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51	Elaboração e estudos de recristalização de ligas alumínio-magnésio-tório e alumínio-magnésio-nióbio ALMEIDA FILHO, AMERICO de 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:50:54Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T13:58:07Z (GMT). No. of bitstreams: 1 11108.pdf: 32426138 bytes, checksum: e0fd60a0b29703462d6537e5ea445860 (MD5) / Tese (Doutoramento) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN/CNEN-SP aluminium alloys powder metallurgy recrystallization microstructure
52	Comportamento mecanico de cermets Usub (3)Osub (8)Al FIGUEIREDO, ANACLETO M. de 09 October 2014 (has links) Made available in DSpace on 2014-10-09T12:30:45Z (GMT). No. of bitstreams: 0 / Made available in DSpace on 2014-10-09T14:00:34Z (GMT). No. of bitstreams: 1 01481.pdf: 5222933 bytes, checksum: 404da01814721acc7363f150cb1a7937 (MD5) / Dissertacao (Mestrado) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN/CNEN-SP cermets fuel elements mechanical properties powder metallurgy
53	Desenvolvimento de implantes dentários por técnicas de metalurgia do pó / Development of the dental implants by powder metallurgy techniques BOMFIM, PAMELA K. dos S. 07 August 2015 (has links) Submitted by Claudinei Pracidelli (cpracide@ipen.br) on 2015-08-07T13:57:03Z No. of bitstreams: 0 / Made available in DSpace on 2015-08-07T13:57:04Z (GMT). No. of bitstreams: 0 / O interesse crescente no desenvolvimento de biomateriais com superfície porosa para aplicações dentárias decorre do suporte propicio ao crescimento do tecido ósseo, aumentando a adesão entre o tecido e material, favorecendo a osteointegração. O titânio pode ser considerado um ótimo material para implantes dentários, pela sua excelente biocompatibilidade, elevada resistência à corrosão e combinação de alta resistência com baixa densidade. Contudo, a alta reatividade do metal no estado líquido acaba dificultando a fabricação de implantes por fundição, sendo a metalurgia do pó composta por técnicas que permitem a obtenção de peças em temperaturas menores de processamento (estado sólido) e com módulo elástico próximo ao do tecido ósseo. O objetivo deste trabalho foi avaliar amostras porosas obtidas pela Metalurgia do Pó (MP) convencional. Inicialmente o pó de titânio comercialmente puro (Ti-cp) obtido pelo processo de hidretação-dehidretação (HDH), foi compactado em matriz uniaxial e sinterizado a vácuo em duas temperaturas,1100 e 1150°C/1h. As amostras sinterizadas foram caracterizadas quanto à densidade, porosidade, microestrutura ( microscopia óptica - MO e microscopia eletrônica de varredura - MEV), fases cristalinas (difração de raios - X - DRX), propriedades mecânicas (microdureza e ensaio de flexão em três pontos), comportamento eletroquímico (potencial de circuito aberto, espectroscopia de impedância eletroquímica e polarização anódica) e o ensaio de imersão foram empregados nas amostras obtidas por (MP) e no titânio fundido. Os resultados indicaram morfologia angular, distribuição granulométrica com média de 45 μm, além de densidade aparente e escoabilidade baixas. Foram obtidas amostras com porosidade de aproximadamente 33% e poros interligados dentro de uma faixa de tamanho de 110 140 μm. As análises por MEV e DRX das amostras sinterizadas indicaram a presença de fase α e poros. As amostras sinterizadas a 1150°C revelaram melhor comportamento mecânico em relação as amsotras sinterizadas a 1100°C. As análises eletroquímicas indicaram a elevada resistência a corrosão do titânio fundido, seguida pela amostra sinterizada 1100°C e finalmente das sinterizadas a 1150°C, quando imersas em solução da saliva artificial. O EDS foi executado para verificar a deposição de elementos na superfície. Testes de citotoxicidade demonstraram que o pó e as amostras sinterizadas não apresentaram qualquer efeito tóxico em culturas celulares. As amostras sinterizadas à 1100°C possuiam grau de porosidade e tamanho de poros que favoreceram o crescimento do tecido ósseo, além do módulo de elasticidade próximo ao tecido ósseo e foram mais resistentes a corrosão na solução simuladora. / Dissertação (Mestrado em Tecnologia Nuclear) / IPEN/D / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP biomaterials implants titanium powder metallurgy porosity biocompatibility
54	Development of Steel-Alumina Composites for Wear Applications Kuforiji, Catherine January 2017 (has links) Ceramic-metal matrix composites produced by powder metallurgy provide a solution in engineering applications where materials with high wear resistance are required. In the mining industry, the wear of materials is a crucial and widely recognized industrial problem as over 50 % of components fail as a result of wear damage. Increasing the wear resistance of these components will contribute to a reduction in maintenance and thereby increase efficiency. In this present research, SS316L-50wt.% Al2O3 composites were fabricated using the powder metallurgy route. The effects of the powder metallurgy processing parameters were studied. The produced cermet composites were characterized with respect to microstructure, density, hardness and toughness. Furthermore, the wear behavior of the composites was studied using pin-on-disc testing under dry sliding conditions. The produced test results were used to improve existing wear models, particularly the Wayne’s model. The highest hardness of 1085.2 HV, the highest density of 94.7 % and the lowest wear rate of 0.00397 mm3/m were obtained at a milling speed of 720 rpm, a compaction pressure of 794.4 MPa and sintering at 1400 °C in an argon atmosphere. Compared to commercial SS316 and fabricated SS316L, the composites had 7.4 times and 11 times lower wear rate, respectively. However, it is shown that using better densification methods such as hot isostatic pressing (HIP) or hot pressing can further substantial enhanced densification and improve of the composites wear resistance. Similar to its effects of the strength and the toughness, the remaining porosity was found to substantially affect the wear resistance of the sintered composites. Therefore, the porosity was used to correct the abrasion parameter in the first step of wear model improvement. The porosity represented a further consideration of the microstructure in addition to the reinforcement particle size introduced earlier by Wayne. In a second model improvement step, the test conditions were introduced in the wear resistance calculation. This model allowed the prediction of corrected wear resistance values that are characteristic of the individual test materials and are widely independent of wear test conditions. The coefficient of correlation of the model was 0.91 with respect to Wayne's data and wear test results from this study, and was 0.66 after generalization to a large range of wear data measured on multiple materials tested under varying test conditions. This opens a potential avenue for a model-based assessment of the wear resistance of novel materials as well as changes that can be expected under different wear conditions. SS316L, Alumina Composites Powder metallurgy Wear resistance
55	De-lubrication during sintering of P/M compacts: Operative mechanism and process control strategy Saha, Deepak 01 October 2004 (has links) "De-lubrication is the first stage in a sintering operation, where the lubricants (higher weight hydrocarbons) are removed from the parts by controlled heating. Improper de-lubrication leads to defects such as blistering, sooting, micro-porosity etc in a sintered part. Most of these problems arise, as there exists a gap in the present understanding of de-lubrication. The primary motive of this work is to direct research towards the development of sensors and controls and thus, mitigate the various problems due to improper de-lubrication. Currently, there exists a myriad of lubricants being used during the process of compaction. They include metallic based lubricants, polymers and non-metallic lubricants. In this work, research was limited in understanding the de-lubrication of EBS (Ethylene Bisstearimide), as, it the most commonly used lubricant in the industry. It has replaced commonly used lubricant due to cleaner burnouts, absence of metallic residue and, cost effectiveness. The entire work is divided into three phases: â€¢ Phase 1: Ascertained the most important parameters that affect the kinetics of de-lubrication. â€¢ Phase 2: Investigated the type of gases released during the decomposition of EBS. â€¢ Phase 3: Recommended a control strategy. TGA (Thermo-gravimetric analysis) was used in the phase I, the results clearly show that the rate of heating is the most important parameter during de-lubrication. Identification of gases was performed using the FTIR (Fourier transform infrared spectroscopy) and DUV (Deep ultraviolet spectroscopy). This constituted the second phase of our experiments. The primary gases identified in Phase II were carbon dioxide and a hydrocarbon (hepta-decane). Finally, an empirical model for de-lubrication has been proposed in Phase III. The model was verified in an industrial furnace. It has been observed that there exists a very good correlation between the proposed empirical model and the experiments performed in Phase II of this study. This study lays down the following guidelines for the development of future sensors and controls: â€¢ The development of future sensors should focus in the detection of CO2 and hepta-decane. â€¢ Rate of heating determines how fast or slow the lubricant decomposes and finally escapes form the compacted part. â€¢ The empirical model may be used, as a means to determine the time a part should reside in a furnace for complete lubricant burnout at a given heating rate." delubrication powder metallurgy lubricant pyrolysis sintering De-lubrication Sintering Powder metallurgy Lubrication and lubricants Metals Heat treatment
56	Materials & Machines: Simplifying the Mosaic of Modern Manufacturing Birt, Aaron M 25 April 2017 (has links) Manufacturing in modern society has taken on a different role than in previous generations. Today’s manufacturing processes involve many different physical phenomenon working in concert to produce the best possible material properties. It is the role of the materials engineer to evaluate, develop, and optimize applications for the successful commercialization of any potential materials. Laser-assisted cold spray (LACS) is a solid state manufacturing process relying on the impact of supersonic particles onto a laser heated surface to create coatings and near net structures. A process such as this that involves thermodynamics, fluid dynamics, heat transfer, diffusion, localized melting, deformation, and recrystallization is the perfect target for developing a data science framework for enabling rapid application development with the purpose of commercializing such a complex technology in a much shorter timescale than was previously possible. A general framework for such an approach will be discussed, followed by the execution of the framework for LACS. Results from the development of such a materials engineering model will be discussed as they relate to the methods used, the effectiveness of the final fitted model, and the application of such a model to solving modern materials engineering challenges. cold spray laser Machine Learning manufacturing powder metallurgy
57	The consolidation and transformation of an ultra-ferritic stainless steel by hot isostatic pressing Kian, Michael Christopher Wong. January 1998 (has links) A dissertation submitted to the faculty of Engineering, University of the Witwatersrand, Johanuesburg, in fulfilment of the requirements for the degree of Master of Science in Engineering. / Ferritic stainless steels possess a number of properties which render them superior to austenitic stainless steels in certain applications. The ferritic stainless steels are highly resistant to stress-corrosion cracking and are generally of lower cost. Previous work had shown that the corrosion properties of the ferritic steels were optimised at a chromium content of forty percent. Extensive research had already characterised the mechanical and corrosion behaviour of the Fe"40Cr alloy in the cast and wrought form. This investigation involves the development of the material by powder metallurgy processing. Particular emphasis is placed on a proprietary powder production technique as well as on powder consolidation by Hot Isostatic Pressing. The effect of Ni, Mo, Ru, Nb, Al and Fe additions and well as various techniques of introducing these additions are examined. The unique effect of powder metallurgy manufacture on microstructure and the kinetics of sigma phase formation is highlighted. Corrosion tests in various concentrations of sulphuric acid and an industrial field trial were performed. It was found that combined Ni and Mo contents exceeding four percent resulted in severe embrittlement due to widespread formation of sigma phase during the HIP process. The use of powder metallurgy techniques was also found to enhance the kinetics of sigma phase formation in a particular alley when compared to the as-cast state. Direct additions of Fe powder were successful in inhibiting embrittlement, possibly due to a mechanism of Fe diffusion into Cr-rich regions. This lowered of the Cr content in these regions, thereby reducing the tendency for sigma precipitation. Corrosion tests indicate satisfactory resistance for the Fc-40Cr-2Ni-2Mo alloys in 70 weight percent sulphuric acid at 50°C. Alloys with 0.2 percent Ru additions were found to be especially resistant, due to the role of Ru as a cathodic modifier. The method of mixing and diffusion bonding metallic powders of varying composition was found to be feasible and certain novel combinations of Ni and Fe-rich alloys exhibited satisfactory corrosion resistance. A mathematical diffusion model was found to provide an order of magnitude approximation of the time required for hornogentsation in a certain mixture of powders. / Andrew Chakane 2018 Ferritic steel. Isostatic pressing. Powder metallurgy -- Pressing. Stainless steel.
58	Desenvolvimento de implantes dentários por técnicas de metalurgia do pó / Development of the dental implants by powder metallurgy techniques Bomfim, Pamela Karina dos Santos 08 August 2014 (has links) O interesse crescente no desenvolvimento de biomateriais com superfície porosa para aplicações dentárias decorre do suporte propicio ao crescimento do tecido ósseo, aumentando a adesão entre o tecido e material, favorecendo a osteointegração. O titânio pode ser considerado um ótimo material para implantes dentários, pela sua excelente biocompatibilidade, elevada resistência à corrosão e combinação de alta resistência com baixa densidade. Contudo, a alta reatividade do metal no estado líquido acaba dificultando a fabricação de implantes por fundição, sendo a metalurgia do pó composta por técnicas que permitem a obtenção de peças em temperaturas menores de processamento (estado sólido) e com módulo elástico próximo ao do tecido ósseo. O objetivo deste trabalho foi avaliar amostras porosas obtidas pela Metalurgia do Pó (MP) convencional. Inicialmente o pó de titânio comercialmente puro (Ti-cp) obtido pelo processo de hidretação-dehidretação (HDH), foi compactado em matriz uniaxial e sinterizado a vácuo em duas temperaturas,1100 e 1150°C/1h. As amostras sinterizadas foram caracterizadas quanto à densidade, porosidade, microestrutura ( microscopia óptica - MO e microscopia eletrônica de varredura - MEV), fases cristalinas (difração de raios - X - DRX), propriedades mecânicas (microdureza e ensaio de flexão em três pontos), comportamento eletroquímico (potencial de circuito aberto, espectroscopia de impedância eletroquímica e polarização anódica) e o ensaio de imersão foram empregados nas amostras obtidas por (MP) e no titânio fundido. Os resultados indicaram morfologia angular, distribuição granulométrica com média de 45 μm, além de densidade aparente e escoabilidade baixas. Foram obtidas amostras com porosidade de aproximadamente 33% e poros interligados dentro de uma faixa de tamanho de 110 140 μm. As análises por MEV e DRX das amostras sinterizadas indicaram a presença de fase α e poros. As amostras sinterizadas a 1150°C revelaram melhor comportamento mecânico em relação as amsotras sinterizadas a 1100°C. As análises eletroquímicas indicaram a elevada resistência a corrosão do titânio fundido, seguida pela amostra sinterizada 1100°C e finalmente das sinterizadas a 1150°C, quando imersas em solução da saliva artificial. O EDS foi executado para verificar a deposição de elementos na superfície. Testes de citotoxicidade demonstraram que o pó e as amostras sinterizadas não apresentaram qualquer efeito tóxico em culturas celulares. As amostras sinterizadas à 1100°C possuiam grau de porosidade e tamanho de poros que favoreceram o crescimento do tecido ósseo, além do módulo de elasticidade próximo ao tecido ósseo e foram mais resistentes a corrosão na solução simuladora. / The development of materials with a porous surface has been widely studied in the field of biomaterials, because the porous structure allows bone tissue growth, increasing the bonding since the tissue and the material, favoring osteointegration. Given the excellent biocompatibility, high corrosion resistance and combination of high strength with low density, titanium is one of the most suitable materials for dental implants. However, the high reactivity in liquid state ends up hindering their fusion. The technique of powder metallurgy (PM) is an alternative for cost reduction, allowing to obtain superior samples at lower temperatures, closer to the bone tissue in terms of elastic modulus. The objective of this study was to evaluate porous samples obtained by conventional PM. Initially the powder of commercially pure titanium (cp-Ti) was obtained by hydridedehydride (HDH) process, followed by uniaxial pressing and vacuum sintering at 1100 and 1150 °C/1h. The sintered samples were characterized - density, porosity, microstructure (SEM), crystalline phases (XRD), mechanical properties (microhardness and three point bending test), electrochemical behavior (open circuit potential, anodic polarization and electrochemical spectroscopy impedance and immersion essay) applied in porous samples and cast titanim The results indicated angular particle morphology, 45 μm average particle size distribution, low apparent density and flowability. The different processing temperatures enabled to obtain samples with approximately 33 % interconnected porosity and average pore size in 110-140μm range. SEM and XRD analysis of the sintered samples revealed the presence of α phase and pores. Samples sintered at 1150°C showed superior mechanical behavior. Electrochemical analysis (in artificial saliva solution) indicated higher corrosion resistance of cast titanium compared to porous samples . Cytotoxicity tests proved that the powder and sintered samples has no toxic effects on cell cultures. Samples sintered at 1100 °C excels in bone growth stimulation, elasticity modulus and corrosion resistance, due to superior porosity and pore size range properties, creating a material analogous to the bone. biocompatibilidade biocompatibility metalurgia do pó porosidade porosity powder metallurgy
59	Active and Passive Thermography for the Detection of Defects in Green-State Powdermetallic Compacts Benzerrouk, Souheil 20 September 2011 (has links) "Despite its maturity, the powder metallurgy (PM) fabrication process continues to rely heavily on indirect methods to determine and predict the quality of its compacts early in the manufacturing line. Currently, the most comprehensive testing is performed on sintered parts, resulting in higher cost and increased waste. This dissertation addresses the need of early inspection by developing a novel approach whereby PM compacts are tested in the green-state without intrusion and with minimal cost per compact tested. The method is based on an infrared detection scheme with two fundamental embodiments. For high resolution applications, or offline testing, an active thermography approach is adopted; electric energy is deposited into the compact in a contact-less fashion to evaluate all parts for cracks, inclusions, or delaminations. As an alternative, for lower resolution high-yield applications, a system based on a passive thermography approach is developed. This system relies on residual heating emanating from the process. Thermal data is then collected and analyzed in an effort to yield part integrity and process stability information. In this dissertation we will discuss our design approach, theoretical modeling aspects, and a proof-of-concept instrument with associated data processing software. We will first describe the underlying physical principles, followed by predictions from the modeling formulation, including a solution of the heat equation. As part of our experimental data processing, we will present results that are collected both in a laboratory setting and in an industrial manufacturing line. The integrity of the compacts is carried out with the aid of a specialized software package." thermography infrared imaging nondestructive evaluations powder metallurgy ndt
60	Synthesis Effects on Grain Size and Phase Content in the Anatase-Rutile TiO2 System Farrell, Kimberly A. 16 August 1999 (has links) "The phase content and grain size of titanium dioxide often have a strong influence on properties for a variety of applications. In many cases it would be desirable to produce the stable rutile phase with an ultra-fine particle size (<10nm), but most low temperature synthesis methods produce predominantly the metastable anatase phase. The anatase-rutile transformation in TiO2 is known to be affected by dopant type and concentration, as well as the titanium precursor used in solution chemical synthesis. Recently, use of cavitation in the synthesis process has been shown to yield smaller grain size for a variety of oxides. However, the relative importance of these synthesis variables on the grain size and phase content of TiO2 is not well understood. In this study, Taguchi analysis was used to determine the relative effects of dopants (Sn), titanium precursor (butoxide, sulfate, chloride), and cavitation power on grain size and phase content. Precursor residuals were also measured by analytical chemistry. Grain size and phase content results were analyzed statistically to determine whether there is a size dependence of the anatase-rutile transformation. Results show that grain size is strongly dependent on the concentration of chlorine. Absent chlorine, a definite grain size-phase content correlation exists; rutile content increases as grain size decreases. An L-4 orthogonal Taguchi analysis shows chlorine content and tin content as the major influences on the final product. With minimum grain size and maximum rutile content being considered optimal, our best result was 100% rutile and an average grain size of 5nm, which was achieved by acoustic synthesis with 3% tin dopant and low residual chlorine. " grain size rutile titania Titanium dioxide Powder metallurgy Nanostructured materials

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