Stabilized space–time computation of wind-turbine rotor aerodynamics

Takizawa, Kenji; Henicke, Bradley; Tezduyar, Tayfun E.; Hsu, Ming‐Chen; Bazilevs, Yuri

doi:10.1007/s00466-011-0589-2

Cited by 127 publications

(51 citation statements)

References 103 publications

(92 reference statements)

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“…This most recent DSD/SST formulation with the turbulence model is a space-time version [9] of the residual-based variational multiscale (VMS) method [10][11][12][13]. It was successfully tested on wind-turbine rotor aerodynamics in [14].…”

Section: Introductionmentioning

confidence: 99%

Numerical-performance studies for the stabilized space–time computation of wind-turbine rotor aerodynamics

et al. 2011

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We present our numerical-performance studies for 3D wind-turbine rotor aerodynamics computation with the deforming-spatial-domain/stabilized space-time (DSD/SST) formulation. The computation is challenging because of the large Reynolds numbers and rotating turbulent flows, and computing the correct torque requires an accurate and meticulous numerical approach. As the test case, we use the NREL 5MW offshore baseline windturbine rotor. We compute the problem with both the original version of the DSD/SST formulation and the version with an advanced turbulence model. The DSD/SST formulation with the turbulence model is a recently-introduced space-time version of the residual-based variational multiscale method. We include in our comparison as reference solution the results obtained with the residual-based variational multiscale Arbitrary Lagrangian-Eulerian method using NURBS for spatial discretization. We test different levels of mesh refinement and different definitions for the stabilization parameter embedded in the "least squares on incompressibility constraint" stabilization. We compare the torque values obtained.

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Section: Introductionmentioning

confidence: 99%

Numerical-performance studies for the stabilized space–time computation of wind-turbine rotor aerodynamics

et al. 2011

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“…Some examples of these applications are animal swimming and flight [13,22,[60][61][62][63][64][65][66], flag flapping [28], spacecraft parachutes [67][68][69][70][71][72][73][74][75][76][77], cardiovascular fluid mechanics [78][79][80][81][82], wind-turbine aerodynamics [83][84][85][86], and non-Newtonian flow [87].…”

Section: Methodsmentioning

confidence: 99%

A numerical study of linear and nonlinear kinematic models in fish swimming with the DSD/SST method

Tian

2014

Comput Mech

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Flow over two fish (modeled by two flexible plates) in tandem arrangement is investigated by solving the incompressible Navier-Stokes equations numerically with the DSD/SST method to understand the differences between the geometrically linear and nonlinear models. In the simulation, the motions of the plates are reconstructed from a vertically flowing soap film tunnel experiment with linear and nonlinear kinematic models. Based on the simulations, the drag, lift, power consumption, vorticity and pressure fields are discussed in detail. It is found that the linear and nonlinear models are able to reasonably predict the forces and power consumption of a single plate in flow. Moreover, if multiple plates are considered, these two models yield totally different results, which implies that the nonlinear model should be used. The results presented in this work provide a guideline for future studies in fish swimming.

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“…The computations reported in 2011 were for detailed parachute FSI analysis [74][75][76], arterial FSI analysis [77][78][79][80][81], and wind-turbine aerodynamics [82][83][84]. The detailed studies included different trial canopy design configurations of the Orion spacecraft parachutes, Orion spacecraft parachute clusters with two and three parachutes, FSI-based dynamical analysis of the Orion spacecraft parachutes and parachute clusters, patient-specific cerebral arteries with aneurysm, and full-scale wind-turbine rotors.…”

Section: Years 2011-2018mentioning

confidence: 99%

Space–time computations in practical engineering applications: a summary of the 25-year history

Tezduyar

Takizawa

2018

Comput Mech

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In an article published online in July 2018 it was stated that the algorithm proposed in the article is "enabling practical implementation of the space-time FEM for engineering applications." In fact, space-time computations in practical engineering applications were already enabled in 1993. We summarize the computations that have taken place since then. These computations started with finite element discretization and are now also with isogeometric discretization. They were all in 3D space and were all carried out on parallel computers. For quarter of a century, these computations brought solution to many classes of complex problems ranging from Orion spacecraft parachutes to wind turbines, from patient-specific cerebral aneurysms to heart valves, from thermo-fluid analysis of ground vehicles and tires to turbocharger turbines and exhaust manifolds.

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Stabilized space–time computation of wind-turbine rotor aerodynamics

Cited by 127 publications

References 103 publications

Numerical-performance studies for the stabilized space–time computation of wind-turbine rotor aerodynamics

Numerical-performance studies for the stabilized space–time computation of wind-turbine rotor aerodynamics

A numerical study of linear and nonlinear kinematic models in fish swimming with the DSD/SST method

Space–time computations in practical engineering applications: a summary of the 25-year history

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