Title of article
The effect of swimmerʹs hand/forearm acceleration on propulsive forces generation using computational fluid dynamics
Author/Authors
Abel Rouboa، نويسنده , , Antonio Silva Cardoso ، نويسنده , , Lu?s Leal، نويسنده , , Jorge Rocha Teixeira، نويسنده , , Francisco Alves Ferreira ، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2006
Pages
10
From page
1239
To page
1248
Abstract
Propulsive forces generated by swimmers hand/forearm, have been studied through experimental tests. However, there are serious doubts as to whether forces quantified in this way are accurate enough to be meaningful. In order to solve some experimental problems, some numerical techniques have been proposed using Computational Fluid Dynamics (CFD). The main purpose of the present work was threefold. First, disseminate the use of CFD as a new tool in swimming research. Second, apply the CFD method in the calculation of drag and lift coefficients resulting from the numerical resolution equations of the flow around the swimmers hand/forearm using the steady flow conditions. Third, evaluate the effect of hand/forearm acceleration on drag and lift coefficients. For these purposes three, two-dimensional (2D), models of a right male hand/forearm were studied. A frontal model (θ=90°, Φ=90°) and two lateral models, one with the thumb as leading edge (θ=0°, =90°), and the other with the small finger as the leading edge (θ=0°, Φ=180°). The governing system of equations considered was the incompressible Reynolds averaged Navier–Stokes equations with the standard k–ε model. The main results reported that, under the steady-state flow condition, the drag coefficient was the one that contributes more for propulsion, and was almost constant for the whole range of velocities, with a maximum value of 1.16 (Cd=1.16). This is valid when the orientation of the hand/forearm is plane and the model is perpendicular to the direction of the flow. Under the hand /forearm acceleration condition, the measured values for propulsive forces calculation were approximately 22.5% (54.440 N) higher than the forces produced under the steady flow condition (44.428 N). By the results, pointed out, we can conclude that: (i) CFD can be considered an interesting new approach for hydrodynamic forces calculation on swimming, (ii) the acceleration of hand/forearm provides more propulsion to swimmers, confirming that some unsteady mechanism must be present in swimming propulsion.
Keywords
CFD , Drag , Lift , hydrodynamics , Turbulence models
Journal title
Journal of Biomechanics
Serial Year
2006
Journal title
Journal of Biomechanics
Record number
453505
Link To Document