Method of feeding electric power by means of a wind energy system

The invention claimed is: 1. A method of feeding electric power at a grid connection point into an electric power grid having a grid voltage using a wind energy system and/or battery, the method comprising: feeding the electric power into the electric power grid in a normal operating mode in which a grid fault or grid malfunction in the electric power grid has not been detected; and in response to detecting the grid fault or grid malfunction, in which the grid voltage increased or decreased, switching to a fault mode operation, wherein: in the normal operating mode, feeding an active current to feed active electric power into the electric power grid; and in response to detecting a current requirement, using a reactive current to additionally feeding a reactive electric power into the electric power grid, wherein a combination of the active current and the reactive current results in an apparent current, and in the fault mode operation, feeding an additional reactive current into the electric power grid or increasing a magnitude of the reactive current to increase or decrease the grid voltage; and using a mode prioritizing reactive power or a mode prioritizing active power, wherein: in the mode prioritizing reactive power, the active current is reduced such that the apparent current remains within an apparent current limit, and in the mode prioritizing active power, the reactive current is limited or reduced such that the apparent current remains within the apparent current limit, and wherein: in the mode prioritizing reactive power: an upper reactive current limit is set for the magnitude of the reactive current; and/or a lower active current limit is set for the active current, or in the mode prioritizing active power: an upper active current limit is set for the active current; and/or a magnitude for a lower reactive current limit is set for the reactive current. 2. The method according to claim 1 , comprising: in the fault mode operation, switching from the mode prioritizing reactive power to the mode prioritizing active power or from the mode prioritizing active power to the mode prioritizing reactive power. 3. The method according to claim 2 , comprising: in response to the apparent current reaching the apparent current limit, switching the upper reactive current limit or the lower active current limit from the mode prioritizing reactive power to the mode prioritizing active power; or in response to the apparent current reaching the apparent current limit, switching the upper active current limit or the lower reactive current limit from the mode prioritizing active power to the mode prioritizing reactive power. 4. The method according to claim 1 , comprising: dynamically changing at least one current of: the upper reactive current limit, the lower active current limit, the upper active current limit, and the lower reactive current limit. 5. The method according to claim 4 , wherein the dynamically changing the at least one current includes: adjusting the at least one current according to a grid characteristic of the electric power grid; or causing the at least one current to be set or become effective after a predetermined time waiting period from switching to the fault mode operation has been made; and/or transmitting the at least one current to an external grid operator. 6. The method according to claim 1 , comprising: adjusting the upper reactive current limit and/or the lower active current limit according to the active power currently available to the wind energy system and/or battery. 7. The method according to claim 1 , wherein, in the fault mode operation, the method includes setting a fault mode reactive current droop specifying the reactive current in relation to the grid voltage in the mode prioritizing reactive power, wherein: the fault mode reactive current droop, outside a deadband range, specifies a linear relationship between the grid voltage and the reactive current, and the fault mode reactive current droop includes a fault mode reactive current increase indicating a ratio between a change in the reactive current and an associated change in the grid voltage, and the fault mode reactive current increases at most to the upper reactive current limit, and/or the active current is reduced to retain the apparent current within a maximum permissible apparent current, wherein the active current is not reduced below the lower active current limit; and in the normal operating mode, a normal mode reactive current droop including a normal mode reactive current increase is set, and the normal mode reactive current increase is greater than the fault mode reactive current increase. 8. The method according to claim 1 , comprising: determining a grid rigidity as a grid characteristic of the electric power grid, a subgrid or a local grid segment, wherein the grid rigidity is a measure of a grid frequency change in response to a change in a power balance in the electric power grid, and wherein the power balance denotes a ratio between the electric power fed into the electric power grid, the subgrid or the local grid segment and a power drawn from the electric power grid, the subgrid or the local grid segment. 9. The method according to claim 8 , comprising: setting the grid rigidity as a quotient of the grid frequency change and a power balance change; and adjusting at least one current limit of the upper reactive current limit, the lower active current limit, the upper active current limit, and the lower reactive current limit according to the grid rigidity. 10. The method according to claim 9 , comprising: classifying the electric power grid, the subgrid or the local grid segment as a soft or a rigid grid depending on the grid rigidity; and adjusting the at least one current limit according to the classification. 11. The method according to claim 10 , comprising: specifying the at least one current limit according to a proportion of converter-controlled feeders in the electric power grid; and/or determining the grid rigidity according to the proportion of converter-controlled feeders in the electric power grid. 12. The method according to claim 1 , comprising: selecting at least one current limit of the upper reactive current limit, the lower active current limit, the upper active current limit, and the lower reactive current limit depending on a local frequency softness at the grid connection point; and/or setting an increase in the reactive current of a reactive current droop depending on the local frequency softness at the grid connection point, wherein: the local frequency softness is detected at the grid connection point if a grid frequency at the grid connection point oscillates with a greater amplitude than at a reference point of the electric power grid, and the local frequency softness is measured based on a ratio of an amplitude of oscillation of the grid frequency at the grid connection point to an amplitude of oscillation of the grid frequency at the reference point. 13. The method according to claim 1 , comprising: setting a reactive current droop or an increase in the reactive current of the reactive current droop according to a grid rigidity in the fault mode operation; and/or setting the reactive current droop or the increase in the reactive current of the reactive current droop according to a proportion of converter-controlled feeders in the electric power grid in the fault mode operation. 14. The method according to claim 1 , wherein, determining a converter proportion as a proportion of converter-controlled feeders for the e