Parallel embedded boundary methods for fluid and rigid-body interaction

Samaniego, Cristóbal; Houzeaux, Guillaume; Samaniego, Esteban; Vázquez, Mariano

doi:10.1016/j.cma.2015.03.008

Cited by 17 publications

(7 citation statements)

References 41 publications

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“…for a rigid circular cylinder. It is noticed that, a narrow lock-in range computed by [9] covers 98 Re 108, which is nearly coincident with our early work [6,12,39,51] and those of [36,[52][53][54]. On the contrary, the present method produces the widened lock-in range and the larger amplitudes during resonance.…”

Section: Vortex-induced Vibration Of a Circular Cylindersupporting

confidence: 89%

“…Key aerodynamic indicators evaluated at Re = 100 are listed in Table 3, exposing that the obtained data are in better agreement with the experimental research [48]. Note that at this Re lock-in is not aroused in [54]. The cylinder oscillation is very faint when Re steps out of the lower end of the lock-in region.…”

Section: Vortex-induced Vibration Of a Circular Cylindersupporting

confidence: 73%

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The use of artificial compressibility to improve partitioned semi-implicit FSI coupling within the classical Chorin–Témam projection framework

Wang

Zhang

2018

Computers & Fluids

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Over the last decade the classical Chorin-Témam projection method has been utilized to address fluid-structure interaction in a semi-implicit manner. In previous studies the fluid projection step is fully coupled with the structural motion due to the divergence-free constraint. A set of simultaneous equations thus have to be iteratively solved. To overcome this difficulty, a simple and accurate partitioned semi-implicit coupling method is proposed based on the artificial compressibility (AC) in this paper. The iterated AC parameter decouples the pressure, end-of-step velocity and structural motion within the characteristic-based split scheme. The present approach is completely matrix-free and has unlimited access to the finite elements. Its performance is demonstrated for an oscillating bluff body subjected to uniform flows.

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Section: Vortex-induced Vibration Of a Circular Cylindersupporting

confidence: 89%

Section: Vortex-induced Vibration Of a Circular Cylindersupporting

confidence: 73%

The use of artificial compressibility to improve partitioned semi-implicit FSI coupling within the classical Chorin–Témam projection framework

Wang

Zhang

2018

Computers & Fluids

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“…These values are compared with the previously published data. 14,38,46,47 The figure is also overlaid with the famous Re − St relationship 48…”

Section: Large-mass-ratio Problems 711 Transverse Oscillations Of Amentioning

confidence: 99%

Improving the CBS‐based partitioned semi‐implicit coupling algorithm for fluid‐structure interaction

Yang

Baniotopoulos

2018

Numerical Methods in Fluids

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Summary We detail in this work 2 simple but effective alternatives to improve the characteristic‐based split–based partitioned semi‐implicit coupling algorithm for fluid‐structure interaction. The basic idea lies in introducing the end‐of‐step velocity into the implicit stages of the 2 algorithms integrating different splits. The algorithm built upon the second‐order pressure split is further stabilized via the pressure gradient projection with particular emphasis on the extremely low mass ratio. The smoothed finite element method is exploited for spatial discretization of fluid and solid equations. Even without any accelerators, both the semi‐implicit solvers incorporating fixed‐point iterations engender visible improvements versus the previously published data for several benchmarks.

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“…The first strategy relies in taking a time step small enough related to the mesh size so that the free surface crosses at most one element in a single time step [60]. This allows to ensure that when looking for the position of a node or integration point in the deformed mesh, it will be found in the first-layer of elements adjacent to the node or integration point, which will be locally stored in the processor owning the node.…”

Section: Mass Correctionmentioning

confidence: 99%

“…The general formulation with details on the implementation and side ingredients like imposition of Dirichlet boundary conditions in immersed boundaries and a Lagrange Multiplier strategy for performing interpolations with restrictions can be found in [34], and its extension to fluid-structure interaction in [11,12]. More recently, the Fixed-Mesh ALE method has been used in [60] in the context of rigid bodies-fluid interaction in a parallel setting.…”

Section: Introductionmentioning

confidence: 99%

An adaptive Fixed-Mesh ALE method for free surface flows

Baiges

Codina

Pont

et al. 2017

Computer Methods in Applied Mechanics and Engineering

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In this work we present a Fixed-Mesh ALE method for the numerical simulation of free surface flows capable of using an adaptive finite element mesh covering a background domain. This mesh is successively refined and unrefined at each time step in order to focus the computational effort on the spatial regions where it is required. Some of the main ingredients of the formulation are the use of an Arbitrary-Lagrangian-Eulerian formulation for computing temporal derivatives, the use of stabilization terms for stabilizing convection, stabilizing the lack of compatibility between velocity and pressure interpolation spaces, and stabilizing the ill-conditioning introduced by the cuts on the background finite element mesh, and the coupling of the algorithm with an adaptive mesh refinement procedure suitable for running on distributed memory environments. Algorithmic steps for the projection between meshes are presented together with the algebraic fractional step approach used for improving the condition number of the linear systems to be solved. The method is tested in several numerical examples. The expected convergence rates both in space and time are observed. Smooth solution fields for both velocity and pressure are obtained (as a result of the contribution of the stabilization terms). Finally, a good agreement between the numerical results and the reference experimental data is obtained.

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Parallel embedded boundary methods for fluid and rigid-body interaction

Cited by 17 publications

References 41 publications

The use of artificial compressibility to improve partitioned semi-implicit FSI coupling within the classical Chorin–Témam projection framework

The use of artificial compressibility to improve partitioned semi-implicit FSI coupling within the classical Chorin–Témam projection framework

Improving the CBS‐based partitioned semi‐implicit coupling algorithm for fluid‐structure interaction

An adaptive Fixed-Mesh ALE method for free surface flows

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