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      Numerical investigations on flow structure and behavior of vortices in the dynamic stall of an oscillating pitching hydrofoil

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      https://www.riss.kr/link?id=A107491846

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      <P><B>Abstract</B></P> <P>This study numerically investigates the behavior of vortices and flow structure in a dynamic stall phenomenon, especially in post-stall where the flow is highly nonlinear. Computational fluid dynamics approaches were used to simulate unsteady flow fields. The Transition SST turbulence model was used to compute the turbulent characteristics, and second-order temporal/spatial schemes were used to reduce dissipation effects. To investigate the behavior of vortices individually, each main vortex core was targeted manually and its strength is computed. It is shown that despite the existence of coherent structures, the interaction of organized vortices is responsible for the complexity of the flow beyond the hydrofoil in post-stall. The primary LEV and primary TEV have the longest lifetime among the LEVs and TEVs, respectively. The Primary LEV loses strength quickly due to counteraction with the TEV and disruption of the energy source provided by the leading edge shear. The secondary LEV plays an important role when dynamic stall occurs and provides a lift peak in post-stall. There are time delays between the maximum circulation of main vortices and corresponding peak of the lift coefficient loop. The general interaction of counter-rotating vortices is responsible for these delays between peaks of the lift coefficient and maximum circulations.</P> <P><B>Highlights</B></P> <P> <UL> <LI> Hydrofoil examination in unsteady conditions for energy extraction. </LI> <LI> Investigations on the flow structure in deep dynamic stall of pitching hydrofoil. </LI> <LI> Analysis of vortex behavior by computing its life-time and strength. </LI> <LI> Interaction of major core vortices leads to instability of flow in post stall. </LI> <LI> The major LEVs and TEVs play important role in the dynamic stall. </LI> </UL> </P>
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      <P><B>Abstract</B></P> <P>This study numerically investigates the behavior of vortices and flow structure in a dynamic stall phenomenon, especially in post-stall where the flow is highly nonlinear. Computational fluid dy...

      <P><B>Abstract</B></P> <P>This study numerically investigates the behavior of vortices and flow structure in a dynamic stall phenomenon, especially in post-stall where the flow is highly nonlinear. Computational fluid dynamics approaches were used to simulate unsteady flow fields. The Transition SST turbulence model was used to compute the turbulent characteristics, and second-order temporal/spatial schemes were used to reduce dissipation effects. To investigate the behavior of vortices individually, each main vortex core was targeted manually and its strength is computed. It is shown that despite the existence of coherent structures, the interaction of organized vortices is responsible for the complexity of the flow beyond the hydrofoil in post-stall. The primary LEV and primary TEV have the longest lifetime among the LEVs and TEVs, respectively. The Primary LEV loses strength quickly due to counteraction with the TEV and disruption of the energy source provided by the leading edge shear. The secondary LEV plays an important role when dynamic stall occurs and provides a lift peak in post-stall. There are time delays between the maximum circulation of main vortices and corresponding peak of the lift coefficient loop. The general interaction of counter-rotating vortices is responsible for these delays between peaks of the lift coefficient and maximum circulations.</P> <P><B>Highlights</B></P> <P> <UL> <LI> Hydrofoil examination in unsteady conditions for energy extraction. </LI> <LI> Investigations on the flow structure in deep dynamic stall of pitching hydrofoil. </LI> <LI> Analysis of vortex behavior by computing its life-time and strength. </LI> <LI> Interaction of major core vortices leads to instability of flow in post stall. </LI> <LI> The major LEVs and TEVs play important role in the dynamic stall. </LI> </UL> </P>

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