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Alloy Design and Characterization of γ′ Strengthened Nickel-based Superalloys for Additive ManufacturingXu, 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>
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Mechanismy únavového poškození niklové superslitiny Inconel 713LC za teploty 800°C / Fatigue failure mechanism of nickel-based superalloy Inconel 713LC under 800°CSmékalová, 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.
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Příprava difuzních bariér s využitím technologie chemické depozice / Formation of Diffusion Barriers Using Chemical Vapour Deposition ProcessFoltýnek, Jaroslav January 2013 (has links)
Masters thesis deals with formation of diffusion barrier coatings by means of powder mixtures chemical vapor deposition. Its theoretical part is focused on the problems with diffusion barriers formation, where predominantly three most commonly used methods are introduced, i.e. CVD from powder mixtures, active gasses and slurries. The experimental part of master thesis deals with the formation of nickel-aluminide diffusion barriers on Inconel 713LC superalloy substrate, where was for aluminization used six different powder mixtures at the temperature of 800 °C and dwell of 0, 2 and 5 hours.
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Primary Processing Parameters and Their Influence on Porosity and Fatigue Life of Additively Manufactured Alloy 718Sheridan, Luke C. 18 May 2020 (has links)
No description available.
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On the Path-Dependent Microstructure Evolution of an Advanced Powder Metallurgy Nickel-base Superalloy During Heat TreatmentKrutz, Nicholas J. January 2020 (has links)
No description available.
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The effect of printing parameters on the deformation and microstructure of Inconel 718 : A study in pulsed laser and powder based directed energy deposition additive manufacturingRepper, Elias January 2020 (has links)
Additive manufacturing has the power to redefine how we create components. In order to minimize removal of printed material, deformation must be kept a minimum. When deposition rate is increased during directed energy deposition so is the power requirement for melting the feedstock. This increases the residual stresses in the material and leads to more deformation. The deposition rate must be increased without introducing large deformation, if additive manufacturing is ever to be economical in many engineering fields. This study aims to explore if pulsing the laser can decrease deformation using a design of experiments approach. Other types of defects and microstructural changes are also evaluated. A total of 17 sets of parameters were used varying laser power, pulse frequency and the time fraction when the laser was powered on. The amount of powder added to a substrate was constant and the build geometry as similar as possible for all tests. Ultimately no conclusion could be drawn regarding pulsing parameters effect on deformation. It was found pulsing the laser lowered the powder efficiency drastically, which may have had a bigger effect on the experimental set up than anticipated. In a similar manner, no relation between pulsing parameters, defects and microstructure could be observed. / Additiv tillverkning ger oss möjligheten att tillverka komponenter på ett sätt som tidigare inte har varit möjligt. För att minimera efterföljande svarvning och fräsning av additivt tillverkade delar måste deformationen kontrolleras. När deponeringshastigheten ökar måste även sträckenergin ökas i direktenergideponeringsprocesser. Detta leder till höjda restspänningsnivåer i materialet och medför en större efterföljande deformation. Om additiv tillverkning i framtiden ska ha en chans att mäta sig ekonomiskt med konventionella metoder måste deponeringshastigheten öka för många applikationsområden. Denna studie använder Design of Experiments för att undersöka om en pulserande laser kan utnyttjas för att minska deformationen när metallpulver används som tillsats. Även andra typer av defekter och förändringar i mikrostruktur har utvärderats. Totalt undersöktes 17 olika parameteruppsättningar med varierande lasereffekt, pulsfrekvens och aktiv lasertid. Pulverdeponeringshastigheten hölls konstant mellan försöken och byggeometrierna var så lika som möjligt för alla tester. I slutändan kunde ingen slutsats dras när det gäller hur pulserande parametrar påverkar deformationen. Det visade sig att en pulserande parameter sänker pulvereffektiviteten drastiskt, vilket kan ha haft en större effekt på experimentets uppsättning än förutspått. På liknande sätt kunde inget säkert samband mellan pulserande parametrar, defekter och mikrostruktur observeras.
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Microstructure-Sensitive Models for Predicting Surface Residual Stress Redistribution in P/M Nickel-Base SuperalloysBurba, Micheal Eric 24 May 2017 (has links)
No description available.
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Characterization and Modeling of Grain Coarsening in Powder Metallurgical Nickel-Based SuperalloysPayton, Eric John 24 September 2009 (has links)
No description available.
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Process understanding of Laser Powder Bed Fusion of Nickel based superalloy Haynes 282 / Processförståelse för laserpulverbäddsfusion av nickelbaserade superlegeringen Haynes 282Swaminathan, Kameshwaran January 2024 (has links)
Laser-material interaction of Nickel based superalloy Haynes 282 melt pools were studied for laser parameters similar to laser powder bed fusion (PBF-LB) without powder. The effect of power, speed, hatch distance and laser focus offset were analysed by characterizing different types of melt pool behaviour, including conduction, transition to keyhole, and keyhole mode. Focus offset parameter was found to modify the melting mode from keyhole to conduction type in experiments with and without powder. This change in melting mode is attributed to the variation in laser beam spot size for the same line energy. Such manipulation of type of melting with control of focus offset can be utilized as a method to optimize process parameters for novel materials in the PBF-LB process at high layer thickness. Based on the above study, cubes were built with refined process parameters utilizing powder layer thicknesses of 60- and 90-microns for improved productivity, using partial factorial design of experiment. The conduction mode of melting helped reducing defects, minimizing lack of fusion and keyhole porosity in specimens built with powder at 60- and 90-microns layer thickness. Effect of process parameters and indirect measure like area energy, on the melt pool overlap, defect level and dominant shape of the defects are presented. Optimizing the process parameters to identify the boundaries for building cubes with reduced porosity is also discussed. / Den Ni-baserade superlegeringen, Haynes 282, skannades med laserparametrar liknande de som används i laserpulverbäddfusion (PBF-LB), men utan pulver.Studien undersökte inverkan av effekt, hastighet, avstånd mellan två intilliggandeskanningspass och laserfokusförskjutning, vilket karakteriserades genom olikatyper av beteenden hos smältbadet, inklusive värmeledning, övergång frånvärmeledning till nyckelhål, och nyckelhål. Fokusförskjutningen visade sig ändrasmältbadets läge från nyckelhål till värmeledning. Denna förändring observeradesbåde i experiment utan pulver och i de med pulver. Förändringen beror påbreddningen av laserstrålens punktstorlek samtidigt som samma linjeenergibibehålls. Denna förändring i smältningstyp genom fokusförskjutning kananvändas som en metod för att optimera utforskningen av nya material i PBFLB-processen. Baserat på detta byggdes kuber med pulver med lagertjocklekar på 60 och 90mikrometer, användande olika processparametrar enligt en experimentell designbaserad på en central sammansatt design. Smältning genom värmeledning bidrogtill att minska defekter, minimera bindningsfel och nyckelhålsporositet i proversom byggts med pulver med lagertjocklekar på 60 och 90 mikrometer. Inverkanav processparametrarna och indirekta mått såsom areaenergi på smältbadetsöverlappning, defektnivå och den dominerande formen på defekter presenteras.Optimering av processparametrarna samt identifiering av parameterrymden föratt bygga kuber med minskad porositet undersöks också. / <p>Paper A is to be submitted, and paper C is acceptet and are not included in this licentiate thesis. We do not have permission to publish paper B in the digital version.</p>
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Crack detection in Waspaloy during the DirectEnergy Deposition Laser Beam Wire Additive Manufacturing process : using Acoustic Emissions and Hierarchical clustering / Crack detection in Waspaloy during the DirectEnergy Deposition Laser Beam Wire Additive Manufacturing process using Acoustic Emissions and Hierarchical clusteringDrysdale, Morgan January 2024 (has links)
Metal additive manufacturing is an important tool for the creation of cost effective and environmentally friendly components for the future of the aerospace industry. Newly developed methods such as Direct Energy Deposition, Laser Beam Wire (DEDLB/w) have the potential to quickly and effciently manufacture aircraft engine components of high quality when utilising the correct set of process parameters. Establishing these parameters is a challenging task as product defects can be diffcult to detect and localise during the DEDLB/w process. This thesis explores the possibility of detecting crack type defects during the additive manufacturing of Nickel-Based Superalloy components using in process acoustic emission inspection and hierarchical clustering to evaluate DEDLB/w process parameter sets. After observing numerous material depositions made using DEDLB/w, crack-like signals were observed and clustered using features derived from Acoustic Emission (AE) data. The results were then evaluated and validated using X-Ray and X-Ray Computed Tomography (µCT) inspection. Crack-like acoustic emissions were recorded from depositions in which cracks were later found using X-rayand µCT inspection, and these emissions were successfully clustered over multiple depositions using statistical analysis and agglomerative clustering.
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