초록 ▼

The disclosure describes implementations of methods, systems and apparatuses that are configured to facilitate normal operating characteristics for a wind turbine during normal operation, as well as during voltage irregularities. In an implementation, a turbine controller coordinates operating prima

The disclosure describes implementations of methods, systems and apparatuses that are configured to facilitate normal operating characteristics for a wind turbine during normal operation, as well as during voltage irregularities. In an implementation, a turbine controller coordinates operating primary turbine systems and ancillary turbine systems during normal operation and during voltage irregularities. During normal operation, the turbine controller coordinates powering both primary and ancillary turbine systems through a power supply. During a detected voltage event, ancillary turbine systems may be transitioned to a having an uninterruptible power supply power these systems. However, the turbine controller coordinates maintaining the power supply as the sole powering device for primary turbine systems despite a voltage irregularity. In some implementations, when the power supply reaches a critical level during a voltage irregularity, a system fault flag is generated and the turbine blades may be driven into a full feather operational position.

대표청구항 ▼

What is claimed is: 1. A wind turbine generator system comprising: a power supply operatively coupled to primary and ancillary turbine systems; an uninterruptible power supply device operatively coupled to ancillary turbine systems; a nacelle supporting one or more turbine blades and having a turbi

What is claimed is: 1. A wind turbine generator system comprising: a power supply operatively coupled to primary and ancillary turbine systems; an uninterruptible power supply device operatively coupled to ancillary turbine systems; a nacelle supporting one or more turbine blades and having a turbine blade pitch controller controlling a hydraulic turbine pitch drive circuit for each of the turbine blades and configured to actuate the blade between a zero feather position and a full feather position; a turbine controller configured to control ancillary turbine systems that are driven by the power supply during ordinary operation and in coordination with the uninterruptible power supply during a voltage irregularity; the turbine controller is also configured to control primary turbine systems including a turbine blade pitch control system, wherein the turbine controller maintains consistent operating characteristics through the power supply powering the primary turbine systems independent of the uninterruptible power supply device during both normal operation and voltage irregularities. 2. The system of claim 1, further comprising: driving all of the turbine blades into a full feather position upon detection of a critical level of the power supply responsible for powering primary turbine control systems. 3. The system of claim 2, further comprising: issuing a system fault flag if the turbine controller detects a critical level in the power supply responsible for the primary turbine control systems. 4. The system of claim 3, wherein the turbine controller requires a manual override to transition back to ordinary operating characteristics after issuing the system fault flag. 5. The system of claim 2, wherein each of the one or more turbine blades have an independent hydraulic blade pitch actuation servo motor. 6. The system of claim 2, wherein each of the independent hydraulic circuits are communitively coupled with a hydraulic cylinder and configured to drive the hydraulic cylinder that changes the pitch of each turbine blade between a zero feather and a full feather position. 7. The system of claim 3, further comprising: the turbine blade pitch controller is operatively connected with a hydraulic pitch drive circuit configured for driving each turbine blade with emergency actuation valves. 8. The system of claim 7, wherein each turbine blade includes a blocking mechanism that is configured to lock the blades in a full feather position after a system fault flag has been generated. 9. The system of claim 8, wherein each blade hydraulic pitch drive circuit is configured to be driven independently by the turbine blade pitch controller. 10. A wind turbine generator comprising: a blade pitch control system configured to vary a pitch associated with one or more turbine blades; a power supply coupled to the blade pitch control system, wherein the power supply is configured to provide power to the blade pitch control system during a low voltage event without transfer to an uninterruptible power supply; and an uninterruptible power supply configured to provide power to non-pitch control turbine components during a low voltage event. 11. The wind turbine generator of claim 10, wherein the blade pitch control system further comprises an independent hydraulic blade actuation system for each of the one or more turbine blades. 12. The wind turbine generator of claim 11, wherein the power supply further comprises an additional energy storage component configured to drive each independent hydraulic blade actuation system during both normal operation and during a low voltage event. 13. The wind turbine generator of claim 12, wherein the voltage output level of the power supply is monitored. 14. The wind turbine generator of claim 13, wherein a system fault flag is issued if the power supply reaches a critical operating voltage level. 15. The wind turbine generator of claim 14, wherein each turbine blade further includes a blade blocking mechanism that is configured to lock the blades into a full feather position after a system fault flag has been issued.