Converter-based generators and method for feeding in electrical power

The invention claimed is: 1. A method for feeding electrical power into an electrical supply network having a network voltage with a network frequency using a converter-based generator, comprising: estimating a converter proportion of a network section of the electrical supply network, wherein the converter proportion represents a ratio of power fed in by converters to a total power fed in; feeding the electrical power into the electrical supply network in a normal mode depending on the estimated converter proportion, wherein the feeding of the electrical power in the normal mode is in response to the estimated converter proportion being below a first reference value; activating a first support mode depending on the estimated converter proportion in accordance with a first activation condition, wherein the activating of the first support mode is in response to the estimated converter proportion being equal to or greater than the first reference value; and activating a second support mode depending on the estimated converter proportion in accordance with a second activation condition different than the first activation condition, wherein the activating of the second support mode is in response to the estimated converter proportion being equal to or greater than a second reference value, wherein the second reference value is greater than the first reference value. 2. The method as claimed in claim 1 , wherein the converter-based generator is a wind power system. 3. The method as claimed in claim 1 , wherein the first reference value is in the range of 50-60% and/or the second reference value is in the range of 80-95%. 4. The method as claimed in claim 1 , comprising: selecting the first reference value and/or the second reference value depending on a network property of the electrical supply network that is a load flow measure representing a maximum power flow between the network section and a remaining part of the electrical supply network. 5. The method as claimed in claim 1 , wherein in the first support mode: an emulation function is activated, which reacts to a frequency change of the network frequency with a power change of the electrical power, wherein the power change as a reaction to the frequency change emulates a behavior of a synchronous machine coupled directly to the electrical supply network, wherein a virtual centrifugal mass with adjustable mass moment of inertia is used, and/or the power change of the electrical power is the reaction to the frequency change, and uses wholly or partly energy from rotational energy of at least one rotor of a wind power installation for the power change, wherein in response to the power change, the wind power installation feeds in more power than it generates from wind, and/or the power change of the electrical power as the reaction to the frequency change has an amplitude that is at least double a magnitude of a power change in the case of the same frequency change in the normal mode, and/or for the power change of the electrical power as the reaction to the frequency change, no minimum frequency deviation of the network frequency from a reference frequency is predefined, or a predetermined minimum frequency deviation is at least smaller than in the normal mode. 6. The method as claimed in claim 1 , wherein in the first support mode: a power limitation function for rapid power limitation is implemented, wherein the power limitation function reduces the electrical power in response to a request signal or request criterion, and the reduction of the electrical power is characterized by a reduction time constant, wherein the reduction time constant represents a time in which the electrical power is reduced by a rated power value, wherein the reduction time constant is less than 2 seconds, and/or with a use of a wind power system as the converter-based generator, the reduction of the electrical power is more rapid than a reduction of power generated from wind using the wind power system, and/or power is additionally consumed in the wind power system for reducing the electrical power, and/or the electrical power is reduced to a value below zero, such that the wind power system draws power from the electrical supply network, and consumes the drawn power. 7. The method as claimed in claim 1 , wherein in the first support mode a frequency gradient control is activated, wherein the frequency gradient control alters the electrical power depending on a frequency gradient that quantitatively represents a frequency change per time. 8. The method as claimed in claim 1 , wherein in the second support mode a frequency-dependent power control is activated, in which the electrical power is altered depending on the network frequency in accordance with a control specification, and the control specification has a control gain and/or is characterized by a control speed, which are altered depending on the converter proportion and/or depending on a load flow measure, and/or in the second support mode and with the use of a wind power system, an instantaneous reserve control is activated, in which depending on the network frequency, at values of the network frequency below a lower frequency reference value, kinetic energy is drawn from at least one rotating rotor and fed into the electrical supply network. 9. The method as claimed in claim 1 , wherein: in the second support mode an inertial angle control is activated, the inertial angle control operates a reference system, in which a virtual centrifugal mass rotates with a rotational speed corresponding to the network frequency, the virtual centrifugal mass is used to derive a reference signal with a reference frequency and a phase angle in relation to the network voltage, and the rotation of the virtual centrifugal mass follows a change of the network frequency with a delay function, such that the phase angle of the reference signal varies as the network frequency changes, and the inertial angle control controls a the electrical power depending on the phase angle of the reference signal. 10. The method as claimed in claim 9 , wherein: the inertial angle control controls a portion of the electrical power proportionally to the phase angle, the virtual centrifugal mass is distinguished by a moment of inertia that is adjustable, the delay function has a ramp-up time constant that is proportional to the moment of inertia, and/or the moment of inertia is selected depending on an operating point of the converter-based generator or the electrical power. 11. The method as claimed in claim 1 , wherein in the second support mode, a power infeed dependent on the network voltage is provided, which represents the electrical power or a portion of the electrical power depending on a voltage deviation of the network voltage from a reference voltage. 12. The method as claimed in claim 11 , wherein: the power infeed represents the electrical power or the portion of the electrical power depending on a rated network voltage, a power portion of the electrical power proportional to the voltage deviation is predefined and fed in, and a further portion of the electrical power depending on an integral portion of the voltage deviation is predefined and fed in. 13. The method as claimed in claim 1 , wherein in the second support mode, a reactive power infeed dependent on the network voltage is provided, the reactive power infeed representing a fed-in reactive power or a portion of the fed-in reactive power depending on a voltage deviation of the network voltage from a reference voltage, and at least one portion of the fed-in reactive power depending on an integral portion of the