avec modification du potentiel imposé) ont été développées. Nous avons pu mettre en relation les états métallurgiques des systèmes revêtement/substrat avec leur comportement électrochimique et avons mis également en lumière que le taux de dissolution est principalement gouverné par la concentration d’aluminium dans le revêtement alors que lorsque le platine est incorporé à ce même revêtement, le taux de dissolution est homogène. De même, nous avons démontré par XPS et par MET que la teneur en chrome modifie de manière significative l’homogénéité du décapage lors des phases de polarisation cathodique par un mécanisme de passivation de la surface, qui bloque l’activité électrochimique. Cependant, la tenue en oxydation cyclique des revêtements décapés par voies chimique et électrochimique n’a pas pu véritablement être démontrée car les revêtements avaient une microstructure différente. Enfin, des essais sur pièces de turbine ont montré le haut degré de sélectivité de l’approche ici étudiée. / Nickel based superalloys of aeronautical turbines are subjected to high temperature oxidation and/or corrosion in service conditions. Thus, protective aluminide coatings are applied onto the parts by chemical vapor deposition. The degradation of the coatings with time requires them to be removed prior to recoating the parts. The chemical baths industrially employed are toxic, polluting and quite empirical. Therefore, this thesis aimed at studying an alternative and original electrochemical method to circumvent the drawbacks of the chemical approach. Fixed potentials (potentiostatic mode) were thus applied to provide selectivity between the coating and the substrate upon the dissolution process, as well as to ensure in-situ control through a 3-electrode cell. The feasibility of the method was first demonstrated, then different procedures (cathodic/anodic cycles; continuous anodic and sometimes with modification of the potential) were investigated. The correlations between the metallurgical phases of the coating/substrate systems were elucidated. It also appeared that dissolution is mainly governed by the concentration of aluminium in the coating whereas the incorporation of platinum to the coating brought about the homogeneous dissolution. In addition, XPS and MET confirmed the hypothesis by which the chromium content drastically change the stripping homogeneity upon the cathodic polarization step by passivation of the surface and the subsequent electrochemical blocking. However, the results on the cyclic oxidation behaviour of the coatings priorly stripped chemically or electrochemically were not conclusive enough as the microstructure of the original coatings was different. Finally, quite a few stripping trials were carried out onto real turbine parts that confirmed the high selectivity of the electrochemical approach studied. Décapage électrochimique Superalliages base nickel Revêtements d’aluminure de nickel Corrosion haute température Electrochemical stripping Nickel based superalloys Nickel aluminide coatings High temperature corrosion Correlations electrochemistry-metallurgy
55	Processability of Laser Powder Bed Fusion of Alloy 247LC : Influence of process parameters on microstructure and defects Adegoke, Olutayo January 2020 (has links) This thesis is about laser powder bed fusion (L-PBF) of the nickel-based superalloy: Alloy 247LC. Alloy 247LC is used mainly in gas turbine blades and processing the blades with L-PBF confers performance advantage over the blades manufactured with conventional methods. This is mainly because L-PBF is more suitable, than conventional methods, for manufacturing the complex cooling holes in the blades. The research was motivated by the need for academia and industry to gain knowledge about the processability of the alloy using L-PBF. The knowledge is essential in order to eventually solve the problem of cracking which is a major problem when manufacturing the alloy. In addition, dense parts with low void content should be manufactured and the parts should meet the required performance. Thus, the thesis answered some of the important questions related to process parameter-microstructure-defect relationships. The thesis presented an introduction in chapter 1. A literature review was made in chapter 2 to 4. In chapter 2, the topic of additive manufacturing was introduced followed by an overview of laser powder bed fusion. Chapter 3 focused on superalloys. Here, a review was made from the broader perspective of superalloys but was eventually narrowed down to the characteristics of nickelbased superalloys and finally Alloy 247LC. Chapter 4 reviewed the main research on L-PBF of Alloy 247LC. The methodology applied in the thesis was discussed in chapter 5. The thesis applied statistical design of experiments to show the influence of process parameters on the defects and microstructure, so a detail description of the method was warranted. This was given at the beginning of chapter 5 and followed by the description of the L-PBF manufacturing and the characterization methods. The main results and discussions, in chapter 6, included a preliminary investigation on how the process parameters influenced the amount of discontinuity in single track samples. This was followed by the results and discussions on the investigation of voids, cracks and microhardness in cube samples (detail presentation was given in the attached paper B). Finally, the thesis presented results of the microstructure obtainable in L-PBF manufactured Alloy 247LC. The initial results of the microstructure investigation were presented in paper A. Bearbetnings-, yt- och fogningsteknik
56	UNIFIED SECONDARY AND TERTIARY CREEP MODELING OF ADDITIVELY MANUFACTURED NICKEL-BASED SUPERALLOYS Harshal Ghanshy Dhamade (11002041) 05 August 2021 (has links) <div>Additively manufactured (AM) metals have been increasingly fabricated for structural applications. However, a major hurdle preventing their extensive application is lack of understanding of their mechanical properties. To address this issue, the objective of this research is to develop a computational model to simulate the creep behavior of nickel alloy 718 manufactured using the laser powder bed fusion (L-PBF) additive manufacturing process. A finite element (FE) model with a subroutine is created for simulating the creep mechanism for 3D printed nickel alloy 718 components.</div><div><br></div><div>A continuum damage mechanics (CDM) approach is employed by implementing a user defined subroutine formulated to accurately capture the creep mechanisms. Using a calibration code, the material constants are determined. The secondary creep and damage constants are derived using the parameter fitting on the experimental data found in literature. The developed FE model is capable to predict the creep deformation, damage evolution, and creep-rupture life. Creep damage and rupture is simulated as defined by the CDM theory.</div><div>The predicted results from the CDM model compare well with experimental data, which are collected from literature for L-PBF manufactured nickel alloy 718 of creep deformation and creep rupture, at different levels of temperature and stress. </div><div><br></div><div>Using the multi-regime Liu-Murakami (L-M) and Kachanov-Rabotnov (K-R) isotropic creep damage formulation, creep deformation and rupture tests of both the secondary and tertiary creep behaviors are modeled.</div><div>A single element FE model is used to validate the model constants. The model shows good agreement with the traditionally wrought manufactured 316 stainless steel and nickel alloy 718 experimental data collected from the literature. Moreover, a full-scale axisymmetric FE model is used to simulate the creep test and the capacity of the model to predict necking, creep damage, and creep-rupture life for L-PBF manufactured nickel alloy 718. The model predictions are then compared to the experimental creep data, with satisfactory agreement.</div><div><br></div><div>In summary, the model developed in this work can reliably predict the creep behavior for 3D printed metals under uniaxial tensile and high temperature conditions.</div> Mechanical Engineering Creep Modeling Additive Manufacturing Nickel-Based Superalloys Secondary and Tertiary Creep Finite element modeling (FEM) 3D Printed Metals Continuum Damage Mechanics (CDM)
57	Alloy Design and Characterization of γ′ Strengthened Nickel-based Superalloys for Additive Manufacturing Xu, Jinghao January 2021 (has links) Nickel-based superalloys, an alloy system bases on nickel as the matrix element with the addition of up to 10 more alloying elements including chromium, aluminum, cobalt, tungsten, molybdenum, titanium, and so on. Through the development and improvement of nickel-based superalloys in the past century, they are well proved to show excellent performance at the elevated service temperature. Owing to the combination of extraordinary high-temperature mechanical properties, such as monotonic and cyclic deformation resistance, fatigue crack propagation resistance; and high-temperature chemical properties, such as corrosion and oxidation resistance, phase stability, nickel-based superalloys are widely used in the critical hot-section components in aerospace and energy generation industries. The success of nickel-based superalloy systems attributes to both the well-tailored microstructures with the assistance of carefully doped alloying elements, and the intently developed manufacturing processes. The microstructure of the modern nickel-based superalloys consists of a two-phase configuration: the intermetallic precipitates (Ni,Co)3(Al,Ti,Ta) known as γ′ phase dispersed into the austenite γ matrix, which is firstly introduced in the 1940s. The recently developed additive manufacturing (AM) techniques, acting as the disruptive manufacturing process, offers a new avenue for producing the nickel-based superalloy components with complicated geometries. However, γ′ strengthened nickel-based superalloys always suffer from the micro-cracking during the AM process, which is barely eliminated by the process optimization. On this basis, the new compositions of γ′ strengthened nickel-based superalloy adapted to the AM process are of great interest and significance. This study sought to design novel γ′ strengthened nickel-based superalloys readily for AM process with limited cracking susceptibility, based on the understanding of the cracking mechanisms. A two-parameter model is developed to predict the additive manufacturability for any given composition of a nickel-based superalloy. One materials index is derived from the comparison of the deformation-resistant capacity between dendritic and interdendritic regions, while another index is derived from the difference of heat resistant capacity of these two spaces. By plotting the additive manufacturability diagram, the superalloys family can be categorized into the easy-to-weld, fairly-weldable, and non-weldable regime with the good agreement of the existed knowledge. To design a novel superalloy, a Cr-Co-Mo-W-Al-Ti-Ta-Nb-Fe-Ni alloy family is proposed containing 921,600 composition recipes in total. Through the examination of additive manufacturability, undesired phase formation propensity, and the precipitation fraction, one composition of superalloy, MAD542, out of the 921,600 candidates is selected. Validation of additive manufacturability of MAD542 is carried out by laser powder bed fusion (LPBF). By optimizing the LPBF process parameters, the crack-free MAD542 part is achieved. In addition, the MAD542 superalloy shows great resistance to the post-processing treatment-induced cracking. During the post-processing treatment, extensive annealing twins are promoted to achieve the recrystallization microstructure, ensuring the rapid reduction of stored energy. After ageing treatment, up to 60-65% volume fraction of γ′ precipitates are developed, indicating the huge potential of γ′ formation. Examined by the high-temperature slow strain rate tensile and constant loading creep testing, the MAD542 superalloy shows superior strength than the LPBF processed and hot isostatic pressed plus heat-treated IN738LC superalloy. While the low ductility of MAD542 is existed, which is expected to be improved by modifying the post-processing treatment scenarios and by the adjusting building direction in the following stages of the Ph.D. research. MAD542 superalloy so far shows both good additive manufacturability and mechanical potentials. Additionally, the results in this study will contribute to a novel paradigm for alloy design and encourage more γ′-strengthened nickel-based superalloys tailored for AM processes in the future. / <p>Additional funding agencies: Agora Materiae Graduate School for multidisiplinary PhD students at Linköping University, and Stiftelsen Axel Hultgren.</p> Nickel-based superalloy Alloy design Laser powder bed fusion Cracking susceptibility Additive manufacturability Heat treatment γ′ precipitate High-temperature mechanical property Creep. Metallurgy and Metallic Materials Metallurgi och metalliska material
58	Mechanismy únavového poškození niklové superslitiny Inconel 713LC za teploty 800°C / Fatigue failure mechanism of nickel-based superalloy Inconel 713LC under 800°C Smékalová, Jana January 2010 (has links) Nickel superalloys are used for high-temperature application in energetic and aerospace industry. They are exposed to aggressive environment at high temperatures with the interactions between fatigue and creep processes, high-temperature oxidation, corrosion and erosion. Lifetime extension of such strained parts while increasing the performance of particular machine is possible by applying protective surface coatings. The subject of this work is to investigate the fatigue failure mechanisms of superalloy Inconel 713LC at 800 °C and to compare these mechanisms between material with a protective coating based on Al-Si and material without coating. The location of initiation fatigue cracks, their propagation and the fatigue crack propagation rate in some areas were analyzed by optical microscopy, scanning electron microscopy and confocal laser scanning microscopy. Based on previous research it was found that the application of the coating AlSi has a positive effect on lifetime of alloy Inconel 713LC. These results were confirmed and estimated in the diploma thesis.
59	Primary Processing Parameters and Their Influence on Porosity and Fatigue Life of Additively Manufactured Alloy 718 Sheridan, Luke C. 18 May 2020 (has links) No description available. Mechanical Engineering Mechanics Materials Science Metallurgy Fatigue Alloy 718 Nickel-Based Superalloy Additive Manufacturing Laser Powder Bed Fusion Compliance Porosity Crack Growth Crack Initiation
60	Thermodynamic Modelling and Experimental Investigation of Tungsten Partitioning in Nickel Based Alloys Kumpati, Joshva January 2018 (has links) Thermo-Calc software AB develops high quality thermodynamic and kinetic databases to predict and simulate accurately multi-component phase behaviour in complex systems. One problem with their Ni-based alloys and superalloy solutions database (TCNI8) is poor description of tungsten partitioning for multi-component nickel based alloys. This work investigates the thermodynamic description of some lower-order systems i.e., Ni-W, Al-Ni-W and Cr-Ni-W by performing key experiments on three binary Ni-W alloys, and two ternary alloys (Al-Ni-W and Cr-Ni-W). Experiments at four different temperatures were carried out in which alloys were homogenized, equilibrated, quenched and investigated to determine the equilibrium solid/liquid compositions. Experimental results are used to validate the thermodynamic descriptions of the liquid and the fcc phase. Unlike ternary Al-Ni-W and Cr-Ni-W, binary Ni-W reproduced the experimental information in a satisfactory way. Ternary parameters for fcc are changed to fit the experimental results of this work. The findings of this work highlight that ternary parameters for the fcc of Al-Ni-W and Cr-Ni-W systems significantly effect the tungsten partitioning values in higher order systems. / Thermo-Calc Software AB utvecklar termodynamiska och kinetiska databaser av hög kvalitet för att korrekt kunna förutsäga och simulera jämvikter och fasomvandlingar i komplexa flerkomponentsystem. Ett problem med deras databas för Ni-baslegeringar och superlegeringar (TCNI8) är att beskrivning av volframpartitionering stämmer dåligt för nickelbaslegeringar. I detta arbete undersöktes den termodynamiska beskrivningen av vissa lägre system, dvs Ni-W, Al-Ni-W och Cr-Ni-W genom att utföra nyckelförsök på tre binära Ni-W-legeringar och två ternära legeringar (Al-Ni-W och Cr-Ni-W). Experimentvid fyra temperaturer utfördes i vilka legeringarna homogeniserades,jämviktsbehandlades, släcktes och undersöktes för att bestämma sammansättning för jämvikt fast fas/smälta. De erhållna experimentella resultaten användes för att validera den termodynamiska beskrivningen av smältan och fcc-fasen. Till skillnad från ternära Al-Ni-W ochCr-Ni-W, reproducerade den experimentella informationen den binära Ni-W-beskrivningen tillfredsställande. Ternära parametrar för fcc justerades efter de experimentella resultaten från detta arbete. Resultaten visar att de ternära parametrarna för fcc i Al-Ni-W och Cr-Ni-W systemen signifikant påverkar volframs fördelning mellan fast fas och smälta i nickelbaslegeringar. Metallurgy and Metallic Materials Metallurgi och metalliska material

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