Y. Sudhakar scite author profile

The surface texture of materials plays a critical role in wettability, turbulence and transport phenomena. In order to design surfaces for these applications, it is desirable to characterise non-smooth and porous materials by their ability to exchange mass and momentum with flowing fluids. While the underlying physics of the tangential (slip) velocity at a fluid-solid interface is well understood, the importance and treatment of normal (transpiration) velocity and normal stress is unclear. We show that, when slip velocity varies at an interface above the texture, a non-zero transpiration velocity arises from mass conservation. The ability of a given surface texture to accommodate for a normal velocity of this kind is quantified by a transpiration length. We further demonstrate that normal momentum transfer gives rise to a pressure jump. For a porous material, the pressure jump can be characterised by so called resistance coefficients. By solving five Stokes problems, the introduced measures of slip, transpiration and resistance can be determined for any anisotropic non-smooth surface consisting of regularly repeating geometric patterns. The proposed conditions are a subset of effective boundary conditions derived from formal multi-scale expansion. We validate and demonstrate the physical significance of the effective conditions on two canonical problems -a lid-driven cavity and a turbulent channel flow, both with non-smooth bottom surfaces. † Email address for correspondence: ugis@mech.kth.se arXiv:1812.09401v2 [physics.flu-dyn]

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Quadrature schemes for arbitrary convex/concave volumes and integration of weak form in enriched partition of unity methods

Sudhakar

Wall

2013

Computer Methods in Applied Mechanics and Engineering

103

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An accurate, robust, and easy-to-implement method for integration over arbitrary polyhedra: Application to embedded interface methods

Sudhakar

Almeida

Wall

2014

Journal of Computational Physics

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Flight force production by flapping insect wings in inclined stroke plane kinematics

Sudhakar

Vengadesan

2010

Computers & Fluids

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Y. Sudhakar

Transfer of mass and momentum at rough and porous surfaces

Quadrature schemes for arbitrary convex/concave volumes and integration of weak form in enriched partition of unity methods

An accurate, robust, and easy-to-implement method for integration over arbitrary polyhedra: Application to embedded interface methods

Flight force production by flapping insect wings in inclined stroke plane kinematics

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