An implementation of the direct-forcing immersed boundary method using GPU power

Tutkun, Bulent; Edis, Fırat Oğuz

doi:10.1080/19942060.2016.1236749

Cited by 5 publications

(3 citation statements)

References 58 publications

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“…After obtaining the pressure and velocity fields, the Cauchy stress tensor can be calculated at grid nodes that are relevant to the mapping process according to Eq. (18). Note that the shape functions integrals in Eq.…”

Section: Computational Proceduresmentioning

confidence: 99%

“…Various approaches are found in the literature of immersed boundary methods for treating this issue. In a continuous forcing approach, source terms are added to the governing equations, and have effect only near the interface [15][16][17][18]. Goldstein et al, [19] introduced another forcing term for the aim of having a velocity feedback control.…”

Section: Introductionmentioning

confidence: 99%

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A Stress Mapping Immersed Boundary Method for Viscous Flows

Ali

Madbouli

Hamouda

et al. 2021

ARFMTS

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This work introduces an immersed boundary method for two-dimensional simulation of incompressible Navier-Stokes equations. The method uses flow field mapping on the immersed boundary and performs a contour integration to calculate immersed boundary forces. This takes into account the relative location of the immersed boundary inside the background grid elements by using inverse distance weights, and also considers the curvature of the immersed boundary edges. The governing equations of the fluid mechanics are solved using a Galerkin-Least squares finite element formulation. The model is validated against a stationary and a vertically oscillating circular cylinder in a cross flow. The results of the model show acceptable accuracy when compared to experimental and numerical results.

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Section: Computational Proceduresmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Stress Mapping Immersed Boundary Method for Viscous Flows

Ali

Madbouli

Hamouda

et al. 2021

ARFMTS

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“…The reduction of computational cost is contributed by one of the CONTACT Hui Feng E0013532@u.nus.edu reasons: there is almost no cost for the mesh regeneration in each individual step (Dillon & Li, 2009); it is much easier to describe a complex motion of the body relative to a fixed domain mesh (Mittal & Iaccarino, 2005); and many mature methods, solver packages, and algorithms developed for Cartesian grids are available. Following this strategy, a variety of refinements and modifications of the IBM have been developed during the past few decades (Diao et al, 2018;Dillon & Li, 2009;Hopkins, Vanderlei, & Fauci, 2012;Mittal & Iaccarino, 2005;Peskin, 2003;Tutkun & Edis, 2017). With proper methods being used to program the IBM solvers, several FSI problems have been solved (Ardekani & Brandt, 2019;Coclite, Ranaldo, de Tullio, Decuzzi, & Pascazio, 2019).…”

Section: Introductionmentioning

confidence: 99%

Simulations of self-propelled anguilliform swimming using the immersed boundary method in OpenFOAM

Feng

Wang

Todd

et al. 2019

Engineering Applications of Computational Fluid Mechanics

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This study extends the existing immersed boundary method (IBM) in the open source toolbox OpenFOAM for solving fluid-structure interactions involving the immersed structure with changeable shapes. To handle a changeable-shape problem, the existing discrete-forcing direct-imposition approach of IBM in OpenFOAM with a pressure-implicit split-operator (PISO) solver is used to solve the fluid domain with interpolated immersed boundary conditions. In the solved fluid domain, the interactions between the fluid domain and the immersed structure are calculated. Making use of these interactions, a user-defined solid solver is applied to compute and update the boundary conditions on the immersed structure. To validate this methodology, models of anguilliform swimming, a typical FSI problem with moving boundaries which has been well studied, is simulated. The accuracy of the present work is examined by comparing the numerical results with the published data. In simulations, anguilliform swimmers are modeled as deformable immersed boundaries. The immersed swimmers propagate in a path determined by the forces from the surrounding fluid acting upon their bodies, as generated by their prescribed changing shapes. The results including the velocity, the thrust, the wake morphology, and the force distribution along the immersed boundaries are presented and discussed. The good agreement of the computational results with reported works validates the extension of IBM in OpenFOAM. ARTICLE HISTORY

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