Method for attenuating low-frequency oscillations in an electrical power supply grid

The invention claimed is: 1. A method comprising: attenuating low-frequency oscillations in an electrical power supply grid by a feed device which feeds into the electrical power supply grid, wherein the electrical power supply grid has a grid voltage and a grid frequency, wherein the low-frequency oscillations are less than 5 hertz, the attenuating comprising: detecting a grid signal having the low-frequency oscillations, splitting a total frequency range of the grid signal in which oscillations to be attenuated are to be expected into a plurality of partial frequency ranges, each partial frequency range having a lower range frequency and an upper range frequency, performing a frequency analysis of the grid signal for each partial frequency range to identify in each case one or more oscillations having an oscillation frequency in the partial frequency range, if present, identifying a low-frequency oscillation to be attenuated as a target oscillation depending on the frequency analyses of all of the plurality of partial frequency ranges, detecting the target oscillation at least according to frequency and amplitude, determining a setpoint attenuation signal depending on the target oscillation detected according to frequency and amplitude for attenuating the detected target oscillation, generating a setpoint feed signal depending on the setpoint attenuation signal and a basic setpoint signal, and generating and feeding in a feed signal depending on the setpoint feed signal. 2. The method as claimed in claim 1 , wherein: the setpoint attenuation signal describes a reactive power to be fed in, and the basic setpoint signal is preset by power factor correction as a setpoint signal for a reactive power to be fed in. 3. The method as claimed in claim 1 , wherein: to generate the setpoint feed signal, a core controller is provided which outputs a controller output signal depending on the basic setpoint signal and the fed-in feed signal, the setpoint feed signal is determined depending on the controller output signal, and the setpoint attenuation signal is: injected onto the basic setpoint signal and taken into consideration by the core controller, and/or injected onto the controller output signal and influences the setpoint feed signal, and/or wherein an attenuation compensation signal, which is dependent on the setpoint attenuation signal, is injected on an input side of the core controller, and is injected onto the basic setpoint signal to at least partially compensate for an influence of the setpoint attenuation signal, via the fed-back feed signal, on the core controller. 4. The method as claimed in claim 3 , wherein: the attenuation compensation signal is injected on the input side of the core controller, and the fed-in feed signal is injected onto the basic setpoint signal, the attenuation compensation signal is generated by filtering out a compensation signal component from the detected feed signal, the compensation signal component has an oscillation frequency of the identified target oscillation, the attenuation compensation signal is formed depending on the compensation signal component, and to filter out the attenuation compensation signal from the detected feed signal, a bandpass filter is used and set to the oscillation frequency of the identified target oscillation. 5. The method as claimed in claim 1 , wherein: at least three overlapping partial frequency ranges are provided, the upper range frequency of a partial frequency range is in a region of 1.5 times to 10 times a value of the lower range frequency of the same partial frequency range, the respective frequency analysis for each partial frequency range uses different time segments of the detected grid signal and has different scanning rates, a time segment of the grid signal is assigned to each partial frequency range for the evaluation, wherein time segments of a plurality of partial frequency ranges overlap one another, and a scanning rate has been assigned to each partial frequency range for performing the frequency analysis, and/or a number of scans per time segment is used which is identical for different partial frequency ranges, the duration of the time segment of the partial frequency range corresponds at least to half inverse value of the lower range frequency, and/or corresponds at most to five times the inverse value of the lower range frequency, and/or the scanning rate of, in each case, one partial frequency range corresponds to at least twice the upper range frequency, and/or the scanning rate of, in each case, one partial frequency range corresponds up to one hundred times the upper range frequency. 6. The method as claimed in claim 1 , wherein: when, in a first of the partial frequency ranges having a higher upper range frequency than a further one of the partial frequency ranges, an oscillation having an oscillation frequency has been identified, the oscillation frequency of the identified oscillation is considered as potential aliasing frequency, and for the frequency analysis of at least a second of the partial frequency ranges having a lower upper range frequency than in a case of the first partial frequency range, a filtered signal of the grid signal is used from which signal components having the aliasing frequency are filtered out. 7. The method as claimed in claim 1 , wherein: in a first analysis step, the frequency analysis is performed for each partial frequency range to identify at least one oscillation having a first frequency, in a second analysis step, frequency, amplitude, and phase of the oscillation are identified by a signal investigation which is adapted to the identified oscillation, and the adapted signal investigation of the identified oscillation has a higher resolution than the frequency analysis and/or has been tuned in a targeted manner to the first frequency identified in the first analysis step. 8. The method as claimed in claim 1 , wherein: to determine the setpoint attenuation signal, an input signal which corresponds to the picked-up grid signal or is derived therefrom is filtered using a bandpass filter, the bandpass filter is set depending on the identified target oscillation to allow, from the input signal, a signal component having the oscillation frequency of the identified target oscillation to pass to only allow the target oscillation from the input signal to pass as extracted grid oscillation, and converting the extracted grid oscillation into the setpoint attenuation signal. 9. The method as claimed in claim 8 , wherein: to convert the extracted grid oscillation into the setpoint attenuation signal, at least one conversion element is used from the list comprising: a low-pass filter for filtering out a noise component, an amplifying element for amplifying the extracted grid oscillation, a high-pass filter for filtering out low-frequency signal components which occurs in the case of feeding wind power installations as a result of fluctuations in the wind, and at least one lead-lag filter for compensating for communications-related delay times. 10. The method as claimed in claim 1 , wherein: the determination and/or injection of the setpoint attenuation signal is activated or deactivated depending on a property of the identified target oscillation depending on an amplitude of the identified target oscillation, to activate, an activation threshold, and to deactivate, a deactivation threshold, is provided in each case as a comparison value for the amplitude of the target oscillation, and the activation threshold is greater than the deactivation threshold. 11. The method as claimed in claim 1 , wherein: to inj