COMPARATIVE STUDY OF THE FLOW ANALYSIS RESULTS FOR BUTTERFLY VALVE USING DIFFERENT TURBULENCE MODELS

In external and internal fluid flow analysis using numerical methods, most attention is paid to the properties of the flow assuming absolute rigidity of the solid bodies involved. However, this is often not the case for water flow or other fluids with high density. The pressure forces cause the geometry to deform which in turn changes the flow properties around it. Thus, a one-way and two-way Fluid-Structure Interaction (FSI) coupling is proposed and compared to a CFD analysis of a windsurfing fin in order to quantify the differences in performance data as well as the properties of the flow. This leads to information about the necessity of the use of FSI in comparison to regular CFD analysis and gives indication of the value of the enhanced results of the deformable analysis applied to water flow around an elastically deformable hydrofoil under different angles of attack. The performance data and flow property evaluation is done in ANSYS Fluent using the k-ω SST and k-ε model with a y+ of 1 and 35 respectively in order to be able to compare the behavior of both turbulence models. It is found that the overall lift coefficient in general is lower and that the flow is less turbulent because of softer transition due to the deformed geometry reducing drag forces. It is also found that the deformation of the tip of the hydrofoil leads to vertical lift forces. For the FSI analysis, one-way and two-way coupling were incorporated leading to the ability to compare results. It has been found that one-way coupling is sufficient as long as there is no stall present at any time.

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Comparative study between turbulence models in unsteady cavitating flow with special emphasis on shock wave propagation

Ocean Engineering ◽

10.1016/j.oceaneng.2021.109988 ◽

2021 ◽

Vol 240 ◽

pp. 109988

Author(s):

Zihao Wang ◽

Xin Zhang ◽

Yaxing Wang ◽

Jinfu Liu

Keyword(s):

Shock Wave ◽

Wave Propagation ◽

Comparative Study ◽

Turbulence Models ◽

Cavitating Flow ◽

Shock Wave Propagation ◽

Unsteady Cavitating Flow

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Application of Hybrid RANS/LES turbulence models in rotor-stator fluid machinery: a comparative study

International Journal of Numerical Methods for Heat &amp Fluid Flow ◽

10.1108/hff-08-2016-0312 ◽

2017 ◽

pp. 00-00 ◽

Cited By ~ 1

Author(s):

Chunbao Liu ◽

Weiyang Bu ◽

Dong Xu ◽

Yulong Lei ◽

Xusong Li

Keyword(s):

Comparative Study ◽

Turbulence Models ◽

Fluid Machinery

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Flow Analysis of a Hydrocyclone Designed to High Oil Content Application

Volume 1: Symposia, Parts A, B and C ◽

10.1115/fedsm2009-78403 ◽

2009 ◽

Author(s):

G. M. Raposo ◽

A. O. Nieckele

Keyword(s):

Experimental Data ◽

Flow Rate ◽

Oil Content ◽

Flow Analysis ◽

Turbulence Models ◽

Reynolds Stress Model ◽

Tangential Component ◽

Inlet Flow ◽

Unit Process ◽

Inlet Flow Rate

Development of small size and weight separation equipment are crucial for the petroleum off-shore exploration. Since centrifugal fields are several times stronger than the gravity field, cyclonic separation has became very important as a unit process for compact gas-liquid, liquid-liquid and solid-liquid separation. The major difference between the various cyclones is their geometry. Cyclone optimization for different uses is, every year, less based on experiments and more based on mathematical models. In the present work, the flow field inside high oil content hydrocyclones is numerically obtained with FLUENT. The performance of two turbulence models, Reynolds Stress Model (RSM) and Large Eddy Simulation (LES), to predict the flow inside a high oil content hydrocyclone, is investigated by comparing the results with experimental data available in the literature. All models overpredicted the tangential component, especially at the reverse cone region. However, the prediction of the tangential turbulent fluctuations with LES was significant better than the RSM prediction. The influences of the inlet flow rate and hydrocyclone length in the flow were also evaluated. RSM model was able to foresee correctly, in agreement with experimental data, the correct tendency of pressure drop reduction with decreasing inlet flow rate and increasing length.

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