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Experimental investigation of turbulent flow in a rotating straight channel with continuous ribs

Haiwang Li, Haoliang You, Ruquan You, Zhi Tao

2020Physics of Fluids18 citationsDOI

Abstract

We experimentally study the combined effects of continuous ribs and rotations constructed in a square duct on the turbulent flows and flow separation. The ribs obstruct the channel by 10% of its height and are arranged in three different pitch-to-height ratios (P/e) of 10, 12, and 15. The Reynolds number (Re = ρU0D/μ) is fixed at 10 000, and the rotation number (Ro = ΩD/U0) varies from 0 to 0.52. A time-resolved particle image velocimetry system is applied to provide insights into the main flow and turbulence mechanism. Results show that rotation significantly changes main flow and turbulent characteristics. In particular, a main flow phenomenon has been found: on account of the secondary flow near the ribs, velocity profile deflects to the leading side under a low rotation number, and when Ro rises to 0.48 (critical value), velocity profile deflects to the trailing side. It gives an insight into main flow in a ribbed channel. Reattachment law has been investigated, which can optimize heat transfer by optimize rib arrangement. A proper orthogonal decomposition analysis is also considered to identify the spatial characteristics of the superimposed flow fields. Based on the experimental data, the existence of ribs with different P/e ratios and Coriolis forces play significant roles in rib-generated vortices as well as their turbulent activities.

Topics & Concepts

TurbulencePhysicsMechanicsReynolds numberVortexParticle image velocimetryOpen-channel flowRotation (mathematics)Flow (mathematics)Rib cageSecondary flowGeometryClassical mechanicsMathematicsStructural engineeringEngineeringHeat Transfer MechanismsFluid Dynamics and Turbulent FlowsFluid Dynamics and Vibration Analysis
Experimental investigation of turbulent flow in a rotating straight channel with continuous ribs | Litcius