Search results for " hydrodynamics"

showing 10 items of 93 documents

A multi-domain approach for smoothed particle hydrodynamics simulations of highly complex flows

2018

Abstract An efficient and accurate method is proposed to solve the incompressible flow momentum and continuity equations in computational domains partitioned into subdomains in the framework of the smoothed particle hydrodynamics method. The procedure does not require any overlap of the subdomains, which would result in the increase of the computational effort. Perfectly matching solutions are obtained at the surfaces separating neighboring blocks. The block interfaces can be both planar and curved surfaces allowing to easily decompose even geometrically complex domains. The smoothing length of the kernel function is maintained constant in each subdomain, while changing between blocks where…

Computer scienceComputational MechanicsGeneral Physics and AstronomyBoundary condition010103 numerical & computational mathematics01 natural sciencesSettore ICAR/01 - IdraulicaMomentumSmoothed-particle hydrodynamicsPhysics and Astronomy (all)Smoothed particle hydrodynamicIncompressible flowComputational mechanicsMechanics of MaterialDomain decomposition0101 mathematicsMirror particleComputational MechanicConservation of massISPHBlock (data storage)Mechanical EngineeringComputer Science Applications1707 Computer Vision and Pattern RecognitionDomain decomposition methodsComputer Science Applications010101 applied mathematicsMechanics of MaterialsMulti-blockAlgorithmSmoothingComputer Methods in Applied Mechanics and Engineering
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Towards an Efficient Implementation of an Accurate SPH Method

2020

A modified version of the Smoothed Particle Hydrodynamics (SPH) method is considered in order to overcome the loss of accuracy of the standard formulation. The summation of Gaussian kernel functions is employed, using the Improved Fast Gauss Transform (IFGT) to reduce the computational cost, while tuning the desired accuracy in the SPH method. This technique, coupled with an algorithmic design for exploiting the performance of Graphics Processing Units (GPUs), makes the method promising, as shown by numerical experiments.

Computer scienceGauss transformOrder (ring theory)Smoothed Particle Hydrodynamics Improved Fast Gauss Transform Graphics Processing UnitsSmoothed-particle hydrodynamicsSmoothed Particle Hydrodynamicssymbols.namesakeImproved Fast Gauss TransformGaussian functionsymbolsAlgorithm designGraphics Processing UnitsGraphicsAlgorithmComputingMethodologies_COMPUTERGRAPHICS
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Free-surface flows solved by means of SPH schemes with numerical diffusive terms

2010

A novel system of equations has been defined which contains diffusive terms in both the continuity and energy equations and, at the leading order, coincides with a standard weakly-compressible SPH scheme with artificial viscosity. A proper state equation is used to associate the internal energy variation to the pressure field and to increase the speed of sound when strong deformations/compressions of the fluid occur. The increase of the sound speed is associated to the shortening of the time integration step and, therefore, allows a larger accuracy during both breaking and impact events. Moreover, the diffusive terms allows reducing the high frequency numerical acoustic noise and smoothing …

Convergence testsGeneral Physics and AstronomyFluid-structure impact problemsSPH pressure evaluationSmoothed particle hydrodynamicsSystem of linear equations01 natural sciences010305 fluids & plasmasSmoothed-particle hydrodynamicsViscositySmoothed particle hydrodynamicSpeed of sound0103 physical sciencesConvergence testsFree-surface flow0101 mathematicsFree-surface flowsPhysicsInternal energyMechanics010101 applied mathematicsFluid-structure impact problemHardware and ArchitectureFree surfaceWeak-compressibilitySmoothing
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A coupled Finite Volume–Smoothed Particle Hydrodynamics method for incompressible flows

2016

Abstract An hybrid approach is proposed which allows to combine Finite Volume Method (FVM) and Smoothed Particle Hydrodynamics (SPH). The method is based on the partitioning of the computational domain into a portion discretized with a structured grid of hexahedral elements (the FVM-domain ) and a portion filled with Lagrangian particles (the SPH-domain ), separated by an interface made of triangular elements. A smooth transition between the solutions in the FVM and SPH regions is guaranteed by the introduction of a layer of grid cells in the SPH-domain and of a band of virtual particles in the FVM one (both neighboring the interface), on which the hydrodynamic variables are obtained throug…

DiscretizationSPHComputational MechanicsGeneral Physics and AstronomyCoupled FVM–SPH approachBoundary condition01 natural sciences010305 fluids & plasmasSettore ICAR/01 - IdraulicaSmoothed-particle hydrodynamicsPhysics and Astronomy (all)0103 physical sciencesComputational mechanicsMechanics of Material0101 mathematicsMirror particleComputational MechanicPhysicsFinite volume methodMechanical EngineeringMathematical analysisSmoothed Particle HydrodynamicComputer Science Applications1707 Computer Vision and Pattern RecognitionGridComputer Science ApplicationsComputational physics010101 applied mathematicsMechanics of MaterialsCompressibilityReduction (mathematics)Interpolation
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An advanced numerical treatment of EM absorption in human tissue

2020

The numerical computation of local electromagnetic absorption at points within the human tissue is proposed by avoiding the mesh generation in the problem domain. Recently, meshless numerical methods have been introduced as an alter- native computational approach to mesh based methods. This is an important feature to generate competitive procedure able to provide final evaluations for large data amounts in real time. In this paper the smoothed particle hydrodynamics method is considered to compute the electromagnetic absorption. First experiments are performed in two dimension at single frequencies by considering incident TM plane wave on 2D cylinder simulating a simplified model of human t…

Electromagnetic absorption SPH Biological tissuesComputer scienceComputationNumerical analysisPlane wave02 engineering and technology01 natural sciences010101 applied mathematicsSmoothed-particle hydrodynamicsSettore MAT/08 - Analisi NumericaSettore ING-IND/31 - ElettrotecnicaMesh generationFeature (computer vision)0202 electrical engineering electronic engineering information engineeringCylinder020201 artificial intelligence & image processing0101 mathematicsAbsorption (electromagnetic radiation)Algorithm2020 IEEE 20th Mediterranean Electrotechnical Conference ( MELECON)
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Improved fast Gauss transform for meshfree electromagnetic transients simulations

2019

Abstract In this paper improved fast summations are introduced to enhance a meshfree solver for the evolution of the electromagnetic fields over time. The original method discretizes the time-domain Maxwell’s curl equations via Smoothed Particle Hydrodynamics requiring many summations on the first derivatives of the kernel function and field vectors at each time step. The improved fast Gauss transform is properly adopted picking up the computational cost and the memory requirement at an acceptable level preserving the accuracy of the computation. Numerical simulations in two-dimensional domains are discussed giving evidence of improvements in the computation compared to the standard formula…

Electromagnetic fieldCurl (mathematics)Numerical approximation Improve fast Gauss transform Smoothed Particle Hydrodynamics Maxwell’s equationsApplied MathematicsComputation010102 general mathematicsGauss transformTime stepSolver01 natural sciences010101 applied mathematicsSmoothed-particle hydrodynamicsSettore MAT/08 - Analisi NumericaSettore ING-IND/31 - ElettrotecnicaApplied mathematics0101 mathematicsMathematics
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Corrective meshless particle formulations for time domain Maxwell's equations

2007

AbstractIn this paper a meshless approximation of electromagnetic (EM) field functions and relative differential operators based on particle formulation is proposed. The idea is to obtain numerical solutions for EM problems by passing up the mesh generation usually required to compute derivatives, and by employing a set of particles arbitrarily placed in the problem domain. The meshless Smoothed Particle Hydrodynamics method has been reformulated for solving the time domain Maxwell's curl equations. The consistency of the discretized model is investigated and improvements in the approximation are obtained by modifying the numerical process. Corrective algorithms preserving meshless consiste…

Electromagnetic fieldRegularized meshless methodMathematical optimizationDiscretizationNumerical analysisApplied MathematicsMeshless particle methodMaxwell's equationSmoothed particle hydrodynamicsElectromagnetic transientsSmoothed-particle hydrodynamicssymbols.namesakeSettore MAT/08 - Analisi NumericaSettore ING-IND/31 - ElettrotecnicaComputational MathematicsMaxwell's equationsMaxwell's equationsMesh generationsymbolsElectromagnetic transientApplied mathematicsTime domainMathematicsJournal of Computational and Applied Mathematics
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Numerical Simulations of the Hydrodynamics of the Abdominal Aorta Aneurysm (AAA) Using a Smoothed Particle Hydrodynamics Code with Deformable Wall Pr…

2018

We present some preliminary results of the numerical simulations of the hydrodynamic characteristics of an abdominal aorta aneurysm (AAA) patient specific test case. Images of the AAA lumen have been acquired in 10 discrete time-steps through a stabilized cardiac cycle by electrocardiogram-gated computer tomography angiography, and are used to approximate the in vivo, time dependent kinematic fields of the (internal) arterial wall. The flow field is simulated by a Smoothed Particle SPH numerical model, where the kinematics of the boundary of the computational domain (the internal aortic vessel) is the one computed by the above procedure. The outputs of the SPH model, i.e., pressure and flow…

Energy Engineering and Power TechnologyKinematicsrupture riskIndustrial and Manufacturing EngineeringSmoothed-particle hydrodynamicsflow velocitystress tensorAneurysmArtificial Intelligencemedicine.arterymedicineinternal pressureInstrumentationPhysicsAortamedicine.diagnostic_testComputer simulationCardiac cycleRenewable Energy Sustainability and the EnvironmentComputer Science ApplicationMechanicsmedicine.diseaseComputer Networks and CommunicationAngiographycardiovascular systemAbdominal aortic aneurysmTomographySPH modelComputer Vision and Pattern RecognitionSettore ICAR/08 - Scienza Delle Costruzioni
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A novel pressure regulation system based on Banki hydro turbine for energy recovery under in-range and out-range discharge conditions

2021

Abstract Efficiency improvement of water distribution networks needs to be in place to guarantee a long life period under suitable operating conditions. Excessive pressure is among the well-known issues encountered in water distribution networks which can cause strength damages to the piping system. In order to overcome this drawback and to reach a suitable water pressure delivery, the present work suggests a novel pressure regulation system. This regulation system is consisting of a Banki turbine equipped with a mobile flap as a control device. The suggested pressure regulation system was experimentally and numerically investigated under in-range i.e. like actual water distribution network…

Energy recoveryPipingRenewable Energy Sustainability and the EnvironmentComputer scienceTurbulence020209 energyFlow (psychology)Energy Engineering and Power Technology02 engineering and technologyTurbineVolumetric flow rateSettore ICAR/01 - IdraulicaPhysics::Fluid DynamicsFuel TechnologyFlow conditions020401 chemical engineeringNuclear Energy and EngineeringControl theory0202 electrical engineering electronic engineering information engineeringRange (statistics)Water distribution network Banki turbine Pressure regulation system Mobile flap Hydrodynamics energy recovery0204 chemical engineering
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Thermodynamics, transport phenomena, and electrochemistry of external field-assisted nonthermal food technologies

2017

Interest in the development and adoption of nonthermal technologies is burgeoning within the food and bioprocess industry, the associated research community, and among the consumers. This is evident from not only the success of some innovative nonthermal technologies at industrial scale, but also from the increasing number of publications dealing with these topics, a growing demand for foods processed by nonthermal technologies and use of natural ingredients. A notable feature of the nonthermal technologies such as cold plasma, electrohydrodynamic processing, pulsed electric fields, and ultrasound is the involvement of external fields, either electric or sound. Therefore, it merits to study…

EngineeringChemical PhenomenaPlasma GasesFood HandlingélectrochimieNanotechnologyhydrodynamique02 engineering and technologycold plasma7. Clean energyIndustrial and Manufacturing Engineeringthermodynamicstempérature froide0404 agricultural biotechnologyResearch community[SDV.IDA]Life Sciences [q-bio]/Food engineeringFood QualityHydrostatic PressureExternal fieldthermodynamiquemicromassplasmaculture non stérileultrasoundbusiness.industryIndustrial scaleéchographie04 agricultural and veterinary sciencesGeneral MedicineNonthermal ; cold plasm PEF ; electrohydrodynamic ; ultrasound ; hydrodynamicsModels TheoreticalElectrohydrodynamicPEF021001 nanoscience & nanotechnology040401 food scienceFood StorageUltrasonic Waveselectrochemistrynonthermalindustrie alimentairehydrodynamicsFood MicrobiologyFood TechnologyBiochemical engineeringReactive Oxygen Species0210 nano-technologybusinessTransport phenomenaFood ScienceCritical Reviews in Food Science and Nutrition
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