J. Alan Luton scite author profile

J. Alan Luton

4Publications

106Citation Statements Received

36Citation Statements Given

How they've been cited

145

How they cite others

Affiliations

Naval Surface Warfare Center, Virginia Tech

Publications

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Fluid‐Structure Interaction Mechanisms for Close‐In Explosions

Wardlaw

Luton

2000

Shock and Vibration

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This paper examines fluid-structure interaction for close-in internal and external underwater explosions. The resulting flow field is impacted by the interaction between the reflected explosion shock and the explosion bubble. This shock reflects off the bubble as an expansion that reduces the pressure level between the bubble and the target, inducing cavitation and its subsequent collapse that reloads the target. Computational examples of several close-in interaction cases are presented to document the occurrence of these mechanisms. By comparing deformable and rigid body simulations, it is shown that cavitation collapse can occur solely from the shock-bubble interaction without the benefit of target deformation. Addition of a deforming target lowers the flow field pressure, facilitates cavitation and cavitation collapse, as well as reducing the impulse of the initial shock loading.

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The three-dimensional interaction of a vortex pair with a wall

Luton

Ragab

1997

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Articles you may be interested inThe onset of three-dimensional centrifugal global modes and their nonlinear development in a recirculating flow over a flat surface Phys. Fluids 22, 114102 (2010) The interaction of vortices passing near a solid surface has been examined using direct numerical simulation. The configuration studied is a counter-rotating vortex pair approaching a wall in an otherwise quiescent fluid. The focus of these simulations is on the three-dimensional effects, of which little is known. To the authors' knowledge, this is the first three-dimensional simulation that lends support to the short-wavelength instability of the secondary vortex. It has been shown how this Crow-type instability leads to three dimensionality after the rebound of a vortex pair. The growth of the instability of the secondary vortex in the presence of the stronger primary vortex leads to the turning and intense stretching of the secondary vortex. As the instability grows the secondary vortex is bent, stretched, and wrapped around the stronger primary. During this process reconnection was observed between the two secondary vortices. Reconnection also begins between the primary and secondary vortices but the weaker secondary vortex dissipates before the primary, leaving reconnection incomplete. Evidence is presented for a new type of energy cascade based on the short-wavelength instability and the formation of continual smaller vortices at the wall. Ultimately the secondary vortex is destroyed by stretching and dissipation leaving the primary vortex with a permanently distorted shape but relatively unaffected strength compared to an isolated vortex.

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Navy Enhanced Sierra Mechanics (NESM): Toolbox for Predicting Navy Shock and Damage

Moyer¹,

Stergiou

Reese

et al. 2016

Comput. Sci. Eng.

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Numerical simulations of flutter and its suppression by active control

Luton

Mook

1993

AIAA Journal

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J. Alan Luton

Fluid‐Structure Interaction Mechanisms for Close‐In Explosions

The three-dimensional interaction of a vortex pair with a wall

Navy Enhanced Sierra Mechanics (NESM): Toolbox for Predicting Navy Shock and Damage

Numerical simulations of flutter and its suppression by active control

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