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Numerical study of fluid elastic vibration of a circular cylinder in shear flowLin, Hung-Chih 08 September 2005 (has links)
The present study aims to explore dynamical behavior of the fluid-elastic instability of a circular cylinder in shear flow by numerical simulations. The theoretical model comprises two groups of transient conservation equations of mass and momentum and the governing equations are solved numerically with an iterative SIMPLEC(Semi-Implicit Method for Pressure-Linked Equations Consistent) algorithm to determine the flow property and to analysis structure stress simultaneously. Additionally, the TFI (Transfinite interpolation) computation procedure is applied to characterize the behavior of fluid-structure interaction. The predictions are in reasonable agreement with literature showing the validity of the present theoretical model. The numerical results indicate that there is a transverse force acting from high velocity side toward the low velocity side in shear flow. The magnitude of this transverse force increases with the shear parameter. The Strouhal number slightly increases as the shear parameter increases for all Reynolds number. As the pattern of the approach flow changes from the uniform to shear flow, the front stagnation point shifts to high velocity side, and the base pressure increase. The magnitude of the shift of front stagnation point is linear with the shear parameter. Furthermore, this study appraises the amplitude and orbit of fluid elastic vibration of a circular cylinder in shear flow, and shows the effects of the spring constant and damping factor on fluid elastic vibration of the cylinder. In addition, various effects including shear parameter and mass ratio on the critical velocity of the fluid elastic vibration also has been examined detail.
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The ITL programming interface toolkitRandrianarivony, Maharavo 27 February 2007 (has links) (PDF)
This document serves as a reference for the beta version of our evaluation
library ITL. First, it describes a library which gives an easy way for
programmers to evaluate the 3D image and the normal vector corresponding to
a parameter value which belongs to the unit square. The API functions which
are described in this document let programmers make those
evaluations without the need to understand the underlying CAD complica-
tions. As a consequence, programmers can concentrate on their own scien-
tific interests. Our second objective is to describe the input which is a set
of parametric four-sided surfaces that have the structure required by some
integral equation solvers.
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Software pertaining to the preparation of CAD data from IGES interface for mesh-free and mesh-based numerical solversRandrianarivony, Maharavo 27 February 2007 (has links) (PDF)
We focus on the programming aspect of the treatment of digitized
geometries for subsequent use in mesh-free and mesh-based numerical
solvers. That perspective includes the description of our C/C++ implementations
which use OpenGL for the visualization and MFC classes for the user
interface. We report on our experience about implementing with the IGES
interface which serves as input for storage of geometric information. For
mesh-free numerical solvers, it is helpful to decompose the boundary of a
given solid into a set of four-sided surfaces. Additionally, we will describe
the treatment of diffeomorphisms on four-sided domains by using transfinite
interpolations. In particular, Coons and Gordon patches are appropriate for
dealing with such mappings when the equations of the delineating curves
are explicitly known. On the other hand, we show the implementation of
the mesh generation algorithms which invoke the Laplace-Beltrami operator.
We start from coarse meshes which one refine according to generalized
Delaunay techniques. Our software is also featured by its ability of treating
assembly of solids in B-Rep scheme.
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Software pertaining to the preparation of CAD data from IGES interface for mesh-free and mesh-based numerical solversRandrianarivony, Maharavo 27 February 2007 (has links)
We focus on the programming aspect of the treatment of digitized
geometries for subsequent use in mesh-free and mesh-based numerical
solvers. That perspective includes the description of our C/C++ implementations
which use OpenGL for the visualization and MFC classes for the user
interface. We report on our experience about implementing with the IGES
interface which serves as input for storage of geometric information. For
mesh-free numerical solvers, it is helpful to decompose the boundary of a
given solid into a set of four-sided surfaces. Additionally, we will describe
the treatment of diffeomorphisms on four-sided domains by using transfinite
interpolations. In particular, Coons and Gordon patches are appropriate for
dealing with such mappings when the equations of the delineating curves
are explicitly known. On the other hand, we show the implementation of
the mesh generation algorithms which invoke the Laplace-Beltrami operator.
We start from coarse meshes which one refine according to generalized
Delaunay techniques. Our software is also featured by its ability of treating
assembly of solids in B-Rep scheme.
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The ITL programming interface toolkitRandrianarivony, Maharavo 27 February 2007 (has links)
This document serves as a reference for the beta version of our evaluation
library ITL. First, it describes a library which gives an easy way for
programmers to evaluate the 3D image and the normal vector corresponding to
a parameter value which belongs to the unit square. The API functions which
are described in this document let programmers make those
evaluations without the need to understand the underlying CAD complica-
tions. As a consequence, programmers can concentrate on their own scien-
tific interests. Our second objective is to describe the input which is a set
of parametric four-sided surfaces that have the structure required by some
integral equation solvers.
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Geometric processing of CAD data and meshes as input of integral equation solversRandrianarivony, Maharavo 23 November 2006 (has links) (PDF)
Among the presently known numerical solvers of integral equations, two main
categories of approaches can be traced: mesh-free approaches, mesh-based approaches.
We will propose some techniques to process geometric data so that they can
be efficiently used in subsequent numerical treatments of integral equations. In
order to prepare geometric information so that the above two approaches can be
automatically applied, we need the following items:
(1) Splitting a given surface into several four-sided patches,
(2) Generating a diffeomorphism from the unit square to a foursided patch,
(3) Generating a mesh M on a given surface,
(4) Patching of a given triangulation.
In order to have a splitting, we need to approximate the surfaces
first by polygonal regions. We use afterwards quadrangulation techniques by
removing quadrilaterals repeatedly. We will generate the diffeomorphisms by
means of transfinite interpolations of Coons and Gordon types.
The generation of a mesh M from a piecewise Riemannian surface will use some
generalized Delaunay techniques in which the mesh size will be determined with
the help of the Laplace-Beltrami operator.
We will describe our experiences with the IGES format because of two reasons.
First, most of our implementations have been done with it. Next, some of the
proposed methodologies assume that the curve and surface representations are
similar to those of IGES.
Patching a mesh consists in approximating or interpolating it by a set of practical
surfaces such as B-spline patches. That approach proves useful when we want to
utilize a mesh-free integral equation solver but the input geometry is represented
as a mesh.
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Modeling of a Heat-Induced Buckling of Plates Using the Mesh-free MethodMejia, Humberto 02 July 2014 (has links)
In the process of engineering design of structural shapes, the flat plate analysis results can be generalized to predict behaviors of complete structural shapes. In this case, the purpose of this project is to analyze a thin flat plate under conductive heat transfer and to simulate the temperature distribution, thermal stresses, total displacements, and buckling deformations. The current approach in these cases has been using the Finite Element Method (FEM), whose basis is the construction of a conforming mesh. In contrast, this project uses the mesh-free Scan Solve Method. This method eliminates the meshing limitation using a non-conforming mesh. I implemented this modeling process developing numerical algorithms and software tools to model thermally induced buckling. In addition, convergence analysis was achieved, and the results were compared with FEM. In conclusion, the results demonstrate that the method gives similar solutions to FEM in quality, but it is computationally less time consuming.
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Geometric processing of CAD data and meshes as input of integral equation solversRandrianarivony, Maharavo 30 September 2006 (has links)
Among the presently known numerical solvers of integral equations, two main
categories of approaches can be traced: mesh-free approaches, mesh-based approaches.
We will propose some techniques to process geometric data so that they can
be efficiently used in subsequent numerical treatments of integral equations. In
order to prepare geometric information so that the above two approaches can be
automatically applied, we need the following items:
(1) Splitting a given surface into several four-sided patches,
(2) Generating a diffeomorphism from the unit square to a foursided patch,
(3) Generating a mesh M on a given surface,
(4) Patching of a given triangulation.
In order to have a splitting, we need to approximate the surfaces
first by polygonal regions. We use afterwards quadrangulation techniques by
removing quadrilaterals repeatedly. We will generate the diffeomorphisms by
means of transfinite interpolations of Coons and Gordon types.
The generation of a mesh M from a piecewise Riemannian surface will use some
generalized Delaunay techniques in which the mesh size will be determined with
the help of the Laplace-Beltrami operator.
We will describe our experiences with the IGES format because of two reasons.
First, most of our implementations have been done with it. Next, some of the
proposed methodologies assume that the curve and surface representations are
similar to those of IGES.
Patching a mesh consists in approximating or interpolating it by a set of practical
surfaces such as B-spline patches. That approach proves useful when we want to
utilize a mesh-free integral equation solver but the input geometry is represented
as a mesh.
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