Driving system and method for a wound rotor synchronous generator

The invention claimed is: 1. A driving system for a wound rotor synchronous generator, comprising: a converter controlling the wound rotor synchronous generator and receiving generated power; and a field winding power supply means supplying power to a field winding of a rotor of the generator, wherein the field winding power supply means is connected to the converter to receive the power from the converter and supply the power to the field winding, the power supplied to the field winding being electrically insulated from the power received from the converter, and wherein the converter includes: at least three switch legs each outputting a voltage at a plurality of levels and including a plurality of semiconductor switches, a plurality of diodes, and a capacitor module including at least one capacitor. 2. The driving system for the wound rotor synchronous generator of claim 1 , wherein at least a portion of the field winding power supply means rotates with the rotor of the generator to supply the power. 3. The driving system for the wound rotor synchronous generator of claim 2 , wherein the field winding power supply means includes a rectification unit rotating with the rotor of the generator and supplying a direct current to the field winding of the generator. 4. The driving system for the wound rotor synchronous generator of claim 3 , wherein the field winding power supply means includes a rotary transformer including a stator and a rotor, wherein the rotor of the rotary transformer is mechanically coupled to a shaft of the generator, the rotor of the rotary transformer includes a secondary winding, and the secondary winding is connected to the rectification unit. 5. The driving system for the wound rotor synchronous generator of claim 4 , wherein the stator of the rotary transformer includes a primary winding connected to the rectification unit. 6. The driving system for the wound rotor synchronous generator of claim 5 , wherein the converter includes at least four switch legs. 7. The driving system for the wound rotor synchronous generator of claim 6 , wherein an output terminal of a fourth switch leg is connected to one end of the primary winding. 8. A wind power generation system, comprising: a wind blade for wind power generation; a wound rotor synchronous generator connected to the wind blade and having a field winding on a rotor thereof; the driving system for a wound rotor synchronous generator of claim 1 ; and an inverter connected between the converter and a power supply grid to transfer the power received by the converter from the generator to the power supply grid. 9. A method for controlling a converter, in a driving system for a wound rotor synchronous generator including a wound rotor synchronous generator, a field winding power supply means supplying power to a field winding of the generator using a rotary transformer, and the converter connected to a primary winding provided on a stator of the rotary transformer, the method comprising: by a control means of the converter, (a) setting a command value of a field current, which is a current flowing in the field winding of the generator, to a predetermined value; (b) measuring the field current; (c) calculating a first voltage command to be applied to the rotary transformer based on a control error that is a difference between the command value of the field current and the measured value of the field current; (d) generating a corrected second voltage command by correcting the first voltage command; (e) generating a pulse width modulation (PWM) control signal of a switch of a switch leg connected to the field winding power supply means based on the second voltage command; and (f) controlling the switch based on the PWM control signal. 10. The method of claim 9 , wherein step (d) includes: (d-1) generating a second voltage command signal by restricting the first voltage command to be between a predetermined maximum value and a predetermined minimum value; (d-2) calculating a difference between the first voltage command and the second voltage command; and (d-3) calculating a correction amount by multiplying the difference by a predetermined gain.