Search results for "PROCESSES"

showing 10 items of 3831 documents

One-dimensional Mixed MHD Convection

2006

The parallel, fully developed flow of an electrically conducting fluid between plane parallel walls under the simultaneous influence of a driving pressure head, buoyancy, and magnetohydrodynamic (MHD) forces is studied. The fluid is assumed to be internally heated and the flow is modeled as one-dimensional and incompressible, while the Boussinesq approximation is adopted for the buoyancy terms. Analytical solutions are obtained for temperature, velocity and electrical potential under different electrical boundary conditions, forced to natural convection intensity ratios and values of the magnetic induction. Generalized working charts are presented which synthetically describe the system''s …

Fluid Flow and Transfer ProcessesPhysicsBuoyancyNatural convectionMagnetohydrodynamic generatorMechanical EngineeringMAGNETIC FIELDMechanicsCUBIC ENCLOSUREengineering.materialCondensed Matter PhysicsOpen-channel flowlaw.inventionPhysics::Fluid DynamicsClassical mechanicslawCombined forced and natural convectionCHANNEL FLOWengineeringMagnetohydrodynamic driveMagnetohydrodynamicsBoussinesq approximation (water waves)LIQUID-METAL
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Numerical simulation of reciprocating turbulent flow in a plane channel

2009

Direct numerical simulation results were obtained for oscillatory flow with zero time mean (reciprocating flow) in a plane channel using a finite volume method, Crank-Nicolson time stepping and central approximation of the advection terms. A pressure gradient varying co-sinusoidally in time was imposed as the forcing term, and its frequency and amplitude were made to vary so as to span a range of regimes from purely laminar to fully turbulent. For the limiting cases of reciprocating laminar flow and steady-state turbulent flow, numerical results were validated against analytical solutions and classic experimental literature data, respectively. For general reciprocating flows, predictions we…

Fluid Flow and Transfer ProcessesPhysicsChézy formulaTurbulenceMechanical EngineeringComputational MechanicsDirect numerical simulationThermodynamicsLaminar sublayerLaminar flowMechanicsReciprocating Flow Channel flow transition to turbulence Direct Numerical SimulationCondensed Matter PhysicsPipe flowOpen-channel flowPhysics::Fluid DynamicsFlow separationMechanics of MaterialsSettore ING-IND/19 - Impianti NucleariPhysics of Fluids
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Three-dimensional linear stability analysis of the flow in a liquid spherical droplet driven by an alternating magnetic field

2003

The paper presents a numerical stability analysis of the flow driven by an alternating (AC) magnetic field in an electromagnetically levitated liquid metal droplet. The basic axisymmetric flow is found to become unstable at Reynolds numbers in the order of 100. The critical Reynolds number Rec and the corresponding most unstable azimuthal wave number m are found for several configurations of the magnetic field depending on the skin-depth d. For a uniform external AC magnetic field the azimuthal wave number of the most unstable mode is m=3. An additional steady (DC) magnetic field imposed along the axis of symmetry increases the stability of the flow.

Fluid Flow and Transfer ProcessesPhysicsCondensed matter physicsMechanical EngineeringComputational MechanicsReynolds numberMagnetic Reynolds numberCondensed Matter PhysicsMagnetic fieldPhysics::Fluid Dynamicssymbols.namesakeFlow (mathematics)Mechanics of MaterialssymbolsMagnetic pressureMagnetohydrodynamicsMagnetic levitationNumerical stabilityPhysics of Fluids
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Experimental and numerical study of anomalous thermocapillary convection in liquid gallium

1999

Thermocapillary Marangoni convection of liquid gallium was studied experimentally and numerically. A specially designed experimental setup ensured an oxide-free surface of the liquid gallium for a very long time. The convective flow at the free surface was found to be directed opposite to both buoyancy-driven and ordinary thermocapillary convection. The anomalous direction of the thermocapillary flow was explained by the presence of a small amount of a surface-active contaminant—lead adsorbed at the free surface. Two different approaches were used to describe the observed phenomenon. First, the flow was treated as a pure thermocapillary convection with a modified dependence of the surface t…

Fluid Flow and Transfer ProcessesPhysicsConvectionMarangoni effectbusiness.industryMechanical EngineeringFlow (psychology)Computational Mechanicschemistry.chemical_elementMechanicsCondensed Matter PhysicsPhysics::Fluid DynamicsSurface tensionOpticsAdsorptionchemistryMechanics of MaterialsImpurityFree surfaceGalliumbusinessPhysics of Fluids
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A non-local model of thermal energy transport: The fractional temperature equation

2013

Abstract Non-local models of thermal energy transport have been used in recent physics and engineering applications to describe several “small-scale” and/or high frequency thermodynamic processes as shown in several engineering and physics applications. The aim of this study is to extend a recently proposed fractional-order thermodynamics ( [5] ), where the thermal energy transfer is due to two phenomena: A short-range heat flux ruled by a local transport equation; a long-range thermal energy transfer that represents a ballistic effects among thermal energy propagators. Long-range thermal energy transfer accounts for small-scale effects that are assumed proportional to the product of the in…

Fluid Flow and Transfer ProcessesPhysicsField (physics)business.industryMechanical EngineeringNon-local thermal energy transportFractional calculuCondensed Matter PhysicsThermal conductionFractional calculusTemperature fieldLong-range heat transportHeat fluxGeneralized entropyHeat transferStatistical physicsSettore ICAR/08 - Scienza Delle CostruzioniConvection–diffusion equationbusinessSettore MAT/07 - Fisica MatematicaThermal energyThermodynamic processInternational Journal of Heat and Mass Transfer
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Quincke rotation driven flows

2020

In density-matched suspensions of Quincke particles, macroscopic flow arises due to the synchronization of their rotations at electric-field values smaller than the threshold field for the spontaneous rotation of a single particle.

Fluid Flow and Transfer ProcessesPhysicsFlow (mathematics)Field (physics)Modeling and SimulationSynchronization (computer science)Computational MechanicsParticleMechanicsRotationPhysical Review Fluids
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Heat solitons and thermal transfer of information along thin wires

2020

Abstract The aim of this paper is to consider soliton propagation of heat signals along a cylinder whose heat exchange with the environment is a non-linear function of the difference of temperatures of the cylinder and the environment and whose heat transfer along the system is described by the Maxwell–Cattaneo equation. To find the soliton solutions we use the auxiliary equation method. Our motivation is to obtain and compare the speed of propagation, the maximum rate of information transfer, and the energy necessary for the transfer of one bit of information for different solitons, by assuming that a localized soliton may carry a bit of information. It is shown that a given total power (e…

Fluid Flow and Transfer ProcessesPhysicsInformation transferThermal solitonsMechanical EngineeringCharacteristic equation02 engineering and technologyThermal transferMechanics021001 nanoscience & nanotechnologyCondensed Matter Physics01 natural sciences010305 fluids & plasmasHeat wave0103 physical sciencesHeat transferRadiative transferRadiative transferCylinderInitial value problemSolitonMaxwell–Cattaneo law0210 nano-technologySettore MAT/07 - Fisica MatematicaAuxiliary equation methodInternational Journal of Heat and Mass Transfer
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Stability of electrically conducting liquid flow driven by a rotating magnetic dipole in a ring channel

2020

The stability of electrically conducting liquid flow in a cylindrical ring channel is studied numerically. The flow is driven by a rotating magnetic dipole placed at the ring’s center. Depending on ring’s width, two distinct flow regimes are observed. In a narrow ring, the flow itself and its instability resemble the related rotating magnetic field driven flow in a cylinder. This changes in a wide ring when an intense radial jet develops on the midplane. Within this jet, the driving magnetic force is overwhelmed by inertial and viscous forces similar to how it occurs in the boundary layer flow. The instability develops as an azimuthally periodic wave-like deformation of this jet. Non-unifor…

Fluid Flow and Transfer ProcessesPhysicsJet (fluid)Rotating magnetic fieldMechanical EngineeringComputational MechanicsMechanicsCondensed Matter PhysicsRing (chemistry)01 natural sciencesInstability010305 fluids & plasmasMagnetic fieldPhysics::Fluid DynamicsBoundary layerMechanics of Materials0103 physical sciencesCylinder010306 general physicsMagnetic dipolePhysics of Fluids
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Dynamic mode decomposition of magnetohydrodynamic bubble chain flow in a rectangular vessel

2021

We demonstrate the first application of dynamic mode decomposition (DMD) to bubble flow with resolved dynamic liquid/gas boundaries. Specifically, we have applied DMD to the output of numerical simulations for a system where chains of bubbles ascend through a rectangular liquid metal vessel. Flow patterns have been investigated in the vessel and bubble reference frames. We show how gas flow rate and applied magnetic affect bubble wake flow and larger-scale flow structures within the liquid metal vessel by examining the velocity field mode statistics over trajectory time and total flow time as well as the computed mode velocity fields. The results of this proof-of-concept study indicate that…

Fluid Flow and Transfer ProcessesPhysicsLiquid metalMechanical EngineeringBubbleComputational MechanicsFluid Dynamics (physics.flu-dyn)FOS: Physical sciencesMechanicsPhysics - Fluid DynamicsWakeCondensed Matter PhysicsVolumetric flow ratePhysics::Fluid DynamicsFlow (mathematics)Mechanics of MaterialsDynamic mode decompositionVector fieldMagnetohydrodynamic drive
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Time-resolved velocity measurements in a magnetic micromixer

2015

Abstract Mixing efficiency is lower in passive micromixers due to viscous forces and substantial research effort is focused on designing high performance micromixers. Active micromixers make use of external forces to enhance mixing efficiency. Among these, magnetic forces are popular because they are non-contact and therefore the micromixer design can be kept simple. Laser-based diagnostic tools have great potential in providing multi-parameter information in microfluidics research on mixing. MicroPIV experiments are performed to investigate the transient flow field in a magnetic micromixer undergoing labyrinthine instability. Velocity and interface front information is extracted from a seq…

Fluid Flow and Transfer ProcessesPhysicsMechanical EngineeringGeneral Chemical EngineeringAcousticsMicrofluidicsAerospace EngineeringMicromixerImage processingEdge detectionFilter (large eddy simulation)Nuclear Energy and EngineeringPrewitt operatorMixing (physics)Microscale chemistryExperimental Thermal and Fluid Science
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