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Development and Testing of a Wind Simulator at an Operating Wind Farm
R. J. Conzemius1, H. Lu2, L. Chamorro2, Y.-T. Wu2, and F. Porte-Agel2,3
1. Introduction The minimization of wind turbine wake impacts is one of the primary considerations in wind
farm design. Yet, due to the turbulent nature of wakes, they are often rather difficult to model,
and the problem becomes particularly challenging when large arrays are planned, due to the
potential for multiple interactions among wakes. The cumulative effects of upstream turbines
can have a substantial impact on both wind farm output as well as site suitability.
Numerous models exist for characterizing wind turbine wakes (Barthalmie et al. 2006). Due
to the great computational expense of explicitly simulating turbine wakes, these models employ
great simplifications in order to make it possible to optimize the layout of large wind turbine
arrays by calculating cumulative wake effects for a myriad of different possible configurations.
Bartholmie et al. (2003, 2006) have tested these models at offshore wind farms, but validation at
various onshore wind farms is rather limited.
In more recent years, computational fluid dynamics (CFD) has become more widely accepted
as a tool for estimating wind turbine multiple wake impacts at large wind farms. This larger
acceptance has come about largely due to the continuing rapid increase in computer power and
storage capacity. However, CFD has not been extensively evaluated within large wind farm
arrays. In particular, the parameterizations used in CFD to calculate the impacts of turbulence on
the mean flow have not been thoroughly tested for atmospheric applications, and the depth of
many CFD domains has been chosen only with the height of the rotor in mind, as opposed to
considering the entire depth over which turbulent flows occur in the atmosphere. In particular,
the relevance of large, organized turbulent structures in the atmospheric boundary layer and their
role in wake meandering and recovery has not been studied. The vertical transport of momentum
and heat accomplished by these large-scale turbulent eddies in the boundary layer is not well
represented by turbulence models.
In the present study, we use large eddy simulation (LES) methodology to resolve these larger
turbulent structures so that their impacts on the mean flow in addition to the development and
dissipation of wind turbine wakes can be explicitly calculated. To focus the LES evaluation
specifically on atmospheric turbulence and its effects on turbine wakes and to avoid the
1 WindLogics, Inc. Grand Rapids, Minnesota, USA 2 Saint Anthony Falls Laboratory, University of Minnesota, Minneapolis, Minnesota, USA 3 Ecole Polytechnique Federale de Lausanne, Switzerland
Corresponding author e-mail address: bobc@windlogics.com
complicating effects of topography, we have chosen for our study a wind farm located in
relatively simple terrain. The wind farm provided supervisory control and data acquisition
(SCADA) data on a turbine-by-turbine level every 10 minutes. Additionally, we placed two
sodar instruments in the farm with the intent of measuring both the free-stream (unwaked) air
flow and the turbine wakes.
By taking measurements of turbine wakes, we also seek to further test the application of LES
methodology to simulate multiple wind turbine wakes. The code to be used for these exercises
(Porté-Agel et al. 2000, Porté-Agel 2004, Stoll and Porté-Agel 2006, Wan et al. 2007, Stoll and
Porté-Agel 2008) has already been tested extensively and compared to both wind tunnel results
and atmospheric observations. These wind tunnel tests have more recently included model wind
turbines and their wakes. However, the spectrum of turbulence in the tunnel is limited by the
width and depth of the wind tunnel, and we would like to further validate the code for
commercial scale wind turbines operating under the full spectrum of atmospheric turbulence. In
particular, the counter-rotational effect of rotor torque has been found to be significant in the
wind tunnel measurements and in LES runs that have included blade torque in the turbine
parameterization. It remains to be seen whether these effects are present and measureable in
operating wind farms. Thus, one goal of the present study is to provide further tests of the LES
methodology applied to operating wind farms and to evaluate the skill of simulations to
reproduce the velocity profile in wind turbine wakes and to discover whether wake
characteristics measured in the wind tunnel differ greatly from those experiencing the full scale
of atmospheric turbulence.
2. Experimental setup
a. Wind Farm Location The wind farm location chosen for our simulations is located in Mower County, Minnesota and
is operated by NextEra Energy Resources, Inc. The farm contains 43 Siemens SWT2.3-93
turbines (see Fig. 1), each with a peak capacity of 2.3 MW, and has been operating since late
2007. In the summer and fall of 2009, we collected SCADA data from the farm. The SCADA
data provide 10-minute averages of ambient atmospheric temperature and wind speed at the
nacelle, power output, blade pitch angle, and rotor RPM. In general, the wind farm layout was
designed to minimize wake impacts for the two prevailing wind directions at the site, which are
from the northwest and from the south. For this reason, we focused our analysis on the
southwestern portion of the farm, where one wind turbine row is oriented more north to south
than the others and is therefore more likely to experience turbine wake effects. Due to the fact
that measurement equipment could only be placed on turbine access roads within the farm, this
southwestern segment was an ideal monitoring location because the row curves at a nearly 90-
degree angle, making it possible to measure waked and unwaked wind profiles within this row
simultaneously.
Fig. 1. Layout of the wind farm and placement of the sodars in the southwest segment.
b. Sodar Data We placed two SecondWind Triton sodars within this wind turbine segment (see Fig. 1) in order
to measure the unwaked and waked wind speed profiles. The first was placed midway between
Turbines 39 (T39) and 40 (T40) with the intention of measuring the background atmospheric
wind profile during periods when the wind is coming from the south, which is one of two
prevailing wind directions for the site. The second sodar was placed between T41 and T42, but
as close to T42 as possible, in order to measure downstream wake impacts from T41.
The sodars measure the vertical wind profile using three beams, each 10 degrees off the vertical,
and separated horizontally by 120 degrees. The half power beam width is approximately 11
degrees. The Tritons are typically deployed so that one of the three beams points directly south.
Pulses from each of these three beams are sent out at approximately 10 second intervals, and the
return signals are averaged over a 10-minute period to calculate the vertical wind profile. The
profile includes all three components of velocity at heights of 40, 50, 60, 80, 100, 120, 140, 160,
180, and 200 meters above ground level (AGL). Additionally, an estimate of turbulence
intensity at each of these levels is included. A barometer is also contained within the unit as well
as a thermometer at the 2-meter level on the outside edge of the dish so that air density can be
calculated for each 10-minute observation. The sodars were deployed on July 31, 2009 and
remained operating in the wind farm until December 14, 2009.
c. Data analysis technique In the wind tunnel (Chamorro and Porte-Agel 2009), the turbulent and time-averaged
components of velocity were measured using a fast-response hot wire probe that could be moved
to any position relative to the wind turbine location, and the air flow and vertical temperature
gradient within the tunnel could be precisely controlled. The measurements provided vertical
cross-sections and profiles of mean wind and turbulence properties for neutral atmospheric
conditions. In the wind farm, such control over the wind and temperature and measurement
locations is not possible, so it is necessary to use a compositing technique to construct the wake
vertical profiles and cross sections from all measurements available throughout the course of the
field measurement campaign. It is possible to categorize the measurements in terms of
Richardson number, nocturnal versus convective boundary layer conditions, or more simply in
terms of the atmospheric temperature gradient. However, due to sampling size limitations, it was
not possible to restrict the measurements to a precise set of conditions as was done in the wind
tunnel. Therefore, some variation in conditions (for example, a composite formed using
measurements with a similar vertical temperature gradient may have had different temperatures
and different wind speeds) within any of the constructed composites was an undesired yet
necessary result.
We used a cylindrical coordinate system for our analyses, with range (meters), azimuth
(degrees), and height (meters above ground level) as the three coordinates and the zero azimuth
pointed in the direction of the upwind turbine, which, in our presented analyses, is Turbine 41
(WT41—hereafter we shall denote wind turbines by the letters ‗WT‘ followed by the turbine
number). For the SCADA data, whose variables are all measured at 80 meters AGL, the
analyses are presented as functions of azimuth only. Analyses based on sodar data are presented
as a function of both azimuth and height above ground level.
In order to classify the data according to atmospheric stability, we calculated the vertical
temperature gradient by taking the difference between the average of the nacelle ambient
temperature measurements (from all 43 turbines) and the average of the two sodar temperatures
and dividing by the 78 meter difference in height between those two levels. The vertical
temperature gradient affects wake recovery by impacting the amount of background atmospheric
turbulence, whose role is to remove velocity gradients in the flow. As the vertical temperature
gradient increases, the atmospheric conditions become less supportive of turbulence, and wakes
persist farther downstream. The largest vertical temperature gradients are found at night, when
temperature often increases with height, turbulence is generally suppressed, and the wakes are
most easily measured. In an unstable profile, when the temperature gradient is less than -10 deg
C/km, buoyancy production of turbulence occurs, and large turbulent structures cause wake
meandering and rapid dissipation of wakes. The vertical temperature gradient values in Table 1
were used as limits of our stability categories.
Table 1. Temperature Gradient Ranges Used for Stability Classification
Stability Class Temperature Gradient (K/km)
A,B <-1.7
C -1.7<x<-1.5
D -1.5<X<-0.55
E -0.55<X<1.5
F 1.5<X<100
In order to focus on occurrences of more meaningful wake impacts, we eliminated any time
periods when either the upstream or waked turbine was offline or when the wind speed was too
light for both turbines to be producing at least 150 kW power. Likewise, if the wind speed was
large enough for either turbine to reach the maximum power of 2300 kW (meaning that one or
both turbines might be operating on the upper, flat part of the power curve), we eliminated that
time period from the analysis. Imposing this upper limit on wind speed also simplified the
turbine parameterization in LES by allowing a fixed blade pitch angle near zero because the
blade pitch does not increase from zero until the turbine is operating at peak capacity. We
thereby eliminated measurements if the blade pitch angle became greater than zero degrees, and
because this happens only at or near the top of the power curve, we used blade pitch angle as a
proxy for maximum power.
The yaw angle of the ―downstream‖ turbine was used as the wind direction for all measurements,
and the compass direction terminology was used. Under such terminology, angles increase in the
clockwise direction and decrease in the counterclockwise.
Prior to performing the calculations, we corrected the yaw angles from the SCADA data. The
correction procedure was needed in order to remove yaw angle offsets that developed in the
archiving system as a result of turbine downtime (for fault conditions, maintenance, or other
reasons). When turbines are subsequently brought back online, the yaw angle is erroneously
recorded as unchanged from its previous uptime value, even when the actual yaw angle has
changed. These errors appear to be a result of archival software design.
In order to construct vertically consistent sodar cross-sections and vertical profiles, we limited
our analysis to times when the entire vertical profile was available. This occurred only 19% of
the time, but the length of the data collection period allowed a sufficient number of
measurements to be collected to form a composite cross section.
d. Large eddy simulation methodology
i. Description of the code
The LES approach explicitly solves the scales of motion larger than the grid resolution (on the
order of 10 m), while the effect of the sub-grid scales (ranging from the grid scale to the
Kolmogorov scale, on the order of 1 mm in the atmospheric boundary layer) need to be
parameterized. Two types of sub-grid models are adopted in the current work: (i) subgrid-scale
models to parameterize the effects of the unresolved turbulent eddy motions, and (ii) wind-
turbine models to parameterize the turbine-induced lift and drag forces.
Large eddy simulations are performed using recently developed scale-dependent Lagrangian
dynamic approach, which is able to account, without tuning, for the effects of local shear and
flow anisotropy on the distribution of the SGS model coefficients (Porté-Agel et al. 2000, Porté-
Agel 2004, Stoll and Porté-Agel 2006, Wan et al. 2007, Stoll and Porté-Agel 2008). The model
overcomes the limitations of traditional models in the near-wall region and delivers improved
predictions of energy spectra, mean velocity profiles as well as other characteristics at different
heights from the ground.
Wind turbine loads are calculated using the actuator disk model (ADM) and the actuator line
model (ALM). The ADM distributes the force loading on the rotor disk; and the ALM distributes
the forces on lines that follow the blade positions and thus it has the strength to capture important
characteristics of the wind turbine wake such as tip vortices and coherent periodic structures in
helical wakes (Sørensen and Shen 2002).
ii. Wind Tunnel Tests of the Code
The wind tunnel measurements of wind turbine wakes are further described in Chamorro and
Porte-Agel (2009). Prior to the application of LES to the wind farm, the LES code was tested in
a wind tunnel environment. A model wind turbine array was constructed at the wind tunnel at
the Saint Anthony Falls Laboratory (SAFL) at the University of Minnesota. The array consisted
of model wind turbines at approximately 1/800 scale mounted on the floor of the tunnel. The tip
speed ratio (λ=4) was adjusted to match that of field-scale turbines (usually between 3.5 and 6).
The tunnel is a closed loop circuit with a plan length of 37.5 m and a main test section 16 m
long, 1.7 m wide, and 1.7 m in depth. The temperature of the lower surface can be precisely
controlled using a series of aluminum strips placed within the floor of the wind tunnel. The
precise control is achieved by pumping a temperature-regulated fluid through the strips. In
addition, the air temperature can be controlled using a heat exchanger mounted in the wind
tunnel expansion after the fan. The regulated temperatures of the air and the test section floor
determine the type of boundary layer that will affect the turbine array. A picture of a model wind
turbine array in the wind tunnel is shown in Fig. 2.
The turbulence is measured by a fast-response 3-wire anemometry. The sensor (a combination of
an x-type hot-wire and a single cold-wire) was used to obtain high resolution and simultaneous
measurements of two velocity components (streamwise and vertical) and temperature. The
measurement frequency ranged from 1 KHz to 2 KHz. The 3-wire anemometer can be moved
throughout the test section to measure the entire cross section of the turbine wake.
Fig. 2. Layout of the turbine wake measurements in the wind tunnel. To the right is the model
turbine, and the 3-wire anemometer is on the left.
Precise measurements were made for a single turbine. The LES was configured to represent the
same single turbine layout in the wind tunnel, and the simulation was performed using the same
conditions of inlet (to the test section) flow, fluxes from the lower surface, and the same
dimensions of the wind turbine.
The results of the initial LES-wind tunnel comparison for the neutral case are shown in Fig. 3,
which shows the vertical wind profile, centered on the turbine at a distance of five rotor
diameters downstream from the turbine. As can be seen from the comparison, the simulation
accounts for the turbine wake effects on the mean flow profile with minimal error, generally less
than five percent over the entire depth of the profile (Fig. 3a). The profile features a local
minimum in wind speed just below the turbine hub, although the velocity deficit is
approximately collocated with the turbine hub. Below z/d=0.25 and above z/d=1.5 (where z is
height, d is the rotor diameter), the wake impacts on the flow are near zero.
It is generally more difficult to predict the mean profiles of turbulence intensity, but Fig. 3b
shows that the overall characteristics of the turbulence profile are predicted very well by the LES
code. Compared to the inflow profile (upstream from the turbine), the turbulence intensity
increases the most near the top of the rotor, where the wind shear experiences a local (in height)
maximum. The wake tip vortices may be most pronounced at this level. A very small decrease
in turbulence intensity occurs near the bottom of the blade-swept depth, likely because of the
decrease in vertical shear there, causing a decrease in mechanical turbulence production.
Fig. 3. 3-wire anemometry measurements of the center of the turbine wake at a downwind
distance of five rotor diameters: (a) mean vertical wind profile; and (b) profile of the standard
deviation of the x-component of velocity (u) scaled by hub height mean flow (uhub).
e. Measurements Used for LES Initialization in Operating Wind Farm
We selected a temporally contiguous set of measurements when WT41 and WT42 were
operating and when Triton169 was, during at least some portion of the selected time interval,
measuring a wake. Unlike the compositing procedure described above, it was not necessary to
restrict the analyses to time intervals when sodars were providing a full or nearly full vertical
profile of measurements, but it was necessary to have measurements up to at least 140 m AGL in
order for the entire wake profile to be measured. Within the selected time period (November 22,
2009), variations of wind speed and direction and temperature occurred, making it possible to
sample different locations in the cross section of the wake. The LES was initialized using the
unwaked profiles measured by Triton172, supplemented with gridded analysis data from the
Rapid Update Cycle (RUC) model at heights above the maximum measurement in the sodar
vertical profile. The temperature was constructed using the 2-meter sodar temperature (average
between the two sodars), the average of the 43 SCADA measurements of temperature taken at
the 80-meter level, and temperature from the RUC levels above 200 m AGL. Linear
interpolation was used between these levels to bring the measurements to the grid vertical levels.
Wind speed horizontal components were interpolated linearly between the lowest sodar level (40
m AGL) and all subsequent levels above that. RUC horizontal wind component data were used
at levels above the sodar measurements. In the lowest 40 meters, the wind was assumed to have
a logarithmic vertical profile with a friction velocity of 0.63 m/s and a surface roughness of 0.3
m.
In order to provide the turbulent component of LES inlet conditions that are representative of
the atmospheric conditions at the time, an LES pre-run was conducted without wind turbines, the
results were saved, and the pre-run data were used as the inlet (south boundary) condition for the
run with the wind turbines. The lateral (east-west) boundary conditions were chosen as periodic,
and the outlet condition (on the north side) was a Neumann zero gradient condition.
3. Results
a. SCADA Analysis Wind turbine wakes are not necessarily seen in the data during individual instances of waking.
Rather, the SCADA data reveal wakes when viewed in a composite manner with all available
observations taken during the course of the field measurement campaign. We show the data by
calculating the ratios of wind speed and power from the SCADA data from WT42 and WT41 in
order to indicate the velocity deficit. Although a large amount of scatter is obvious in the plots
(Fig. 4), if the data points are binned in five-degree increments (red lines), the wakes are more
clearly seen in the data When WT42 is waked, the ratio of the WT42 to WT41 wind speeds
drops below unity. When WT41 is waked and WT42 is unwaked, the ratio becomes larger than
one. It is possible to see the evidence of waking from various pairs of turbines in the row.
However, only neighboring turbines appear to have an impact on each other in these plots. Due
to the roughly cubic nature of the relationship between wind speed and power over the range of
wind speeds considered, plots of power ratio as a function of wind direction (Fig. 4b) show
larger peaks and valleys and also more scatter in the ratio, but overall, the power data confirm
the relationships among turbines shown by the wind speed data.
Atmospheric stability plays a large role in the scatter of the data points due to its impact on
background atmospheric turbulence (Fig. 5). When the background atmospheric temperature
profile is unstable (Fig. 5a), there is considerably larger scatter in the power ratio, making it
difficult to detect the wake impacts, even when the data are binned. The results are strongly
indicative of the role of atmospheric turbulence in bringing about the breakup of turbine wakes
during unstable conditions, when the production of atmospheric turbulence due to buoyancy
effects is rather pronounced. On the opposite end of the stability scale (Fig. 5b), wake impacts
are more pronounced, relative to the background scatter, when the atmospheric temperature
profile is very stable and background atmospheric turbulence is either suppressed or its length
scales reduced. In either case, the impact on turbine wakes is much less, and they persist farther
downstream.
Fig. 4. Ratio of WT42 to WT41 SCADA variables: (a) wind speed, and (b) active power. The
red lines denote averages of observations in 5-degree bins.
Fig. 5. Ratio of WT42:WT41 power as a function of atmospheric stability (see Table 1): (a) class
A/B, and (b) class F. The red lines denote averages of observations in 5-degree bins.
b. Sodar Data Sodar composite cross-sections can reveal the effects of multiple atmospheric processes on the
turbine wakes. One question about the wake measurements is whether or not rotational effects
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exist in the wake, and if so, whether they can be detected by sodar. The cross sections of vertical
velocity (Fig. 6) suggest that the sodars have measured rotation of the turbine wake during the
experiment. Positive vertical velocity is preferentially located to the left of the wake centerline,
and negative vertical velocity is oriented more to the right, with the zero isotach slanting
downward from left to right across the wake. Although this configuration may not be purely
rotational (in particular, positive vertical velocity tends to be found at low levels under the entire
wake), the sign of rotation matches that which would be expected for the blade rotation of the
SWT2.3-93 turbines.
An additional aspect of the wake is that it appears sheared and rather oval-shaped, with the long
axis of the oval oriented from the upper left to lower right. This effect is due to the wind shear
that is most often present during nocturnal or stable conditions, when the wakes are most
pronounced. During such conditions, the wind vectors point more to the left at very low altitudes
and more to the right above (when seen in the framework moving with the flow), due to the
balance of vertical turbulent momentum exchange (otherwise known as Reynolds stresses) and
the Coriolis and pressure gradient forces. This sort of a vertical profile is consistent with the
Ekman profile: if the horizontal component of the velocity vectors were plotted on a Cartesian
axis, a spiral shape would result.
Perhaps the most noticeable characteristic of the wake is the offset of minimum velocity deficits
to the left of the so-called centerline at Y/Rd=0. We hypothesize that the positive vertical
velocity may advect smaller wind speeds from lower altitudes. Alternatively, the effects of wind
shear may simply move the deficit, which can generally be expected to occur just above the hub
height, to the left. Note that the reference wind speed is taken from the 80 meter level.
The wake recovery as a function of distance can be estimated using all of the available data from
the two operating sodars in the farm. Figure 7 shows the wind speed ratios of the sodars as a
function of wind direction. In this case, zero degrees is oriented to the north. This plot, which
we refer to as a ―sodar rose‖, reveals distinct wakes whose impacts can be roughly quantified by
taking the minimum of velocity ratio along a 30-degree arc centered on the azimuth pointing to
the turbine causing the wake. Although there are more turbines in the row than are indicated in
the sodar rose, not all of them have a discrete wake impact. In those cases, the turbine may be
too far away for the sodar to consistently measure its wake, or the wake may be too close to the
wake of another turbine to be measured as a distinct wake. For example, WT39 appears to have
no impact on Triton169 because the sodar wind speed ratio is almost exactly unity in the
direction from Triton169 to WT39.
(a)
(b)
Fig. 6. Cross sections of waked:unwaked wind speed ratio (shading) and vertical velocity (black
lines—dashed lines are negative, contour interval of 0.05 m/s) for the following pairs of turbines:
(a) WT42 (waked) and WT41 (unwaked), and (b) WT40 (waked) and WT39 (unwaked). The
rotor diameter of each turbine responsible for a velocity deficit is shown with a solid gray line.
Taking into account all the wake information from the sodar rose, as well as the distances
between the sodars and the respective turbines, one can estimate the wake as a function of
distance (Fig. 8). In general, the curve that can be inferred is that of a negative exponential
function that asymptotically approaches unity.
Fig. 7. Wind speed ratios of the two sodars computed by averaging all observations in 5-degree
bins. The red line denotes the ratio Triton172:Triton169, and the black line denotes its inverse.
The radials indicate the direction towards turbines responsible for the measured wakes and are
colored according to the sodar that is measuring the wake (red for Triton 172; black for Triton
169).
Fig. 8. Wind speed ratio as a function of distance for the wakes indicated in Fig. 7, taken as the
minimum of the ratio in a 30-degree arc centered on each turbine direction. The black line
indicates the ratio for all observations, the red line indicates class A/B stabilities, and the blue
line indicates class F.
We made an attempt to categorize the wake recovery according to atmospheric stability, but the
results do not have the expected stratification. One would expect a slower wake recovery with
stronger stability, but either the atmospheric stability is not having such an effect on the wakes,
or the field experiment collected an insufficient number of samples to clearly see the
relationships that exist between atmospheric stability and turbine wake recovery. We believe the
latter of these two possibilities to be true. In either case, approximately 80 percent wake
recovery has occurred by 12 rotor diameters downstream, with speed ratios there increasing to
0.9 from a minimum of 0.5 at a distance of 3 rotor diameters downstream.
c. Cumulative Wake Impacts Finally, we examine the cumulative wake impacts of multiple turbines in a row. We oriented the
SCADA analyses for WT33 through WT38 so that the zero azimuth was pointed at WT32. As is
demonstrated in the analysis (Fig. 9), the accumulation of wakes causes the velocity deficit to
grow in width and depth proceeding down the row of turbines. We averaged the wind power
ratio (WTXX:WT32) over a 30-degree width centered on zero degrees for each of these turbines,
and the results are presented in Fig. 10. We have also separated the results into the various
atmospheric stability categories. In general, the wake accumulation is more severe for more
stable conditions, which favor the persistence of wakes. In unstable conditions, greater
atmospheric turbulence favors the rapid breakup of wakes. Nevertheless, significant wake
accumulation occurs in all of the stability categories.
a. Large Eddy Simulation Case Study We chose November 22, 2009 at 2200 to 2300 UTC as a case study because of near neutral
atmospheric stability, the atmospheric conditions were favorable for good sodar echoes, and the
wind direction was from the south, which brought the wake from WT41 over Triton169. The
LES setup procedure was as described in the previous section. The simulation was set up as a
neutral ABL case with a surface roughness of z0=0.3 m, a friction velocity of u*=0.63 m/s,
domain dimensions of Lx=2100 m (including buffer zone), Ly=1350 m, and Lz=300 m at a
resolution of Nx=360, Ny=288, and Nz=64. These dimensions produce grid cells that are
approximately 5 meters on a side, allowing for approximately 20 grid points over the diameter of
the wind turbine rotor.
A snapshot of LES output on the X-Y plane at approximately 80 meters above the surface (Fig.
11) shows the turbulent nature of the flow for this case. The turbine wakes are visible, but the
velocity deficits within them are not a lot larger than the velocity fluctuations due to the
background atmospheric turbulence. The largest wind speeds are found on the inlet (left) side
upstream from the turbines, and the smallest wind speeds are found in the wake of WT42, where
the combined wakes of WT41 and WT42 are present. An X-Z cross section taken along the
plane intersecting both WT41 and WT42 (Fig. 12a) shows a significant amount of velocity
fluctuation in the vertical direction as well. When time-averaging is applied to the flow (Fig.
12b), the wakes stand out more clearly.
Fig. 9. Ratio of the power output of the selected turbine to the power output of WT32 during all
occurrences of F class stability: (a) WT33, (b) WT34, (c) WT35, (d) WT36, (e) WT37, and (f)
WT38. The red lines denote the average of data points in five-degree bins.
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Fig. 10. Power ratio of waked:unwaked turbines as a function of the number of upwind turbines
in the WT32 to WT38 row for all observations in the dataset (solid gray line) and separated
according to stability category (dashed colored lines).
Fig. 11. X-Y cross section of the x-component of velocity for the LES of the November 22,
2009 case.
An idealized neutral simulation was also conducted with Lx=2400m (including buffer zone),
Ly=1200m, and Lz=300m at a resolution of Nx=128, Ny=128, and Nz=32 (each rotor plane
covers 10 grid points). The incoming flow was treated as neutrally stratified with z0=0.2m and
u*=0.65m/s. The time-averaged data on the X-Z plane intersecting WT41 and WT42 (Fig. 13)
show some interesting characteristics of the wakes. Fig. 13a shows the rotational component of
the flow in the turbine wakes to be on the order of 0.5 m/s. As in the case study, the largest
velocity deficit (Fig. 13b) is found downstream from WT42, where the wakes from WT41 and
WT42 combine. X-Z turbulence intensity cross sections from this simulation through the axis of
WT39 (Fig. 13c) confirm that the largest turbulence intensity in the wake is in the upper portion
where wind shear is the largest (see Fig. 13b). With combined wakes (Fig. 13d), the turbulence
intensity was larger in this simulation where wakes combined, creating larger shear at the top of
the combined wake than at the top of the single wake.
x [m]
y [m
]X-direction velocity contours in x-y plane
200 400 600 800 1000 1200 1400 1600
200
400
600
800
1000
1200
0
2
4
6
8
10
(a)
(b)
Fig. 12. X-Z cross sections of the x-component velocity field: (a) instantaneous values, and (b)
time-averaged over five minutes.
These simulations are preliminary, and much work remains to be done to determine whether the
turbulence intensity in the simulations matches that of the background flow. We will be
conducting a second phase of the field experiment with better methods for characterizing the
background atmospheric turbulence intensity. In addition we plan to incorporate larger domains,
particularly in the vertical direction in convective boundary layer conditions. Nocturnal
boundary layer simulations will likely utilize a shallower domain and finer resolution due to the
smaller length scales of turbulence in the nocturnal boundary layer flows. For convective
boundary layer flows, the turbulence length scales are much larger, so it may be a challenge to
simulate the atmospheric turbulence while still resolving turbine wakes.
Finally, we would like to present a data point of comparison between the simulation and the
measured turbine wake (Fig. 14) for the November 22, 2009 case. Overall, the profiles match
reasonably well, yet there is some disagreement between the LES wind speed on the measured
wind speed in the wake below hub height. The errors are mostly less than 1 m/s, which is
relatively small for a single profile of 10-minute average winds.
x [m]
z [m
]
X-direction velocity contours in x-z plane
200 400 600 800 1000 1200 1400 16000
100
200
300
2
4
6
8
10
12
x [m]
z [m
]
Averaged x-direction velocity contours in x-z plane
200 400 600 800 1000 1200 1400 16000
100
200
300
2
4
6
8
10
12
x [m]
z [m
]
<u'u'>1/2
contours in x-z plane
200 400 600 800 1000 1200 1400 16000
100
200
300
0.5
1
1.5
2
2.5
(a)
(b)
(c)
(d)
Fig. 13. Time-averaged (over one hour) contours along the indicated planes: (a) x-component
velocity u on the x-z plane through the axis of the 3rd
turbine; (b) y-component velocity v on the
x-z plane through the axis of the 3rd
turbine; (c) turbulence intensity (u)2 on the x-z plane
through the axis of the 1st turbine; and (d) turbulence intensity (u)
2 on the x-z plane through the
axis of the 3rd
turbine.
x
z
200 400 600 800 1000 1200 1400 1600 18000
100
200
300
-0.5
0
0.5
x
z
200 400 600 800 1000 1200 1400 1600 18000
100
200
300
4
6
8
10
12
x
z
200 400 600 800 1000 1200 1400 1600 18000
100
200
300
0.5
1
1.5
x
z
200 400 600 800 1000 1200 1400 1600 18000
100
200
300
0.5
1
1.5
50
100
150
200
4 5 6 7 8 9 10 11 12
Sodar 172 from field
Sodar 169 from field
Log-law fit (u*=0.63,z0=0.3)
Sodar 172 from LES
Sodar 169 from LES
U [m/s]
z [m
]
Fig. 14. Vertical wind speed profile comparison for the November 22, 2009 case. The unwaked
profile measured by sodar is indicated by the solid black squares, the LES counterpart is
indicated by the solid black line, and the logarithmic fit to the sodar data is shown with a thin,
dashed line. The sodar-measured waked profile is indicated with empty squares, and the LES
waked profile is the dot-dashed line.
4. Summary and Future Work The SCADA data show that wakes can be measured on land when the data are composited.
However, atmospheric turbulence plays a major role in determining how persistent and
detectable those wakes are. In unstable conditions, which are supportive of buoyancy-produced
turbulence, a deep convective boundary layer forms with large, organized structures on the order
of 1 km in size. This turbulence causes meandering and rapid destruction of wind turbine wakes.
In these conditions, the composited SCADA data show only a relatively subtle wake signature.
In stable conditions, turbulence is of a smaller length scale and relatively suppressed. Turbine
wakes in those conditions are much more persistent and are well-vidualized in the SCADA data.
Cross sections prepared from composite SODAR data, show the effects of multiple atmospheric
processes on the wakes. Some wake rotation is evident and matches the rotation that would be
expected from the rotation of the turbine blades. The oval shape of the wake reflects wind shear
that occurs during stable atmospheric conditions. Additionally, the greatest velocity deficit is
shifted up and to the left when viewed from a perspective looking upstream at the turbine
generating the wake. This displacement could be due either to the shear or to the upward
advection of slower velocity by the upward component of the turbine rotation. SODAR data also
have been used to demonstrate the recovery of wakes and show that by about 12 rotor diameters
downstream, at least 80 percent recovery has occurred.
The effect of accumulated wakes has been measured by SCADA data from a turbine row within
the farm. The accumulation of velocity deficit in the combined wakes is most significant during
the most stable atmospheric conditions. The wake accumulation is manifested in both the width
and the minimum of the velocity deficit within the wake.
LES of specific and idealized cases to date shows that the turbulent structure of the background
atmospheric flow tends to obscure the wakes. Time-averaging of this turbulent flow is necessary
to more clearly reveal the turbine wakes, which disperse relatively quickly in the turbulent flows
that have been simulated to date. The simulated wake profile from the November 22, 2009 case
shows a relatively close match with sodar data in the upper half of the profile, but the simulated
profile is slower than the measured profile in the lower portion of the wake.
A lot of simulation work remains to be done. In particular, a pre-simulation without wind
turbines is always needed to provide inflow conditions to the simulation with wind turbines. The
pre-simulation needs to be carefully checked to ensure that the time-averaged wind profiles
match the measured incoming flow, the turbulence is fully developed, and its statistics (intensity,
etc.) match the turbulence in the incoming flow. Only after these careful checks have been made
can the simulated wakes be meaningfully compared with the sodar-measured wakes. SCADA
and sodar measurements have provided strong evidence that the background atmospheric
turbulence plays a critical role in the downstream evolution of wind turbine wakes, and it is
critically important to get the atmospheric turbulence characteristics correct in order to perform
useful simulations of wind turbine wakes. Additionally, multiple simulations, encompassing a
variety of atmospheric conditions, need to be performed before the results can be interpreted in a
more general sense.
Acknowledgements This research was supported by the National Science Foundation (grant ATM-0854766), NASA (grant
NNG06GE256), customers of Xcel Energy through a grant (RD3-42) from the Renewable Development
Fund, and the University of Minnesota Institute for Renewable Energy and the Environment. Computing
resources were provided by the Minnesota Supercomputing Institute. The sodars were provided by
SecondWind, Inc., and Barr Engineering Company assisted with their deployment.
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