Unstructured Cartesian refinement with sharp interface immersed boundary method for 3D unsteady incompressible flows

Angelidis, Dionysios; Chawdhary, Saurabh; Sotiropoulos, Fotis

doi:10.1016/j.jcp.2016.08.028

Cited by 46 publications

(34 citation statements)

References 82 publications

(223 reference statements)

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“…According to the topological connection of the subdomains, Angelidis et al classified the numerical methods using mesh adaptation techniques into 3 categories: overlapping decomposition, nonoverlapping decomposition, and nondecomposed methods. The present method is nondecomposed because the adapted mesh is monolithic and fully unstructured.…”

Section: Mesh Adaptation Methods For Unsteady Flowsmentioning

confidence: 99%

An approach of dynamic mesh adaptation for simulating 3‐dimensional unsteady moving‐immersed‐boundary flows

Peng

Zhou

2018

Numerical Methods in Fluids

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This work is the first endeavor to combine dynamic adaptation of tetrahedral mesh with an immersed boundary method for simulating 3D moving‐boundary flows. The complexity of adaptive mesh generation is reduced by implementing the rule that the level difference of neighboring cells never exceeds 1. The geometric quality of mesh does not degrade as the mesh level increases and the error caused by each solution transferring from the old mesh to the new one is relatively small.

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Section: Mesh Adaptation Methods For Unsteady Flowsmentioning

confidence: 99%

An approach of dynamic mesh adaptation for simulating 3‐dimensional unsteady moving‐immersed‐boundary flows

Peng

Zhou

2018

Numerical Methods in Fluids

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“…The freesurface boundary of the flow channel is treated as a rigid lid, an assumption that has been successfully applied in the previous works of Kang et al, (, , ) and Yang, Kang, et al () among others, for low Froude number flows ( F r ≈0.2 for the flow in the East River). More details about numerical method can be found in Angelidis et al ().…”

Section: Methodsmentioning

confidence: 99%

“…The actuator line model can also predict the significant levels of time‐averaged spanwise velocity induced by the rotating turbines, which is more intense in the wake of the first and second turbines (Figure b). The distribution of the time‐averaged velocity profiles provides evidence of the smooth transition of the flow properties across cells with different levels of refinement (Angelidis et al, ). Figure c depicts contours of the streamwise turbulence intensity computed on a two‐level refined grid.…”

Section: Model Validation: Flow Over Aligned Wind Turbine Arraymentioning

confidence: 99%

“…Such a grid resolution is known to give acceptable results for the turbine modeled with an actuator line model (Yang, Kang, et al, ). Actuator line models have been previously used successfully to predict the far wake dynamics of axial hydrokinetic turbines (Churchfield et al, ; Kang et al, ) and wind turbines (Angelidis et al, ; Porté‐Agel et al, ; Yang, Sotiropoulos, et al, ). Also, it is evident from prior numerical studies (Angelidis et al, ), and the results we present herein that the proposed numerical framework allows turbine simulations on locally refined grids without introducing any artificial reflection of the vortical structures at the coarse/fine interface of the computational mesh.…”

Section: Simulation Of East River With the Turbine Arraymentioning

confidence: 99%

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Multiresolution Large‐Eddy Simulation of an Array of Hydrokinetic Turbines in a Field‐Scale River: The Roosevelt Island Tidal Energy Project in New York City

Chawdhary

Angelidis

Colby

et al. 2018

Water Resources Research

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Marine hydrokinetic (MHK) power generation systems enable harvesting energy from waterways without the need for water impoundment. A major research challenge for numerical simulations of field-scale MHK farms stems from the large disparity in scales between the size of waterway and the energy harvesting device. We propose a large-eddy simulation (LES) framework to perform high-fidelity, multiresolution simulations of MHK arrays in a real-life marine environment using a novel unstructured Cartesian flow solver coupled with a sharp-interface immersed boundary method. The potential of the method as a powerful engineering design tool is demonstrated by applying it to simulate a 30 turbine MHK array under development in the East River in New York City. A virtual model of the MHK power plant is reconstructed from high-resolution bathymetry measurements in the East River and the 30 turbines placed in 10 TriFrame arrangements as designed by Verdant Power. A locally refined, near the individual turbines, background unstructured Cartesian grid enables LES across a range of geometric scales of relevance spanning approximately 5 orders of magnitude. The simulated flow field is compared with a baseline LES of the flow in the East River without turbines. While velocity deficits and increased levels of turbulence kinetic energy are observed in the vicinity of the turbine wakes, away from the turbines as well as on the water surface only a small increase in mean momentum is found. Therefore, our results point to the conclusion that MHK energy harvesting from large rivers is possible without a significant disruption of the river flow.

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“…The computational cost of these simulations is still too high for real-time applications for owners and operators. Research efforts are being directed to make LES computationally more affordable by using advanced numerical techniques, as in the recent example of [12]. LES provide rich detailed data, which can be of great value, for example, for tuning the parameters of engineering models, or can provide physical insights to guide wind turbine or wind farm design.…”

Section: Introductionmentioning

confidence: 99%

Large-Eddy Simulations of Two In-Line Turbines in a Wind Tunnel with Different Inflow Conditions

Ciri

Petrolo²,

Salvetti³

et al. 2017

Energies

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Numerical simulations reproducing a wind tunnel experiment on two in-line wind turbines have been performed. The flow features and the array performances have been evaluated in different inflow conditions. Following the experimental setup, different inlet conditions are obtained by simulating two grids upstream of the array. The increased turbulence intensity due to the grids improves the wake recovery and the efficiency of the second turbine. However, the inlet grid induces off-design operation on the first turbine, decreasing the efficiency and increasing fatigue loads. Typical grid flow patterns are observed past the rotor of the first turbine, up to the near wake. Further downstream, the signature of the grid on the flow is quite limited. An assessment of numerical modeling aspects (subgrid scale tensor and rotor parameterization) has been performed by comparison with the experimental measurements.

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Unstructured Cartesian refinement with sharp interface immersed boundary method for 3D unsteady incompressible flows

Cited by 46 publications

References 82 publications

An approach of dynamic mesh adaptation for simulating 3‐dimensional unsteady moving‐immersed‐boundary flows

An approach of dynamic mesh adaptation for simulating 3‐dimensional unsteady moving‐immersed‐boundary flows

Multiresolution Large‐Eddy Simulation of an Array of Hydrokinetic Turbines in a Field‐Scale River: The Roosevelt Island Tidal Energy Project in New York City

Large-Eddy Simulations of Two In-Line Turbines in a Wind Tunnel with Different Inflow Conditions

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