Control system for aligning a nacelle of a wind turbine with a target yaw angle

The invention claimed is: 1. A control system for aligning a nacelle of a wind turbine with a target yaw angle, the control system comprising: a detection device configured for detecting at least one parameter indicative of wind forces acting on at least one component of the wind turbine for determining a current yaw angle of the nacelle, and an actuation device configured for manipulating a position of the nacelle until the current yaw angle is aligned with the target yaw angle, wherein the detection device further comprises at least one first bending moment sensor on a first component of the wind turbine, and at least one second bending moment sensor on a second component of the wind turbine, wherein the detection device is further configured for determining a bending moment of the first component of the wind turbine based on data received from the first bending moment sensor as the at least one parameter indicative of wind forces acting on the at least one component of the wind turbine, and a bending moment of the second component of the wind turbine based on data measured by the second bending moment sensor, and wherein the detection device is further configured for cross-checking the bending moment of the first component of the wind turbine with the bending moment of the second component of the wind turbine. 2. The control system of claim 1 , wherein the target yaw angle is a downwind orientation of the nacelle. 3. The control system of claim 2 , wherein the detection device comprises a sensor for detecting at least one of an electrical current and a temperature of at least one yaw motor of the nacelle, wherein the actuation device is further configured for yawing the nacelle until an increase in at least one of the electrical current and the temperature of the at least one yaw motor is detected by the sensor. 4. The control system of claim 2 , wherein the control system further comprises an initiating device configured for activating the detection device and the actuation device based on a parameter indicative of a reliable operation of the wind turbine exceeding a predefined threshold; and wherein the parameter indicative of the reliable operation of the wind turbine is at least one of a duration of a non-valid wind data condition, an estimated wind speed, and a turbine loading. 5. The control system of claim 1 , wherein the detection device comprises a memory unit which is configured for storing values for the at least one parameter, the values being assigned to respective yaw angles. 6. The control system of claim 1 , wherein the detection device comprises at least one strain gauge on at least one blade of the wind turbine, and wherein the detection device is further configured for determining a rotor-induced yaw load based on data received from the at least one strain gauge as the at least one parameter indicative of wind forces acting on the at least one blade. 7. The control system of claim 6 , wherein the actuation device is further configured for periodically yawing the nacelle in both yaw directions relative to a position of the nacelle at the current yaw angle; and wherein the detection device is further configured for comparing the at least one parameter indicative of wind forces acting on at least one component of the wind turbine at different nacelle positions, and for determining an extent of misalignment of the current yaw angle with respect to the target yaw angle. 8. The control system of claim 1 , wherein the detection device further comprises at least one strain gauge on at least one blade, at least one further strain gauge on a tower, and a rotor azimuth sensor, wherein the detection device is further configured for determining a tower bending moment and a root bending moment of the at least one blade over a blade azimuth range based on data received from the at least one strain gauge, the at least one further strain gauge and the rotor azimuth sensor as the at least one parameter indicative of wind forces acting on the at least one blade and the tower. 9. The control system of claim 8 , wherein the detection device further comprises at least one nacelle accelerometer and/or at least one tower accelerometer, and wherein the detection device is further configured for determining accelerometer-based turbine loads based on data received from the at least one nacelle accelerometer and/or the at least one tower accelerometer, and for cross-checking the tower bending moment with the accelerometer-based turbine loads. 10. The control system of claim 8 , wherein the actuation device is further configured for periodically yawing the nacelle in both yaw directions relative to a position of the nacelle at the current yaw angle; and wherein the detection device is further configured for comparing the at least one parameter indicative of wind forces acting on at least one component of the wind turbine at different nacelle positions, and for determining an extent of misalignment of the current yaw angle with respect to the target yaw angle. 11. The control system according to claim 1 , wherein the detection device is further configured for controlling that the current yaw angle is aligned with the target yaw angle by comparing the at least one parameter indicative of wind forces acting on at least one component of the wind turbine to a threshold indicative for the target yaw angle. 12. The control system of claim 11 , wherein the actuation device is further configured for periodically yawing the nacelle in both yaw directions relative to a position of the nacelle at the current yaw angle, and wherein the detection device is further configured for comparing the at least one parameter indicative of wind forces acting on at least one component of the wind turbine at different nacelle positions, and for determining an extent of misalignment of the current yaw angle with respect to the target yaw angle. 13. The control system of claim 1 , wherein the actuation device is further configured for periodically yawing the nacelle in both yaw directions relative to a position of the nacelle at the current yaw angle; and wherein the detection device is further configured for comparing the at least one parameter indicative of wind forces acting on at least one component of the wind turbine at different nacelle positions, and for determining an extent of misalignment of the current yaw angle with respect to the target yaw angle. 14. The control system of claim 13 , wherein the detection device is further configured for determining a yaw direction towards the target yaw angle based on the extent of misalignment of the current yaw angle with respect to the target yaw angle; and wherein the actuation device is further configured for manipulating the position of the nacelle in the yaw direction until the current yaw angle is aligned with the target yaw angle. 15. The control system of claim 14 , wherein the control system further comprises an initiating device configured for activating the detection device and the actuation device based on a parameter indicative of a reliable operation of the wind turbine exceeding a predefined threshold; and wherein the parameter indicative of the reliable operation of the wind turbine is at least one of a duration of a non-valid wind data condition, an estimated wind speed, and a turbine loading. 16. The control system of claim 1 , wherein cross-checking comprises verifying the bending moment of the first component of the wind turbine by the bending moment of the second component of the wind turbine.