Wind turbine deceleration method and system

The invention claimed is: 1. A wind turbine comprising: wind turbine blades; a wind turbine rotor coupled to the wind turbine blades; a wind turbine generator coupled to the wind turbine rotor; a wind turbine converter coupled to the wind turbine generator; a controllable brake comprising one or more sources of controllable rotor torque adjustment for providing a first level of torque adjustment, wherein the one or more sources of controllable rotor torque adjustment comprise the wind turbine blades and the wind turbine generator; a discrete brake for more coarsely providing a second level of torque adjustment; and a controller programmed for responding to a deceleration event by determining a required torque adjustment for braking, determining a sequence of applying the controllable brake and the discrete brake for driving a combination of the first and second levels of torque adjustment towards the required torque adjustment, and providing control signals for decelerating the wind turbine. 2. The wind turbine of claim 1 wherein the controller is programmed for determining whether a potential first level of torque adjustment from the controllable brake meets the required torque adjustment, and if so, providing control signals for using the controllable brake for providing the required torque adjustment; or if not, providing control signals for applying the discrete brake for more coarsely providing the second level of torque adjustment and for using the controllable brake for more finely providing the first level of torque adjustment. 3. The wind turbine of claim 2 wherein the discrete brake comprises a mechanical brake. 4. The wind turbine of claim 2 wherein the discrete brake comprises an electrical brake. 5. The wind turbine of claim 1 wherein the one or more sources of controllable rotor torque adjustment further comprises a controllable electrical brake. 6. The wind turbine of claim 5 wherein the discrete brake comprises a mechanical brake or a second electrical brake, which is designed to be a discrete, on-off type of brake. 7. The wind turbine of claim 5 wherein the controller is further programmed for sending control signals to simultaneously use the wind turbine blades and the wind turbine generator to provide the first level of torque adjustment. 8. The wind turbine of claim 5 wherein the controller is further programmed for sending control signals to use the wind turbine generator to provide at least some of the first level of torque adjustment and, if necessary, also sending control signals to use the wind turbine blades to provide the first level of torque adjustment. 9. The wind turbine of claim 5 wherein when the wind turbine generator and the wind turbine converter are coupled to a grid and each of the wind turbine generator, the wind turbine converter, and the grid are functional to provide at least some of the first level of torque adjustment, the controller is programmed to send control signals for using the wind turbine generator, the wind turbine converter, and the grid to provide the at least some of the first level of torque adjustment, and wherein when the wind turbine generator, the wind turbine converter, and the grid are not functional to provide all of the first level of torque adjustment, the controller is programmed for sending one or more control signals for using the controllable electrical brake to provide the at least some other of the first level of torque adjustment. 10. The wind turbine of claim 1 wherein the controller is programmed for determining the sequence of applying the discrete brake and the controllable brake based at least in part on the operability of the discrete brake and the operability of the controllable brake. 11. A method of decelerating a wind turbine comprising wind turbine blades, a rotor coupled to the wind turbine blades, a wind turbine generator coupled to the rotor, a converter coupled to the wind turbine generator, a controllable brake comprising one or more sources of controllable rotor torque adjustment for providing a first level of torque adjustment, wherein the one or more sources of controllable rotor torque adjustment comprise the wind turbine blades and the wind turbine generator, and a discrete brake for more coarsely providing a second level of torque adjustment, the method comprising: responding to a deceleration event by: determining a required torque adjustment for braking, determining a sequence of applying the controllable brake and the discrete brake for driving a combination of the first and second levels of torque adjustment towards the required torque adjustment; and providing control signals to the controllable brake, the discrete brake, or both for decelerating the wind turbine. 12. The method of claim 11 wherein determining the sequence of applying the controllable brake and the discrete brake and providing control signals comprise: determining whether a potential first level of torque adjustment from the controllable brake meets the required torque adjustment, and if so, providing control signals for using the controllable brake for providing the required torque adjustment; or if not, providing control signals for applying the discrete brake for more coarsely providing the second level of torque adjustment and for using the controllable brake for more finely providing the first level of torque adjustment. 13. The method of claim 11 wherein the one or more sources of controllable rotor torque adjustment further comprises a controllable electrical brake. 14. The method of claim 13 wherein the discrete brake comprises a mechanical brake or a second electrical brake, which is designed to be a discrete, on-off type of brake. 15. The method of claim 11 wherein the sequence of applying the discrete brake and the controllable brake is determined based at least in part on the operability of the discrete brake and the operability of the controllable brake.