Method for starting a wind turbine in a cold climate environment

The invention claimed is: 1. A method of starting a wind turbine in a cold climate environment from a stand-still or near stand-still condition, the wind turbine having a tower, a rotor with at least one blade, a generator for producing electrical power, and a gear box having a main shaft operatively coupled to the rotor and a high speed shaft operatively coupled to the generator, the wind turbine being configured to be operatively connected to an electrical grid, the method comprising: performing a start up period, wherein the rotation speed of the rotor is controlled to increase and wherein the wind turbine is not delivering any electrical power to the electrical grid during the start up period; providing heat generation within the gear box by increasing the rotation speed until the gear box has reached a threshold temperature; and delivering electrical power generated using the wind turbine to the electrical grid when the temperature of the gear box reaches the threshold temperature. 2. The method according to claim 1 , wherein heat generation within the gear box comprises maximizing internal power losses in the gear box. 3. The method according to claim 2 , wherein controlling the rotation speed of the rotor so as to maximize the internal power losses in the gear box further comprises controlling the rotation speed of the rotor according to a substantially linear relationship between a rotation speed of the high speed shaft and the gear box temperature. 4. The method according to claim 3 , further comprising controlling the rotation speed in a first region of the start up according to a substantially linear relationship between the rotation speed of the high speed shaft and the gear box temperature characterized by a first slope, and controlling the rotation speed in a second region of the start up according to a substantially linear relationship between the rotation speed of the high speed shaft and the gear box temperature characterized by a second slope, wherein the first and second slopes are different from each other. 5. The method according to claim 3 , wherein controlling the rotation speed of the rotor according to the substantially linear relationship between the rotation speed of the high speed shaft and the gear box temperature terminates when the gear box reaches a first threshold temperature. 6. The method according to claim 5 , wherein the rotation speed of the high speed shaft is greater than about 60% of a nominal operating speed of the high speed shaft when the temperature of the gear box reaches the first threshold temperature. 7. The method according to claim 5 , further comprising increasing the rotation speed of the high speed shaft up to a nominal operating speed when the temperature of the gear box reaches the first threshold temperature. 8. The method according claim 5 , wherein the power production of the wind turbine is increased up to a nominal power output when the temperature of the gear box reaches the first threshold temperature. 9. The method according to claim 1 , further comprising reducing the internal power losses in the gear box after delivery of electrical power to the electrical grid has begun. 10. The method according to claim 1 , wherein the heat generation in the gear box is achieved using only the energy resulting from the rotation of the rotor. 11. The method according to claim 1 , wherein the heat generation in the gear box is achieved without the use of external heaters. 12. A method of starting a wind turbine in a cold climate environment, comprising: providing a wind turbine in a cold climate environment in a stand-still or near stand-still condition, the wind turbine having a tower, a rotor with at least one blade, a generator for producing electrical power, and a gear box having a main shaft operatively coupled to the rotor and a high speed shaft operatively coupled to the generator, the wind turbine configured to be operatively connected to an electrical grid; allowing the rotation speed of the rotor to increase during start up of the wind turbine; with the rotor turning and prior to the wind turbine providing electrical power to the electrical grid, increasing the temperature of the gear box up to a first threshold temperature without the use of external heaters; and generating electrical power using the wind turbine after the temperature of the gear box has reached the first threshold temperature. 13. The method according to claim 12 , further comprising maximizing the internal power losses in the gear box so as to increase the temperature of the gear box up to the first threshold temperature. 14. The method according to claim 13 , wherein maximizing the internal power losses in the gear box further comprises controlling the speed of the rotor according to a substantially linear relationship between a rotation speed of the high speed shaft and the gear box temperature. 15. The method according to claim 12 , further comprising reducing the internal power losses in the gear box after the temperature of the gear box reaches the first threshold temperature. 16. A method of operating a wind turbine in a cold climate environment in a fully operating state, the wind turbine having a tower, a rotor with at least one blade, a generator for producing electrical power, and a gear box having a main shaft operatively coupled to the rotor and a high speed shaft operatively coupled to the generator, the wind turbine providing electrical power to an electrical grid when in the fully operating state, the method comprising: interrupting the supply of electrical power from the wind turbine to the electrical grid during a period of low wind conditions; providing heat generation within the gear box during the period of low wind conditions by controlling the rotation speed of the rotor above a minimal rotation speed of the rotor; and reestablishing the supply of electrical power from the wind turbine to the electrical grid once the period of low wind conditions has terminated. 17. The method according to claim 16 , wherein the supply of electrical power from the wind turbine to the electrical grid is reestablished without executing a start up sequence for the wind turbine.