Control system and method for operating a plurality of wind turbines

The invention claimed is: 1. A method for operating a first wind turbine ( 14 ) and a second wind turbine ( 15 ), the second wind turbine ( 15 ) being located downwind of the first wind turbine ( 14 ), said method comprising: providing a current wind value of the first wind turbine ( 14 ) to a prediction model ( 28 ), said current wind value comprising a current wind speed value or a current wind direction value; in said prediction model ( 28 ), using the current wind value of the first wind turbine ( 14 ) to predict a future time point ( 25 ) at which an area swept by a rotor of the second wind turbine ( 15 ) overlaps a wake ( 30 ) of the first wind turbine ( 14 ); in response to said prediction, generating a control signal to alter a pitch angle of a rotor blade of the second wind turbine ( 15 ) relative to the pitch angle of another rotor blade of the second wind turbine ( 15 ) before the future time point ( 25 ); and beginning to adapt the pitch angle of the rotor blades of the second wind turbine ( 15 ) to the control signal before the future time point. 2. The method of claim 1 , wherein the prediction model ( 28 ) comprises an assumption that the wake ( 30 ) widens in a radial direction as a distance from the first wind turbine ( 14 ) increases. 3. The method of claim 1 , wherein the prediction model ( 28 ) comprises an assumption that a wind speed in the wake ( 30 ) is reduced in comparison with a wind field that is not disturbed by the first wind turbine ( 14 ). 4. The method of claim 1 , wherein the prediction model ( 28 ) comprises an assumption that the wind speed in the wake ( 30 ) has a radial distribution according to which a wind speed in the center of the wake ( 30 ) is less than in the periphery of the wake ( 30 ). 5. The method of claim 1 , wherein the prediction model ( 28 ) comprises an assumption that the turbulence intensity in the wake ( 30 ) is increased in comparison with a wind field that is not disturbed by the first wind turbine ( 14 ). 6. The method of claim 1 , comprising determining an estimated wind value on the basis of an air mass-flow acting upon the entire rotor of the first wind turbine ( 14 ); and using the estimated wind value as the current wind value of the first wind turbine ( 14 ). 7. The method of claim 1 , wherein the current wind value of the first wind turbine ( 14 ) and a current wind value the second wind turbine ( 15 ) are used to predict a propagation direction of the wake ( 30 ). 8. The method of claim 1 , wherein the prediction model maps a wind prediction into a geographical coordinate system. 9. The method of claim 8 , wherein a location of the first wind turbine ( 14 ) and the location of the second wind turbine ( 15 ) are defined by coordinates within the geographical coordinate system. 10. The method of claim 1 , wherein the current wind value comprises a value for turbulence intensity derived from a standard deviation of a current output power of the first wind turbine ( 14 ). 11. The method of claim 1 , wherein the prediction model ( 28 ) determines a time span within which a change in wind direction propagates from the first wind turbine ( 14 ) to the second wind turbine ( 15 ) as the sum of a time lag, which is derived from the current wind speed value and a wake-related additional time. 12. The method of claim 1 , comprising: equipping the second wind turbine ( 15 ) with load sensors to determine an actual wind load acting on the second wind turbine ( 15 ). 13. The method of claim 1 , comprising: determining a sequence of current wind values at different time points for the first wind turbine ( 14 ) or the second wind turbine ( 15 ); and storing the sequence of current wind values for the first wind turbine ( 14 ) or the second wind turbine ( 15 ). 14. The method of claim 1 , wherein the pitch angle of the rotor blades of the second wind turbine ( 15 ) is adapted to the control signal before the future time point. 15. A control system for wind turbines, said control system comprising: an acquisition means for recording a current wind value of a first wind turbine ( 14 ), a prediction model ( 28 ) that processes the current wind value to predict a future time point ( 25 ) at which a second wind turbine ( 15 ), located in a wake ( 30 ) of the first wind turbine ( 14 ), is overlapped by the wake ( 30 ) of the first wind turbine ( 14 ), wherein, in response to said prediction, the control system generates a control signal to alter a pitch angle of a rotor blade of the second wind turbine ( 15 ) relative to a pitch angle of another rotor blade of the second wind turbine ( 15 ) before the future time point ( 25 ) and begins to adapt the pitch angle of the rotor blades of the second wind turbine ( 15 ) to the control signal before the future time point. 16. The control system of claim 15 , wherein the pitch angle of the rotor blades of the second wind turbine ( 15 ) is adapted before the future time point ( 25 ). 17. The control system of claim 16 , wherein the pitch angle of the rotor blades of the second wind turbine according to the control signal varies depending upon the angular position of each rotor blade. 18. A method for operating a first wind turbine ( 14 ) and a second wind turbine ( 15 ), the second wind turbine ( 15 ) being located downwind of the first wind turbine ( 14 ), said method comprising: when a current wind speed at said first turbine ( 14 ) is above a nominal speed or the second wind turbine ( 15 ) is presently being operated at a nominal output; providing a current wind value of the first wind turbine ( 14 ) to a prediction model ( 28 ), said current wind value comprising a current wind speed value or a current wind direction value; in said prediction model ( 28 ), using the current wind value of the first wind turbine ( 14 ) to predict a future time point ( 25 ) at which an area swept by a rotor of the second wind turbine ( 15 ) overlaps a wake ( 30 ) of the first wind turbine ( 14 ); and in response to said prediction, generating a control signal to alter a pitch angle of a rotor blade of the second wind turbine ( 15 ) relative to the pitch angle of another rotor blade of the second wind turbine ( 15 ).