Numerical computations of wind turbine wakes

Ivanell, Stefan S. A.

January 2009

Numerical simulations of the Navier-Stokes equations are performed to achieve a better understanding of the behaviour of wakes generated by wind turbines. The simulations are performed by combining the in-house developed computer code EllipSys3D with the actuator line and disc methodologies. In the actuator line and disc methods the blades are represented by a line or a disc on which body forces representing the loading are introduced. The body forces are determined by computing local angles of attack and using tabulated aerofoil coefficients. The advantage of using the actuator disc technique is that it is not necessary to resolve blade boundary layers. Instead the computational resources are devoted to simulating the dynamics of the flow structures. In the present study both the actuator line and disc methods are used. Between approximately six to fourteen million mesh points are used to resolve the wake structure in a range from a single turbine wake to wake interaction in a farm containing 80 turbines. These 80 turbines are however represented by 20 actuator discs due to periodicity because of numerical limitations. In step one of this project the objective was to find a numerical method suitable to study both the flow structures in the wake behind a single wind turbine and to simulate complicated interaction between a number of turbines. The study resulted in an increased comprehension of basic flow features in the wake, but more importantly in the use of a numerical method very suitable for the upcoming purpose. The second objective of the project was to study the basic mechanisms controlling the length of the wake to obtain better understanding of the stability properties of wakes generated by wind turbine rotors. The numerical model was based on large eddy simulations of the Navier-Stokes equations using the actuator line method to generate the wake and the tip vortices. To determine critical frequencies the flow is disturbed by inserting a harmonic perturbation. The results showed that instability is dispersive and that growth occurs only for specific frequencies and mode types. The study also provides evidence of a relationship between the turbulence intensity and the length of the wake. The relationship however needs to be calibrated with measurements. In the last project objective, full wake interaction in large wind turbine farms was studied and verified to measurements. Large eddy simulations of the Navier-Stokes equations are performed to simulate the Horns Rev off-shore wind farm 15 km outside the Danish west coast. The aim is to achieve a better understanding of the wake interaction inside the farm. The simulations are performed by using the actuator disc methodology. Approximately 13.6 million mesh points are used to resolve the wake structure in the park containing 80 turbines. Since it is not possible to simulate all turbines, the 2 central columns of turbines have been simulated with periodic boundary conditions. This corresponds to an infinitely wide farm with 10 turbines in downstream direction. Simulations were performed within plus/minus 15 degrees of the turbine alignment. The infinitely wide farm approximation is thus reasonable. The results from the CFD simulations are evaluated and the downstream evolution of the velocity field is depicted. Special interest is given to what extent production is dependent on the inflow angle and turbulence level. The study shows that the applied method captures the main production variation within the wind farm. The result further demonstrates that levels of production correlate well with measurements. However, in some cases the variation of the measurement data is caused by the different measurement conditions during different inflow angles. / QC 20100720

Actuator Line Model

Actuator Disc Model

Wind Turbine Wake

CFD

LES

EllipSys3D

Fluid mechanics

Strömningsmekanik

Propulsion modelling of a generic submarine propeller

Boman, Gustav

January 2023

Self propulsion modelling is important in order to accurately simulate ships and submarinesusing Computational Fluid Dynamics (CFD). However, fully resolved simulations of hull andpropeller geometries are computationally heavy and time consuming. As such there is a greatinterest in lower order CFD models of propellers. This work investigates three lower ordermodels of a non-cavitating generic submarine propeller (INSEAN E1619) in OpenFOAM. Themodels investigated are Actuator Disk (AD). Rotor Disk (RD) and Actuator Line Model (ALM).The AD model applies a momentum change based on propeller performance coefficients overa disc cell set. The RD uses Blade Element Method (BEM) to calculate a more realistic thrustdistribution over the disk. Finally the ALM applies BEM over seven rotating lines within the cellset disc. The source code to the RD model was modified according to suggestions provided fromearlier studies on the model. The ALM used was originally designed for turbines which wasrectified by changing the force projection vectors in the source code to model propellers instead.There was not enough published data to directly utilize BEM on the E1619 propeller, thus thedata was generated by conducting 2D simulations on every element. The simulations were setup to replicate results provided in earlier works with higher order models in order to compareboth quantitative and qualitative results. It was found the ALM matched the reference databest out of the models tested in this work. The RD was qualitatively similar to the time averageof the ALM fields but numerically inaccurate. The AD results were poor, both quantitativelyand qualitatively.

OpenFOAM

CFD

actuator line model

rotor disk

actuator disk

INSEAN E1619

propeller

Engineering and Technology

Teknik och teknologier