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181	Study of Synergy between Plastic Deformation Mechanisms, Tribo-oxidation And Mechanically Mixed Layers in Tribology Of Ti-6Al-4V Slid Against SS316L And Alumina Ashok Raj, J January 2016 (has links) (PDF) Alloys of titanium are highly preferred materials for their excellent strength to weight ratio but the tribological issues while using them has been posing challenging issues for the tribological analyst, which are still areas of active research. Ti-6Al-4V (Ti64) is the most popular alloy of titanium and our understanding of the fundamental mechanisms of wear and friction of this alloy is still not complete. Previous investigations related to the tribology of these alloys have suggested a synergistic effect of plastic deformation and tribo-oxidation. The present investigation described in this thesis explores the existence of one more mode, namely the formation of a Mechanically Mixed Layer (MML). The thesis examines the effect of these modes one by one and analyses the synergistic effect of these mechanisms, and also the effect of heat generation during sliding. The tribological condition existing have been varied by doing wear experiments using Ti64 pins sliding against alumina and SS316L (controls MML), diameter of pin (expected to control debris entrapment and thus MML formation), tribo-system (horizontal disc Vs vertical disc, which is also expected to control debris entrapment and thus MML formation), environment (ambient and vacuum, expected to control tribo-oxidation) and sliding speed (expected to control interface temperature and thus plastic deformation mechanism and tribo-oxidations). The division of the main chapters has been so made to present the findings spread over Chapters 5-8, with each chapter dealing with specific tribological test conditions. In each chapter, results from the tribological experimentations in the form of wear and friction are presented, together with the characterization methods which throw light into the tribological mechanisms. These characterization methods include Scanning Electron Microscopy (SEM), Energy Dispersive X-ray Spectroscopy (EDAX), X-Ray Diffraction (XRD) and Electron probe micro-analyzer (EPMA). Wherever possible, the debris collected from the experiments have been subjected to morphological and detailed chemical analysis, and a feature which has not been explored much in detail by tribological investigators, but having a promising potential. Experimental results from tribological testing when Ti64 pins slides against two different materials (Alumina and SS316L) in pin-on-disc tribometers under two different environmental conditions (ambient /vacuum) are analyzed. Each set of experiments looks at two different effects - (1) the effect of sliding speed on the tribological behavior while using a pin of a fixed diameter (all other parameters remaining the same) and (2) the effect of using pins of different diameters for a given set of parameters. Three different pin-sizes were employed (2.1 mm. 4.6 mm and 6.6 mm), the normal loads on these pins were changed according to the pin-size used so that all experiments were done at the same contact pressure (2.8 MPa). By performing the experiments against the ceramic disc (alumina) under vacuum conditions, the effect of this plastic deformation is studied in isolation because the possibility of the Tribo Chemical Reaction (TCR) due to oxidation is inhibited and no MML was found to be formed due to poor compatibility of mixing between the metallic pin and the ceramic disc. For the low speeds/strain rates experiments, the effect of plastic deformation as influenced by the adiabatic shear banding is seen to influence wear which progressively changes to temperature induced plastic deformation and wear. The situation is found to be different when we change the environmental conditions from vacuum to ambient for the same tribo-combination. The tests shows a reduction in wear rate with speed, and this is due to the oxide formations due to TCR as confirmed from the SEM/EDAX characterization. In contrast to previous experiments under vacuum, these permit the effect of TCR also to influence the tribological behavior. The scenario changes when the alumina disc is replaced by a metallic one (SS316L) and tests carried out in vacuum, as the MML was found to be formed with this tribo-pair. Because of the mutual affinity of the materials in the tribo-pair, the wear damage is severe in this case and the flash temperatures crossing the phase transition temperature (~880oC) for Ti64 at high speeds. The growth of the β phase with increase in the sliding (temperature) conditions is captured from the XRD spectra of the wear debris. Synergistic effect of all these mechanisms (plastic deformation, MML, and TCR) is permitted by conducting experiments with Ti64 pin against stainless steel and in ambient conditions. A comparison of the tribological response by presenting results when experiments are run over a range of speeds while using different sized pins under ambient conditions (and compared with similar results in vacuum) while using SS316L disc serve to demarcate the differences in the wear modes which are active/inactive depending on the tribological conditions. In addition a study incorporating the effect of frictional heating and its influence on the tribological phenomena is analyzed. Main conclusions from the thesis are: The wear resistance of Ti64 alloy when sliding against SS316L is found to be influenced by Strain Rate Response (SRR), Tribo Oxidation (TO), Mechanically Mixed Layer (MML) and the prevailing heat flux conditions at the contact. The wear rates were found to decrease marginally with sliding speeds (strain rates) up to a certain speed, which is ascribed to reduction in adiabatic shear band intensity with increase in strain rate. Adiabatic Shear Band (ASB), which allows easy crack propagation, intensity reduces as temperature of deformation of Ti64 is increased. From the results it can be confirmed that the propensity for formation of MML depends on compatibility of the disc and the pin material. The contribution due to of entrapment and retention of debris in the contact zone also would influence formation of the MML. The effect of frictional heating plays an influential role as it can affect the factors (TO, ASB, MML) governing the tribological response. The sensitivity to temperature, which is a marked feature of this alloy in undergoing softening, as confirmed by previous researchers, is reflected in the experimental results. Since the main factor that triggers the micro-structural instability is the energy dissipation that accompanies deformation more fundamental research which can improve the thermal transport properties of this alloy, would be the future scope of work of this thesis. Also, the unique composition of the MML which offers high wear resistance under specific operating conditions opens up the possibility of new such alloy formulations, production routes and techniques which should improve the tribological response of this alloy. Plastic Deformation Tribology Tribo-Oxidation Titanium Alloys Mechanically Mixed Layer (MML) Alumina Discs Mechanical Wear Tribo Chemical Reactions Metal-Ceramics Stainless Steel Discs Strain Rate Response Sliding-Titanium Tribosystems Titanium Alloy Tribology SS316L Disc Ti-6Al-4V Slid Mechanical Engineering
182	Evolution of Microstructure and Texture during Severe Plastic Deformation of a Magnesium-Cerium Alloy Sabat, Rama Krushna January 2014 (has links) (PDF) Magnesium alloys have poor formability at room temperature, due to a limited number of slip systems owing to the hexagonal closed packed structure of magnesium. One possibility to increase the formability of magnesium alloys is to refine the grain size. A fine grain magnesium alloy shows high strength and high ductility at room temperature, hence an improved formability. In addition to grain refinement, the formability of Mg alloys can be improved by controlling crystallographic texture. Severe plastic deformation (SPD) processes namely, equal channel angular pressing (ECAP) and multi-axial forging (MAF) have led to improvement in room temperature mechanical property of magnesium alloys. Further, it has been reported that by adding rare earth elements, room temperature ductility is enhanced to nearly 30%. The increase in property is attributed to crystallographic texture. Many rare earth elements have been added to magnesium alloys and new alloy systems have been developed. Amongst these elements, Ce addition has been shown to enhance the tensile ductility in rolled sheets at room temperature by causing homogeneous deformation. It has been observed that processing of rare-earth containing alloys below 300°C is difficult. Processing at higher temperatures leads to grain growth which ultimately leads to low strength at room temperature. The present thesis is an attempt to combine the effect SPD and rare earth addition, and to examine the overall effect on microstructure and texture, hence on room temperature mechanical properties. In this thesis, Mg-0.2%Ce alloy has been studied with regard to the two SPD processes, namely, ECAP and MAF. The thesis has been divided into six chapters. Chapter 1 is dedicated to introduction and literature review pertaining to different severe plastic deformation processes as applied to different Mg alloys. Chapter 2 includes the details of experimental techniques and characterization procedures, which are commonly employed for the entire work. Chapter 3 addresses the effect of ECAP on the evolution of texture and microstructure in Mg-0.2%Ce alloy. ECAP has been carried out on two different initial microstructure and texture in the starting condition, namely forged and extruded. ECAP has been successfully carried out for the forged billets at 250°C while cracks get developed in the extruded billet when ECAP was done at 250°C. The difference in the deformation behaviour of the two alloys has been explained on the basis of the crystallographic texture of the initial materials. The microstructure of the ECAP materials indicates the occurrence of recrystallization. The recrystallization mechanism is identified as “continuous dynamic recovery and recrystallization” (CDRR) and is characterized by a rotation of the deformed grains by ~30⁰ along c-axis. The yield strengths and ductility of the two ECAP materials have been found quite close. However, there is a difference in the yield strength as well as ductility values when the materials were tested under compression. The extruded billet has the tension compression asymmetry ~1.7 while the forged material has the asymmetry as ~2.2. After ECAP, the yield asymmetry reduces to ~1 for initially extruded billet, while for the initially forged billet the yield asymmetry value reduces to ~1.9. In chapter 4, the evolution of microstructure and texture was examined using another severe plastic deformation technique, namely multi axial forging (MAF). In this process, the material was plastically deformed by plane strain compression subsequently along all three axes. In this case also two different initial microstructures and texture were studied, namely the material in as cast condition and the extruded material. The choice of initial materials in this case was done in order to examine the effect of different initial grain size in addition to different textures. By this method, the alloy Mg-0.2%Ce could be deformed without fracture at a minimum temperature of 350⁰C leading to fine grain size (~3.5 µm) and a weak texture. Grain refinement was more in the initial cast billets compared to the initial extruded billet after processing. The mechanism of grain refinement has been identified as twin assisted dynamic recrystallization (TDRX) and CDRR type. The mechanical properties under tension as well as under compression were also evaluated in the present case. The initially extruded billet has shown low tension compression asymmetry (~1.2) than cast billet (~1.9), after MAF. Chapter 5 addresses the exclusive effect of texture on room temperature tensile properties of the alloy. Different textures were the outcomes of ECAP and MAF processes. In this case, in order to obtain an exact role of texture, a third of deformation mode, rolling, was also introduced. All the processed materials were annealed to obtain similar grain size but different texture. A similar strength and ductility for ECAP and MAF, where the textures were qualitatively very different, was attributed to the fact that texture of both the ECAP and MAF processed materials, was away from the ideal end orientation for tensile tests. In chapter 7, the final outcomes of the thesis have been summarized and scope for the future work has been presented. Magnesium-Cerium Alloys Mg Alloys Equal Channel Angular Pressing (ECAP) Multi-Axial Forging (MAF) Magnesium Alloys Deformation Texture Analysis Metallurgy
183	Aplikace metody difrakce zpětně odražených elektronů v materiálovém inženýrství / Application of Electron Backscatter Diffraction in Materials Engineering Man, Ondřej January 2010 (has links) The thesis deals with principles and common applications of the electron backscatter diffraction (EBSD) method. Some practical experience in application of the method to a study of highly deformed structure of copper and its thermal stability is described on one hand, and, on the other hand, to a study of phase composition of TRIP steel on various levels of imposed strain. The limitations of EBSD method are discussed along with its resolution in comparison with other complimentary techniques.
184	Improving the Plasticity of Metallic Glass through Heterogeneity Induced by Electropulsing-assisted Surface Severe Plastic Deformation Chi, Ma 29 August 2019 (has links) No description available. Metallurgy Mechanical Engineering Molecular Physics Molecules Materials Science Nanotechnology Nanocrystals Free volume Metallic glasses Plasticity Fracture strength Molecular dynamics simulation Shear bands characterization
185	Diffraction Studies Of Deformation In Shape Memory Alloys And Selected Engineering Components Rathod, Chandrasen 01 January 2005 (has links) Deformation phenomena in shape memory alloys involve stress-, temperature-induced phase transformations and crystallographic variant conversion or reorientation, equivalent to a twinning operation. In near equiatomic NiTi, Ti rich compositions can exist near room temperature as a monoclinic B19' martensitic phase, which when deformed undergoes twinning resulting in strains as large as 8%. Upon heating, the martensite transforms to a cubic B2 austenitic phase, thereby recovering the strain and exhibiting the shape memory effect. Ni rich compositions on the other hand can exist near room temperature in the austenitic phase and undergo a reversible martensitic transformation on application of stress. Associated with this reversible martensitic transformation are macroscopic strains, again as large as 8%, which are also recovered and resulting in superelasticity. This work primarily focuses on neutron diffraction measurements during loading at the Los Alamos Neutron Science Center at Los Alamos National Laboratory. Three phenomena were investigated: First, the phenomena of hysteresis reduction and increase in linearity with increasing plastic deformation in superelastic NiTi. There is usually a hysteresis associated with the forward and reverse transformations in superelastic NiTi which translates to a hysteresis in the stress-strain curve during loading and unloading. This hysteresis is reduced in cold-worked NiTi and the macroscopic stress-strain response is more linear. This work reports on measurements during loading and unloading in plastically deformed (up to 11%) and cycled NiTi. Second, the tension-compression stress-strain asymmetry in martensitic NiTi. This work reports on measurements during tensile and compressive loading of polycrystalline shape-memory martensitic NiTi with no starting texture. Third, a heterogeneous stress-induced phase transformation in superelastic NiTi. Measurements were performed on a NiTi disc specimen loaded laterally in compression and associated with a macroscopically heterogeneous stress state. For the case of superelastic NiTi, the experiments related the macroscopic stress-strain behavior (from an extensometer or an analytical approach) with the texture, phase volume fraction and strain evolution (from neutron diffraction spectra). For the case of shape memory NiTi, the macroscopic connection was made with the texture and strain evolution due to twinning and elastic deformation in martensitic NiTi. In all cases, this work provided for the first time insight into atomic-scale phenomena such as mismatch accommodation and martensite variant selection. The aforementioned technique of neutron diffraction for mechanical characterization was also extended to engineering components and focused mainly on the determination of residual strains. Two samples were investigated and presented in this work; first, a welded INCONEL 718 NASA space shuttle flow liner was studied at 135 K and second, Ti-6Al-4V turbine blade components were investigated for Siemens Westinghouse Power Corporation. Lastly, also reported in this dissertation is a refinement of the methodology established in the author's masters thesis at UCF that used synchrotron x-ray diffraction during loading to study superelastic NiTi. The Los Alamos Neutron Science Center is a national user facility funded by the United States Department of Energy, Office of Basic Energy Sciences, under Contract No. W-7405-ENG-36. The work reported here was made possible by grants to UCF from NASA (NAG3-2751), NSF CAREER (DMR-0239512), Siemens Westinghouse Power Corporation and the Space Research Initiative. shape memory alloys in-situ diffraction neutron synchrotron x-ray NiTi superelasticity linear superelasticity shape memory effect tension compression plastic deformation heterogeneous transformation martensitic transformation Inc Engineering Materials Science and Engineering
186	MECHANICAL PROPERTIES AND RADIATION RESPONSE OF NANOSTRUCTURED FERRITIC-MARTENSITIC STEELS Zhongxia Shang (9171533) 17 November 2022 (has links) <p>Structural metallic materials exposed to energetic particle bombardments often experience various types of irradiation-induced microstructural damage, thus degrading the mechanical properties of the materials in form of irradiation hardening and embrittlement. Nanostructured materials have shown better radiation resistance than their coarse-grained (CG) counterparts due to the existence of abundant defect sinks, such as grain boundaries, twin boundaries, and phase boundaries. However, recently developed nanocrystalline (NC) steels show limited room-temperature tensile ductility (< 1%), which may become a concern for their future application for nuclear reactors. The focus of this thesis is to explore the strength-ductility dilemma in modified 9Cr1Mo (T91) ferritic/martensitic (F/M) steel processed by thermomechanical treatment (TMT) and surface severe plastic deformation (SSPD) with an attempt to fabricate strong, ductile and radiation resistant F/M steels. </p> <p><b>Carbon partitioning</b> between the quenched martensite and the other phases (bainitic ferrite or retained austenite) is critical for enhancing the strength and ductility of T91 steel. The tensile properties of partially tempered (PT) T91 steel can be tailored through introducing bainitic ferrite with high-density nanoscale transition carbides and refined lath martensite. In addition, retained austenite was introduced by increasing the carbon concentration of T91 steel to 0.6 wt.%. The carbon-modified steel processed by quenching partitioning (Q-P) treatment exhibits an ultrahigh strength, ~ 2 GPa, with a uniform strain of ~ 5% due to the existence of coherent carbides, ultrafine martensite and retained austenite. </p> <p>Meanwhile, surface mechanical grinding treatment (SMGT) on T91 steel reveals that introducing <b>gradient structures</b> on the sample surface contributes to a higher strength and an improved plasticity than its homogeneously structured counterpart. The deformation mechanism of the gradient structures was investigated with the assistance of quasi <i>in situ</i> crystal orientation analyses. Furthermore, <i>ex situ</i> He ion irradiation on the gradient T91 steel indicates that radiation-induced damage, such as bubble-induced swelling and irradiation hardening, were gradually mitigated by grain refinement from the sample surface to the center, resulting in superior radiation resistance. The results obtained from this thesis may facilitate the design and fabrication of strong, ductile and radiation-tolerant F/M steels.</p> Metals and alloy materials Nanomaterials Ferritic-martensitic steels thermomechanical treatment (TMT) process surface severe plastic deformation mechanical properties radiation damages Metals and Alloy Materials Nanomaterials
187	Изучение структуры, свойств и релаксационной стойкости аустенитной стали после различных термомеханических обработок : магистерская диссертация / The study of the structure , properties, and relaxation resistance of austenitic steel after various thermomechanical treatments Лысов, А. С., Lisov, A. January 2015 (has links) In the work, it is studied almost carbon-free corrosion-resistant Fe-Cr-Ni-based steel, with the additional alloying with cobalt, molybdenum, aluminum and titanium, with high ductility and processability in production of high-strength wire. / В настоящей работе проводятся исследования новой практически безуглеродистой коррозионно-стойкой стали на Fe-Cr-Ni основе, с дополнительным легированием кобальтом, молибденом, алюминием и титаном, обладающей высокой пластичностью и технологичностью при производстве высокопрочной проволоки. MASTER'S THESIS CORROSION-RESISTANT STEEL HIGH-STRENGTH WIRE METASTABLE AUSTENITE COLD PLASTIC DEFORMATION MARTENSITE OF DEFORMATION МАРТЕНСИТ ДЕФОРМАЦИИ
188	Изучение особенностей производства проволоки и шин из кислородосодержащей меди для кабельной промышленности : магистерская диссертация / Study of the peculiar properties of the oxygen-containing copper wire and buses production for the cable industry Ерёмин, А. В., Yeryomin, A. V. January 2019 (has links) Предметом исследования является производство прямоугольной медной проволоки для электротехнических целей. Приведен патентно-литературный обзор, включающий в себя некоторые особенности производства медной проволоки, а также способы ее производства, оборудование и инструмент. Представлена общая технологическая схема производства прямоугольной медной проволоки. Также приведена информация, касающаяся схемы напряженного состояния в зоне очага деформации при волочении и конфигурация канала волоки. Помимо вышеприведенной, приведена информация, касающаяся испытаний проволоки на растяжение и анализ их результатов. / The subject of the study is production of rectangular copper wire for electrical purposes. There are patent and literature review which include several features of production of copper wire, methods of production, equipment and tools. Given the general technological scheme of production of rectangular copper wire. Given information about scheme of stress state in deformation zone when drawing and configuration of die hole. Also given information about tensile test and analysis of its results. ВОЛОЧЕНИЕ НАПРЯЖЕНИЯ ПРОЧНОСТНЫЕ СВОЙСТВА ПЛАСТИЧНОСТЬ MASTER'S THESIS OXYGEN-CONTAINING COPPER DRAWING RECTANGULAR COPPER WIRE PLASTIC DEFORMATION STRESSES STRENGTH PROPERTIES PLASTICITY
189	Numerische Simulation und Analyse des Fertigungsprozesses von vorgewölbten Berstscheiben Treude, Benjamin 20 June 2024 (has links) Bei der Druckabsicherung von verfahrenstechnischen Anlagen spielen Berstscheiben eine entscheidende Rolle. Sie reagieren auf kritische Druckänderungen im zu schützenden System und geben ihren Entlastungsquerschnitt bei Bedarf vollständig frei. Als drucktragende Komponente einer Berstscheibe muss die Berstmembran die regulären Betriebsbelastungen des abzusichernden Prozesses zuverlässig abtragen und darf erst bei Erreichen einer kritischen Druckbelastung ansprechen. Aufgrund ihres guten Tragverhaltens bieten Berstscheiben mit vorgewölbter Berstmembran ein breites Einsatzspektrum. Während des Fertigungsprozesses von vorgewölbten Berstscheiben wird eine anfänglich flache Blechronde über einen Aeroforming- Prozess zu einer Berstmembran mit annähernd sphärischer Gestalt geformt. Dieser plastische Deformationsprozess wird über eine numerische Simulation mittels Finite-Elemente-Methode beschrieben und die dabei wirkenden Zusammenhänge aufgezeigt. Die Simulation wird zudem durch experimentelle Versuche begleitet und validiert. / Rupture discs play an essential role in the pressure protection of process engineering systems. They react to critical pressure changes in the system to be protected and fully release their relief cross-section as required. As the pressure-bearing component of a rupture disc, the rupture diaphragm must reliably withstand the regular operating loads of the process to be protected and may only respond when a critical pressure load is reached. Due to their good load- bearing behavior, rupture discs with pre-domed rupture diaphragms offer a wide range of applications. During the manufacturing process of pre-domed rupture discs, an initially flat sheet metal blank is formed into a rupture diaphragm with an approximately spherical shape using an aeroforming process. This plastic deformation process is described by a numerical simulation using the finite element method and the relationships involved are shown. The simulation is also accompanied and validated by experimental tests. info:eu-repo/classification/ddc/620 ddc:620 info:eu-repo/classification/ddc/600 ddc:600
190	Utilisation of Kernel Average Misorientation (KAM) to analyse the microstructure of cemented carbide after plastic deformation Caroline, Löwnertz January 2024 (has links) Cemented carbide tools are subjected to high loads and temperatures during use. Long before any significant wear can occur on the tool, the material will experience plastic deformation. The purpose of this master thesis was to investigate how Kernel Average Misorientation (KAM) can be utilised to analyse plastic deformation within the microstructure or grains of cemented carbides. Six different cemented carbides were investigated. The materials were plastically deformed by utilizing cutting tests with a feed rate staircase method to induce the plastic deformation. Each material was characterised by using Scanning Electron Microscopy (SEM) either equipped with a secondary electron detector or an Electron Backscatter Diffraction detector (EBSD). This made it possible to investigate the WC grain size, Co infiltration, step formation, cavities and pores, KAM and the average grain size. It was concluded that KAM showed to be a valuable tool to visualise the plastic deformation in the materials. There were some limitations to KAM regarding materials with similar amounts of plastic deformation. Additionally, the data from KAM could be used to create graphs to more easily display the misorientation. However, KAM cannot showcase the mechanisms that lead to plastic deformation. Other characterisation methods are needed as a compliment to completely understand what is happening in the material on a microstructural level. Cemented carbide Analysis method Kernel Average Misorientation KAM Plastic deformation pores cavities voids Cobalt infiltration stepping Hårdmetall Analysmetod KAM Porer Plastisk deformation Kobolt infiltrering stegning Metallurgy and Metallic Materials Metallurgi och metalliska material Composite Science and Engineering Kompositmaterial och -teknik Materials Chemistry Materialkemi

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