Method for detecting different vibrations of a wind turbine

The invention claimed is: 1. A method comprising: operating a wind turbine, sensing at least one tower vibration of the wind turbine by a vibration sensor, sensing a mechanical generator vibration, caused by at least one electrical fault, by the vibration sensor, and controlling the operation of the wind turbine in dependence on the sensed tower vibration and the sensed generator vibration, wherein the sensor is an acceleration sensor configured to sense vibration in at least two directions. 2. The method as claimed in claim 1 , wherein the sensor is arranged on a stator of a generator of the wind turbine, a stator carrier of the wind turbine, a nacelle of the wind turbine, or a tower of the wind turbine. 3. The method as claimed in claim 1 , wherein sensing at least one tower vibration comprises sensing a longitudinal vibration signal and a transverse vibration signal, wherein the longitudinal vibration signal is sensed from a force acting in a longitudinal direction of a generator axis, wherein the transverse vibration signal is sensed from a force acting in a direction transverse to the longitudinal direction. 4. The method as claimed in claim 1 , separating at least one vibration signal sensed by the vibration sensor into a tower-vibration signal and a generator-vibration signal, wherein the separating is in dependence on frequency. 5. The method as claimed in claim 1 , wherein sensing the at least one tower vibration of the wind turbine comprises sensing a tower longitudinal vibration and a tower transverse vibration. 6. The method as claimed in claim 1 , wherein the controlling of the wind turbine is functionally divided into: a working-point control for controlling the wind turbine at a working point, and a protective control, which is hierarchically of a higher order than the working-point control, for checking protective functions of the wind turbine, wherein the protective control checks for disturbance criteria and, if a predetermined disturbance criterion is identified, take over the working-point control, and in dependence on the predetermined disturbance criterion that is sensed, moves to a safe working point, in particular reduces or stops a rotation of the rotor of the wind turbine. 7. The method as claimed in claim 6 , wherein the protective control has a main and a secondary control, wherein the main control executes the protective control, and the secondary control takes over at least a portion of the protective control if the main control fails. 8. The method as claimed in claim 1 , further comprising comparing the at least one tower vibration to a tower vibration limit value, wherein a disturbance is identified in response to the at least one sensed tower vibrations exceeding the predetermined tower-vibration limit value. 9. The method as claimed in claim 1 , comprising: monitoring a vibration characteristic of at least one vibration chosen from the tower longitudinal vibration, the tower transverse vibration and the generator vibration, comparing the vibration characteristic in each case to a first vibration tolerance band, when the respective vibration characteristics depart from the first vibration tolerance band, summing or integrating each vibration characteristic to form an exceedance sum, comparing the exceedance sum to a predetermined maximum sum, and if the exceedance sum attains or exceeds the predetermined maximum sum in a predetermined first check period, stopping the wind turbine due to a disturbance, or outputting a first vibration warning and a stopping of the wind turbine depends on a subsequent variation of the vibration characteristic. 10. The method as claimed in claim 9 , comprising obtaining the subsequent variation of the vibration characteristic, wherein obtaining the subsequent variation of the vibration characteristic comprises: in a first subsequent step, setting the exceedance sum to zero, and in a second subsequent step, summing or integrating each departure from the first vibration tolerance band to form the exceedance sum until a second vibration warning is output again, repeating the first and second subsequent steps, and counting the vibration warnings that occur during the first and second subsequent steps, and checking whether, in a predetermined second check period that is longer than the first check period, a number of vibration warnings has attained a predetermined warning number limit, and depending on this, the wind turbine is stopped due to a disturbance or continues to be operated, and checking whether the predetermined or a second warning number limit is attained, while the number of vibration warnings is in each case reduced by one counter following an expiration of a duration of a reduction interval, and depending on this, the wind turbine is stopped due to a disturbance or continues to be operated. 11. The method as claimed in claim 9 , wherein a disturbance is identified, and wherein the wind turbine is stopped if the vibration characteristic departs once from a second vibration tolerance band, wherein the second vibration tolerance band is broader than the first tolerance band. 12. The method as claimed in claim 3 , further comprising: comparing the longitudinal vibration signal to a predetermined tower longitudinal-vibration limit value, comparing the transverse vibration signal to a predetermined exceeds a predetermined tower transverse-vibration limit value, and identifying a disturbance in response to at least one signal, chosen among the longitudinal vibration signal and the transverse vibration signal, exceeding the predetermined tower longitudinal-vibration limit value or the predetermined tower transverse-vibration limit value, respectively. 13. The method as claimed in claim 4 , wherein separating in dependence on frequency comprises using a filter and wherein frequency components lying below a predefinable separation frequency are used as the tower-vibration signal and frequency components lying above the separation frequency are used as the generator-vibration signal. 14. A wind turbine, comprising: a generator having a generator axis for generating electrical power from wind, wherein the generator is configured to be driven by an aerodynamic rotor having one or more rotor blades, a nacelle, the generator coupled to the nacelle, a tower for supporting the nacelle, a vibration sensor for sensing a tower vibration, wherein the vibration sensor is configured to sense a mechanical generator vibration caused by at least one electrical fault, and a controller configured to control the wind turbine in dependence on the sensed tower vibration and the sensed generator vibration, wherein the vibration sensor is an acceleration sensor configured to sense acceleration in at least two directions. 15. The wind turbine as claimed in claim 14 , wherein the wind turbine is a gearless wind turbine. 16. The wind turbine as claimed in claim 14 , wherein the sensor is arranged on a stator of the generator, a generator carrier that supports the generator, or a front part of the nacelle.