Systems containing a double fed induction machine and a fly wheel, and methods of operating such systems

1 . A system, comprising: a double fed induction machine having a stator and a rotor; a fly wheel coupled to said rotor; and a control system for providing a rotor voltage and a rotor current to said rotor, said control system connected to said rotor and said stator and capable of generating the rotor voltage and the rotor current in response to an electrical signal that is applied to said stator, said control system having a multilevel converter and a controller for controlling said multilevel converter. 2 . The system according to claim 1 , wherein said multilevel converter is a Matrix Multilevel Converter. 3 . The system according to claim 1 , wherein: said controller is configured to calculate a first frequency in dependence on an actual rotational velocity of said rotor; said controller is configured to calculate a second frequency in dependence on the first frequency and a frequency of the electrical signal that is applied to said stator; and said controller is configured to control said multilevel converter in order to apply the rotor voltage and the rotor current that each comprise both the first and second frequencies, in order to counteract deviations between an actual stator current and a predefined stator current. 4 . The system according to claim 3 , wherein: said controller calculates the first frequency by multiplying the actual rotational velocity of the rotor and a pole pair number of said double fed induction machine; and said controller calculates the second frequency by subtracting the first frequency from a fundamental frequency of the electrical signal that is applied to said stator. 5 . The system according to claim 3 , wherein: said stator is connected to an energy supply grid; the predefined stator current corresponds to a stator current under normal grid conditions before a Low-Voltage Ride Through situation occurs; said controller is configured to control the rotor current in order to stabilize the energy supply grid in case of the Low-Voltage Ride Through situation by counteracting deviations between the stator current and the predefined stator current with respect to the first frequency and the second frequency; and the first frequency is dependent on the actual rotational velocity of said rotor and a pole pair number of said double fed induction machine, and the second frequency is dependent on a difference between the first frequency and a frequency of the energy supply grid. 6 . The system according to claim 3 , wherein said controller has a transformation unit that is configured to receive measured stator phase current values and calculate a d-component and a q-component of the actual stator current in Park-coordinates and to receive measured rotor phase current values and calculate a d-component and a q-component of an actual rotor current in Park-coordinates. 7 . The system according to claim 6 , wherein: said controller contains an evaluator that is configured to generate d-components and q-components of the rotor current and the rotor voltage that are to be applied to said rotor, namely: with respect to the first frequency and the second frequency; and in response to a deviation between the d-component of the actual stator current and a corresponding d-component of a predefined stator current and a deviation between the q-component of the actual stator current and a corresponding q-component of the predefined stator current. 8 . The system according to claim 7 , wherein: said evaluator contains a first evaluation branch and a second evaluation branch; said first evaluation branch is configured to generate the d-components of the rotor current and the rotor voltage that are to be applied to said rotor, in response to and in order to minimize the deviation between the d-component of the actual stator current and the d-component of the predefined stator current; and said second evaluation branch is configured to generate the q-components of the rotor current and the rotor voltage that are to be applied to the rotor, in response to and in order to minimize the deviation between the q-component of the actual stator current and the q-component of the predefined stator current. 9 . The system according to claim 8 , wherein said first evaluation branch has: a first d-subunit configured to generate the d-component of the rotor current that is to be applied to said rotor, in response to the deviation between the d-component of the actual stator current and the d-component of the predefined stator current with respect to the first frequency; a second d-subunit configured to generate the d-component of the rotor current that is to be applied to said rotor, in response to the deviation between the d-component of the actual stator current and the d-component of the predefined stator current with respect to the second frequency; a d-adder that adds generated d-components of the first and second frequencies and generates a d-component of a sum current; a d-subtractor that is configured to subtract the d-component of the actual rotor current from the d-component of the sum current; a third d-subunit configured to generate the d-component of the rotor voltage that is to be applied to the rotor, in response to the output of the d-subtractor with respect to the first frequency; and a fourth d-subunit that is configured to generate the d-component of the rotor voltage that is to be applied to said rotor, in response to the output of the d-subtractor with respect to the second frequency. 10 . The system according to claim 9 , wherein said second evaluation branch contains: a first q-subunit configured to generate the q-component of the rotor current that is to be applied to said rotor, in response to the deviation between the q-component of the actual stator current and the q-component of the predefined stator current with respect to the first frequency; a second q-subunit configured to generate the q-component of the rotor current that is to be applied to said rotor, in response to the deviation between the q-component of the actual stator current and the q-component of the predefined stator current with respect to the second frequency; a q-adder that adds the generated q-components of the first and second frequencies and generates a q-component of a sum current; a q-subtractor configured to subtract the q-component of the actual rotor current from the q-component of the sum current; a third q-subunit configured to generate the q-component of the rotor voltage that is to be applied to said rotor, in response to an output of the q-subtractor with respect to the first frequency; and a fourth q-subunit that is configured to generate the q-component of the rotor voltage that is to be applied to said rotor, in response to said output of the q-subtractor with respect to the second frequency. 11 . The system according to claim 10 , wherein: said first and third d-subunits are resonant controllers; said second and fourth d-subunits are P I-controllers; and/or said first and third q-subunits are resonant controllers; and said second and fourth q-subunits are P I-controllers. 12 . The system according to claim 1 , wherein said controller contains a transformation unit configured to receive d-components and q-components of the rotor current and the rotor voltage that are to be applied said rotor, and to generate corresponding α-components and β-components in Clarke-coordinates. 13 . The system according to claim 12 , wherein said controller contains a converter unit configured to control branch voltages of internal branches of said multilevel converter in response to the α-components and the β-co