Disclosed is a method for dismantling a wind turbine gearbox (15) from a main shaft (7) in the nacelle (3) of a wind turbine (1), wherein a first end (11) of the main shaft (7) is connected to the gearbox (15) in a connection cavity (22) of the gearbox (15) and a second end (12) of the main shaft (7) is connected to a rotor (4) of the wind turbine (1). The method comprises the steps of: arranging a hydraulic connection plug (13) in a centre channel (14) of a second end (37) of a gearbox shaft (21) of the gearbox (15), wherein a first end (20) of the gearbox shaft (21) is arranged at the connection cavity (22) on a first side (23) of the gearbox (15) and wherein the second end (37) of the gearbox shaft (21) is arranged at a second side (24) of the gearbox (15) opposite the first side (23), securing the hydraulic connection plug (13) and the gearbox shaft (21) against axial displacement in a direction towards the second side (24) of the gearbox (15), connecting a hydraulic pump (25) to the hydraulic connection plug (13), andpumping liquid into the connection cavity (22) by means of the hydraulic pump (25) to force the main shaft (7) out of the connection cavity (22). Furthermore, use of the method is disclosed.

A repair method for a gearbox assembly for a wind turbine is disclosed. The gearbox includes a gearbox housing having an upwind end and a downwind end, a gear assembly configured within the gearbox housing, at least one shaft configured with the gear assembly and extending from the gearbox housing to a generator of the wind turbine, and a sleeve assembly configured with the gearbox housing. Further, the sleeve assembly is removable so as to provide additional space in the gearbox housing during at least one of disassembly or assembly of the gearbox assembly such that the various components can be easily repaired and/or replaced.

A wind turbine gear box arrangement having one or more bearings located in a single region along the longitudinal axis and arranged to provide support between an input shaft and a non-rotating support component. The one or more bearings are arranged to at least partially restrict non-rotational movement between the input shaft and the non-rotating support component. A portion along the longitudinal axis between said input shaft and the non-rotating support component is bearingless outside the single region.

Systems and methods in accordance with embodiments of the invention efficaciously implement robust gearbox housings. In one embodiment, a method of fabricating a gearbox housing includes: providing an alloy composition from which the gearbox housing will be fabricated from; casting the alloy composition around a solid body so as to form a part characterized by the inclusion of a cavity, where the cast part includes a metallic glass-based material; and nondestructively separating the cast part from the solid body.

A rotor lock assembly for locking a rotor of a wind turbine. The rotor lock assembly has at least one relocatable rotor lock. The relocatable rotor lock has a housing, a bushing element, a pin shaft position within the bushing element, and a locking mechanism. The housing includes a mounting portion adapted for mounting to a bearing housing adjacent to a rotor lock plate of the rotor.

A drive train for a wind tunnel having a nacelle housing with a fan and a fan hub assembly. The drive train comprises: a ratio gear box directly connected to the fan; and a motor disposed remote from the nacelle for powering the fan via a jackshaft and the ratio gearbox. In an embodiment, the wind tunnel has a single fan and single hub assembly. The jackshaft operatively connects the motor and gearbox.

A modular gearbox assembly for a wind turbine having improved up-tower serviceability includes a low-speed gear stage module, a separate, intermediate-speed gear stage module adjacent to the low-speed gear stage module, and a separate high-speed gear stage module adjacent to the intermediate-speed gear stage module. The gearbox assembly also includes a first flange removably connecting the intermediate and high-speed gear stage modules and a second flange removably connecting the intermediate and low-speed gear stage modules. Thus, the low-speed gear stage module converts a low-speed, high torque input from a rotor shaft of the wind turbine to a high-speed, low torque output for a generator of the wind turbine via the intermediate and high-speed gear stage modules. In addition, the first and second flanges allow for easy disassembly of the gear stage modules such that the various stages can be easily repaired, replaced, and/or inspected.

A bell housing includes a first region configured to be secured in a nacelle of a wind turbine, a second region configured to receive a gear mechanism, and a wall connecting the first region and the second region together. The wall is provided with at least two recesses.

A housing component includes a flange defining a center point and having an end face formed with microstructures in a first region and a second region to increase a local friction coefficient. The microstructures have each a blade shape with a cutting line, the cutting line in the first region being arranged concentrically about a first local center point, and the cutting line in the second region being arranged concentrically about a second local center point. The first and second local center points have different radial distances from the center point of the flange.

Provided is a rotor blade hub for a wind turbine. The rotor blade hub includes a connecting portion for torque-transmitting coupling of the rotor blade hub to a main shaft of the wind turbine. The rotor blade hub has a single-stage transmission which is non-rotatably mounted to the rotor blade hub at the drive input side and has the connecting portion at the drive output side.