Evaluation of the wind farm parameterization in the Weather Research and Forecasting model (version 3.8.1) with meteorological and turbine power data

Lee, Joseph C. Y.; Lundquist, Julie K.

doi:10.5194/gmd-10-4229-2017

Cited by 62 publications

(51 citation statements)

References 61 publications

(69 reference statements)

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“…During this period, a lack of major synoptic events allowed strong nightly nocturnal low-level jets to occur (Vanderwende et al, 2015). Lee and Lundquist (2017a) found that WRF performed well in capturing the timing, intensity, and position of these low-level jets. Furthermore, the wind turbines operated without curtailment, and the instruments were online collecting data, making this period ideal for a model sensitivity and performance evaluation.…”

Section: Specific Examples Includementioning

confidence: 91%

“…Past studies have begun evaluating this sensitivity in the WRF WFP. Lee and Lundquist (2017a) note that a ∼12-m vertical resolution is necessary to reproduce observed power production, while Mangara et al (2019) find that the wake dynamics simulated by the WFP are more sensitive to horizontal resolution than vertical resolution. Xia et al (2019) find differences in the WFP solution of surface temperature changes depending on the inclusion of the turbine-generated TKE term.…”

Section: Specific Examples Includementioning

confidence: 99%

“…Here we expand upon and synthesize the work of Lee and Lundquist (2017a) generally flat terrain and a vegetated surface of corn and soybeans and featured an operating wind farm northeast of the city of Ames, Iowa. In the 2013 CWEX campaign, seven surface flux stations, a radiometer, three profiling lidars, and a scanning lidar were deployed within and around this wind farm to explore the interaction of multiple wakes in a range of atmospheric stability conditions (Vanderwende et al, 2015;Bodini et al, 2017;Sanchez Gomez and Lundquist, 2019).…”

Section: Specific Examples Includementioning

confidence: 99%

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Simulated wind farm wake sensitivity to configuration choices in the Weather Research and Forecasting model version 3.8.1

Tomaszewski¹,

Lundquist²

2019

Preprint

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Abstract. Wakes from wind farms can extend over 50 km downwind in stably stratified conditions. These wakes can undermine power production at downwind turbines, adversely undermining revenue. As such, wind farm wake impacts must be considered in wind resource assessments, especially in regions of dense wind farm development. The open-source Weather Research and Forecasting (WRF) numerical weather prediction model includes a wind farm parameterization to estimate wind farm wake effects, but model configuration choices can influence the resulting predictions of wind farm wakes. These choices include vertical resolution, horizontal resolution, and whether or not to include the addition of turbulent kinetic energy generated by the spinning wind turbines. Despite the sensitivity to model configuration, no clear guidance currently exists for these options. Here we compare simulated wind farm wakes produced by varying model configurations with observations from in situ meteorological observations near an onshore wind farm in flat terrain over several diurnal cycles. A WRF configuration comprised of horizontal resolutions of 3 km or 1 km paired with a vertical resolution of 10 m provides the most accurate representation of wind farm wake effects, such as the correct surface warming and elevated wind speed deficit. The inclusion of turbine-generated turbulence is also critical to produce accurate surface warming and should not be omitted.

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Section: Specific Examples Includementioning

confidence: 91%

Section: Specific Examples Includementioning

confidence: 99%

Section: Specific Examples Includementioning

confidence: 99%

See 1 more Smart Citation

Simulated wind farm wake sensitivity to configuration choices in the Weather Research and Forecasting model version 3.8.1

Tomaszewski¹,

Lundquist²

2019

Preprint

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“…We use the wind farm parameterization (WFP) of Fitch et al (2012) to simulate the interaction between atmosphere and wind farms. The WFP extracts kinetic energy from the mean flow and acts as a source of turbulence, depending on the thrust and power coefficients of the installed turbines in the model (Fitch et al 2012, Jiménez et al 2015, Lee and Lundquist 2017. Therefore, the WFP interacts with the planetary boundary layer scheme of Nakanishi and Niino (2004) that we use in all three domains.…”

Section: Numerical Simulationsmentioning

confidence: 99%

Micrometeorological impacts of offshore wind farms as seen in observations and simulations

Siedersleben

Lundquist

Platis

et al. 2018

Environ. Res. Lett.

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106

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In Europe, offshore wind farms have a capacity of 16 GW, with 71% installed at the North Sea. These wind farms represent an additional source of turbulence and may influence the stratification of the marine boundary layer. We present aircraft measurements and simulations showing an impact on temperature and humidity at hub height in the order of 0.5 K and 0.5gkg −1 even 60 km downwind of a wind farm cluster. We extend these simulations to explore a realistic future scenario, suggesting wakes in potential temperature and water vapor propagating more than 100 km downwind. Such impacts of wind farms are only observed in case of a strong stable stratification at rotor height, allowing wind farms to mix warmer air downward.

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“…The vertical direction is discretized with 100 grid cells in all the domains. The grid points are clustered near the surface and in the rotor region where the resolution is between 7 and 12 m. Lee et al 21 showed that a resolution of 12 m near the surface is sufficient to obtain good agreement with the observed wind speed, wind direction, and power production. The turbines are modeled as a momentum sink (drag) and turbulent kinetic energy source as in Fitch et al 2 The drag generated by the turbine in a grid cell is given by…”

Section: Experimental Measurementsmentioning

confidence: 99%

One‐way mesoscale‐microscale coupling for simulating a wind farm in North Texas: Assessment against SCADA and LiDAR data

et al. 2020

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One-way nested mesoscale to microscale simulations of an onshore wind farm have been performed nesting the Weather Research and Forecasting (WRF) model and our in-house high-resolution large-eddy simulation code (UTD-WF). Each simulation contains five nested WRF domains, with the largest domain spanning the North Texas Panhandle region with a 4 km resolution, while the highest resolution (50 m) nest simulates microscale wind fluctuations and turbine wakes within a single wind farm. The finest WRF domain in turn drives the UTD-WF LES higher-resolution domain for a subset of six turbines at a resolution of ∼ 5 m. The wind speed, direction, and boundary layer profiles from WRF are compared against measurements obtained with a met-tower and a scanning Doppler wind LiDAR located within the wind farm. Additionally, power production obtained from WRF and UTD-WF are assessed against supervisory control and data acquisition (SCADA) system data. Numerical results agree well with the experimental measurements of the wind speed, direction, and power production of the turbines. UTD-WF high-resolution domain improves significantly the agreement of the turbulence intensity at the turbines location compared with that of WRF. Velocity spectra have been computed to assess how the nesting allows resolving a wide range of scales at a reasonable computational cost. A domain sensitivity analysis has been performed. Velocity spectra indicate that placing the inlet too close to the first row of turbines results in an unrealistic peak of energy at the rotational frequency of the turbines. Spectra of the power production of a single turbine and of the cumulative power of the array have been compared with analytical models.

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Evaluation of the wind farm parameterization in the Weather Research and Forecasting model (version 3.8.1) with meteorological and turbine power data

Cited by 62 publications

References 61 publications

Simulated wind farm wake sensitivity to configuration choices in the Weather Research and Forecasting model version 3.8.1

Simulated wind farm wake sensitivity to configuration choices in the Weather Research and Forecasting model version 3.8.1

Micrometeorological impacts of offshore wind farms as seen in observations and simulations

One‐way mesoscale‐microscale coupling for simulating a wind farm in North Texas: Assessment against SCADA and LiDAR data

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