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A method for controlling a two-bladed pitchable swept-blade wind turbine in extreme wind conditions is described, wherein when extreme conditions are detected or forecast for the wind turbine, the wind turbine blades are pitched such that they will passively align in a substantially horizontal arran

A method for controlling a two-bladed pitchable swept-blade wind turbine in extreme wind conditions is described, wherein when extreme conditions are detected or forecast for the wind turbine, the wind turbine blades are pitched such that they will passively align in a substantially horizontal arrangement. The blades can be yawed such that a tip of one of the wind turbine blades points into the wind direction, resulting in a reduced surface area of the blades exposed to the extreme wind forces. This reduced surface area provides for a reduction in the extreme loads which may be experienced by the wind turbine in such extreme wind conditions.

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1. A method for reducing extreme wind loads in a pitchable two-bladed wind turbine during extreme wind conditions, the wind turbine having a pair of wind turbine blades of at least 35 meters length, wherein the tip ends of the pair of wind turbine blades are swept relative to a central axis of the p

1. A method for reducing extreme wind loads in a pitchable two-bladed wind turbine during extreme wind conditions, the wind turbine having a pair of wind turbine blades of at least 35 meters length, wherein the tip ends of the pair of wind turbine blades are swept relative to a central axis of the pair of wind turbine blades, the method comprising the steps of: pitching the pair of wind turbine blades such that the swept tip ends, which swept tip ends have a swept profile that extends along a central axis of each of the pair of wind turbine blades, point in substantially the same direction along a rotational path of the pair of wind turbine blades, and, when pitching each of the pair of wind turbine blades to a pitch angle, the pair of wind turbine blades provide a combined aerodynamic profile, the combined aerodynamic profile acting to passively rotate the pair of wind turbine blades into a substantially horizontal alignment; andaligning the substantially horizontal wind turbine blades such the pair of wind turbine blades are longitudinally aligned with a direction of a wind at the wind turbine to reduce the extreme wind loads experienced by the pair of wind turbine and stabilizing the pair of wind turbine blades in a substantially horizontal arrangement. 2. The method of claim 1, wherein the step of pitching comprises pitching said pair of wind turbine blades such that the swept tip ends have a pitch angle of approximately 90 degrees. 3. The method of claim 1, wherein a first of said pair of wind turbine blades has a first swept tip end and a second of said pair of wind turbine blades has a second swept tip end, and wherein the step of pitching comprises pitching said first wind turbine blade such that said first swept tip end has a pitch angle of approximately 85-95 degrees and pitching said second wind turbine blade such that said second swept tip end has a pitch angle of approximately 45-85 degrees. 4. The method of claim 1, wherein the method comprises the steps of: pitching said pair of wind turbine blades such that said swept tip ends of said pair of wind turbine blades have a pitch angle of approximately 85-95 degrees to passively align the wind turbine blades in said substantially horizontal alignment; andwhen said pair of wind turbine blades are substantially horizontally aligned, pitching one of said wind turbine blades such that the tip end of said one of said wind turbine blades has a pitch angle of between approximately 45-85 degrees. 5. The method of claim 3, wherein said step of pitching is performed such that the second wind turbine blade which is pitched to a pitch angle of between approximately 45-85 degrees is one of the pair of wind turbine blades which points into the direction of the wind at the wind turbine. 6. The method of claim 4, wherein said step of pitching is performed such that the one of the pair of wind turbine blades which is pitched to a pitch angle of between approximately 45-85 degrees is one of the pair of wind turbine blade which points into the direction of the wind at the wind turbine. 7. The method of claim 1, wherein each of the pair of wind turbine blades forms a substantially concave pressure side and a substantially convex suction side along the central axis thereof, and wherein the method comprises: pitching at least a portion of said pair of wind turbine blades such that at least a portion of said concave pressure sides face in substantially the same direction along the rotational path of the pair of wind turbine blades, such that the drag forces produced by the concave pressure side of a first of said wind turbine blades and the convex suction side of a second of said wind turbine blades will substantially balance with the drag forces produced by the convex suction side of the first wind turbine blade and the concave pressure side of the second wind turbine blade to provide said stabilization of the pair of wind turbine blades in the substantially horizontal arrangement. 8. The method of claim 7, wherein the method comprises the step of increasing the drag of the pitched concave pressure sides of the pair of wind turbine blades. 9. The method of claim 1, wherein the method comprises the steps of: in the event of an extreme wind condition, pitching the pair of wind turbine blades such that the swept tip ends of the pair of wind turbine blades point in substantially the same direction along the rotational path of the pair of wind turbine blades, and aligning said pair of wind turbine blades such that the rotational path of the pair of wind turbine blades is in line with the pair of wind direction at the pair of wind turbine, such that the pitched swept tip ends act to align the pair of wind turbine blades in a substantially horizontal position; andwhen in a substantially horizontal position, pitching the pair of wind turbine blades such that the swept tip ends of the pair of wind turbine blades point in a substantially downwards direction, to lower the center of mass of the pair of wind turbine blades and to resist the rotation of the pair of wind turbine blades from said substantially horizontal position. 10. The method of claim 1, wherein the wind turbine comprises a tower, a nacelle located at the top of said tower, a rotor hub rotatably mounted at said nacelle, a generator coupled to said rotor hub via a shaft, the pair of wind turbine blades of at least 35 meters length provided on said rotor hub, and a yaw system coupled to said nacelle, and wherein said step of aligning the substantially horizontal pair of wind turbine blades comprises actively yawing said nacelle and said rotor hub by actuating said yaw system. 11. The method of claim 1, wherein the pair of wind turbine blades comprise a partial pitch blade having an inner blade section and an outer blade section, and wherein said step of pitching comprises pitching said outer blade section relative to said inner blade section. 12. A wind turbine comprising a tower,a nacelle located at the top of said tower,a rotor hub rotatably mounted at said nacelle,a generator coupled to said rotor hub via a shaft, andfirst and second wind turbine blades of a length of at least 35 meters provided on said rotor hub, where tip ends of the first and second wind turbine blades are swept relative to a central axis of said first and second wind turbine blades so as each of the first and second wind turbine blades forms a substantially concave pressure side and a substantially convex suction side along the central axis thereof, wherein the first and second wind turbine further comprises a controller configured to pitch the first and second wind turbine blades to a pitch angle such that the swept tip ends of the first and second wind turbine blades point in substantially the same direction along a rotational path of the first and second wind turbine blades, wherein the first and second wind turbine blades provide a combined aerodynamic profile configured to passively rotate the first and second wind turbine blades into a substantially horizontal alignment and stabilizing the first and second wind turbine blades in a substantially horizontal arrangement and wherein the controller is further configured to longitudinally align the substantially horizontal first and second wind turbine blades with the wind direction to reduce extreme wind loads experienced by the wind turbine blades.