Method for controlling a wind turbine

The invention claimed is: 1. A method for controlling a wind turbine for feeding electrical power into an electrical supply grid, wherein the wind turbine comprises: a tower having a nacelle arranged rotatably thereon; an aerodynamic rotor operable to be driven by wind; a generator coupled to the aerodynamic rotor and configured to generate the electrical power from the wind; an active rectifier configured to control the generator and one or more of: the electrical power output by the generator or a generator torque; and an inverter configured to feed the electrical power output by the generator or a portion of the electrical power output by the generator into the electrical supply grid, and wherein the method comprises: controlling the wind turbine, in normal operation, to feed an electrical feed-in power into the electrical supply grid depending on the wind; and changing the electrical feed-in power depending on one or more of a grid state or a grid demand of the electrical supply grid, wherein the changing of the electrical feed-in power is controlled such that a specifiable mechanical loading limit of the wind turbine is maintained, wherein the changing of the electrical feed-in power is controlled such that: following the generator torque exceeding a torque limit value having a predetermined amount, a further generator torque exceeding the torque limit value is suppressed for a predetermined recovery time period or is limited to the torque limit value, and/or in response to a decaying oscillation of the generator torque with a maximum amplitude that exceeds a predetermined amplitude limit value, a further generator torque pulse with at least half an amplitude of the predetermined amplitude limit value is avoided until at least one of: the decaying oscillation has decayed to an amplitude less than a predetermined amplitude decay value, or a predetermined decay has elapsed. 2. The method as claimed in claim 1 , comprising: setting at least one limit gradient for the changing of the electrical feed-in power, wherein the limit gradient represents a maximum amount or a maximum change over time of the electrical power generated by the generator, or the limit gradient represents a maximum amount or a maximum change over time of the generator torque to be controlled. 3. The method as claimed in claim 1 , wherein: the generator torque is controlled based on a setpoint torque value, the setpoint torque value is output by a filter, the setpoint torque value is set to reduce oscillation of the generator or avoid initiating the oscillation of the generator, and the filter is a lowpass filter or a delay element. 4. The method as claimed in claim 1 , wherein: a generator control circuit includes the generator and the inverter, eigenvalues and/or poles are specified for the generator control circuit, and the eigenvalues and/or poles are specified such that the specifiable mechanical loading limit of the wind turbine is maintained. 5. The method as claimed in claim 4 , wherein the generator control circuit includes mechanical elements or uses mechanical properties selected from a list including: the aerodynamic rotor, a moment of inertia of the aerodynamic rotor or at least one blade eigenfrequency of the aerodynamic rotor, and the tower and the nacelle or at least one eigenfrequency of an oscillation of the tower and the nacelle. 6. The method as claimed in claim 5 , wherein the generator control circuit uses a property or a behavior of the electrical supply grid. 7. The method as claimed in claim 6 , wherein the property of the electrical supply grid is an eigenfrequency or the behavior of the electrical supply grid is an oscillation of the electrical supply grid. 8. The method as claimed in claim 5 , wherein the generator control circuit uses a mechanical model of the wind turbine for the changing of the electrical feed-in power to cause the specifiable mechanical loading limit of the wind turbine to be maintained. 9. The method as claimed in claim 1 , wherein: an oscillation detector is provided for detecting at least one oscillation of the wind turbine, wherein the at least one oscillation is a mechanical oscillation and/or an oscillation of the generator, and the at least one oscillation is used for the changing of the electrical feed-in power such that the specifiable mechanical loading limit of the wind turbine is maintained. 10. The method as claimed in claim 1 , wherein: a filter controls the generator using a setpoint torque value, wherein the filter limits a control signal to a predetermined limit amplitude in a specified frequency range. 11. The method as claimed in claim 10 , wherein the control signal is a setpoint torque value and the predetermined limit amplitude varies depending on a frequency. 12. The method as claimed in claim 1 , wherein: the generator is a synchronous generator, and the wind turbine includes a rectifier and a stepup converter or the wind turbine includes a controlled rectifier, and the stepup converter or the controlled rectifier are used for controlling the generator. 13. The method as claimed in claim 12 , wherein the synchronous generator is a separately excited synchronous generator and the wind turbine includes an exciter generator for controlling an exciter current of the synchronous generator. 14. The method as claimed in claim 1 , wherein the specifiable mechanical loading limit is a momentary mechanical loading limit. 15. The method as claimed in claim 3 , wherein the filter is a linear delay element of a first order or a second order. 16. The method as claimed in claim 1 , wherein the predetermined amplitude decay value is less than 25% of the predetermined amplitude limit value or the predetermined decay is between 5 and 30 seconds. 17. A wind turbine for feeding electrical power into an electrical supply grid, comprising: a tower having a nacelle arranged rotatably thereon; an aerodynamic rotor operable to be driven by wind; a generator coupled to the aerodynamic rotor and configured to generate the electrical power from the wind; an active rectifier configured to control the generator and one or more of: the electrical power output by the generator or a generator torque; an inverter configured to feed the electrical power output by the generator or a portion of the electrical power output by the generator into the electrical supply grid; and a controller configured to: control the wind turbine, in normal operation, to feed an electrical feed-in power into the electrical supply grid depending on the wind; and change the electrical feed-in power depending on one or more of a grid state or a grid demand of the electrical supply grid, wherein the changing of the electrical feed-in power is controlled such that a specifiable mechanical loading limit of the wind turbine is maintained, wherein the changing of the electrical feed-in power is controlled such that: following the generator torque exceeding a torque limit value having a predetermined amount, a further generator torque exceeding the torque limit value is suppressed for a predetermined recovery time period or is limited to the torque limit value, and/or in response to a decaying oscillation of the generator torque with a maximum amplitude that exceeds a predetermined amplitude limit value, a further generator torque pulse with at least half an amplitude of the predetermined amplitude limit value is avoided until at least one of: the decaying oscillation has decayed to an amplitude less than a predetermined amplitude decay