Your search keyword '"Shervin Bagheri"' showing total 2 results

1. Near-wall turbulence alteration with the transpiration-resistance model

Author

Seyed Morteza, Habibi Khorasani, Uǧis, Lācis, Simon, Pasche, Marco Edoardo, Rosti, Shervin, Bagheri, Seyed Morteza, Habibi Khorasani, Uǧis, Lācis, Simon, Pasche, Marco Edoardo, Rosti, and Shervin, Bagheri

Abstract

A set of boundary conditions called the transpiration-resistance model (TRM) is investigated in altering near-wall turbulence. The TRM was proposed by Lacis et al. (J. Fluid Mech., vol. 884, 2020, p. A21) as a means of representing the net effect of surface micro-textures on their overlying bulk flows. It encompasses conventional Navier-slip boundary conditions relating the streamwise and spanwise velocities to their respective shears through the slip lengths ℓx and ℓz . In addition, it features a transpiration condition accounting for the changes induced in the wall-normal velocity by expressing it in terms of variations of the wall-parallel velocity shears through the transpiration lengths mx and mz . Greater levels of drag increase occur when more transpiration takes place at the boundary plane, with turbulent transpiration being predominately coupled to the spanwise shear component for canonical near-wall turbulence. The TRM reproduces the effect of a homogeneous and structured roughness up to k+≈18 , encompassing the regime of smooth-wall-like turbulence described using virtual origins (Luchini, 1996 Reducing the turbulent skin friction. In Computational Methods in Applied Sciences’ 96 (Paris, 9–13 Sept. 1996), pp. 465–470. Wiley; Ibrahim et al., J. Fluid Mech., vol. 915, 2021, p. A56) and slightly beyond it. The transpiration factor is defined as the product of the slip and transpiration lengths, i.e. (mℓ)x,z . This factor contains the compound effect of the wall-parallel velocity occurring at the boundary plane and increased permeability, both of which lead to the transport of momentum in the wall-normal direction. A linear relation between the transpiration factor and the roughness function is observed for regularly textured surfaces in the transitionally rough regime of turbulence. This shows that such effective flow quantities can be suitable measures for characterizing rough surfaces in this flow regime., source:https://www.cambridge.org/core/journals/journal-of-fluid-mechanics/article/nearwall-turbulence-alteration-with-the-transpirationresistance-model/E3016E23C8DDADF3AE6412E33D3DF682

Published

2022

2. Input?output analysis, model reduction and control of the flat-plate boundary layer.

Author

SHERVIN BAGHERI, LUCA BRANDT, and DAN S. HENNINGSON

Subjects

BOUNDARY layer (Aerodynamics), NAVIER-Stokes equations, PERTURBATION theory, UNSTEADY flow (Aerodynamics), FLUID mechanics, FLUID dynamics, ACTUATORS, SIMULATION methods & models

Abstract

The dynamics and control of two-dimensional disturbances in the spatially evolving boundary layer on a flat plate are investigated from an input?output viewpoint. A set-up of spatially localized inputs (external disturbances and actuators) and outputs (objective functions and sensors) is introduced for the control design of convectively unstable flow configurations. From the linearized Navier?Stokes equations with the inputs and outputs, controllable, observable and balanced modes are extracted using the snapshot method. A balanced reduced-order model (ROM) is constructed and shown to capture the input?output behaviour of the linearized Navier?Stokes equations. This model is finally used to design a 2-feedback controller to suppress the growth of two-dimensional perturbations inside the boundary layer. [ABSTRACT FROM AUTHOR]

Published

2009