Smart power management during voltage dip in wind turbines

What is claimed is: 1. A method of reducing mechanical load in a wind turbine when facing a grid voltage dip, the wind turbine having a drive train, a converter control unit, and a wind turbine generator controller, the method comprising: receiving an indication signal by the wind turbine generator controller from the converter control unit, the indication signal indicating a voltage dip in the wind turbine; commanding to move the pitch angle of the blade towards a feather position with a specific rate; delivering a maximum active power generation value by the converter control unit to the wind turbine generator controller after the grid recovers; setting a saturation value of the set points for the drive train to assure a correct Drive Train Damper action application, the saturation value set by the converter control unit depending on the maximum active power generation value; ramping up the power or torque set points with different rates according to the Drive Train Damper action to come up with a ramped value of the power taking into account network operators settling time restrictions; applying a first order filter to the ramped value of the power to reduce the torque overshoot; and applying the drive train damper torque command to the ramped value of the power in order to reduce the mechanical load in the wind turbine and to damp the oscillation in the wind turbine generator. 2. The method of claim 1 , wherein the specific rate of the pitch movement is calculated to avoid generator overspeed taking into account remaining transmitted torque T t (aerodynamic torque). 3. The method of claim 1 , wherein remaining aerodynamic torque during any moment of the voltage dip is calculated by an algorithm that uses as parameters an initial aerodynamic torque and a derivative of torque with respect to the pitch angle. 4. The method of claim 1 , wherein a maximum saturation active power or torque value is set as subtraction of the maximum active power generation value sent by the converter control unit and a variable offset to ensure the correct DTD Drive Train Damper torque reference application. 5. The method of claim 1 , wherein the wind turbine generator is a doubly fed induction generator. 6. The method of claim 1 , wherein the wind turbine generator uses a full converter technology in which the drive train is affected by voltage dips. 7. The method of claim 1 , wherein the method is used during the voltage dip and after the voltage dip is cleared. 8. The method of claim 1 , further comprising a step of deactivating the method. 9. The method of claim 1 , wherein the maximum active power generation value is calculated as a value of maximum active current generation by the converter multiplied by the grid voltage. 10. A method of smart power management during a voltage dip in a wind turbine, the method comprising: receiving by the wind turbine generator controller receives an indication signal from the converter control unit, the indication signal indicating a voltage dip in the wind turbine; delivering a maximum active power generation value by the converter control unit to the wind turbine generator controller; commanding to move the pitch angle of the blades towards a feather position with a specific rate; delivering a maximum active power generation value by the converter control unit to the wind turbine generator controller after the grid recovers; setting a saturation value of the set points for the drive train to assure a correct Drive Train Damper action application, the saturation value set by the converter control unit depending on the maximum active power generation value; ramping up the power or torque set points with different rates according to the Drive Train Damper action to come up with a ramped value of the power taking into account network operators settling time restrictions; applying a first order filter to the ramped value of the power to soften e reduce the torque overshoot; and applying the drive train damper torque command to the ramped value of the power in order to reduce the mechanical load in the wind turbine and to damp the oscillation in the wind turbine generator.