%K Channel flow; Drag reduction; Reynolds number; Turbulent flow; Velocity; Wall flow, Large-eddy simulations; Near-wall turbulent flows; Near-wall velocity profile; Performance; Rectangular channel; Riblets; Streamlined riblet; Structured surfaces; Turbulence controls; Turbulent channel flows, Large eddy simulation
%J Thermal Science
%I Serbian Society of Heat Transfer Engineers
%L scholars13796
%P 2793-2808
%A H.H. Al-Kayiem
%A D.C. Lim
%A J.C. Kurnia
%X Sharkskin-inspired riblets are widely adopted as a passive method for drag reduction of flow over surfaces. In this research, large eddy simulation of turbulent flow over riblet-structured surface in a rectangular channel domain were performed at various Reynolds numbers, ranging from 4200-10000, to probe the resultant drag change, compared to smooth surface. The changes of mean streamwise velocity gradient in wall-normal direction at varied locations around riblet structures were also investigated to reduce mechanisms of streamlined riblet in reducing drag. The computational model is validated by comparing the simulation results against analytical and experimental data, for both smooth and riblet surfaces. Results indicating that the performance of the proposed streamlined riblet shows 7 drag reduction, as maximum, which is higher than the performance of L-shaped riblet with higher wetted surface area. The mean velocity profile analysis indicates that the streamlined riblet structures help to reduce longitudinal averaged velocity component rate in the normal to surface direction of near-wall region which leads to laminarization process as fluid-flows over riblet structures. © 2020 Society of Thermal Engineers of Serbia.
%R 10.2298/TSCI190909059A
%T Large eddy simulation of near-wall turbulent flow over streamlined riblet-structured surface for drag reduction in a rectangular channel
%V 24
%O cited By 3
%D 2020