An implementation of the Spalart–Allmaras DES model in an implicit unstructured hybrid finite volume/element solver for incompressible turbulent flow

Tu, Shuangzhang; Aliabadi, Shahrouz; Patel, Reena; Watts, Marvin

doi:10.1002/fld.1864

Cited by 25 publications

(27 citation statements)

References 15 publications

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“…The finite volume (FV) method is used to discretize this system in space and solve for the velocity field using the Newton-Raphson iterative method [18,19]. After the computational domain is discretized into conforming elements, the finite volume formulation can be written for each control volume.…”

Section: Camel Finite Volume Methods For Momentum Equationmentioning

confidence: 99%

“…In this context u n+1 is an intermediate velocity field during the nonlinear iteration and the balance between u and u n+1 will be enforced through the gradient of h . This process is similar to the projection methods commonly used to solve incompressible Navier Stokes equations [18][19][20]. Note that as h → 0 , then ∇h → 0 which ensures u n+1 → u .…”

Section: Predictormentioning

confidence: 96%

“…areas ( [18,19], to name a few). It has moving mesh capabilities to solve problems with highly nonlinear structural deformations.…”

Section: Camel Model Approachmentioning

confidence: 99%

See 2 more Smart Citations

CaMEL and ADCIRC Storm Surge Models—A Comparative Study

Akbar

Luettich

Fleming³

et al. 2017

JMSE

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Abstract:The Computation and Modeling Engineering Laboratory (CaMEL), an implicit solver-based storm surge model, has been extended for use on high performance computing platforms. An MPI (Message Passing Interface) based parallel version of CaMEL has been developed from the previously existing serial version. CaMEL uses hybrid finite element and finite volume techniques to solve shallow water conservation equations in either a Cartesian or a spherical coordinate system and includes hurricane-induced wind stress and pressure, bottom friction, the Coriolis effect, and tidal forcing. Both semi-implicit and fully-implicit time stepping formulations are available. Once the parallel implementation is properly validated, CaMEL is evaluated against ADCIRC, an established storm surge model, using a hindcast of storm surge due to Hurricane Katrina. Observed high water marks are used to verify that both models have comparable accuracy. The effects of time step on the stability and accuracy of the models are investigated and indicate that the semi-and fully-implicit solvers in CaMEL allow the use of larger timesteps than ADCIRC's explicit and semi-implicit solvers. However, ADCIRC outperforms CaMEL in parallel scalability and execution wall clock times. Wall times of CaMEL improve significantly when the largest stable time step sizes are used in respective models, although ADCIRC still is faster.Keywords: shallow water equation; storm surge; parallel model; hybrid finite volume and finite element method; implicit matrix-free solver; spherical coordinate system

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Section: Camel Finite Volume Methods For Momentum Equationmentioning

confidence: 99%

Section: Predictormentioning

confidence: 96%

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CaMEL and ADCIRC Storm Surge Models—A Comparative Study

Akbar

Luettich

Fleming³

et al. 2017

JMSE

Self Cite

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“…This deployment provides a convenient way to evaluate the pressure gradient using the local FE basis functions without the need of reconstruction as required for the velocity field. Refer to [1,8] for more details.…”

Section: Solution Strategymentioning

confidence: 99%

A hybrid scheme based on finite element/volume methods for two immiscible fluid flows

Wan

Aliabadi

Bigler

2009

Numerical Methods in Fluids

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SUMMARYWe have successfully extended our implicit hybrid finite element/volume (FE/FV) solver to flows involving two immiscible fluids. The solver is based on the segregated pressure correction or projection method on staggered unstructured hybrid meshes. An intermediate velocity field is first obtained by solving the momentum equations with the matrix-free implicit cell-centered FV method. The pressure Poisson equation is solved by the node-based Galerkin FE method for an auxiliary variable. The auxiliary variable is used to update the velocity field and the pressure field. The pressure field is carefully updated by taking into account the velocity divergence field. This updating strategy can be rigorously proven to be able to eliminate the unphysical pressure boundary layer and is crucial for the correct temporal convergence rate. Our current staggered-mesh scheme is distinct from other conventional ones in that we store the velocity components at cell centers and the auxiliary variable at vertices. The fluid interface is captured by solving an advection equation for the volume fraction of one of the fluids. The same matrix-free FV method, as the one used for momentum equations, is used to solve the advection equation. We will focus on the interface sharpening strategy to minimize the smearing of the interface over time. We have developed and implemented a global mass conservation algorithm that enforces the conservation of the mass for each fluid.

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“…It is well known that the DES concept combines the advantages of RANS and LES methods in a simple and effective way by using the grid spacing as an adjusting scale, which has been proven promising for engineering flows, and a variety of hybrid approaches have since appeared [3,7]. However, the DES models are not without problems [8,9], and the main stumbling stone for DES is the ambiguous response to the grid refinement. When exceeding a critical level of grid refinement near walls, the standard DES formulation may negatively impact the RANS performance and arise some issues, such as, gray area, modeled stress depletion (MSD), and grid-induced separation (GIS) [10].…”

Section: Introductionmentioning

confidence: 99%

An Improved Scale-Adaptive Simulation Model for Massively Separated Flows

Liu

Guan

2018

International Journal of Aerospace Engineering

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A new hybrid modelling method termed improved scale-adaptive simulation (ISAS) is proposed by introducing the von Karman operator into the dissipation term of the turbulence scale equation, proper derivation as well as constant calibration of which is presented, and the typical circular cylinder flow at Re = 3900 is selected for validation. As expected, the proposed ISAS approach with the concept of scale-adaptive appears more efficient than the original SAS method in obtaining a convergent resolution, meanwhile, comparable with DES in visually capturing the fine-scale unsteadiness. Furthermore, the grid sensitivity issue of DES is encouragingly remedied benefiting from the local-adjusted limiter. The ISAS simulation turns out to attractively represent the development of the shear layers and the flow profiles of the recirculation region, and thus, the focused statistical quantities such as the recirculation length and drag coefficient are closer to the available measurements than DES and SAS outputs. In general, the new modelling method, combining the features of DES and SAS concepts, is capable to simulate turbulent structures down to the grid limit in a simple and effective way, which is practically valuable for engineering flows.

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An implementation of the Spalart–Allmaras DES model in an implicit unstructured hybrid finite volume/element solver for incompressible turbulent flow

Cited by 25 publications

References 15 publications

CaMEL and ADCIRC Storm Surge Models—A Comparative Study

CaMEL and ADCIRC Storm Surge Models—A Comparative Study

A hybrid scheme based on finite element/volume methods for two immiscible fluid flows

An Improved Scale-Adaptive Simulation Model for Massively Separated Flows

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