Rotational Turbulent Wind Field Simulation of Wind Turbine

Wei He; De Tian; Qi Li; Ning Bo Wang

doi:10.4028/www.scientific.net/AMM.291-294.472

Paper Titles

Large-Eddy Simulation of Flow around a Horizontal-Axis Wind Turbine
p.450

Numerical Simulations of Spherical Vertical-Axis Wind Rotor
p.456

Reliability Modeling of Wind Farm Considering the Outages of Connection Cables
p.461

Research on an Improved Control Strategy for Enhancing LVRT Ability of DFIG System
p.467

Rotational Turbulent Wind Field Simulation of Wind Turbine
p.472

The Realization of Individual Pitch Control
p.477

Using Dynamic Reactive Power Compensation Equipments to Enhance Low Voltage Ride-Through Capability of Fixed Speed Asynchronous Wind Farms
p.481

Numerical Simulation of Unsteady Flow for Variable-Pitch Vertical Axis Wind Turbine
p.490

Stall Nonlinear Flutter of Wind Turbine Blade Modeled as Thin-Walled Composite Beam Integrated with Structural Damping
p.496

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 291-294Rotational Turbulent Wind Field Simulation of Wind...

Rotational Turbulent Wind Field Simulation of Wind Turbine

Abstract:

In order to accurately obtain the influence of rotational effect on fluctuating component of turbulent wind acted on wind turbine, rotational Fourier spectrum with considering rotational effect of rotor was deduced. Physical nature of the rotational Fourier spectrum embodied by coherence function and phase lag was indicated. Auto power spectral density and cross power spectral density of rotational Fourier spectrum with introducing phase lag were proposed. The spectrum matrix constructed by the module of rotational Fourier spectrum was decomposed with Cholesky's method, according to the spectrum representation method with introducing phase lag, the random turbulent wind speed field was generated by superposing a set of cosine functions. Finally, an example involving simulation of the longitudinal turbulent wind velocity time series of a 1.5 MW three-bladed pitch regulated wind turbine was investigated. The target spectrum and simulated spectrum were compared. The result shows that the proposed algorithm is more accurate to simulate the fluctuating wind velocity of rotational blade.