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21	Obtenção do TiFe por moagem com alta energia / Obtention of TiFe by high-energy ball milling FALCAO, RAILSON B. 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:33:49Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:03:57Z (GMT). No. of bitstreams: 0 / Neste trabalho, investigou-se a elaboração mecânica do composto intermetálico TiFe por moagem de bolas com alta energia. Uma forte aderência do material moído, particularmente nas paredes do recipiente de moagem, foi o principal problema verificado com tempos de moagem superiores a 1 hora (moinho agitador). Tentativas para resolver este problema foram realizadas inicialmente com o emprego de agentes controladores de processo (ACPs), como etanol, ácido esteárico, polietileno de baixa densidade, benzeno e ciclohexano, em diferentes quantidades (1 a 20% em massa) e tempos (1 a 40 h), mantendo-se constantes outros parâmetros de moagem como a razão bola:pó em massa (10:1) e o tamanho das bolas (=7mm). Os rendimentos mais elevados (em termos da massa de pó não aderido) foram obtidos quando se utilizaram grandes quantidades de benzeno e ciclohexano (101 e 103% em massa, respectivamente), porém com a formação de TiC ao invés de TiFe em razão da decomposição do ACP e reação do carbono com as partículas de titânio. As moagens foram realizadas posteriormente sem o emprego de qualquer ACP e também utilizando um moinho planetário. Várias estratégias foram investigadas para se tentar mitigar a aderência incluindo-se: (a) moagem de uma pequena quantidade da mistura de pós de Ti e de Fe, revestindo as paredes do recipiente e as bolas de moagem, antes da moagem da carga principal, (b) moagem pausada com aberturas intermediarias do recipiente em atmosfera ambiente, (c) moagem pausada para rotação e inversão da posição do recipiente de moagem (apenas no moinho agitador), (d) moagem isolada dos pós de Ti e de Fe, antes da moagem da mistura, e (e) moagem do pó de Fe com o Ti hidretado. Os melhores resultados, em termos de diminuição da aderência combinada com a formação majoritária do composto TiFe durante a moagem, foram obtidos quando se adotou o procedimento de inversão/rotação, juntamente com o processo de revestimento preliminar do recipiente e das bolas de moagem (26% em massa). Rendimentos maiores foram obtidos com a utilização do TiH2 no moinho planetário, porém sem a formação majoritária do TiFe durante a moagem. / Dissertação (Mestrado) / IPEN/D / Instituto de Pesquisas Energéticas e Nucleares - IPEN-CNEN/SP intermetallic compounds titanium iron powders mixtures mechanical alloying milling
22	Mecanismos de ativação mecânica de misturas de nióbio e alumínio para a síntese por reação do NbAlsub(3) / Mechanical activation mechanisms of niobium and aluminium mixtures for the reaction synthesis of NbAI3 ROCHA, CLAUDIO J. da 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:54:37Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:07:21Z (GMT). No. of bitstreams: 0 / Neste trabalho, a moagem com alta energia foi utilizada para a ativação mecânica de misturas de pós de alumínio e nióbio, na proporção de 75% atômico de alumínio, para a síntese por reação de combustão do NbAl3. O objetivo foi investigar os mecanismos de ativação atuantes e a eventual preponderância de um deles. A moagem foi realizada tanto nos pós de alumínio e de nióbio separadamente (pré-ativação), como nas misturas. O processo de síntese por reação foi realizado no modo combustão simultânea, em pastilhas compactadas a partir de misturas com e sem ativação mecânica. O comportamento térmico das pastilhas foi registrado durante todo o ciclo térmico de aquecimento e, as principais características térmicas da reação de combustão, foram determinadas. O parâmetro de rede, o tamanho de cristalito e a microdeformação elástica do alumínio e do nióbio foram determinados por difratometria de raios X, mediante análise pelo método de Rietveld. A microscopia eletrônica de varredura foi utilizada para caracterização microestrutural dos pós moídos e da pastilha reagida. Constatou-se que o mecanismo preponderante de ativação mecânica é o aumento da área de interface, que ocorre durante a formação de agregados de partículas de alumínio e nióbio. A eficiência na formação de interfaces diminuiu com a utilização de nióbio pré-ativado (encruado) e com o aumento da quantidade de ácido esteárico (utilizado como agente controlador de processo durante a moagem). O efeito principal da ativação mecânica na síntese por reação de combustão foi a redução da temperatura de ignição com o aumento do tempo de moagem. A alta densidade de defeitos cristalinos, gerada durante a pré-ativação dos pós de alumínio e nióbio e na ativação mecânica das misturas, não produziu efeitos mensuráveis sobre o comportamento térmico das pastilhas. / Tese (Doutoramento) / IPEN/T / Instituto de Pesquisas Energéticas e Nucleares - IPEN/CNEN-SP niobium aluminium mechanical alloying powder metallurgy powders milling synthesis pellets
23	Simulation and Optimization of Mechanical Alloying Using the Event-Driven Method Barahona, Javier January 2011 (has links) Mechanical Alloying is a manufacturing process that produces alloys by cold welding of powders. Usually, a vial containing both the powder and steel balls is agitated. Due to impact between the balls and balls and the vial, the powder is mechanically deformed, crushed, and mixed at nano-scales. In this thesis, a numerical model is developed to simulate the dynamics of the vial and the grinding balls of the SPEX 8000 ball milling device, a standardized equipment in both industrial and academic investigations of ball milling. The numerical model is based on the Event Driven Method, typically used to model granular flows. The method implemented is more efficient than the discrete element method used previously to study ball milling dynamics. The numerical tool obtained is useful for scale-up and optimization of mechanical alloying of various materials. An optimization study is presented for the SPEX 8000. Mechanical Alloying Event Driven Method SPEX Simulation Optimization Ball Milling
24	Synthèses, analyses structurales et propriétés thermoélectriques de matériaux sulfures / Synthesis, structurals analysis and thermoelectrics properties of sulphides materials Bourgés, Cédric 30 November 2017 (has links) Les travaux présentés dans cette thèse portent sur la synthèse et la caractérisation structurale et physico-chimique de composés sulfures à propriétés thermoélectriques. Un intérêt a été porté sur plusieurs familles de composés sulfures avec pour objectif le développement et/ou l’optimisation des performances thermoélectriques de ces composés.Un premier composé binaire, TiS2, a été élaboré par mécanosynthèse suivi d’une étape de densification par Spark Plasma Sintering (SPS). Les caractérisations structurales ont démontré un effet du processus d’élaboration sur la microstructure ainsi que sur la stœchiométrie du composé. Ce procédé induit une réduction considérable de la conductivité thermique mais aussi électrique du matériau ne permettant pas d’optimiser la figure de mérite du composé. Un second composé a ensuite été développé selon deux voies de synthèses (conventionnelle et mécanosynthèse), le composé ternaire Cu4Sn7S16. Il a été mis en évidence que ce composé semi-conducteur possède une structure complexe qui favorise une conductivité thermique intrinsèquement faible. Les propriétés thermoélectriques ainsi que l’influence de la non-stœchiométrie sur ce composé ont été rapportées. Enfin les composés CuCoxTi2-xS4 et Cu26V2Sn6S32 ont été au cœur des derniers résultats présentés. Ces composés présentent des propriétés de transport plus métalliques propices à l’obtention de facteurs de puissance plus élevés que dans composé Cu4Sn7S16. D’une part, l’élaboration du matériau et l’influence du taux de Co sur le transport électronique ont été discutées sur le composé CuCoxTi2-xS4. D’autre part, l’élaboration par la mécanosynthèse ainsi que les conditions de densification ont été reliés aux propriétés de transport du composé Cu26V2Sn6S32. Une amélioration significative des performances thermoélectriques de ce dernier a été rapportée.Ces différentes études ouvrent des perspectives intéressantes dans l’élaboration et l’optimisation des composés sulfures en vue d’applications industrielles. / The work presented in this thesis focuses on the synthesis and the structural/physicochemical characterizations of sulfide compounds with thermoelectric properties. Several families of sulphide compounds have been studied with the aim of developing and/or optimizing their thermoelectric performances.A binary compound, TiS2, was synthesized by mechanical alloying followed by a densification using Spark Plasma Sintering (SPS). The structural characterizations have revealed the effect of the elaboration on the microstructure and stoichiometry of the compound. This process induces a considerable reduction in the thermal and electrical conductivity of the material which hindered the optimization of the figure of merit. The ternary compound Cu4Sn7S16 was then developed according to two synthetic routes (conventional and mechanical alloying). It has been demonstrated that this semiconductor compound has a complex structure which promotes an intrinsic low thermal conductivity. The influence of the non-stoichiometry on the thermoelectric properties has been reported. Finally, the CuCoxTi2-xS4 and Cu26V2Sn6S32 compounds were the last interesting results presented. These compounds show metallic transport properties with high power factors. The synthesis and the influence of the Co content on the electronic transport properties have been discussed on the CuCoxTi2-xS4 compound. The effect of mechanical alloying and densification conditions were related to the transport properties of the Cu26V2Sn6S32 compound. Substantial improvement of the thermoelectric performances as reported.These various studies open interesting perspectives for the development and optimization of sulfide compounds for industrial application. Chimie des matériaux Chemistry Material Sulfides Thermoelectricity Mechanical alloying
25	Processing, Microstructural And Mechanical Characterization Of Mechanically Alloyed Al-al2o3 Nanocomposites Katiyar, Pushkar 01 January 2004 (has links) Aluminum-alumina nanocomposites were synthesized using mechanical alloying of blended component powders of pure constituents. This study was performed on various powder mixtures with aluminum as the matrix and alumina as the reinforcement with volume fractions of 20, 30, and 50 % and Al2O3 particle sizes of 50 nm, 150 nm, and 5 µm. X-ray diffraction (XRD) and scanning electron microscopy (SEM) techniques were used for the crystal structure and microstructural characterization of the powders at different stages of milling. Al2O3 powders with 50 nm and 150 nm particle size were predominantly of γ-type, while Al2O3 of 5 µm size was of α-type. The main goal was to achieve uniform distribution of the Al2O3 ceramic particles in the Al matrix, which was achieved on milling for 24 h in a SPEX mill or 100 h in a Fritsch Pulverisette planetary ball mill. The powders were consolidated in two stages: pre-compaction at room temperature followed by vacuum hot pressing (VHP) or hot isostatic pressing (HIP) techniques to a fully dense condition. The effect of reinforcement particle size and volume fraction on the stress-strain response, elastic modulus and yield strength of the composites was investigated. Nanoindentation and compression tests were performed to characterize the composite material. Yield strength of 515 MPa, compressive strength of 685 MPa and elastic modulus of 36 GPa were obtained from compression tests. Nanoindentation results gave the yield strength of 336 MPa, maximum shear stress of 194 MPa and an elastic modulus of 42 GPa. The low elastic modulus values obtained from the above tests might be because of localized yielding possibly due to residual stresses. Alumina Aluminum Mechanical alloying Nanocomposites Engineering Materials Science and Engineering
26	The Effect of Milling Time on the Structure and the Properties of Mechanically Alloyed High Carbon Iron-Carbon Alloys Khalfallah, Ibrahim Youniss A. 22 November 2017 (has links) The effects of mechanical alloying milling time and carbon concentration on microstructural evolution and hardness of high-carbon Fe-C alloys were investigated. Mechanical alloying and powder metallurgy methods were used to prepare the samples. Mixtures of elemental powders of iron and 1.4, 3, and 6.67 wt.% pre-milled graphite were milled in a SPEX mill with tungsten milling media for up to 100h. The milled powders were then cold-compacted and pressure-less sintered between 900°C and 1200°C for 1h and 5h followed by furnace cooling. Milled powders and sintered samples were characterized using X-ray diffraction, differential scanning calorimetry, Mossbauer spectroscopy, scanning and transmission electron microscopes. Density and micro-hardness were measured. The milled powders and sintered samples were studied as follows: In the milled powders, the formation of Fe_3 C was observed through Mossbauer spectroscopy after 5h of milling and its presence increased with milling time and carbon concentration. The particle size of the milled powders decreased and tended to become more equi-axed after 100h of milling. Micro-hardness of the milled powders drastically increased with milling time as well as carbon concentration. A DSC endothermic peak around 600°C was detected in all milled powders, and its transformation temperature decreased with milling time. In the literature, no explanation was found. In this work, this peak was found to be due to the formation of Fe_3 C phase. A DSC exothermic peak around 300°C was observed in powders milled for 5h and longer; its transformation temperature decreased with milling time. This peak was due to the recrystallization and/or recovery α-Fe and growth of Fe_3 C . In the sintered samples, almost 100% of pearlitic structure was observed in sintered samples prepared from powders milled for 0.5h. The amount of the pearlite decreased with milling time, contrary to what was found in the literature. The decrease in pearlite occurred at the same time as an increase in graphite-rich areas. With milling, carbon tended to form graphite instead of Fe_3 C. Longer milling time facilitated the nucleation of graphite during sintering. High mount of graphite-rich areas were observed in sintered samples prepared from powders milled for 40h and 100h. Nanoparticles of Fe_3 C were observed in a ferrite matrix and the graphite-rich areas in samples prepared from powders milled for 40h and 100h. Micro-hardness of the sintered samples decreased with milling time as Fe_3 C decreased. The green density of compacted milled powders decreased with milling time and the carbon concentration that affected the density of sintered samples. / Ph. D. Mechanical alloying High-carbon Fe-C alloys Powder processing and characterization
27	On a Bimodal Distribution of Grain Size in Mechanically Alloyed Bulk Tungsten Heavy Alloys Zeagler, Andrew 25 July 2011 (has links) Elemental W and Ni powders were mechanically alloyed in a SPEX mill with WC grinding media for durations ranging from 5 to 50 hours, then compacted samples were sintered in hydrogen to generate bulk tungsten heavy alloys with 2, 4 and 6 wt.% Ni. Evidence of a bimodal grain size distribution was seen in X-ray diffractograms of sintered samples and confirmed by scanning electron microscopy. Grain sizes in the small-grained regions ranged from 200–600 nm; those in the large-grained regions ranged from 1–2 µm. Furthermore, the volume fraction of the small-grained region increased linearly as milling time increased. A slice from a sintered sample was prepared for examination by TEM, in which particles 30–100 nm in diameter were regularly observed on the boundaries of the 200–600 nm grains. EDS point analysis showed that the particles are WC. Therefore it is concluded that heterogeneously distributed contamination from the grinding media is continually incorporated during mechanical alloying and, during sintering, inhibits grain growth through Zener pinning. Densities of sintered samples increased as milling time increased to a maximum of almost 96% of the theoretical value. Density increases with respect to milling time were initially great but diminished upon further milling. While the samples with 4 and 6 wt.% Ni both approached 96% of the theoretical density value by 50 hours of milling, densities in the samples with 2 wt.% Ni were considerably lower. Thus it appears that the Ni that becomes incorporated into the bcc W structure during mechanical alloying activates W diffusion during sintering, though there is a limit to the amount of Ni that the W structure can accommodate. This is evinced in W lattice parameter values from the as-milled powders; while the lattice parameter drops considerable from 2 to 4 wt.% Ni, the difference between 4 and 6 wt.% Ni is much smaller and the Ni content limit surely falls between the two values. Otherwise-equivalent samples with added WC powder were also produced, but did not increase the volume fraction of the small-grained region – probably because the particles remained large and were homogeneously distributed. / Ph. D. powder metallurgy tungsten tungsten heavy alloys mechanical alloying
28	Polymer blends formed by the solid state mechanical alloying process Farrell, Michael P. 04 December 2009 (has links) In the early 1970's a new processing technique to produce metallic alloys was developed by Benjamin and co-workers. This novel technique, called Mechanical Alloying (MA), involves the repeated welding, working hardening, and fracture of metallic powders to form an alloy. The research presented in this thesis describes the use of the MA process to form polymer blends. Until recently there has been no published work discussing the possibility of using this technique with polymers. This research lays the ground work for using the MA process to produce polymer blends by comparing this technique to conventional polymer processing techniques. The MA process was used to form blends of polypropylene (PP) and a liquid crystalline polymer (LCP). Samples were prepared and then characterized using thermal analysis via differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA). Mechanical testing, Fourier transform infrared (FTIR) spectroscopy and X-ray diffraction (XRD) were performed on the materials. Scanning electron micrographs (SEM) of fracture surfaces are also presented. The results suggest that the solid state mechanical alloying process is a viable technique to form polymer blends. / Master of Science Mechanical Alloying (MA) metallic alloys LD5655.V855 1994.F378
29	Microstructural Engineering of Titanium-Cellulose Nanocrystals Alloys via Mechanical Alloying and Powder Processing Angle, Jonathan Willis 05 November 2018 (has links) Titanium been used industrially for nearly a century. Ever since it was first reduced to its elemental form, concerted efforts have been made to improve the material and to reduce the cost of production. In this thesis, titanium is mechanically alloyed with cellulose nanocrystals followed by powder consolidation and sintering to form a solid titanium metal matrix composite. Cellulose nanocrystals (CNCs) were chosen as the particle reinforcement as they are a widely abundant and natural material. Additionally, the nanocrystals can be derived from waste materials such as pistachio shells. This offers a unique advantage to act as a green process to enhance the mechanical properties of the titanium as well as to reduce to cost of production. Vibrational milling using a SPEX 8000M mill was used to mechanically alloy titanium powder with varying concentrations of CNCs. Additionally, the milling time was varied. This process showed that varying the concentrations of CNCs between 0.5% - 2% by weight did not noticeably alter the microstructural or mechanical properties of the materials. Conversely, changing the milling time from 0.5 hours to 5 hours proved to greatly alter the microstructural and mechanical properties of the titanium matrix metal composites. Further increasing the milling time to 10 and 25 hours caused the materials to become exceedingly brittle thus, the majority of experiments focused on samples milled between 0.5 hours and 5 hours. The hardness values for the Ti-1%CNC materials increased from 325-450-600-800 for the samples milled for 0.5, 1, 2, and 5 hours respectively. The other concentrations used were found to yield similar values and trends. SEM micrographs showed that small precipitates had formed within the grains except materials milled at 5 hours, which showed the production of very coarse particles at the grain boundaries. Similarly, an attrition mill was used to mechanically alloy titanium with varying CNC concentrations. Milling time was also varied. The powders were consolidated, sintered and characterized. It was found that increasing CNC content at low milling times caused a reduction in hardness. The X-ray diffractograms also showed a trend in that the diffraction patterns shifted to the lower angle with increasing CNC concentration, thereby suggesting that the increase in CNC content facilitated the removal of oxygen atoms housed within the interstitial sites. The oxygen was observed to diffuse and precipitate platelet titanium dioxide particles. These particles were found to be located within the titanium grains and coarsened with milling time. Generally, increasing the milling time to 15 hours was found precipitate particles at the grain boundaries as well as to excessively dissolve oxygen into the titanium lattice leading to embrittlement. The materials milled for 5 hours showed the best increase in strength while maintaining good ductility. / Master of Science / Titanium has only been used industrially since the early 1940’s thanks in large to the modern advances to reduce titanium ore to its elemental state. Titanium gained much interest as a structural material because of its corrosion resistance and its exceptional strength for a lightweight metal, making the material ideal for medical and aerospace applications. Pure titanium was found to be soft and had poor wear resistance, therefore, efforts were made to create titanium alloys which mitigated these weaknesses. Often titanium is alloyed with costly and toxic elements to enhance its strength properties, making it dangerous to use in the medical field. One way to enhance the strength properties of titanium without the addition of these harmful alloying elements is to create a titanium composite by adding strong inert particles to a titanium matrix. One method to create titanium metal matrix composites is to violently mix titanium powder with the reinforcement material, through a process called mechanically alloying. Following the mixing process the powder is then compacted and heated to form a solid part through a process called sintering. While these powder processing methods are known and viable for forming titanium metal matrix composites, some of the reinforcement materials can be expensive. In this thesis, cellulose nanocrystals (CNCs) will be added as reinforcement to titanium by means of two mechanical alloying processes, vibratory milling (shaking) and attrition milling (stirring). CNCs can be derived from plant matter which is widely abundant and inexpensive. The viability of CNCs to be used as a reinforcement material, as well as the mechanical alloying processes were investigated to determine the effect on the titanium strength properties. The powder processing steps were found to cause the CNCs to react with the surrounding titanium matrix which caused beneficial oxides to form as the reinforcement materials. In general, it was found that vibratory milling caused the final titanium metal matrix composite to be hard and brittle. Attrition milling was found to be more favorable as some materials were observed to be strong yet ductile. Titanium Metal Matrix Composites Cellulose Nanocrystals Particulate Reinforcement Mechanical Alloying
30	Processing and Properties of Amorphous NiW Reinforced Crystalline Ni Matrix Composites Wensley, Charles Alexander 13 January 2006 (has links) Metal Matrix Composites (MMCs) are used as structural materials because of their ability to have a combination of high strength and good ductility. A common problem with MMCs utiliz-ing vastly different materials is the difficulty in forming a strong matrix/reinforcement interface without suffering extensive dissolution, debonding, or chemical reactions between the compo-nents. In this work, a nickel base amorphous particulate reinforced crystalline nickel matrix composite is processed. The reinforcement, an equimolar NiW amorphous powder, was synthe-sized using the mechanical alloying process. The amorphous and crystalline nickel powders were blended in varying volume fractions and then consolidated using hot-isostatic pressing (HIP). This work reveals that the amorphous NiW reinforcement provides strength and hardness to the ductile Ni matrix while simultaneously maintaining a strong interfacial bond due to the similar chemistry of the two components. The strengthening achieved in the composite is attrib-uted to the particulate/matrix boundary strengthening. / Master of Science Particulate Reinforcement Amorphous Mechanical Alloying Metal Matrix Composites

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