Global ETD Search

11	Material Characterization and Forming of Light Weight Alloys at Elevated Temperature Shah, Manan Kanti 29 July 2011 (has links) No description available. Engineering Mechanical Engineering Metallurgy Sheet hydroforming Aluminum alloy AA5754-O Magnesium alloy MgAZ61L finite element simulation hydraulic bulge test warm forming hot stamping material properties
12	Templated Metallic Nanostructures on Electrospun Fibers: Synthesis, Mechanical Characterization and Filtration Application Temitope Q Aminu (10716801) 29 April 2021 (has links) <p>The functionalization of nonwoven electrospun polymeric fibers with metallic nanostructures has enabled the design of novel nanocomposite materials used in a wide range of applications. In particular, designs based on incorporating established antimicrobial species such as copper and silver have potential applications as antimicrobial filtration membranes, leveraging on the convoluted fiber assembly and high surface area–to–volume ratios of the constitutive fibers. Electroless deposition based on spontaneous electrochemical reactions offers a facile and tunable methodology for surface–confined growth of metallic nanostructures on the non–planar substrate architectures presented by nonwoven electrospun fibers. </p> <p>Firstly, this work explores, in a broad sense, the effects of two different seed catalyst chemistries, palladium and silver, on the evolution of copper nanoparticles on electrospun polyacrylonitrile fibers. Copper nanoparticle coverage and conformity; deposition kinetics; modifications in the surface chemistry of the PAN fibers; and thermal stability of the resultant nanocomposites were examined. Secondly, qualitative and quantitative assessment of the interfacial adhesion between the copper nanostructures and PAN fibers were undertaken by exploiting the elastic mismatch between both phases during tensile deformation. For copper nanocubes on nanofibers, the adhesion energy is estimated to be between 0.48 J/m<sup>2</sup> and 1.0 J/m<sup>2</sup> using strain and growth based adhesion models.</p> <p>Macroscopically, the compliant nature of the nonwoven fiber mats makes them susceptible to out-of-plane deformation during water filtration processes which may alter their size exclusion configuration for effective filtration. A bulge testing device is built and implemented to simulate and characterize hydraulic flow – induced deformation in the electrospun PAN fiber mats. The pressure–deflection relationships of the mats show a sub-linear dependence in contrast to classical continuum materials. The macroscopic mat behavior was governed by the properties of the constituent fibers, with an apparent mat bending rigidity dependent on the fiber diameters.</p> <p> Lastly, the nonwoven fiber mats functionalized with copper nanoparticles were evaluated for use as potential antimicrobial microfiltration membranes. The fiber mats displayed high water flux and high separation efficiency for model 3 μm particles, with separation factors reaching above 99%.</p> Bulge Test electrospinning nanostructures Nanocubes Adhesion electroless deposition Filtration fiber mat deformation polyacrylonitrile fibers polymer
13	Caractérisation mécanique et microstructurale du comportement à rupture de la capsule de Glisson pour la prédiction du risque de lésions des tissus hépatiques humains / Mechanical and microstructural characterization of Glisson's capsule behavior up to failure, for the prediction of human hepatic tissues injury risk Jayyosi, Charles 05 November 2015 (has links) Les modèles numériques personnalisables d'organes du corps humain offrent un formidable potentiel pour évaluer le risque lésionnel dans les domaines de la sécurité des transports, du médical ou du sport. Suivant les applications, différents niveaux de détails peuvent être nécessaires. En particulier, lorsque le comportement mécanique des tissus biologiques doit être finement reproduit, les modèles de comportement doivent intégrer des considérations sur la structure du tissu, et simuler les mécanismes suivant lesquels il réagit à un chargement mécanique. Le travail de thèse présenté ici s'est focalisé sur la capsule de foie, notamment sur ses propriétés microstructurales et mécaniques, afin d'identifier les hypothèses importantes à intégrer dans la construction d'un modèle constitutif de tissu fibreux basé sur la microstructure. La méthodologie expérimentale a été mise en place afin de caractériser le comportement mécanique de ce tissu, en lien avec l'organisation de sa microstructure. Des essais de traction uniaxiale et de gonflement sous microscope confocal biphotonique ont été développés, pour observer l'évolution de la microstructure sous chargement. Des déformations macroscopiques ont été mesurées, et une méthode de mesure de champs de déformations locaux a été développée pour quantifier l'état de déformation du réseau de fibres. La réorganisation du réseau de fibre de collagène a également été quantifiée. L'analyse des liens existant entre les grandeurs mesurées à l'échelle macroscopique et ces phénomènes microscopiques est proposée, pour préciser les hypothèses à adopter dans les modèles permettant de passer de l'échelle des fibres au comportement global du tissu / Customized human body models offer a great potential to assess the injury risks in the fields of transport safety, surgery or sport. Various detail levels can then be needed, according to the targeted application. In particular, when the mechanical behavior of biological tissues needs to be accurately reproduced, numerical models have to include information about the structure of the tissue, and model the mechanisms of the response to mechanical loading. The work presented here focuses on the microstructural and mechanical characterization of the human liver capsule, in order to identify the important hypotheses that need to be included in a fibrous tissue constitutive model, based on microstructure. Thus, an experimental methodology has been developed to identify the mechanical behavior of this particular tissue, related with its microstructural organization. Uniaxial tensile tests, as well as bulge tests under a multiphoton confocal microscope have been performed, to observe the microstructure evolution during loading. Macroscopic strain has been assessed, and a method to measure local strain fields has been developed, to quantify the strain state of the fibrous network. The reorganization of the collagen fibers network has also been quantified. An analysis of the links between the measured macroscopic parameters and the microscopic phenomena is given. Therefore, the hypotheses that need to be included in constitutive models are highlighted, with particular consideration given to the affine transformation hypothesis which allows to link the fibers behavior to the global response of the tissue Capsule de foie humaine Microscopie confocale multiphoton Collagène Élastine Corrélation d’images Essai de gonflement elliptique Photoblanchiment Membrane conjonctive fibreuse Human liver capsule Confocal multiphoton microscopy Collagen Elastin Image correlation Elliptic bulge test Photobleaching Connective fibrous membrane 531
14	Formability Evaluation of Tailor Welded Blanks (TWBs) Singhal, Hitansh January 2020 (has links) No description available. Mechanical Engineering Industrial Engineering Aerospace Engineering Stamping Sheet Metal Forming Tailor Welded Blanks Formability Manufacturing Microhardness Tensile Tests Finite Element Analysis PAM-STAMP DEFORM Frictionless Dome Test Viscous Pressure Bulge Test
15	Characterization of Sheet Materials for Stamping and Finite Element Simulation of Sheet Hydroforming Al-Nasser, Amin Eyad 08 September 2009 (has links) No description available. Automotive Materials Engineering Industrial Engineering Materials Science Mechanical Engineering AHSS Uniaxial Tensile Test Biaxial Bulge Test Flow Stress Formability Dual Phase (DP) Transformation-Induced Plasticity (TRIP) Alluminum AA5754 AA5182 AA3003 Sheet Hydroforming with a Punch (SHF-P)

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