A Numerical Study of Forest Influences on the Atmospheric Boundary Layer and Wind Turbines

Oxana Agafonova A Numerical Study of Forest Influences on the Atmospheric Boundary Layer and Wind Turbines Lappeenranta 2017 144 pages Acta Universitatis Lappeenrantaensis 757 Diss. Lappeenranta University of Technology ISBN 978-952-335-110-3, ISBN 978-952-335-111-0 (PDF), ISSN-L 1456-4491, ISSN 1456-4491 In the past years, energy consumption in Finland was not fully covered by the energy produced in Finland, and approximately 20% of the total energy consumption was imported. Despite the suitable wind condition, the wind energy production in Finland is very small only 2.8% of the total demand. Massive land area (about 72%) in Finland is covered with forest. Therefore, there is a high chance that wind turbines will be installed in forests. It is known that wind behaviour in forests is rather complicated. Therefore, before the arrangement of a wind farm in and above the forest, the investing company has to study the forest influences on the windturbine wakes, fatigue and power production. In the present thesis, Large-Eddy Simulations are carried out using OpenFOAM to investigate the forest-canopy effects on the atmospheric boundary layer and wind turbines. The effects were studied in small (two-turbine) as well as large wind-turbine arrays. For every case, simulations are performed separately for two identical setups, with and without forest. The results of the simulations in the forest case are further compared to the results of the corresponding non-forest case to clearly show the changes in the wake and turbulence structure due to the forest. Moreover, the actual mechanical shaft power produced by each turbine in the small wind-turbine array and by a single turbine in the large array is calculated for the forest and non-forest cases. Aerodynamic efficiency and power losses due to forest are discussed as well. It is found that the loss of actual power due to forest amounts to nearly 20%. The blade angle of attack is studied for cases with and without forest. It is found that a non-optimal angle of attack in the forest case is responsible for the power loss. Therefore, an active pitch control is proposed in order to reduce the loss of actual power in the forest.

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