Method for robust wireless wind turbine condition monitoring

We claim: 1. A wind turbine condition monitoring system for at least one wind turbine, each of the at least one wind turbine comprising a tower, a gearbox supported by the tower and a plurality of turbine blades coupled to the gearbox, the condition monitoring system comprising: a plurality of blade sensors configured to provide blade sensor readings associated with an associated one of the plurality of turbine blades, each of the plurality of blade sensors coupled to the associated one of the plurality of turbine blades; at least one hub node, each of the at least one hub nodes supported by the gearbox of a respective one of the at least one wind turbine; and a controller in communication with the at least one hub node and the plurality of blade sensors; wherein the controller determines the position of each turbine blade of the plurality of turbine blades based on the blade sensor readings. 2. The wind turbine condition monitoring system of claim 1 , wherein each of the plurality of blade sensors is a multi-axis accelerometer. 3. The wind turbine condition monitoring system of claim 1 , wherein the controller has direct wireless communication with the at least one hub node and with each of the plurality of blade sensors. 4. The wind turbine condition monitoring system of claim 3 , wherein the controller only communicates with a particular blade sensor of the plurality of blade sensors when the particular blade sensor is outside blade shadowing areas, direct wireless communication between the controller and the particular blade sensor being obstructed when the particular blade sensor is in the blade shadowing areas. 5. The wind turbine condition monitoring system of claim 4 , wherein the controller only communicates with a particular hub node of the at least one hub node when the particular hub node is outside hub node shadowing areas, direct wireless communication between the controller and the particular hub node being obstructed when the particular hub node is in the hub node shadowing areas. 6. The wind turbine condition monitoring system of claim 1 , wherein: the controller has direct wireless communication with the at least one hub node; each of the at least one hub nodes has direct wireless communication with each of the plurality of blade sensors of the respective one of the at least one wind turbine; and the controller is in communication with the plurality of blade sensors through the at least one hub node. 7. The wind turbine condition monitoring system of claim 6 , wherein each of the at least one hub nodes only communicates with a particular blade sensor of the plurality of blade sensors when the particular blade sensor is not in blade shadowing areas, direct wireless communication between the at least one hub node and the particular blade sensor being obstructed when the particular blade sensor is in the blade shadowing areas. 8. The wind turbine condition monitoring system of claim 7 , wherein the controller only communicates with a communicating hub node of the at least one hub node when the communicating hub node is outside hub node shadowing areas, direct wireless communication between the controller and the communicating hub node being obstructed when the communicating hub node is in the hub node shadowing areas. 9. The wind turbine condition monitoring system of claim 1 , wherein the controller only communicates with a particular blade sensor of the plurality of blade sensors when the particular blade sensor is in a favorable communication region, the controller determining whether the particular blade sensor is in the favorable communication region based on the blade sensor readings; the favorable communication region having an unobstructed communication path between the controller and the particular blade sensor. 10. The wind turbine condition monitoring system of claim 9 , wherein the favorable communication region is further constrained such that a separation distance between the controller and the particular blade sensor is less than a separation distance threshold when the particular blade sensor is in the favorable communication region. 11. The wind turbine condition monitoring system of claim 10 , wherein the favorable communication region is further constrained such that only one blade sensor of the plurality of blade sensors is in the favorable communication region at a time. 12. The wind turbine condition monitoring system of claim 9 , wherein the favorable communication region is further constrained such that only one blade sensor of the plurality of blade sensors is in the favorable communication region at a time. 13. A wind turbine condition monitoring method for wind turbines with a monitoring system, each wind turbine comprising a tower, a gearbox coupled to the tower, and a plurality of turbine blades coupled to the gearbox, and the monitoring system comprising a controller, a hub node coupled to each gearbox, and a plurality of blade sensors, the condition monitoring method comprising: determining for each one of the plurality of blade sensors respective shadowing areas where a communication path between the one of the plurality of blade sensors and the controller is obstructed when the one of the plurality of blade sensors is in the respective shadowing areas; each one of the plurality of blade sensors coupled to a respective one of the plurality of turbine blades; configuring each one of the plurality of blade sensors to only transmit when outside the respective shadowing areas; receiving blade sensor readings at the controller from each one of the plurality of blade sensors when each one of the plurality of blade sensors is outside the respective shadowing areas; and determining a position of each one of the plurality of blade sensors based on the blade sensor readings. 14. The wind turbine condition monitoring method of claim 13 , further comprising: determining respective favorable communication regions outside the respective shadowing areas where the communication path between each one of the plurality of blade sensors and the controller is less than a separation distance threshold; configuring each one of the plurality of blade sensors to only transmit when within the respective favorable communication regions; and receiving blade sensor readings at the controller from each one of the plurality of blade sensors when each one of the plurality of blade sensors is within the respective favorable communication regions. 15. The wind turbine condition monitoring method of claim 13 , further comprising: determining a respective transmission region outside the respective shadowing areas such that only one blade sensor of the plurality of blade sensors is in the respective transmission region at a time; configuring each one of the plurality of blade sensors to only transmit when within the respective transmission region; and receiving blade sensor readings at the controller from each one of the plurality of blade sensors when each one of the plurality of blade sensors is within the respective transmission region. 16. The wind turbine condition monitoring method of claim 13 , wherein each of the plurality of blade sensors includes a multi-axis accelerometer. 17. The wind turbine condition monitoring method of claim 14 , further comprising: determining a respective transmission region within the respective favorable communication regions such that only one blade sensor of the plurality of blade sensors is in the respective transmission region at a time; configuring each one of the plurality of blade sensors to only transmit when w