Free Elastic Plate Impact into Water

Reinhard, Moritz (2013) Free Elastic Plate Impact into Water. Doctoral thesis, University of East Anglia.

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    Abstract

    Abstract
    The Wagner theory, developed 80 years ago, is an analytical method for solving problems
    where a body with small deadrise angle impacts onto an undisturbed water surface of infinite
    depth. In this study, two-dimensional impact models based on the Wagner theory are
    developed which account for the elasticity of the body, for large horizontal speed of the body
    and flow separation from the body.
    In chapter 3, the problems of inclined rigid and elastic plates, impacting the fluid vertically,
    are solved. The elastic plate deflection is governed by Euler’s beam equation, subject
    to free-free boundary conditions. In chapter 4 and 5, impact problems of rigid and elastic
    plates and blunt bodies with high horizontal speed are considered. A smooth separation of
    the free surface flow from the body is imposed by Kutta’s condition and the Brillouin-Villat
    condition. In chapter 6, we account for fluid separation from the body in the free vertical
    fall of a rigid plate and a blunt body. In all problems considered in this thesis, the rigid
    and elastic plate motions, the fluid flow, and the positions of the turnover regions and the
    separation points are coupled.
    We found that hydrodynamic forces on an elastic body can be significantly different
    from those on a rigid body. In particular, the elasticity of the body can promote cavitation
    and ventilation. It is shown that horizontal speed of the body increases the hydrodynamic
    forces on the body and the jet energy significantly. For free-fall problems at high horizontal
    speed, the body can exit the fluid after entering if the forward speed is large enough. It is
    illustrated that the hydrodynamic forces on the body and the motion of the body strongly
    depend on the separation model. For the Brillouin-Villat separation criterion, we found that
    the position of the separation point is sensitive to the body vibration.

    Item Type: Thesis (Doctoral)
    Faculty \ School: Faculty of Science > School of Mathematics
    Depositing User: Mia Reeves
    Date Deposited: 05 Mar 2014 12:26
    Last Modified: 05 Mar 2014 12:26
    URI: https://ueaeprints.uea.ac.uk/id/eprint/47926
    DOI:

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