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A method of operating a wind turbine system includes: determining, by an industrial process controller, if an actual wind speed value, received from an anemometer, of a wind at a location of the wind turbine system is less than a predetermined minimum wind speed value. If so, then calculating a comm

A method of operating a wind turbine system includes: determining, by an industrial process controller, if an actual wind speed value, received from an anemometer, of a wind at a location of the wind turbine system is less than a predetermined minimum wind speed value. If so, then calculating a command speed value that will cause a variable-speed drive to drive the motor/generator and a sail assembly at a speed that the sail assembly would turn if the actual wind speed value was the minimum wind speed value, such that the sail assembly turns and provides a visual effect. If not, then calculating a command speed value based on the actual wind speed value such that the variable-speed drive and the motor/generator will operate in a braking mode to recover a braking energy of a load of the wind on the sail assembly.

대표청구항 ▼

1. A method of operating a wind turbine system comprising: determining, by an industrial process controller, if an actual wind speed value, received from an anemometer, of a wind at a location of the wind turbine system is less than a predetermined minimum wind speed value; if so, then calculating a

1. A method of operating a wind turbine system comprising: determining, by an industrial process controller, if an actual wind speed value, received from an anemometer, of a wind at a location of the wind turbine system is less than a predetermined minimum wind speed value; if so, then calculating a command speed value that will cause a variable-speed drive in communication with a motor/generator of the wind turbine system to drive the motor/generator and a sail assembly attached to the motor/generator at a speed that the sail assembly would turn if the actual wind speed value was the minimum wind speed value, such that the sail assembly turns and provides a visual effect; andif not, then calculating a command speed value based on the actual wind speed value such that the variable-speed drive and the motor/generator will operate in a braking mode to recover a braking energy of a load of the wind on the sail assembly; andsending the command speed value to the variable-speed drive. 2. The method of operating a wind turbine system of claim 1, wherein the step of calculating a command speed based on the actual wind speed value further comprises: defining a range of command speed values that will cause the motor/generator and sail assembly to turn at a range of speeds that cause harmonic frequencies in a structure supporting the motor/generator and the sail assembly; andif the calculated command speed value falls in the defined range, then setting the command speed value to a speed below the defined range. 3. The method of operating a wind turbine system of claim 1, further comprising: before determining if the actual wind speed value is less than the predetermined minimum wind speed value, determining, by the industrial process controller, that an ambient air temperature value, received from a thermometer, of air at the location of the wind turbine system is less than a predetermined snow accumulation air temperature value, and that the wind turbine system has been in a stand-by mode of no operation for more than a predetermined snow accumulation time period, then, sending a predetermined snow removal command speed value to the variable-speed drive to turn the sail assembly via the motor/generator;maintaining a speed of the motor/generator above a predetermined minimum snow removal speed for a predetermined minimum snow removal time; andsending a command speed value of zero to stop the motor/generator and the sail assembly. 4. The method of operating a wind turbine system of claim 1, wherein power produced by the motor/generator has a form of a variable frequency AC signal, the method further comprising: inputting the variable frequency AC signal into a rectifier to produce a rectified signal;inputting the rectified signal into an AC-to-DC converter to produce a DC signal;inputting the DC signal into an isolation transformer to produce a transformed DC signal having a voltage above zero volts; andinputting the transformed DC signal into a photo-voltaic inverter to produce an AC power signal that can be returned to a power system. 5. The method of operating a wind turbine system of claim 1, further comprising: before determining if the actual wind speed value is less than the predetermined minimum wind speed value, entering a stand-by mode of no operation;determining, by the industrial process controller, that there are no system fault or trip alarms for the wind turbine system;determining that the wind turbine system has been powered up for more than a predetermined startup time period;entering one of an economy mode or a continuous mode of operation;enabling the variable-speed drive and reading that the variable-speed drive is enabled;releasing a brake assembly applying a braking force on rotation of the sail assembly, and reading that the brake assembly is released;wherein the economy mode comprises, determining that an average wind speed value over a predetermined monitoring period exceeds a predetermined start value before enabling the variable-speed drive, andupon determining that the average wind speed value over the predetermined monitoring period is less than a predetermined stop value, overriding the calculated command speed value to stop rotation of the sail assembly, engaging the brake assembly, and reading that the brake assembly is engaged;wherein the continuous mode of operation comprises operating the wind turbine system until a request is received to go to the stand-by mode. 6. A method of operating a wind turbine system comprising: determining, by an industrial process controller, that an ambient air temperature value, received from a thermometer, of air at a location of the wind turbine system is less than a predetermined snow accumulation air temperature value, and that the wind turbine system has been in a stand-by mode of no operation for more than a predetermined snow accumulation time period, then sending a predetermined snow removal command speed value to a variable-speed drive in communication with a motor/generator of the wind turbine system to drive the motor/generator and a sail assembly attached to the motor/generator to turn the sail assembly via the motor/generator;maintaining a speed of the motor/generator above a predetermined minimum snow removal speed for a predetermined minimum snow removal time; andsending a command speed value of zero to stop the variable-speed drive to stop turning the sail assembly via the motor/generator. 7. The method of operating a wind turbine system of claim 6, further comprising: determining, by the industrial process controller, if an actual wind speed value, received from an anemometer, of a wind at the location of the wind turbine system is less than a predetermined minimum wind speed value, if so, then calculating a command speed value that will cause the variable-speed drive to drive the motor/generator and the sail assembly at a speed that the sail assembly would turn if the actual wind speed value was the minimum wind speed value, such that the sail assembly turns and provides a visual effect; andif not, then calculating a command speed value based on the actual wind speed value such that the variable-speed drive and the motor/generator will operate in a braking mode to recover a braking energy of a load of the wind on the sail assembly; andsending the command speed value to the variable-speed drive. 8. The method of operating a wind turbine system of claim 7, wherein the step of calculating a command speed based on the actual wind speed value further comprises: defining a range of command speed values that will cause the motor/generator and sail assembly to turn at a range of speeds that cause harmonic frequencies in a structure supporting the motor/generator and the sail assembly; andif the calculated command speed value falls in the defined range, then setting the command speed value to a speed below the defined range. 9. The method of operating a wind turbine system of claim 8, wherein power produced by the motor/generator has a form of a variable frequency AC signal, the method further comprising: inputting the variable frequency AC signal into a rectifier to produce a rectified signal;inputting the rectified signal into an AC-to-DC converter to produce a DC signal;inputting the DC signal into an isolation transformer to produce a transformed DC signal having a voltage above zero volts; andinputting the transformed DC signal into a photo-voltaic inverter to produce an AC power signal that can be returned to a power system. 10. A wind turbine system comprising: a motor/generator;a variable-speed drive operably connected to the motor/generator;a sail assembly mounted to a shaft, the shaft operably connected to the motor/generator;an anemometer for measuring an actual wind speed value of a wind at a location of the sail assembly;an industrial process controller including a data storage device, a processing device in communication with the data storage device, and an input/output (I/O) interface device in communication with the processing device, the variable-speed drive, and the anemometer, the data storage device including computer-readable instructions for execution by the processing device to cause the industrial process controller to determine if the actual wind speed value is less than a predetermined minimum wind speed value, if so, then to calculate a command speed value that will cause the variable-speed drive to drive the motor/generator and the sail assembly attached to the motor/generator at a speed that the sail assembly would turn if the actual wind speed value was the minimum wind speed value, such that the sail assembly turns and provides a visual effect, andif not, then to calculate a command speed value based on the actual wind speed value such that the variable-speed drive and the motor/generator will operate in a braking mode to recover a braking energy of a load of the wind on the sail assembly; andsend the command speed value to the variable-speed drive. 11. The wind turbine system of claim 10, wherein the computer-readable instructions include a range of command speed values that will cause the motor/generator and sail assembly to turn at a range of speeds that cause harmonic frequencies in a structure supporting the motor/generator and the sail assembly, wherein the computer-readable instructions cause the processing device to determine if the calculated command speed value falls in the defined range, and, if so, to set the command speed value to a speed below the defined range. 12. The wind turbine system of claim 10, further comprising: a thermometer for measuring a temperature value at the location of the sail assembly, the thermometer in communication with the I/O interface device; andcomputer-readable instructions for execution by the processing device to cause the industrial process controller to before determining if the actual wind speed value is less than the predetermined minimum wind speed value, determine that an ambient air temperature value, received from the thermometer is less than a predetermined snow accumulation air temperature value, and that the wind turbine system has been in a stand-by mode of no operation for more than a predetermined snow accumulation time period;send a predetermined snow removal command speed value to the variable-speed drive to turn the sail assembly via the motor/generator;maintain a speed of the motor/generator above a predetermined minimum snow removal speed for a predetermined minimum snow removal time; andsend a command speed value of zero to stop the motor/generator and the sail assembly. 13. The wind turbine system of claim 10, further comprising: a rectifier for receiving a generated variable frequency AC signal produced by the motor/generator, and producing a rectified signal;an AC-to-DC converter receiving the rectified signal and producing a DC signal;an isolation transformer receiving the DC signal and producing a transformed DC signal having a voltage above zero volts; anda photo-voltaic inverter receiving the transformed DC signal and producing an AC power signal that can be returned to a power system. 14. The wind turbine system of claim 10, further comprising: a brake assembly applying a braking force on rotation of the sail assembly;computer-readable instructions for execution by the processing device to cause the industrial process controller to before determining if the actual wind speed value is less than the predetermined minimum wind speed value, enter a stand-by mode of no operation,determine that there are no system fault or trip alarms for the wind turbine system,determine that the wind turbine system has been powered up for more than a predetermined startup time period,enter one of an economy mode or a continuous mode of operation,enable the variable-speed drive and read that the variable-speed drive is enabled,release the brake assembly, and read that the brake assembly is released;when in the economy mode, the computer-readable instructions cause the industrial process controller to determine that an average wind speed value over a predetermined monitoring period exceeds a predetermined start value before enabling the variable-speed drive, andupon determining that the average wind speed value over the predetermined monitoring period is less than a predetermined stop value, override the calculated command speed value to stop rotation of the sail assembly, engage the brake assembly, and read that the brake assembly is engaged; andwhen in the continuous mode, the computer-readable instructions cause the industrial process controller to operate the wind turbine system until a request is received to go to the stand-by mode.