skip to main content
OSTI.GOV title logo U.S. Department of Energy
Office of Scientific and Technical Information

Title: Does the rotational direction of a wind turbine impact the wake in a stably stratified atmospheric boundary layer?

Journal Article · · Wind Energy Science (Online)
 [1]; ORCiD logo [1]; ORCiD logo [2]
  1. German Aerospace Center, Oberpfaffenhofen (Germany). Inst. of Atmospheric Physics
  2. National Renewable Energy Lab. (NREL), Golden, CO (United States); Univ. of Colorado, Boulder, CO (United States)
+ Show Author Affiliations

Stably stratified atmospheric boundary layers are often characterized by a veering wind profile, in which the wind direction changes clockwise with height in the Northern Hemisphere. Wind-turbine wakes respond to this veer in the incoming wind by stretching from a circular shape into an ellipsoid. We investigate the relationship between this stretching and the direction of the turbine rotation by means of large-eddy simulations. Clockwise rotating, counterclockwise rotating, and non-rotating actuator disc turbines are embedded in wind fields of a precursor simulation with no wind veer and in wind fields with a Northern Hemispheric Ekman spiral, resulting in six combinations of rotor rotation and inflow wind condition. The wake strength, extension, width, and deflection depend on the interaction of the meridional component of Ekman spiral with the rotational direction of the actuator disc, whereas the direction of the disc rotation only marginally modifies the wake if no veer is present. The differences result from the amplification or weakening/reversion of the spanwise and the vertical wind components due to the effect of the superposed disc rotation. They are also present in the streamwise wind component of the wake and in the total turbulence intensity. In the case of an counterclockwise rotating actuator disc, the spanwise and vertical wind components increase directly behind the rotor, resulting in the same rotational direction in the whole wake while its strength decreases downwind. In the case of a clockwise rotating actuator disc, however, the spanwise and vertical wind components of the near wake are weakened or even reversed in comparison to the inflow. This weakening/reversion results in a downwind increase in the strength of the flow rotation in the wake or even a different rotational direction in the near wake in comparison to the far wake. The physical mechanism responsible for this difference can be explained by a simple linear superposition of a veering inflow with a Rankine vortex.

Research Organization:
National Renewable Energy Laboratory (NREL), Golden, CO (United States)
Sponsoring Organization:
USDOE Office of Energy Efficiency and Renewable Energy (EERE), Wind Energy Technologies Office (EE-4W)
Grant/Contract Number:
AC36-08GO28308
OSTI ID:
1726055
Report Number(s):
NREL-JA-5000-78465; MainId:32382; UUID:abcca0c7-590e-4cde-970c-5b951612759e; MainAdminID:18879
Journal Information:
Wind Energy Science (Online), Vol. 5, Issue 4; ISSN 2366-7451
Publisher:
European Wind Energy Association - CopernicusCopyright Statement
Country of Publication:
United States
Language:
English

References (41)

Field Measurements of Wind Turbine Wakes with Lidars journal February 2013
Large eddy simulation of wind turbine wake dynamics in the stable boundary layer using the Weather Research and Forecasting Model journal May 2014
Near-wake flow structure downwind of a wind turbine in a turbulent boundary layer journal December 2011
Coherent structure of the convective boundary layer derived from large-eddy simulations journal March 1989
Implications of Stably Stratified Atmospheric Boundary Layer Turbulence on the Near-Wake Structure of Wind Turbines journal September 2014
MPDATA: A Finite-Difference Solver for Geophysical Flows journal March 1998
Analysis of Counter-Rotating Wind Turbines journal June 2007
Numerical investigation of wind turbine wake development in directionally sheared inflow: Numerical investigation of wind turbine wake development in directionally sheared inflow journal July 2016
Impact of Neutral Boundary-Layer Turbulence on Wind-Turbine Wakes: A Numerical Modelling Study journal October 2016
The effect of atmospheric stability on wind-turbine wakes: A large-eddy simulation study journal June 2014
Large-eddy simulations of convective boundary layers using nonoscillatory differencing journal September 1999
Turbulence and the Isolated Wind Turbine conference June 2012
The Effect of Wind-Turbine Wakes on Summertime US Midwest Atmospheric Wind Profiles as Observed with Ground-Based Doppler Lidar journal July 2013
A Simulation of the Wangara Atmospheric Boundary Layer Data journal December 1975
Influence of the Coriolis force on the structure and evolution of wind turbine wakes journal October 2016
The impact of stable atmospheric boundary layers on wind-turbine wakes within offshore wind farms journal September 2015
Three-dimensional structure of wind turbine wakes as measured by scanning lidar journal January 2017
The Effects of Wind Veer During the Morning and Evening Transitions journal January 2020
The effect of wind direction shear on turbine performance in a wind farm in central Iowa journal January 2020
An experimental study on the effects of relative rotation direction on the wake interferences among tandem wind turbines journal March 2014
Modelling atmospheric flows with adaptive moving meshes journal April 2012
On the Effects of Wind Turbine Wake Skew Caused by Wind Veer conference January 2018
An Introduction to Boundary Layer Meteorology book January 1988
Numerical flow computation around aeroelastic 3D square cylinder using inflow turbulence journal April 2002
Impact of the Diurnal Cycle of the Atmospheric Boundary Layer on Wind-Turbine Wakes: A Numerical Modelling Study journal October 2017
The effect of rotational direction on the wake of a wind turbine rotor – a comparison study of aligned co- and counter rotating turbine arrays journal October 2017
An Experimental Investigation on the Effects of Turbine Rotation Directions on the Wake Interference of Wind Turbines conference January 2013
Towards mesh adaptivity for geophysical turbulence: continuous mapping approach journal January 2005
Extending Gal-Chen and Somerville terrain-following coordinate transformation on time-dependent curvilinear boundaries journal January 2004
U.S. East Coast Lidar Measurements Show Offshore Wind Turbines Will Encounter Very Low Atmospheric Turbulence journal May 2019
Initial results from a field campaign of wake steering applied at a commercial wind farm – Part 1 journal January 2019
Wake flow in a wind farm during a diurnal cycle journal December 2015
An Introduction to Dynamic Meteorology journal May 1973
Offshore Wind Turbines Will Encounter Very Low Atmospheric Turbulence journal January 2020
EULAG, a computational model for multiscale flows journal October 2008
Wind turbine wake aerodynamics journal August 2003
Observing and Simulating Wind-Turbine Wakes During the Evening Transition journal May 2017
Speed and Direction Shear in the Stable Nocturnal Boundary Layer journal January 2009
The effects of mean atmospheric forcings of the stable atmospheric boundary layer on wind turbine wake journal January 2015
Implementation of a generalized actuator disk wind turbine model into the weather research and forecasting model for large-eddy simulation applications journal January 2014
Building resolving large-eddy simulations and comparison with wind tunnel experiments journal November 2007

Cited By (2)

Estimation of turbulence dissipation rate from Doppler wind lidars and in situ instrumentation for the Perdigão 2017 campaign journal January 2019
The effect of wind direction shear on turbine performance in a wind farm in central Iowa journal January 2020

Similar Records

Related Subjects

17 WIND ENERGY
wind energy
wake
atmospheric boundary layer
wind turbine