Journal ArticleDOI
Use of bionic inspired surfaces for aerodynamic drag reduction on motor vehicle body panels
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In this article, the authors introduced bionic non-smooth surfaces as appendices into vehicle body design, aiming to further reduce aerodynamic drag by adapting the structure of a vehicle body from the point of boundary layer control that reduces the burst and the loss of turbulent kinetic energy.Abstract:
Inspired by the successful applications of biological non-smoothness, we introduced bionic non-smooth surfaces as appendices into vehicle body design, aiming to further reduce aerodynamic drag. The size range of the non-smooth units with pits and grooves was determined according to our analysis with the mechanisms underlying non-smooth unit mediated aerodynamic drag reduction. The bionic non-smooth units reported here were designed to adapt the structure of a given vehicle body from the point of boundary layer control that reduces the burst and the loss of turbulent kinetic energy. The engine cover lid and vehicle body cap were individually treated with the non-smooth units, and the treated vehicles were subjected to aerodynamic drag coefficient simulation tests using the computational fluid dynamics (CFD) analysis method. The simulation results showed that, in comparison with smooth surfaces, properly designed non-smooth surfaces can have greater effects on drag reduction. The mechanism underlying drag reduction mediated by non-smooth surfaces was revealed by further analyses, in which the effects of non-smooth and smooth surfaces were directly compared.read more
Citations
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Journal ArticleDOI
Reduction in the aerodynamic drag around a generic vehicle by using a non-smooth surface:
TL;DR: In this paper, the effect of the non-smooth surface on the aerodynamic drag of a vehicle was investigated by analyzing the flow field structure of the wake, and a multi-island genetic algorithm was employed to obtain the optimal solution for the surrogate model.
Journal ArticleDOI
A comparative study on the performance of typical types of bionic groove dry gas seal based on bird wing
TL;DR: In this paper, a series of bionic grooves based on bird wing, such as cluster spiral groove, multi-array spiral groove and flow-split spiral groove are introduced to improve the film stiffness and sealing properties of dry gas seal.
Journal ArticleDOI
Application of the Bionic Concept in Reducing the Complexity Noise and Drag of the Mega High-Speed Train Based on Computer Simulation Technologies
He-xuan Hu,Bo Tang,Ye Zhang +2 more
TL;DR: The paper aims to take bionic concept as the entry point, selecting the hummingbird as the bionic prototype and extracting bionic elements to establish a bionic train model, and proves that drag and noise of the bionics head type were lower than those of the original train.
Journal ArticleDOI
Skin friction reduction characteristics of variable ovoid non-smooth surfaces
TL;DR: In this article, a variable ovoid nonsmooth structure is proposed based on three size parameters, the radius, semimajor, and depth, and a 3D model is created based on UG software.
Journal ArticleDOI
Numerical investigation of flow around a 3D bluff body using deflector plate
TL;DR: In this article, a numerical study of drag reduction technique using passive flow device around a realistic car model is presented, where the model used in this investigation is Ahmed body, at the rear top of which a deflector is installed.
References
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Journal ArticleDOI
The numerical computation of turbulent flows
Brian Launder,D. B. Spalding +1 more
TL;DR: In this paper, the authors present a review of the applicability and applicability of numerical predictions of turbulent flow, and advocate that computational economy, range of applicability, and physical realism are best served by turbulence models in which the magnitudes of two turbulence quantities, the turbulence kinetic energy k and its dissipation rate ϵ, are calculated from transport equations solved simultaneously with those governing the mean flow behaviour.
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TL;DR: This chapter discusses the development of the Finite Volume Method for Diffusion Problems, a method for solving pressure-Velocity Coupling in Steady Flows problems, and its applications.
Journal ArticleDOI
Delaying transition to turbulence by a passive mechanism.
TL;DR: This work takes a second approach consisting of keeping the boundary layer laminar as long as possible by forcing small optimal perturbations, and shows that by using this passive control technique it is possible to sensibly delay transition to turbulence.
Journal ArticleDOI
Turbulent drag reduction by passive mechanisms
TL;DR: In this paper, the authors report the results of a series of wind-tunnel experiments that demonstrate a passive means of effectively controlling turbulence in channel flow, which involves the introduction of specified patterns of protrusions on the confining walls, which interact with the coherent, energy-bearing eddy structures in the wall region.
Journal ArticleDOI
Drag reduction of turbulent flow over thin rectangular riblets
TL;DR: In this article, a second-order accurate finite volume code is modified in order to reconstruct the adjacent cells to the riblets at Cartesian coordinates, and a quadratic interpolation scheme is used to estimate the fluxes at the reformed cells.