using mesoscale weather model output as boundary ... microscale – openfoam o created from open...
TRANSCRIPT
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NREL is a national laboratory of the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, operated by the Alliance for Sustainable Energy, LLC.
Using Mesoscale Weather Model Output as Boundary Conditions for Atmospheric Large-Eddy Simulations and Wind-Plant Aerodynamics Simulations
International Conference on Future Technologies for Wind Energy
University of Wyoming October 7‒9, 2013
Matthew J. Churchfield John Michalakes Brian Vanderwende Sang Lee NREL/PR-5000-61122
Michael A. Sprague Julie K. Lundquist Avi Purkayastha Patrick J. Moriarty
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Subject and Motivation
• The Subject: Mesoscale-microscale one-way coupled simulation of atmospheric flow with focus on turbulence evolution
• The Motivation: Real wind plants are subject to microscale weather that is driven by mesoscale weather. Canonical microscale simulations do not capture: o Frontal passages o Large-scale mean wind direction/speed changes o Significant wind direction/speed variation across the plant
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Simulation Tools
• Mesoscale – WRF o Nested Weather Research and Forecasting (WRF) model o Compressible, structured, higher-order finite-difference spatial scheme
• Intermediary – WRF-LES
o Large-eddy simulation (LES) mode WRF (WRF-LES) o 1.5 equation turbulent-kinetic-energy (TKE) subgrid-scale (SGS) model
• Microscale – OpenFOAM
o Created from Open-source Field Operations and Manipulations (OpenFOAM) computational fluid dynamics toolbox
o Incompressible atmospheric LES solver with buoyancy forcing and shear stress lower boundaries
o Unstructured, second-order finite-volume solver o Standard Smagorinksy model, Cs=0.135 (dynamic models available)
• Turbine Model – FAST
o NREL’s Fatigue, Aerodynamics, Structures, and Turbulence (FAST) tool o Blade element actuator line rotor with turbine system dynamics and control response model
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Simulation Tools
NREL’s Multiscale Coupling Effort:
Available at http://wind.nrel.gov/designcodes/simulators/sowfa/
Mesoscale weather modeling (WRF)
Microscale/wind-plant-scale large-eddy simulation (LES) (OpenFOAM)
Turbine system/structural dynamics (FAST)
Photo by Dennis Schroeder, NREL 19075
Photo by Iberdrola Renewables, Inc., NREL 15177
Photo by NASA, NREL 03565
The Simulator for On/Offshore Wind Farm Applications (SOWFA)
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Mesoscale-Microscale Simulation Strategy
1 km
flow
inner-nest WRF-LES
Neumann: U, T, p
Dirichlet: U, T from WRF Neumann: p Dirichlet: surface T flux from WRF Neumann: p Surface stress model
1. Run WRF and WRF-LES 2. Interpolate time history to OpenFOAM
boundary locations and initial field to OpenFOAM interior
3. Run OpenFOAM using WRF-LES initialization and boundary conditions
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Case Simulated
• Crop and Wind Energy eXperiment (CWEX) • Wind plant in Iowa over relatively flat farm land • Summer, daytime case – moderately convective • 1 hr of coupled simulation
photo courtesy of Julie Lundquist Image by Brian Vanderwende
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Results: Coupling with No Turbines
WRF-LES
OpenFOAM
horizontal
horizontal
vertical
vertical
from
WRF
-LES
do
mai
n fr
om O
penF
OAM
do
mai
n
Instantaneous velocity at 85 m above surface
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Results: Coupling with No Turbines
WRF-LES initialized flow field
Finer-scale flow features begin to develop
Region in which finer scales visually appear fully developed
Black crosses denote actual turbine locations (turbines not included in this simulation)
Horizontal velocity time history at 80 m above surface from OpenFOAM microscale calculation
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Results: Coupling with No Turbine Spectra evolution in time
Spectrum of different segments of time history averaged over y constant line
Higher frequency energy substantially builds, then slightly decreases
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Results: Coupling with No Turbines Spectra evolution in space
Spectrum of segments of time history averaged over time and y-constant lines
Higher frequency energy substantially builds, then slightly decreases
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Results: Coupling with No Turbines Spectra evolution in space
Time-averaged integral of high wavenumber part of spectrum at every location
• Roughly 1.5 km required for high wave number energy to “fill in” • High wave number content “overshoots” then decays
horizontal vertical
κ1 κ2
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Results: Coupling with No Turbines
• Near the surface, the horizontal velocity predicted in OpenFOAM domain rapidly decreases with distance from the inflow boundaries
• Unclear why this mismatch between WRF-LES and OpenFOAM LES occurs
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Coupling with Turbines
• Eight 1.5-MW turbines modeled using rotating actuator lines
• Turbine model includes control so rotor speed reacts to flow
• Multi-resolution unstructured mesh o 10 m background o 1.25 m around turbine and
in wake
10m
1.25 m + + + + + +
+ +
Horizontal slice through microscale mesh with region of refinement around turbines and wakes
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Results: Coupling with Turbines
Blade out-of plane bending load
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Conclusions
• One-way mesoscale-microscale coupling allows for non-canonical conditions o Extreme events o Nonhomogeneous flow across farm o Ramp events
• Extension to two-way coupling will facilitate wind plant parameterization
for mesoscale models o Plant-to-plant interaction o Environmental effects
• Significant distance necessary for microscale high wavenumber content
to develop (1.5 km in this case)
• Some time also required for high wavenumber development
• Following the flow direction or progressing in time, an overshoot in high wavenumber energy is observed, followed by decay
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Future Work
• Examine effect of mesoscale inner nest resolution o Does coarser resolution require more distance in microscale
domain for high wave number turbulence development?
• Examine effect of atmospheric stability o Do neutral conditions require more distance in microscale
domain for high wave number turbulence development?
• Examine inflow perturbation methods o i.e., Muñoz-Esparza and Kosović
• Would a dynamic SGS model avoid overshoot of high
wavenumber energy content?