0000000000448122

AUTHOR

Sylwia Włodarczak

0000-0003-0561-0177

showing 4 related works from this author

Conical Two-Phase Swirl Flow Atomizers—Numerical and Experimental Study

2021

This paper presents the results of numerical simulations for the developed and discussed conical two-phase atomizers with swirl flow, differing in the ratio of the height of the swirl chamber to its diameter. Experiments were carried out for SAN-1 with HS/DS = 1 and SAN-2 with HS/DS = 4 atomizers. The study was conducted over a range of Reynolds number for liquid ReL = (1400

Control and OptimizationMaterials scienceEulerian model020209 energyFlow (psychology)Energy Engineering and Power Technology02 engineering and technologyComputational fluid dynamics01 natural scienceslcsh:Technology010305 fluids & plasmasPhysics::Fluid Dynamicssymbols.namesakePhase (matter)0103 physical sciencesatomization0202 electrical engineering electronic engineering information engineeringFluid dynamicsElectrical and Electronic EngineeringEngineering (miscellaneous)conical swirl atomizerRenewable Energy Sustainability and the EnvironmentTurbulencebusiness.industrylcsh:TReynolds numberMechanicsConical surfaceVolumetric flow ratesymbolsbusinessCFDEnergy (miscellaneous)Energies
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Sedimentation Tanks for Treating Rainwater: CFD Simulations and PIV Experiments

2021

The removal of solids is the most important step when treating rainwater. The article evaluates two designs of sedimentation tanks that can be used for the continuous separation of fine particles from water: OS—standard sedimentation tanks, and OW—swirl sedimentation tanks. The tanks were studied by conducting computational fluid dynamics (CFD) modeling and particle image velocimetry (PIV) experiments. The settling process in sedimentation tank was carried out at varying operating flow rates. A tank with a modified structure was used for the tests, where water was supplied by a nozzle placed at an angle. This solution made it possible to obtain a rotational flow that transported the suspend…

TechnologyControl and OptimizationSedimentation (water treatment)NozzleFlow (psychology)Energy Engineering and Power TechnologyComputational fluid dynamicsCFD; PIV; rainwater treatment; sedimentation tank; swirl motionSettlingCalibrationElectrical and Electronic EngineeringEngineering (miscellaneous)swirl motionRenewable Energy Sustainability and the Environmentbusiness.industryTrainwater treatmentMechanicsVolumetric flow ratePIVParticle image velocimetrysedimentation tankEnvironmental scienceCFDbusinessEnergy (miscellaneous)Energies
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Study on Interfacial Surface in Modified Spray Tower

2019

This paper presents an analysis of the changes in interfacial surface and the size of droplets formed in a spray tower. The interfacial surface and the size of droplets formed are of fundamental importance to the performance of the equipment, both in terms of pressure drop and process efficiency. Liquid film and droplet sizes were measured using a microphotography technique. The confusors studied were classical, with profiled inside surface, and with double profiled inside surface. The liquids studied were water and aqueous solutions of high-molecular polyacrylamide (PAA) of power-law characteristics. The ranges of process Reynolds number studied were as follows: ReG &isin

Surface (mathematics)Materials science020209 energyPolyacrylamideBioengineering02 engineering and technologylcsh:Chemical technologyconfusorlcsh:ChemistryPhysics::Fluid Dynamicschemistry.chemical_compoundsymbols.namesake020401 chemical engineering0202 electrical engineering electronic engineering information engineeringChemical Engineering (miscellaneous)lcsh:TP1-11850204 chemical engineeringComposite materialinterfacial surfacePressure dropAqueous solutionProcess Chemistry and TechnologySauter mean diameterReynolds numberSauter mean diameterlcsh:QD1-999chemistrymodified spray towerSpray towersymbolsDimensionless quantityProcesses
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Numerical Simulation as a Tool for Design Optimization of Two-Phase Swirl Flow Atomizers

2021

This study aims to analyze the hydrodynamics in two-phase swirl flow conical atomizers. The Euler-Euler model was used for the calculations. Numerical simulations were performed to provide information about the fluid velocity distribution and the atomizer’s internal flow. The numerical calculations confirmed the experimental data. This data was found based on the consistency of the spray angles obtained by both methods. Assuming the correctness of the numerical simulations performed, they can be treated as a tool for further analysis of mass and energy exchange along with the atomizer and optimizing the atomizer’s design depending on the requirements. The influence of the swirl chamber geom…

Materials scienceEulerian modelComputer simulationInternal flowFlow (psychology)Phase (waves)Chamber geometrySwirl chamberConical surfaceMechanicsPhysics::Fluid DynamicsFlow velocityConical two-phase atomizersEnergy exchange
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