Search results for "Computational Mechanics"

showing 10 items of 155 documents

Spectral WENO schemes with Adaptive Mesh Refinement for models of polydisperse sedimentation

2012

The sedimentation of a polydisperse suspension with particles belonging to N size classes (species) can be described by a system of N nonlinear, strongly coupled scalar first-order conservation laws. Its solutions usually exhibit kinematic shocks separating areas of different composition. Based on the so-called secular equation [J. Anderson, Lin. Alg. Appl. 246, 49–70 (1996)], which provides access to the spectral decomposition of the Jacobian of the flux vector for this class of models, Burger et al. [J. Comput. Phys. 230, 2322–2344 (2011)] proposed a spectral weighted essentially non-oscillatory (WENO) scheme for the numerical solution of the model. It is demonstrated that the efficiency …

Conservation lawAdaptive mesh refinementApplied MathematicsComputational MechanicsScalar (physics)KinematicsSuspension (topology)Matrix decompositionNonlinear systemsymbols.namesakeClassical mechanicsJacobian matrix and determinantsymbolsApplied mathematicsMathematicsZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik
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Kinematic splitting algorithm for fluid–structure interaction in hemodynamics

2013

Abstract In this paper we study a kinematic splitting algorithm for fluid–structure interaction problems. This algorithm belongs to the class of loosely-coupled fluid–structure interaction schemes. We will present stability analysis for a coupled problem of non-Newtonian shear-dependent fluids in moving domains with viscoelastic boundaries. Fluid flow is described by the conservation laws with nonlinearities in convective and diffusive terms. For simplicity of presentation the structure is modelled by the generalized string equation, but the results presented in the paper may be generalized to more complex structure models. The arbitrary Lagrangian–Eulerian approach is used in order to take…

Conservation lawMechanical EngineeringComputational MechanicsStability (learning theory)General Physics and AstronomyKinematicsNon-Newtonian fluidComputer Science ApplicationsPhysics::Fluid DynamicsMechanics of MaterialsFluid–structure interactionNewtonian fluidFluid dynamicsAlgorithmBifurcationMathematicsComputer Methods in Applied Mechanics and Engineering
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Adaptive mesh refinement techniques for high-order shock capturing schemes for multi-dimensional hydrodynamic simulations

2006

The numerical simulation of physical phenomena represented by non-linear hyperbolic systems of conservation laws presents specific difficulties mainly due to the presence of discontinuities in the solution. State of the art methods for the solution of such equations involve high resolution shock capturing schemes, which are able to produce sharp profiles at the discontinuities and high accuracy in smooth regions, together with some kind of grid adaption, which reduces the computational cost by using finer grids near the discontinuities and coarser grids in smooth regions. The combination of both techniques presents intrinsic numerical and programming difficulties. In this work we present a …

Conservation lawPartial differential equationComputer simulationbusiness.industryAdaptive mesh refinementApplied MathematicsMechanical EngineeringComputational MechanicsComputational fluid dynamicsGridComputer Science ApplicationsNonlinear systemMechanics of MaterialsMesh generationbusinessAlgorithmMathematicsInternational Journal for Numerical Methods in Fluids
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A Polynomial Approach to the Piecewise Hyperbolic Method

2003

In this paper, a local (third-order accurate) shock capturing method for hyperbolic conservation laws is presented. The method has been made with the same idea as the PHM method, but with a simpler reconstruction. A comparison with the classic high order methods is discussed.

Conservation lawPolynomialMechanical EngineeringHyperbolic functionMathematical analysisComputational MechanicsEnergy Engineering and Power TechnologyAerospace EngineeringCondensed Matter PhysicsMechanics of MaterialsShock capturing methodPiecewiseHigh orderHyperbolic partial differential equationMathematicsInternational Journal of Computational Fluid Dynamics
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Regular and singular pulse and front solutions and possible isochronous behavior in the Extended-Reduced Ostrovsky Equation: Phase-plane, multi-infin…

2016

In this paper we employ three recent analytical approaches to investigate several classes of traveling wave solutions of the so-called extended-reduced Ostrovsky Equation (exROE). A recent extension of phase-plane analysis is first employed to show the existence of breaking kink wave solutions and smooth periodic wave (compacton) solutions. Next, smooth traveling waves are derived using a recent technique to derive convergent multi-infinite series solutions for the homoclinic orbits of the traveling-wave equations for the exROE equation. These correspond to pulse solutions respectively of the original PDEs. We perform many numerical tests in different parameter regime to pinpoint real saddl…

Control and OptimizationComputational MechanicsDiscrete Mathematics and CombinatoricsStatistical and Nonlinear PhysicsExtended-Reduced Ostrovsky Equation Traveling Waves Singular Solutions Homoclinic and Heteroclinic Orbits Variational Solitary Waves
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Coupling between oxidation kinetics and anisothermal oil flow during deep-fat frying

2021

Deep-fat frying is a cooking technique that has been used continuously since prehistoric times. A domestic deep-fryer heated from the bottom develops significant convection inside the bath cavity. It is responsible for very high heat transfer coefficients and the exposure of the deep-frying oil to the atmospheric oxygen. The continuous conversion of gaseous dioxygen into unstable and reactive hydroperoxides and their subsequent advection throughout the bulk volume is at the origin of the main complaints made of frying which includes issues such as odors, fouling, and generation of several toxic compounds. This study analyzes the coupling between natural convection of triacylglycerols and th…

ConvectionComputational MechanicsThermodynamics010402 general chemistry01 natural sciencesEndothermic process0404 agricultural biotechnologyFluid Flow and Transfer ProcessesPhysicsNatural convectionAutoxidationHeating elementAdvectionMechanical Engineering[SPI.FLUID]Engineering Sciences [physics]/Reactive fluid environment04 agricultural and veterinary sciences[SPI.FLUID] Engineering Sciences [physics]/Reactive fluid environmentCondensed Matter Physics040401 food scienceDecomposition0104 chemical sciences[SDV.AEN] Life Sciences [q-bio]/Food and NutritionVolume (thermodynamics)13. Climate actionMechanics of Materials[SDV.AEN]Life Sciences [q-bio]/Food and Nutrition
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A fast BEM for the analysis of damaged structures with bonded piezoelectric sensors

2010

A fast boundary element method for the analysis of three-dimensional solids with cracks and adhesively bonded piezoelectric patches, used as strain sensors, is presented. The piezoelectric sensors, as well as the adhesive layer, are modeled using a 3D state-space finite element approach. The piezoelectric patch model is formulated taking into account the full electro-mechanical coupling and embodying the suitable boundary conditions and it is eventually expressed in terms of the interface variables, to allow a straightforward coupling with the underlying host structure, which is modeled through a 3D dual boundary element method, for accurate analysis of cracks. The technique is computationa…

CouplingEngineeringbusiness.industryPiezoelectric sensorMechanical EngineeringAcousticsComputational MechanicsGeneral Physics and AstronomyStructural engineeringSolverPiezoelectricityFinite element methodPiezoelectric patcheComputer Science ApplicationsSHM systems modelingMechanics of MaterialsBoundary element methodBoundary value problemStructural health monitoringSettore ING-IND/04 - Costruzioni E Strutture AerospazialibusinessFast BEM solverBoundary element methodComputer Methods in Applied Mechanics and Engineering
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Introducing randomness in the analysis of chemical reactions: An analysis based on random differential equations and probability density functions

2021

[EN] In this work we consider a particular randomized kinetic model for reaction-deactivation of hydrogen peroxide decomposition. We apply the Random Variable Transformation technique to obtain the first probability density function of the solution stochastic process under general conditions. From the rst probability density function, we can obtain fundamental statistical information, such as the mean and the variance of the solution, at every instant time. The transformation considered in the application of the Random Variable Transformation technique is not unique. Then, the first probability density function can take different expressions, although essentially equivalent in terms of comp…

Differential equationComputational MechanicsRandom modelProbability density functionChemical reactionComputational MathematicsComputational Theory and MathematicsChemical kinetic modelRandom modelRandom variable transformation techniqueFirst probability density functionStatistical physicsMATEMATICA APLICADARandomnessMathematicsComputational and Mathematical Methods
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Solving fully randomized higher-order linear control differential equations: Application to study the dynamics of an oscillator

2021

[EN] In this work, we consider control problems represented by a linear differential equation assuming that all the coefficients are random variables and with an additive control that is a stochastic process. Specifically, we will work with controllable problems in which the initial condition and the final target are random variables. The probability density function of the solution and the control has been calculated. The theoretical results have been applied to study, from a probabilistic standpoint, a damped oscillator.

Differential equationDynamics (mechanics)Computational MechanicsRandom damped linear oscillatorsRandom control differential equationComputational MathematicsComputational Theory and MathematicsRandom variable transformation techniqueApplied mathematicsOrder (group theory)First probability density functionMATEMATICA APLICADALinear controlMathematics
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Numerical analysis of masonry structures via interface models

2001

The present paper is devoted to the theoretical formulation and numerical implementation of an interface model suitable to simulate the behavior of mortar joints in masonry structures. The interface laws are formulated in the framework of elasto-plasticity for non-standard materials in order to simulate the softening response which occurs along the decohesion process in presence of shear and tension tractions. A variable material dilatancy parameter is introduced together with a further geometrical dilatancy related to the roughness of contact surfaces after joint fracture. An asperity model is adopted with the aim to describe the evolution of the contact surface shape during the loss of co…

DilatantEngineeringbusiness.industryMechanical EngineeringNumerical analysisComputational MechanicsGeneral Physics and AstronomyStructural engineeringSurface finishMasonryComputer Science ApplicationsContact surfacesShear (geology)Mechanics of MaterialsMortarbusinessSofteningComputer Methods in Applied Mechanics and Engineering
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