Abstract: A wind turbine tower for mounting tower internals is disclosed. The wind turbine tower may include a plurality of tower sections and each of the tower sections may comprise a plurality of cans axially joined together, the plurality of cans including a top can and a bottom can and intermediate cans. Each wind turbine tower section may further include a top flange attached to the top can and a bottom flange attached to the bottom can. Brackets for supporting the tower internals are welded to the inside wall of each tower section, but the welded brackets are restricted to only the top one or two cans, and the bottom one or two cans, while a the remainder of the intermediate cans do not have any brackets welded thereto. The intermediate cans without any welded brackets may be fabricated of steel plate that is less thick, and therefore less costly.

Abstract: A direct drive wind turbine and an electric generator for the wind turbine are disclosed. The generator may include a stator, a rotor spaced apart from the stator and a main shaft defining an axis of rotation, the main shaft at least indirectly connected to the generator rotor. The generator may also include a bearing assembly supporting the main shaft and defining a center of deflection on the axis of rotation. The generator may further include a convexly profiled air gap defined between the stator and the rotor, the air gap having a maximum width in regions of maximum deflection and a minimum width in regions of minimum deflection, the regions of maximum and minimum deflection determined with respect to the center of deflection.

Abstract: A method of damping harmonic output of an inverter is provided. The method may receive output phase signals from sensors disposed at an output of the inverter and on an associated electrical grid, filter the output phase signals using a low pass filter configured to extract a fundamental component from the output phase signals, isolate harmonics from the output phase signals based on the extracted fundamental component, and subtract the harmonics from the output phase signals.

Abstract: A power supply system having a spot network is disclosed. The spot network may include first and second power output lines, and first and second accessory power circuits connected in parallel to the first and the second power output lines, respectively. Each of the first and the second accessory power circuits may have a transformer and a circuit breaker connected together to protect the spot network by coordinating impedance of the transformer with trip characteristics of the circuit breaker.

Abstract: A flexible pin for a helical gear system. A countering realignment equal and opposite to the misalignment caused by the overturning moment and other gear forces is created without adding components or wearing surfaces. On the pin elements, one or more different or varying cross sections with the principal axes of their sections non-vertically orientated utilize the tangential and radial forces to cause deflections in two planes to perfectly compensate for misalignment caused by helical gear forces, thus keeping the mesh aligned the same as when using spur gears and traditional flexpins.

Abstract: A method for mitigating loads on a wind turbine in yaw error events is disclosed. The method may include determining a yaw error and a speed of the wind turbine and determining a magnitude of de-rating of the wind turbine based upon magnitudes of the yaw error and the speed. The method may further include reducing power output of the wind turbine based upon the magnitude of de-rating.

Abstract: A method for locking a rotor of a wind turbine in a long term parking state is disclosed. The method may include applying rotor brakes, enabling a long term parking configuration of the rotor and providing an emergency feather response for protecting the wind turbine against faults.

Abstract: A wind turbine includes a wind turbine tower and a power electronic control system located within the wind turbine tower. The power electronic control system includes heat generating components. The heat generating components are directly mounted to the inner surface of the wind turbine tower dissipating the heat generated by the heat generating components directly to the inner surface of the wind turbine tower. In this way, a good thermal conducting path to the entire wind turbine tower is provided. A method for conducting heat generated in electronic equipment housed within a wind turbine tower uses the tower as a heat sink for cooling purposes.

Abstract: A service crane for a wind turbine comprising a main crane beam (128) having a track (154) that accommodates a trolley (156). A hinge (144) is provided at a pivot point (148) near a proximate end of the main beam (128), such that an aft portion of the main beam (128) extends beyond the pivot point (148) to the exterior of the turbine. A distal end of the main beam (128) rests upon a forward beam. A lateral motion actuator (134) moves the main beam (128) back and forth along the forward beam. The trolley (156) runs back and forth along the main beam (128). A turbine component is attached to a hook lowered by cable from the trolley (156). The trolley (156) with the component on the hook is moved to the aft portion of the main beam (128), which extends beyond the turbine. The hook is lowered to the ground so that the component can be serviced or replaced.

Abstract: A generator housed in a wind turbine nacelle includes a generator rotor that is mounted to gearbox output pinions, thereby eliminating the need for couplings. The generator frame is located directly on the gearbox and is located to control the air gap. To facilitate removal of the generator, tapers are used that have steep angles that exceed the friction coefficient of the materials used. To provide adequate support over its length, the shaft employs dual tapers, each short and precisely located conical surface of which provides exact location on the near and far sides of the shaft. The length of straight shaft between the dual locating tapers serves to support the generator during mounting and de-mounting. During installation, the tapers center the rotor and bullet pins center the frame (stator). When the system aligns the rotor and stator, retainer elements act as labyrinth seals designed to protect the generator interior from contamination.