Wind power conversion system with plural first converting circuits and a second converting circuit

What is claimed is: 1. A wind power conversion system electrically connected between a wind power generator and an isolating transformer, the wind power conversion system comprising: plural first converting circuits performing a power converting task, and comprising respective first generator-side terminals and respective first network-side terminals, wherein the first generator-side terminals are electrically connected with the wind power generator, and the first network-side terminals are electrically connected with corresponding secondary windings of plural secondary windings of the isolating transformer; and a second converting circuit comprising plural second generator-side terminals and a second network-side terminal, wherein the second network-side terminal is electrically connected with a corresponding secondary winding of the plural secondary windings of the isolating transformer, and the second generator-side terminals are serially connected with the corresponding first generator-side terminals of the first converting circuits and electrically connected with the wind power generator through the first converting circuits, wherein the second converting circuit is selectively operated in a non-crowbar mode or in a crowbar mode, wherein when the second converting circuit is operated in a non-crowbar mode, the second converting circuit performs the power converting task so that the power converting task of the plural first converting circuits is shared by the second converting circuit. 2. The wind power conversion system according to claim 1 , wherein the wind power generator is operated at a voltage level of 1 KV˜10 KV. 3. The wind power conversion system according to claim 1 , wherein the wind power generator comprises three phase windings, and the first generator-side terminals of the first converting circuits are electrically connected with the corresponding phase windings. 4. The wind power conversion system according to claim 3 , wherein if a phase voltage of one phase winding of the wind power generator is higher than the maximum output voltage of the corresponding first generator-side terminal of the first converting circuit, the second converting circuit is operated in the non-crowbar mode, wherein in the non-crowbar mode, the second converting circuit is enabled to share the power converting task. 5. The wind power conversion system according to claim 3 , wherein if a phase voltage of each phase winding of the wind power generator is lower than or equal to the maximum output voltage of the corresponding first generator-side terminal of the first converting circuit, the second converting circuit is operated in the crowbar mode, wherein in the crowbar mode, the second converting circuit is short-circuited. 6. The wind power conversion system according to claim 3 , wherein each of the first converting circuits is a three phase to single phase converting circuit and has an AC/DC/AC circuitry configuration. 7. The wind power conversion system according to claim 6 , wherein the second converting circuit is a three phase to three phase converting circuit and has an AC/DC/AC circuitry configuration. 8. The wind power conversion system according to claim 7 , wherein each of the first converting circuits comprises a first generator-side converter with two bridge arms. 9. The wind power conversion system according to claim 8 , wherein the second converting circuit comprises a second generator-side converter with three bridge arms. 10. The wind power conversion system according to claim 9 , wherein the first generator-side converter of each first converting circuit and the second generator-side converter of the second converting circuit are controlled by a sinusoidal pulse width modulation method based on a carrier phase-shifting technique, wherein if the second converting circuit is operated in the non-crowbar mode, phase shift angles among carrier waves of the two bridge arms of the first generator-side converter of the first converting circuit and the corresponding bridge arm of the second converting circuit are 120°. 11. The wind power conversion system according to claim 9 , wherein the first generator-side converter of each first converting circuit is controlled by a sinusoidal pulse width modulation method based on a carrier phase-shifting technique, wherein if the second converting circuit is operated in the crowbar mode, a phase shift angle between carrier waves of the two bridge arms of the first generator-side converter of the first converting circuit is 180°. 12. The wind power conversion system according to claim 6 , wherein the second converting circuit is a three phase to three phase converting circuit and has an AC/AC circuitry configuration. 13. The wind power conversion system according to claim 12 , wherein each of the first converting circuits comprises a first generator-side converter with two bridge arms, wherein the first generator-side converter of each first converting circuit is controlled by a sinusoidal pulse width modulation method based on a carrier phase-shifting technique, and a phase shift angle between carrier waves of the two bridge arms of the first generator-side converter of the first converting circuit is 180°. 14. The wind power conversion system according to claim 12 , wherein the second converting circuit is a two stage matrix converting circuit. 15. The wind power conversion system according to claim 12 , wherein the second converting circuit is a conventional matrix converting circuit. 16. The wind power conversion system according to claim 3 , wherein the first converting circuits and the second converting circuits have two-level circuitry configurations. 17. The wind power conversion system according to claim 3 , wherein the first converting circuits and the second converting circuits have three-level circuitry configurations. 18. The wind power conversion system according to claim 3 , wherein each of the first converting circuits is a three phase to single phase converting circuit and has an AC/AC circuitry configuration. 19. The wind power conversion system according to claim 18 , wherein the first converting circuit is a three phase to single phase matrix converting circuit. 20. The wind power conversion system according to claim 1 , wherein the number of the plural secondary windings of the isolating transformer is equal to the total number of the plural first converting circuits and the second converting circuit, wherein the plural first converting circuits comprise three first converting circuits, and the isolating transformer comprises four secondary windings.