Add to ORKGp. 2600-2610Mesh motion strategy is one of the key problems in fluid-structure interaction analysis (FSI). One popular technique which often used to solve this problem is known as the spring analogy method. In this paper a new mesh update approach based on the spring analogy method is presented for the effective treatment of mesh moving boundary problem,which can avoid the generation of squashed invalid elements and maintain mesh quality by considering each element shape and grid scale in the definition of the spring stiffness. Meanwhile, the approach is applied to several 2D and 3D boundary correction problems for fully unstructured meshes and evaluated by a mesh quality indicator. With this application, it is demonstrated that the presen...
Mesh deformation is crucial to the accuracy and efficiency of the numerical simulations involving mo...
This paper presents an adaptive mesh moving technique for three-dimensional (3D) fluid flow problems...
S. Miyauchi, A. Ito, S. Takeuchi and T. Kajishima, "Fixed-mesh approach for different dimensional so...
In this paper a new mesh update technique is proposed combined with a PCG-based algorithm, for the s...
In this work, moving mesh methods based on the solution of pseudo structural and fluid problems are ...
In this paper a new mesh update technique is proposed and a numerical study for this method and othe...
Fluid structure interaction, as applied to flexible structures, has wide application in diverse area...
The fluid–structure interaction and aerodynamic shape optimization usually involve the moving or def...
One of the challenges in modern computational engineering is the simulation of fluid-structure inter...
Report on activity presented to RAS.The presence of moving meshes when motions of fluids and solids ...
A three-dimensional finite volume, unstructured mesh (FV-UM) method for dynamic fluid–structure inte...
Collana seminari interni 2012, Number 20120411.In the Computational Fluid Dynamics (CFD) simulation ...
International audienceThis work is motivated by the success of the adaptive finite element methods i...
International audienceMany applications involving Fluid-Structure Interaction (FSI) feature large di...
A three-dimensional finite volume, unstructured mesh (FV-UM) method for dynamic fluid–structure inte...
Mesh deformation is crucial to the accuracy and efficiency of the numerical simulations involving mo...
This paper presents an adaptive mesh moving technique for three-dimensional (3D) fluid flow problems...
S. Miyauchi, A. Ito, S. Takeuchi and T. Kajishima, "Fixed-mesh approach for different dimensional so...
In this paper a new mesh update technique is proposed combined with a PCG-based algorithm, for the s...
In this work, moving mesh methods based on the solution of pseudo structural and fluid problems are ...
In this paper a new mesh update technique is proposed and a numerical study for this method and othe...
Fluid structure interaction, as applied to flexible structures, has wide application in diverse area...
The fluid–structure interaction and aerodynamic shape optimization usually involve the moving or def...
One of the challenges in modern computational engineering is the simulation of fluid-structure inter...
Report on activity presented to RAS.The presence of moving meshes when motions of fluids and solids ...
A three-dimensional finite volume, unstructured mesh (FV-UM) method for dynamic fluid–structure inte...
Collana seminari interni 2012, Number 20120411.In the Computational Fluid Dynamics (CFD) simulation ...
International audienceThis work is motivated by the success of the adaptive finite element methods i...
International audienceMany applications involving Fluid-Structure Interaction (FSI) feature large di...
A three-dimensional finite volume, unstructured mesh (FV-UM) method for dynamic fluid–structure inte...
Mesh deformation is crucial to the accuracy and efficiency of the numerical simulations involving mo...
This paper presents an adaptive mesh moving technique for three-dimensional (3D) fluid flow problems...
S. Miyauchi, A. Ito, S. Takeuchi and T. Kajishima, "Fixed-mesh approach for different dimensional so...