Simulation of surface piercing body coupled response to underwater bubble dynamics utilizing 3DYNAFS, a three-dimensional BEM code

We have developed a three-dimensional BEM based code (3DYNAFS©) to study nonlinear free surface flows. The code is being used here to study bubble dynamics, such as that due to an underwater explosion, beneath surface piercing bodies. Six degree-of-freedom rigid body motion of the surface piercing b...

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Bibliographic Details
Published in:Computational mechanics 2003-12, Vol.32 (4-6), p.319-326
Main Authors: CHAHINE, G. L, KALUMUCK, K. M, HSIAO, C.-T
Format: Article
Language:English
Subjects:
Boundary-integral methods
Bubbles
Computational methods in fluid dynamics
Computational techniques
Computer simulation
Cylindrical bodies
Drops and bubbles
Electric sparks
Exact sciences and technology
Floating structures
Fluid dynamics
Fluid-structure interaction
Free floating
Free surfaces
Fundamental areas of phenomenology (including applications)
Mathematical methods in physics
Mathematical models
Nonhomogeneous flows
Physics
Piercing
Rigid structures
Rigid-body dynamics
Simulation
Underwater explosions
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Summary:We have developed a three-dimensional BEM based code (3DYNAFS©) to study nonlinear free surface flows. The code is being used here to study bubble dynamics, such as that due to an underwater explosion, beneath surface piercing bodies. Six degree-of-freedom rigid body motion of the surface piercing bodies are modeled producing a fully coupled fluid-structure interaction effect simulation. Validation of the code is presented by comparison of simulations with laboratory experimental data obtained from high speed video recordings of surface piercing bodies interacting with bubbles generated by electric spark discharge. Two cylindrical body configurations are considered under both free floating and rigidly constrained conditions. The results of the numerical simulation show very good comparison to the experimental data in terms of bubble shapes and periods, the time evolution of the bubble and the induced motion of the bodies.
ISSN:0178-7675
1432-0924
DOI:10.1007/s00466-003-0489-1