Search results for "T method"

showing 10 items of 1254 documents

Pre-Stressed Sub-Surface Contribution on Bulk Diffusion in Metallic Solids

2011

Our recent modelling works and corresponding numerical simulations realized to describe the UO2 oxidation processes confirm the theory showing that an applied mechanical strain can strongly affect the local oxygen diffusion in a stressed solid. This result allows us to assume that stress field, previously applied at the surface of a metallic sample on several microns, will delay the degradation during its oxidation. Considering this hypothesis, we implemented a FEM simulation code developed in our laboratory to numerically investigate some different stress fields applied on a sample sub-surface, that might significantly modify the volume diffusion of oxygen during the oxidation process. The…

Materials scienceFEM Simulation[ SPI.MAT ] Engineering Sciences [physics]/MaterialsFOS: Physical scienceschemistry.chemical_element02 engineering and technologyPhysics - Classical Physics Surface Treatment01 natural sciences[SPI.MAT]Engineering Sciences [physics]/MaterialsMetalStress (mechanics)[PHYS.MECA.MEMA]Physics [physics]/Mechanics [physics]/Mechanics of materials [physics.class-ph]0103 physical sciences[SPI.MECA.MEMA]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Mechanics of materials [physics.class-ph]General Materials ScienceDiffusion (business)010302 applied physicsZirconiumCondensed Matter - Materials ScienceRadiationMaterials Science (cond-mat.mtrl-sci)Classical Physics (physics.class-ph)Bonding in solidsMechanics[CHIM.MATE]Chemical Sciences/Material chemistry021001 nanoscience & nanotechnologyCondensed Matter PhysicsDurabilityFinite element methodStress fieldchemistryvisual_art[ CHIM.MATE ] Chemical Sciences/Material chemistry[ SPI.MECA.MEMA ] Engineering Sciences [physics]/Mechanics [physics.med-ph]/Mechanics of materials [physics.class-ph][ PHYS.MECA.MEMA ] Physics [physics]/Mechanics [physics]/Mechanics of materials [physics.class-ph]visual_art.visual_art_medium Stress-Diffusion Coupling Zirconium0210 nano-technology
researchProduct

Dissimilar material lap joints by Friction Stir Welding of Steel and Titanium Sheets: Process Modeling

2013

In the paper a continuum based FEM model for Friction Stir Welding of different material lap joint made out of thin stainless steel and titanium sheets is proposed. The simulation campaign was made out using the 3D Lagrangian implicit code DEFORM{trade mark, serif} by means of a rigid-visco-plastic approach. The model, already set up and tuned for FSW process of similar materials and geometrical configurations takes into account the different mechanical and thermal behavior of the two materials and the microstructural evolution of the considered titanium alloy in the same joint. Additionally, it is able to predict temperature, phase, strain and strain rate distributions and evolution at the…

Materials scienceFSW Titanium alloys Stainless steel FEM Lap jointsTitanium alloychemistry.chemical_elementWeldingStrain rateFinite element methodlaw.inventionLap jointchemistrylawFriction stir weldingComposite materialJoint (geology)Titanium
researchProduct

Friction stir welding of stainless steel thin sheets in lap configuration

2013

New research trends for Friction Stir Welding include the use of highly resistant materials as steels and titanium alloys. In the paper a continuum based FEM model for Friction Stir Welding of lap joint made out of thin stainless steel sheets is proposed, that is 3D Lagrangian implicit, coupled, rigid-viscoplastic. The model, whose potential has been analyzed though temperature distribution comparisons, is able to predict temperature, strain and strain rate distributions, with varying process variables. In this way the FEM model can be applied for effective process and tool design.

Materials scienceFSWMetallurgyTitanium alloylap jointsThin sheetStrain rateElectric resistance weldingFinite element methodLap jointFriction stir weldingFriction weldingComposite materialstainless steelSettore ING-IND/16 - Tecnologie E Sistemi Di Lavorazione
researchProduct

Friction Stir Welding of Magnesium Alloys under Different Process Parameters

2010

Experimental and numerical investigations have been performed in order to study the effect of welding parameters on properties of FSW-ed AZ31 magnesium alloy sheets. The results, presented in terms of tensile strength and numerical field variables distributions, allow to understand the behaviour of such material when FSW-ed using different rotational and welding speeds for a given tool geometry.

Materials scienceField (physics)MagnesiumMechanical EngineeringMetallurgyProcess (computing)chemistry.chemical_elementWeldingCondensed Matter PhysicsFinite element methodlaw.inventionchemistryMechanics of MaterialslawUltimate tensile strengthFriction stir weldingGeneral Materials ScienceComposite materialMagnesium alloyMaterials Science Forum
researchProduct

Nonstationary heat conduction in a stator

1996

In this chapter we describe a method for computing the 3d nonstationary temperature field in the lamination pack of a stator of a synchronous or asynchronous (induction) motor with a centrifugal, meander or chamber ventilation (see [Křižek, Preiningerova]). The stator of a motor has quite a complicated geometrical form. Moreover, it consists of anisotropic materials which have very different heat conductivities, e.g., 332.8 [W/mK] for copper wires and 0.2 [W/mK] for their insulations. This causes big jumps in coefficients of the appropriate heat conduction equation, and is the main source of numerical difficulties in practical calculations.

Materials scienceField (physics)lawStatorWeak solutionLaminationHeat equationMechanicsAnisotropyThermal conductionFinite element methodlaw.invention
researchProduct

Formulation and validation of a reduced order model of 2D materials exhibiting a two-phase microstructure as applied to graphene oxide

2018

Abstract Novel 2D materials, e.g., graphene oxide (GO), are attractive building blocks in the design of advanced materials due to their reactive chemistry, which can enhance interfacial interactions while providing good in-plane mechanical properties. Recent studies have hypothesized that the randomly distributed two-phase microstructure of GO, which arises due to its oxidized chemistry, leads to differences in nano- vs meso‑scale mechanical responses. However, this effect has not been carefully studied using molecular dynamics due to computational limitations. Herein, a continuum mechanics model, formulated based on density functional based tight binding (DFTB) constitutive results for GO …

Materials scienceFinite element analysiMembrane deflection02 engineering and technologyCondensed Matter Physic010402 general chemistry01 natural scienceslaw.inventionMolecular dynamicsTight bindingContinuum damage modellawNano-MonolayerMechanics of MaterialComposite materialGraphene oxideContinuum mechanicsGrapheneMechanical Engineering021001 nanoscience & nanotechnologyCondensed Matter PhysicsMicrostructureRepresentative volume elementFinite element method0104 chemical sciencesMechanics of MaterialsChemical physicsModel development and validation0210 nano-technology
researchProduct

Study of Snowboard Sandwich Structures

2005

The aim of the present research is to extend the knowledge of mechanical properties both on single components and on complete structure employed for snowboard. Flexural and torsion tests are performed to acquire important comparison parameters between snowboard sandwich structures that differ for the core material employed (wood, PVC foam core). A simplified FEM model is proposed to simulate the flexural tests of the sandwich structure showing good predictive capability.

Materials scienceFlexural strengthbusiness.industryTorsion (mechanics)Predictive capabilityStructural engineeringbusinesssnowboard sandwich structure mechanical propertiesFinite element method
researchProduct

Forming of aluminum foam sandwich panels: Numerical simulations and experimental tests

2006

Abstract The forming of the completed aluminium foam sandwich (AFS) panels would determine an improvement in the manufacturing of parts and panels. In this paper the authors have investigated the formability of AFS through experiments and numerical simulations. As far as the former are concerned, commercially prepared panels have been considered and bending and stamping processes have been taken into account. In addition, FEM analyses have been developed, utilizing a porous material model following the evolution of the material density throughout the forming processes.

Materials scienceFoams AFS FEMBending (metalworking)business.industryMetals and AlloysForming processesMetal foamStructural engineeringStampingIndustrial and Manufacturing EngineeringFinite element methodComputer Science ApplicationsAluminium foam sandwichModeling and SimulationCeramics and CompositesFormabilityComposite materialbusinessSettore ING-IND/16 - Tecnologie E Sistemi Di LavorazioneSandwich-structured compositeJournal of Materials Processing Technology
researchProduct

Infrared thermography-based evaluation of the elastic-plastic J-integral to correlate fatigue crack growth data of a stainless steel

2019

Abstract The elastic-plastic J-integral is adopted to correlate fatigue crack growth data of ductile metals. An analytical link is known to exist between the J-integral and the strain energy density averaged in a control volume embracing the crack tip. On the other hand, the strain energy fluctuation is the source of temperature variations close to a fatigue crack tip of a metal material; hence the possibility to measure the J-integral from infrared thermographic scanning at the crack tip is envisaged and it is the focus of this paper. It is proposed that the elastic component of the J-integral is derived from a thermoelastic stress analysis, while the plastic component of the J-integral is…

Materials scienceFracture mechanic02 engineering and technologyIndustrial and Manufacturing EngineeringStrain energyStress (mechanics)Thermoelastic damping0203 mechanical engineeringThermoelastic Stress AnalysisGeneral Materials ScienceComposite materialFatigueJ-integralCrack tip plasticityMechanical EngineeringEnergy methodTemperatureStrain energy density functionFracture mechanicsParis' law021001 nanoscience & nanotechnologyFinite element method020303 mechanical engineering & transportsMechanics of MaterialsModeling and SimulationFracture mechanics Crack tip plasticity Thermoelastic Stress Analysis Energy methods Fatigue Temperature J-integralThermography0210 nano-technology
researchProduct

Engineering the crack path in lattice cellular materials through bio-inspired micro-structural alterations

2019

Abstract A computational study on the fracture behaviour of bio-inspired finite-size lattice configurations is performed in this work. The study draws inspiration from recent investigations aimed at increasing the fracture energy of some materials through small modifications of their microstructure. The main question here is whether it is possible, to some extent, to engineer the crack path in metallic cellular materials through such small micro-structural modifications and how to quantify the effect of alternative strategies. Nature provides several examples of strategies used to delay or arrest damage and crack propagation. One striking example is given by the micro-architecture of severa…

Materials scienceFracture mechanicCellular architectureMechanical EngineeringFinite element analysisBioengineeringFracture mechanicsMetallic lattice02 engineering and technology010402 general chemistry021001 nanoscience & nanotechnologyMicrostructure01 natural sciencesFinite element method0104 chemical sciencesMicroarchitectureMechanics of MaterialsLattice (order)Chemical Engineering (miscellaneous)Figure of meritWood microstructure0210 nano-technologyBiological systemBio-inspired materialEngineering (miscellaneous)Extreme Mechanics Letters
researchProduct