Circuit arrangement with active rectifier circuit and its application in a synchronous machine

The invention claimed is: 1. A circuit arrangement having an active rectifier circuit, in particular on the secondary side of an inductive energy transmission path, with a half or full bridge of first and second power transistors (Q 1 , Q 2 ) for rectifying an AC voltage induced in an input inductor (L 2 ) of the circuit arrangement, and with a resonant circuit formed by a parallel circuit of the input inductor (L 2 ) and a first capacitor (C 2,p ), characterized in that the first and second power transistors (Q 1 , Q 2 ) are connected to the input inductor (L 2 ) such that an auxiliary voltage for switching the power transistors (Q 1 , Q 2 ) is split off from said resonant circuit, and wherein the first of said first and second power transistors (Q 1 ) establishes a switchable electrical connection between a first side of the input inductor (L 2 ) and a first pole of an output terminal, the second of said first and second power transistors (Q 2 ) establishes a switchable electrical connection between a second side of the input inductor (L 2 ) and the first pole of the output terminal, a drain terminal of a first control transistor (Q S1 ) is connected to a drain terminal of the first power transistor (Q 1 ) and a source terminal of the first control transistor (Q S1 ) is connected to a gate terminal of the second power transistor (Q 2 ), a drain terminal of a second control transistor (Q S2 ) is connected to a drain terminal of the second power transistor (Q 2 ) and a source terminal of the second control transistor (Q S2 ) is connected to a gate terminal of the first power transistor (Q 1 ), a centre tap of the input inductor (L 2 ) or both sides of the input inductor (L 2 ) of the resonant circuit is/are connected to a second pole of the output terminal via respective chokes (L DR2 ), and gate terminals of the first and second control transistors (Q S1 , Q S2 ) are connected via a resistor (R 0 ) and a diode to both sides of the input inductance (L 2 ) of the resonant circuit via at least one resistor (R 0 ) and a diode (R f ) and connected to the first pole of the output terminal via a parallel circuit consisting of a second capacitor (C 0 ) and a Zener diode (R Z ). 2. The circuit arrangement according to claim 1 , characterized in that the control transistors (Q S1 , Q S2 ) are MOSFETs. 3. The circuit arrangement according to claim 1 , characterized in that the power transistors (Q 1 , Q 2 ) are MOSFETs. 4. A method for the use of the circuit arrangement according to claim 1 on a rotor of a synchronous machine, comprising: performing an inductive energy transmission to the rotor via the input inductor (L 2 ) of the circuit arrangement. 5. A method for the use of the circuit arrangement according to claim 1 on a rotor of a synchronous machine, comprising: performing an inductive energy transmission to the rotor via the input inductor (L 2 ) of the circuit arrangement, and forming the one or multiple chokes (L DR2 ) by rotor windings of the rotor. 6. A rotor of a synchronous machine comprising the circuit arrangement according to claim 1 , wherein an inductive energy transmission to the rotor is performed via the input inductor (L 2 ) of the circuit arrangement. 7. A rotor of a synchronous machine comprising the circuit arrangement of claim 1 , wherein an inductive energy transmission to the rotor is performed via the input inductor (L 2 ) of the circuit arrangement, and wherein one or multiple chokes (L DR2 ) are formed by rotor windings of the rotor. 8. A circuit arrangement having an active rectifier circuit, in particular on the secondary side of an inductive energy transmission path, with a half or full bridge of first and second power transistors (Q 1 , Q 2 ) for rectifying an AC voltage induced in an input inductor (L 2 ) of the circuit arrangement, and with a resonant circuit formed by a parallel circuit of the input inductor (L 2 ) and a first capacitor (C 2,p ), characterized in that the first and second power transistors (Q 1 , Q 2 ) are connected to the input inductor (L 2 ) such that an auxiliary voltage for switching the power transistors (Q 1 , Q 2 ) is split off from said resonant circuit, and wherein the first of said first and second power transistors (Q 1 ) establishes a switchable electrical connection between a first side of the input inductor (L 2 ) and a first pole of an output terminal, the second of said first and second power transistors (Q 2 ) establishes a switchable electrical connection between a second side of the input inductor (L 2 ) and the first pole of the output terminal, a drain terminal of a first control transistor (Q S1 ) is connected to a drain terminal of the first power transistor (Q 1 ) and a source terminal of the first control transistor (Q S1 ) is connected to a gate terminal of the second power transistor (Q 2 ), a drain terminal of a second control transistor (Q S2 ) is connected to a drain terminal of the second power transistor (Q 2 ) and a source terminal of the second control transistor (Q S2 ) is connected to a gate terminal of the first power transistor (Q 1 ), a centre tap of the input inductor (L 2 ) or both sides of the input inductor (L 2 ) of the resonant circuit is/are connected to a second pole of the output terminal via respective chokes (L DR2 ), and wherein gate terminals of the first and second power transistors (Q 1 , Q 2 ) in each case are connected to the first pole of the output terminal either via a series circuit of another Zener diode (R z1 , R z2 ) and another diode (R d1 , R d2 ) or via a bidirectional Zener diode, wherein the further Zener diode (R z1 , R z2 ) prevents a current from flowing from the gate terminal of the respective power transistors (Q 1 , Q 2 ) to the first pole until the Zener voltage is reached, and the further diode (R d1 , R d2 ) prevents a current flowing from the first pole to the gate terminal of the respective power transistors (Q 1 , Q 2 ). 9. The circuit arrangement according to claim 8 , characterized in that the control transistors (Q S1 , Q S2 ) are MOSFETs. 10. The circuit arrangement according to claim 8 , characterized in that the power transistors (Q 1 , Q 2 ) are MOSFETs. 11. A method for the use of the circuit arrangement according to claim 8 on a rotor of a synchronous machine, comprising: performing an inductive energy transmission to the rotor via the input inductor (L 2 ) of the circuit arrangement. 12. A method for the use of the circuit arrangement according to claim 8 on a rotor of a synchronous machine, comprising: performing an inductive energy transmission to the rotor via the input inductor (L 2 ) of the circuit arrangement, and forming the one or multiple chokes (LDR 2 ) by rotor windings of the rotor. 13. A rotor of a synchronous machine comprising the circuit arrangement according to claim 8 , wherein an inductive energy transmission to the rotor is performed via the input inductor (L 2 ) of the circuit arrangement. 14. A rotor of a synchronous machine comprising the circuit arrangement of claim 8 , wherein an inductive energy transmission to the rotor is performed via the input inductor (L 2 ) of the circuit arrangement, and wherein one or multiple chokes (LDR 2 ) are formed by rotor windings of the rotor.