Davide Fransos scite author profile

Protection from windblown-sand is one of the key engineering issues for construction and maintenance of human infrastructures in arid environments. In the last century, several barriers with different shapes have been proposed in order to overcome this problem, but literature lacks of a systematic performance quantitative analysis, and the key geometric parameters that promote sedimentation have not been yet recognized. A deep understanding of the aerodynamics effects of sand barrier on the flow is an unavoidable step to achieve these objectives. The present computational study aims to comparatively analyze different kinds of windblown sand mitigation solid barriers, clarify their working principles, extract from the aerodynamics analysis key geometrical features of the barriers and relate them to the sand trapping performances. Approximated metrics for performance assessment are introduced using aerodynamic parameters. The performances of an innovative solid barrier and the ones of commonly used solid barriers are compared in terms of these metrics. The effects of incoming wind velocity profiles on sand trapping performances are evaluated as well. An empirical dimensionless performance estimator is proposed and used to provide general design guidelines.

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Determination of the aeroelastic transfer functions for streamlined bodies by means of a Navier–Stokes solver

Fransos

Bruno

2006

Mathematical and Computer Modelling

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Evaluation of Reynolds number effects on flutter derivatives of a flat plate by means of a computational approach

Bruno¹,

Fransos²

2008

Journal of Fluids and Structures

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A multiphase first order model for non-equilibrium sand erosion, transport and sedimentation

Preziosi

Fransos²,

Bruno

2015

Applied Mathematics Letters

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Three phenomena are involved in sand movement: erosion, wind transport, and sedimentation. This paper presents a comprehensive easy-to-use multiphase model that include all three aspects with a particular attention to situations in which erosion due to wind shear and sedimentation due to gravity are not in equilibrium. The interest is related to the fact that these are the situations leading to a change of profile of the sand bed.

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Davide Fransos

3D flow around a rectangular cylinder: A computational study

Simulated flow around a rectangular 5:1 cylinder: Spanwise discretisation effects and emerging flow features

Stochastic aerodynamics and aeroelasticity of a flat plate via generalised Polynomial Chaos

Edge degree-of-sharpness and free-stream turbulence scale effects on the aerodynamics of a bridge deck

Solid barriers for windblown sand mitigation: Aerodynamic behavior and conceptual design guidelines

Determination of the aeroelastic transfer functions for streamlined bodies by means of a Navier–Stokes solver

Evaluation of Reynolds number effects on flutter derivatives of a flat plate by means of a computational approach

A multiphase first order model for non-equilibrium sand erosion, transport and sedimentation

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