Control of an induction generator of a wind turbine

The invention claimed is: 1. A method of controlling an induction generator connected to a utility grid, the method comprising: receiving an actual grid frequency; and controlling rotor windings of the generator by a rotor control signal having a rotor winding reference frequency (Ω_ref) being set in dependence of the actual grid frequency; wherein the rotor winding reference frequency (Ω_ref) is set such that a slip (s) adheres to a predefined value and substantially does not change with changing actual grid frequency (f) at least in a predefined frequency range of the actual grid frequency, wherein the slip (s) is given by: s =(Ω( f )− ns ( f ))/ ns ( f ), wherein: f is the actual grid frequency, Ω is the actual speed of generator at the actual grid frequency f, ns(f) is a synchronous speed at the actual grid frequency f, wherein ns in rpm is given by ns=60*f/p, wherein p is the number of pole pairs of the generator rotor and f is given in Hz. 2. The method according to claim 1 , wherein the utility grid is configured to be operated with a nominal grid frequency, wherein the rotor winding reference frequency is set in dependence of a deviation between the actual grid frequency and the nominal grid frequency. 3. The method according to claim 1 , wherein the predefined frequency range is between 0.90 and 1.1, or between 0.97 and 1.03 times the nominal grid frequency, wherein for a nominal grid frequency of 50 Hz the predefined frequency range is between 45 Hz and 55 Hz, in particular between 47 Hz and 53 Hz, or between 48 Hz and 52 Hz. 4. The method according to claim 1 , wherein the rotor winding reference frequency (Ω_ref) is set such that: a rotor power (Protor) output by the rotor windings adheres to a predefined relative rotor power; and/or stator power output (Pstator) by stator windings adheres to a predefined relative stator power and the rotor power and/or stator power does not change with changing actual grid frequency, at least in the predefined frequency range. 5. The method according to claim 1 , wherein the stator windings are dimensioned according to the predefined relative stator power such that they are required to be operated with a load not higher than 1%, in or 0.1%, above the predefined relative stator power. 6. The method according to claim 1 , wherein a converter is connected to the rotor windings for supplying the rotor control signal, wherein the converter in particular comprises a AC-DC converter portion, a DC-link, and a DC-AC converter portion, wherein output terminals of the converter are connected to output terminals of the stator windings. 7. The method according to claim 1 , wherein the rotor windings and/or a converter connected to the rotor windings are dimensioned according to the predefined relative rotor power such that they are required to be operated with a load not higher than 1%, or 0.1%, above the predefined relative rotor power. 8. The method according to claim 1 , wherein the rotor winding reference frequency (Ω_ref) is set as follows: Ω_ref( f )=Ω( f 0)*(1+( f−f 0)/ f 0), wherein f is the actual grid frequency, f0 is the nominal grid frequency, Ω(f) is the rotor winding reference frequency at the actual grid frequency, Ω(f0) is the rotor winding reference frequency at the nominal grid frequency, Ω(f0)=f0*s, s is the slip. 9. The method according to claim 1 , wherein the actual grid frequency is determined as averaging and/or filtering an instantaneous grid frequency over a predetermined time range, or spanning between 1 min and 10 min. 10. The method according to claim 1 , wherein the actual grid frequency deviates from the nominal frequency (f0) by less than 5%, or less than 3%, and/or wherein the induction generator includes a, in particular three-phase, doubly-fed induction generator and/or a squirrel cage type generator. 11. The method according to claim 1 , wherein the induction generator is driven by a rotating shaft of a wind turbine, in or coupled via a gear box to a main shaft at which plural rotor blades are connected. 12. An arrangement for controlling an induction generator connected to a utility grid, the arrangement comprising: an input port configured to receive an actual grid frequency; and a controller configured to control rotor windings of the generator by a rotor control signal having a rotor winding reference frequency (Ω_ref) being set in dependence of the actual grid frequency; wherein the rotor winding reference frequency (Ω_ref) is set such that a slip (s) adheres to a predefined value and substantially does not change with changing actual grid frequency (f) at least in a predefined frequency range of the actual grid frequency, wherein the slip (s) is given by: s =(Ω( f )− ns ( f ))/ ns ( f ), wherein: f is the actual grid frequency, Ω is the actual speed of generator at the actual grid frequency f, ns(f) is a synchronous speed at the actual grid frequency f, wherein ns in rpm is given by ns=60*f/p, wherein p is the number of pole pairs of the generator rotor and f is given in Hz. 13. A wind turbine, including: an induction generator driven by wind energy, the generator having rotor windings; and an arrangement according to claim 12 .