Search results for "Computational Mechanic"

showing 9 items of 159 documents

A computational framework for low-cycle fatigue in polycrystalline materials

2021

Abstract A three-dimensional framework for low-cycle fatigue analysis of polycrystalline aggregates is proposed in this work. First, a cohesive law coupling plasticity and damage is developed for modelling cycle-by-cycle degradation of material interfaces up to complete de-cohesion and failure. The law may model both quasi-static degradation under increasing monotonic load and degradation under cyclic loading, through a coupled plasticity-damage model whose activation and flow rules are formulated in a thermodynamically consistent framework. The proposed interface laws have been then implemented and coupled with a multi-region boundary element formulation, with the aim of analysing low-cycl…

Work (thermodynamics)Materials scienceMechanical EngineeringFlow (psychology)Computational MechanicsGeneral Physics and AstronomyMicromechanicsMonotonic functionMechanicsPlasticityIntergranular corrosionComputer Science ApplicationsMechanics of MaterialsBoundary Element method Cohesive Zone Modelling Low-cycle fatigue Multiscale Materials Modelling Polycrystalline materialsDegradation (geology)Coupling (piping)Settore ING-IND/04 - Costruzioni E Strutture Aerospaziali
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The interphase model applied to the analysis of masonry structures

2014

Abstract Masonry material presents a mechanical response strongly dependent on the static and kinematic phenomena occurring in the constituents and at their joints. At the mesoscopic level the interaction between the units is simulated by means of specific mechanical devices such as the zero thickness interface model where the contact tractions and the displacement discontinuities are the primary static and kinematic variables respectively. In many cases the joint response depends also on internal stresses and strains within the interface layer adjacent to the joint interfaces. The introduction of internal stresses and strains leads to the formulation of the interphase model, a sort of enha…

Work (thermodynamics)Materials sciencePlasticityComputational MechanicsGeneral Physics and Astronomysymbols.namesakemedicineMasonryJoint (geology)Interphasebusiness.industryMechanical EngineeringStructural engineeringMechanicsMasonryFinite element methodComputer Science ApplicationsDamageMechanics of MaterialsJoint stiffnessHelmholtz free energysymbolsInterphasemedicine.symptombusinessSettore ICAR/08 - Scienza Delle CostruzioniDisplacement (fluid)
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A comparative molecular dynamics-phase-field modeling approach to brittle fracture

2016

Abstract In this work, a novel comparative method for highly brittle materials such as aragonite crystals is proposed, which provides an efficient and accurate in-sight understanding for multi-scale fracture modeling. In particular, physically-motivated molecular dynamics (MD) simulations are performed to model quasi-static brittle crack propagation on the nano-scale and followingly compared to macroscopic modeling of fracture using the phase-field modeling (PFM) technique. A link between the two modeling schemes is later proposed by deriving PFM parameters from the MD atomistic simulations. Thus, in this combined approach, MD simulations provide a more realistic meaning and physical estima…

business.industryComputer scienceMechanical EngineeringComputational MechanicsGeneral Physics and AstronomyNew materials02 engineering and technologyStructural engineering021001 nanoscience & nanotechnologyCombined approachBiological materialsComputer Science ApplicationsCondensed Matter::Materials ScienceMolecular dynamics020303 mechanical engineering & transportsBrittleness0203 mechanical engineeringBrittle crackMechanics of MaterialsStatistical physics0210 nano-technologybusinessBrittle fractureComputer Methods in Applied Mechanics and Engineering
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Dynamic Shakedown Sensitivity Analysis by Means of a Probabilistic Approach

2017

The shakedown limit load multiplier problem for elastic plastic structures subjected to a combination of fixed and seismic loads is treated. In particular, reference is firstly made to the unrestricted dynamic shakedown theory. The relevant seismic load history is modeled as a repeated one and, with reference to classically damped structures, appropriate modal analyses are utilized. With the aim of evaluating the reliability of the results arising from the application of the cited theory, a recent probabilistic approach is also utilized. This approach adopts the Monte Carlo method in order to define the necessary seismic acceleration histories and finally compute the related shakedown limit…

business.industryCumulative distribution functionSeismic loadingMonte Carlo method0211 other engineering and technologiesComputational MechanicsProbabilistic logic02 engineering and technologyBuilding and ConstructionStructural engineeringShakedown020303 mechanical engineering & transportsModal0203 mechanical engineeringMechanics of MaterialsArchitectureLimit loadMultiplier (economics)Safety Risk Reliability and Qualitybusiness021106 design practice & managementCivil and Structural EngineeringMathematicsInternational Review of Civil Engineering (IRECE)
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Complex composite structures with integrated piezoelectric transducers

2016

International audience; Nowadays, in different industrial fields as transport or aerospace, a research effort is conducted to reduce the structural weight. One of the most promising solutions is the use of composite structures due to their high stiffness, their low mass density and their low damping factor. At the same time, there is an intensification of the operational dynamic environment and an increase of durability requirements. These different expectations seem to be contradictory. One solution to manage these points is to design and manufacture smart composite structures with a fully distributed set of integrated piezoelec-tric transducers. These structures are able to modify their m…

composite structureComputer scienceComposite numberComputational MechanicsMechanical engineering[SPI.MECA.MSMECA]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Materials and structures in mechanics [physics.class-ph]02 engineering and technology01 natural sciences[SPI]Engineering Sciences [physics]Active vibration control0103 physical sciencesAerospace[PHYS.MECA.VIBR]Physics [physics]/Mechanics [physics]/Vibrations [physics.class-ph]010302 applied physicsbusiness.industryApplied Mathematicstransducers integration[PHYS.MECA]Physics [physics]/Mechanics [physics]material characterizationMechatronics021001 nanoscience & nanotechnologyPiezoelectricityDurabilityComputer Science ApplicationsComputational Mathematicscomplex structureModeling and SimulationDamping factorPMUT[PHYS.MECA] Physics [physics]/Mechanics [physics]0210 nano-technologybusiness
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Thermographic quantitative variables for diabetic foot assessment: preliminary results

2018

The aim of this study was to define aspects of a protocol for a diabetic population by obtaining and evaluating thermographic images following thermal stress (cooling of the sole of the foot with c...

education.field_of_studymedicine.medical_specialtybusiness.industryPopulationBiomedical EngineeringComputational MechanicsSkin temperature02 engineering and technologymedicine.diseaseDiabetic foot030218 nuclear medicine & medical imagingComputer Science Applications03 medical and health sciences0302 clinical medicinePhysical medicine and rehabilitationDiabetes mellitus0202 electrical engineering electronic engineering information engineeringmedicine020201 artificial intelligence & image processingRadiology Nuclear Medicine and imagingeducationbusinessFoot (unit)Computer Methods in Biomechanics and Biomedical Engineering: Imaging & Visualization
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A boundary condition for arbitrary shaped inlets in lattice-Boltzmann simulations

2009

We introduce a mass-flux-based inlet boundary condition for the lattice-Boltzmann method. The proposed boundary condition requires minimal amount of boundary data, it produces a steady-state velocity field which is accurate close to the inlet even for arbitrary inlet geometries, and yet it is simple to implement. We demonstrate its capability for both simple and complex inlet geometries by numerical experiments. For simple inlet geometries, we show that the boundary condition provides very accurate inlet velocities when Re less than or similar to 1. Even with moderate Reynolds number, the inlet velocities are accurate for practical purposes. Furthermore, the potential of our boundary condit…

geographygeography.geographical_feature_categorybusiness.industryApplied MathematicsMechanical EngineeringComputational MechanicsLattice Boltzmann methodsReynolds numberGeometryMechanicsComputational fluid dynamicsPhysics::Classical PhysicsInletBoltzmann equationPhysics::GeophysicsComputer Science ApplicationsPhysics::Fluid Dynamicssymbols.namesakeMechanics of MaterialssymbolsVector fieldBoundary value problembusinessLattice model (physics)MathematicsInternational Journal for Numerical Methods in Fluids
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Modelling landslides in unsaturated slopes subjected to rainfall infiltration using material point method

2016

This paper presents a dynamic fully coupled formulation for saturated and unsaturated soils that undergo large deformations based on material point method. Governing equations are applied to porous material while considering it as a continuum in which the pores of the solid skeleton are filled with water and air. The accuracy of the developed method is tested with available experimental and numerical results. The developed method has been applied to investigate the failure and post-failure behaviour of rapid landslides in unsaturated slopes subjected to rainfall infiltration using two different bedrock geometries that lie below the top soil. The models show different failure and post-failur…

landslidesDynamic coupled analysiRainfall infiltrationdynamic coupled analysisLarge deformationunsaturated soilslarge deformationsMaterial point methodGeotechnical Engineering and Engineering GeologyLandslideMechanics of MaterialsUnsaturated soilMaterials Science (all)Computational Mechanic
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Modelling cardiac mechanics of left ventricular noncompaction

2020

Left ventricular noncompaction (LVNC) can be defined as a cardiomyopathy characterised by a pattern of prominent trabecular structure and deep intertrabecular recesses, that is thought to be caused by an arrest of normal endomyocardial morphogenesis. Using patient-specific computational modelling, we assessed the cardiac mechanics of five patients with LVNC and compared myocardial stress and pump performance to those of healthy controls. Findings shown that patients with LVNC have impaired left ventricular (LV) function, making it possible that the lack of fibre shortening of noncompacted layer can determine poor heart function. Pronounced end-systolic wall stress on left ventricular wall o…

medicine.medical_specialtygenetic structuresBiomedical EngineeringComputational MechanicsCardiomyopathy02 engineering and technology030218 nuclear medicine & medical imaging03 medical and health sciencesWall stress0302 clinical medicinecardiac mechanics finite element analysis Left ventricular noncompaction wall stressInternal medicine0202 electrical engineering electronic engineering information engineeringmedicineRadiology Nuclear Medicine and imagingbusiness.industryfungifood and beveragesmedicine.diseaseComputer Science ApplicationsCardiologyLeft ventricular noncompaction020201 artificial intelligence & image processingsense organsbusinessCardiac mechanics
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