124 research outputs found
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Atmospheric and Wake Turbulence Impacts on Wind Turbine Fatigue Loading: Preprint
Large-eddy simulations of atmospheric boundary layers under various stability and surface roughness conditions are performed to investigate the turbulence impact on wind turbines. In particular, the aeroelastic responses of the turbines are studied to characterize the fatigue loading of the turbulence present in the boundary layer and in the wake of the turbines. Two utility-scale 5 MW turbines that are separated by seven rotor diameters are placed in a 3 km by 3 km by 1 km domain. They are subjected to atmospheric turbulent boundary layer flow and data is collected on the structural response of the turbine components. The surface roughness was found to increase the fatigue loads while the atmospheric instability had a small influence. Furthermore, the downstream turbines yielded higher fatigue loads indicating that the turbulent wakes generated from the upstream turbines have significant impact
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Floating Platform Effects on Power Generation in Spar and Semisubmersible Wind Turbines
The design and financing of commercial-scale floating offshore wind projects require a better understanding of how power generation differs between newer floating turbines and well-established fixed-bottom turbines. In floating turbines, platform mobility causes additional rotor motion that can change the time-averaged power generation. In this work, OpenFAST simulations examine the power generated by the National Renewable Energy Laboratory\u27s 5-MW reference turbine mounted on the OC3-UMaine spar and OC4-DeepCWind semisubmersible floating platforms, subjected to extreme irregular waves and below-rated turbulent inflow wind from large-eddy simulations of a neutral atmospheric boundary layer. For these below-rated conditions, average power generation in floating turbines is most affected by two types of turbine displacements: an average rotor pitch angle that reduces power, caused by platform pitch; and rotor motion upwind-downwind that increases power, caused by platform surge and pitch. The relative balance between these two effects determines whether a floating platform causes power gains or losses compared to a fixed-bottom turbine; for example, the spar creates modest (3.1%-4.5%) power gains, whereas the semisubmersible creates insignificant (0.1%-0.2%) power gains for the simulated conditions. Furthermore, platform surge and pitch motions must be analyzed concurrently to fully capture power generation in floating turbines, which is not yet universal practice. Finally, a simple analytical model for predicting average power in floating turbines under below-rated wind speeds is proposed, incorporating effects from both the time-averaged pitch displacement and the dynamic upwind-downwind displacements
The aerodynamics of the curled wake: a simplified model in view of flow control
When a wind turbine is yawed, the shape of the wake changes and a curled wake
profile is generated. The curled wake has drawn a lot of interest because of
its aerodynamic complexity and applicability to wind farm controls. The main
mechanism for the creation of the curled wake has been identified in the
literature as a collection of vortices that are shed from the rotor plane
when the turbine is yawed. This work extends that idea by using aerodynamic
concepts to develop a control-oriented model for the curled wake based on
approximations to the Navier–Stokes equations. The model is tested and
compared to time-averaged results from large-eddy simulations using actuator
disk and line models. The model is able to capture the curling mechanism for
a turbine under uniform inflow and in the case of a neutral atmospheric
boundary layer. The model is then incorporated to the FLOw Redirection and
Induction in Steady State (FLORIS)
framework and provides good agreement with power predictions for cases with
two and three turbines in a row.</p
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Role of Design Standards in Wind Plant Optimization
When a turbine is optimized, it is done within the design constraints established by the objective criteria in the international design standards used to certify a design. Since these criteria are multifaceted, it is a challenging task to conduct the optimization, but it can be done. The optimization is facilitated by the fact that a standard turbine model is subjected to standard inflow conditions that are well characterized in the standard. Examples of applying these conditions to rotor optimization are examined. In other cases, an innovation may provide substantial improvement in one area, but be challenged to impact all of the myriad design load cases. When a turbine is placed in a wind plant, the challenge is magnified. Typical design practice optimizes the turbine for stand-alone operation, and then runs a check on the actual site conditions, including wakes from all nearby turbines. Thus, each turbine in a plant has unique inflow conditions. The possibility of creating objective and consistent inflow conditions for turbines within a plant, for used in optimization of the turbine and the plant, are examined with examples taken from LES simulation
Do wind turbines pose roll hazards to light aircraft?
Wind energy accounted for 5.6 % of all electricity generation
in the United States in 2016. Much of this development has occurred in rural
locations, where open spaces favorable for harnessing wind also serve general
aviation airports. As such, nearly 40 % of all United States wind turbines exist
within 10 km of a small airport. Wind turbines generate electricity by
extracting momentum from the atmosphere, creating downwind wakes
characterized by wind-speed deficits and increased turbulence. Recently, the
concern that turbine wakes pose hazards for small aircraft has been used to
limit wind-farm development. Herein, we assess roll hazards to small aircraft
using large-eddy simulations (LES) of a utility-scale turbine wake. Wind-generated
lift forces and subsequent rolling moments are calculated for hypothetical
aircraft transecting the wake in various orientations. Stably and neutrally
stratified cases are explored, with the stable case presenting a possible
worst-case scenario due to longer-persisting wakes permitted by lower ambient
turbulence. In both cases, only 0.001 % of rolling moments experienced by
hypothetical aircraft during down-wake and cross-wake transects lead to an
increased risk of rolling.</p
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Large-Eddy Simulation of Wind-Plant Aerodynamics: Preprint
In this work, we present results of a large-eddy simulation of the 48 multi-megawatt turbines composing the Lillgrund wind plant. Turbulent inflow wind is created by performing an atmospheric boundary layer precursor simulation and turbines are modeled using a rotating, variable-speed actuator line representation. The motivation for this work is that few others have done wind plant large-eddy simulations with a substantial number of turbines, and the methods for carrying out the simulations are varied. We wish to draw upon the strengths of the existing simulations and our growing atmospheric large-eddy simulation capability to create a sound methodology for performing this type of simulation. We have used the OpenFOAM CFD toolbox to create our solver
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