Global ETD Search

111	Investigation of Novel Precursor Routes for Incorporation of Titanium Alloys and Nano-Sized Features into Ceramic-Metallic Composites Formed via the TCON Process Myers, Kyle M. January 2012 (has links) No description available. Chemistry Materials Science Ceramic-Metallic Composites Reactive Metal Penetration Alumina Composites Spinel Composites
112	Mechanical response of unidirectional Boron/Aluminum under combined loading Becker, Wolfgang January 1987 (has links) Three test methods were employed to characterize the response of unidirectional Boron/Aluminum metal matrix composite material under monotonic and cyclic loading conditions, namely: Iosipescu Shear, Off-Axis Tension and Compression. The characterization of the elastic and plastic response includes the elastic material properties, yielding and subsequent hardening of the unidirectional composite under different stress ratios in the material principal coordinate system. The elastic response is compared with the prediction of the transformation theory, based on the far field stress ōₓₓ, the Pagano-Halpin Model, and finite element analysis. Yield loci were generated for different stress ratios and were compared for the three different test methods, taking into account residual stresses and specimen geometry. The yield locus for in-plane shear was compared with the prediction of an analytical micromechanical model. The influence of the scatter in the experimental data on the predicted yield surface was also analyzed. Likewise the experimental material strength in tension and compression was compared with the Maximum Stress and the Tsai-Wu failure criterion. / M.S. LD5655.V855 1987.B42 Anisotropy Aluminum -- Testing Boron -- Testing Metallic composites Composite materials -- Testing
113	Analysis of metal matrix composite structures using a micromechanical constitutive theory Arenburg, Robert Thomas January 1988 (has links) The nonlinear behavior of continuous-fiber-reinforced metal-matrix composite structures is examined using a micromechanical constitutive theory. Effective lamina and laminate constitutive relations based on the Aboudi micromechanics theory are presented. The inelastic matrix behavior is modeled by the unified viscoplasticity theory of Bodner and Partom. The laminate constitutive relations are incorporated into a first-order shear deformation plate theory. The resulting boundary value problem is solved by utilizing the finite element method. · Computational aspects of the numerical solution, such as the temporal integration of the inelastic strains and the spatial integration of bending moments are addressed. Numerical results are presented which illustrate the nonlinear response of metal matrix composites subjected to extensional and bending loads. Experimental data from available literature are in good agreement with the numerical results. / Ph. D. / incomplete_metadata LD5655.V856 1988.A736 Metallic composites Composite construction Structural analysis (Engineering)
114	Effective thermal condutivity of damaged composites Graham, Samuel, Jr. 08 1900 (has links) No description available. Composite materials Fracture Composite materials Cracking Metallic composites Thermal properties Micro mechanics Fracture mechanics
115	Electrodeposited Metal Matrix Composites for Enhanced Corrosion Protection and Mechanical Properties Thurber, Casey Ray 05 1900 (has links) In the oil and gas industry, high corrosion resistance and hardness are needed to extend the lifetime of the coatings due to exposure to high stress and salt environments. Electrodeposition has become a favorable technique in synthesizing coatings because of low cost, convenience, and the ability to work at low temperatures. Electrodeposition of metal matrix composites has become popular for enhanced corrosion resistance and hardness in the oil and gas industry because of the major problems that persist with corrosion. Two major alloys of copper-nickel, 90-10 and 70-30, were evaluated for microbial corrosion protection in marine environments on a stainless steel substrate. Copper and copper alloys are commonly used in marine environments to resist biofouling of materials by inhibiting microbial growth. Literature surveying the electrodeposition of Cu-Ni incorporated with nano- to micro- particles to produce metal matrix composites has been reviewed. Also, a novel flow cell design for the enhanced deposition of metal matrix composites was examined to obtain the optimal oriented structure of the layered silicates in the metal matrix. With the addition of montmorillonite into the Ni and Cu-Ni matrix, an increase in strength, adhesion, wear and fracture toughness of the coating occurs, which leads to an increase corrosion resistance and longevity of the coating. These coatings were evaluated for composition and corrosion using many different types of instrumental and electrochemical techniques. The overall corrosion resistance and mechanical properties were improved with the composite films in comparison to the pure metals, which proves to be advantageous for many economic sectors including the oil and gas industry. Cu-Ni copper-nickel montmorillonite corrosion coatings analytical chemistry electrodeposition Corrosion resistant alloys. Alloy plating. Metallic composites. Montmorillonite.
116	Room and Elevated Temperature Sliding Wear Behavior of Cold Sprayed Ni-WC Composite Coatings Torgerson, Tyler B. 08 1900 (has links) The tribological properties of cold sprayed Ni-WC metal matrix composite (MMC) coatings were investigated under dry sliding conditions from room temperature (RT) up to 400°C, and during thermal cycling to explore their temperature adaptive friction and wear behavior. Characterization of worn surfaces was conducted using scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), and Raman spectroscopy to determine the chemical and microstructural evolution during friction testing. Data provided insights into tribo-oxide formation mechanisms controlling friction and wear. It was determined that the steady-state coefficient of friction (CoF) decreased from 0.41 at RT to 0.32 at 400˚C, while the wear rate increased from 0.5×10-4 mm3/N·m at RT to 3.7×10-4 mm3/N·m at 400˚C. The friction reduction is attributed primarily to the tribochemical formation of lubricious NiO on both the wear track and transfer film adhered to the counterface. The increase in wear is attributed to a combination of thermal softening of the coating and a change in the wear mechanism from adhesive to more abrasive. In addition, the coating exhibited low friction behavior during thermal cycling by restoring the lubricious NiO phase inside the wear track at high temperature intervals. Therefore, cold sprayed Ni-WC coatings are potential candidates for elevated temperature and thermally self-adaptive sliding wear applications. cold spray metal matrix composite dry sliding wear elevated temperature tribology oxidative wear Metallic composites. Tribology. Coatings -- Thermal properties.
117	A New Approach to Sensitized Luminescence in Trivalent Lanthanide Coordination Polymers: From Fundamental Luminescence and Crystal Engineering Toward Sensing Applications Unknown Date (has links) Luminescent lanthanide containing coordination polymers and metal-organic frameworks hold great potential in many applications due to their distinctive spectroscopic properties. While the ability to design coordination polymers for specific functions is often mentioned as a major benefit bestowed upon these compounds, the lack of a meaningful understanding of the crystal engineering and luminescence in lanthanide coordination polymers remains a significant challenge toward functional design. Currently, the study of luminescence attributed to these compounds is based on the antenna effect as derived from molecular systems, where organic antennae are used to facilitate lanthanide-centered luminescence. This molecular based approach does not take into account the unique features of extended network solids, particularly the formation of band structure. By comparing molecular and band-based approaches, it was determined that the band structure of the organic sensitizing linker needs to be considered when evaluating the luminescence of lanthanide coordination polymers. This new model, as well as work on the crystal engineering and sensor applications of these materials will be presented. / Includes bibliography. / Dissertation (Ph.D.)--Florida Atlantic University, 2017. / FAU Electronic Theses and Dissertations Collection Rare earth metals. Lanthanide shift reagents. Organic compounds--Synthesis. Inorganic compounds--Synthesis. Metallic composites--Speciation. Polymeric composites. Organorare earth metal compounds. Nanostructured materials.
118	Experimental and numerical study of metal foam composites in innovative application of thermal energy storage / Etude expérimentale et numérique des mousses métalliques composites dans une application d'énergie thermique Zhu, Feng 16 March 2017 (has links) L'objectif de cette thèse de doctorat est d'étudier expérimentalement et numériquement le comportement thermique des mousses d'aluminium et des matériaux à changement de phase (MCP), présentés sous la forme d’un composite, afin de connaître le phénomène de stockage d’énergie thermique dans ces matériaux. Le procédé de fabrication de la mousse d'aluminium à cellules ouvertes est d’abord analysé numériquement dans le but de réduire les défauts formés durant la fabrication. Les caractéristiques de transfert de chaleur du MCP dans les mousses d'aluminium comportant différentes porosités sont ensuite étudiées en analysant les processus de fusion et la variation de températures dans ces composites. Deux modèles numériques pour la mousse d'aluminium à faible et à haute porosité sont établis afin d’évaluer la performance de stockage d'énergie des composites. Les résultats montrent que la mousse d'aluminium peut améliorer considérablement la performance de transfert de chaleur du MCP en raison de sa conductivité thermique élevée. La performance de stockage d'énergie dépend fortement de la porosité des mousses d'aluminium. Une porosité optimisée met en évidence cette performance et l’amélioration du comportement thermique. La dernière partie de la thèse porte sur une structure améliorée de la mousse par rapport à la structure uniforme: Association de l’ailette métallique et du gradient de porosité de la mousse. Cette nouvelle structure donne ainsi une performance de stockage d'énergie encore meilleure surtout dans le cas d’une source de chaleur isotherme / The objective of this Ph.D. thesis is to study the thermal behavior of the aluminum foam and phase change material (PCM) composite by both experimental and numerical methods in order to know the phenomena of storage of thermal energy in these materials. The manufacturing process of open-cell aluminum foam is firstly analyzed numerically to reduce the manufacturing defects in the samples. The heat transfer characteristics of PCM embedded in aluminum foams with different porosities are then investigated by analyzing the melting processes and the temperature variations in the composites. Two numerical models for low and high porosity aluminum foam are established to evaluate the energy storage performance of the composites. The results show that the aluminum foam can greatly improve the heat transfer performance in PCM due to its high thermal conductivity. The energy storage performance depends strongly on the porosity of the aluminum foam/PCM composite. An optimized porosity highlights this performance and improves the thermal behavior. The last part of this thesis proposes an improved structure of aluminum foam with respect to the uniform structure: Association of the metal fin and the foam with graded porosity. This new structure possesses a better energy storage performance especially in the case of the isothermal heat source Mousses métalliques Composites à matrice métallique Simulation, Méthodes de Chaleur -- Stockage Analyse thermique Metal foams Metallic composites Simulation methods Heat storage Thermal analysis 671.722
119	Processing and Characterization of Nickel-Carbon Base Metal Matrix Composites Borkar, Tushar Murlidhar 05 1900 (has links) Carbon nanotubes (CNTs) and graphene nanoplatelets (GNPs) are attractive reinforcements for lightweight and high strength metal matrix composites due to their excellent mechanical and physical properties. The present work is an attempt towards investigating the effect of CNT and GNP reinforcements on the mechanical properties of nickel matrix composites. The CNT/Ni (dry milled) nanocomposites exhibiting a tensile yield strength of 350 MPa (about two times that of SPS processed monolithic nickel ~ 160 MPa) and an elongation to failure ~ 30%. In contrast, CNT/Ni (molecular level mixed) exhibited substantially higher tensile yield strength (~ 690 MPa) but limited ductility with an elongation to failure ~ 8%. The Ni-1vol%GNP (dry milled) nanocomposite exhibited the best balance of properties in terms of strength and ductility. The enhancement in the tensile strength (i.e. 370 MPa) and substantial ductility (~40%) of Ni-1vol%GNP nanocomposites was achieved due to the combined effects of grain refinement, homogeneous dispersion of GNPs in the nickel matrix, and well-bonded Ni-GNP interface, which effectively transfers stress across metal-GNP interface during tensile deformation. A second emphasis of this work was on the detailed 3D microstructural characterization of a new class of Ni-Ti-C based metal matrix composites, developed using the laser engineered net shaping (LENSTM) process. These composites consist of an in situ formed and homogeneously distributed titanium carbide (TiC) as well as graphite phase reinforcing the nickel matrix. 3D microstructure helps in determining true morphology and spatial distribution of TiC and graphite phase as well as the phase evolution sequence. These Ni-TiC-C composites exhibit excellent tribological properties (low COF), while maintaining a relatively high hardness. Spark plasma sintering SPS laser engineering net shaping LENSTM nickel carbon nanotube CNT grapheme nanoplatelet GNP titanium carbide TiC phase evolution Nickel. Carbon nanotubes. Graphene. Metallic composites.
120	Aluminum foams composite : elaboration and thermal properties for energy storage / Mousses d’aluminium composites : élaboration et propriétés thermiques pour le stockage d’énergie Zhang, Chuan 07 July 2017 (has links) L'objectif de cette thèse est d'étudier et d'optimiser le processus de fabrication des mousses métalliques et le comportement thermique du matériau de la mousse d'aluminium/matériau de changement de phase (MCP) par des méthodes expérimentales et numériques. Le processus d’élaboration de la mousse d’aluminium à pore ouvert est développé et optimisé pour contrôler précisément les paramètres de fabrication. Deux modèles de mousse d'aluminium à haute porosité (MAHP)/MCP composite et à faible porosité (MALP)/MCP composite sont établis pour la simulation numérique. En simulant le processus de fusion d'un système de stockage d'énergie, les composites MAHP/MCP et MALP/MCP sont comparés numériquement afin d'évaluer la performance de stockage d'énergie thermique. Les résultats montrent que la mousse d'aluminium améliore nettement le processus de transfert de chaleur dans MCP en raison de sa haute conductivité thermique. La porosité des mousses d'aluminium influence non seulement le processus de fusion du composite mais aussi la performance de stockage d'énergie thermique. Grâce à la collaboration avec EPF, une nouvelle méthode d’élaboration des mousses périodiques d'aluminium à pore ouvert est développée dans cette thèse sur la base d’impression 3D. Le comportement thermique des mousses d'aluminium périodiques à pore ouvert/MCP est analysé expérimentalement et numériquement / The objective of this thesis is to study and optimize the manufacturing process of metal foams and the thermal behavior of the aluminum foam/phase change material (PCM) composite by experimental and numerical methods. The manufacturing process of open-cell aluminum foam is developed and optimized to precisely control the parameters of mufacturing. Two pore-scale models of high porosity aluminum foams (HPAF)/PCM composite and low porosity aluminum foams (LPAF)/PCM composite are established for numerical simulation. By simulating the melting process of a layer energy storage system, the HPAF/PCM and LPAFS/PCM composite are compared numerically in order to evaluate the energy storage performance. The results show that aluminum foam improves greatly the heat transfer process in PCM due to its high thermal conductivity. The porosity of aluminum foams could not only influence the melting process of composite but also the energy storage performance. Thanks to the collaboration with EPF, a new manufacturing method of periodic open-cell aluminum foams is developed based on 3D rapid tooling. The thermal behavior of the periodic open-cell aluminum foams/PCM composite is experimentally and numerically analyzed Mousses métalliques Chaleur -- Stockage Composites à matrice métallique Analyse thermique Simulation, Méthodes de Impression 3D Metal foams Heat storage Metallic composites Thermal analysis Simulation methods Three-dimensional printing 671.2

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