A kinetic energy harvesting mechanism has a fixing shaft, a rotating shell, an input member, and a fixing shaft driving assembly. The rotating shell is disposed on the fixing shaft. The input member is axially connected to the fixing shaft. The fixing shaft driving assembly is disposed in the rotating shell and has a first one-way bearing, a second one-way bearing, a first driving member, a second driving member, and a third driving member. Unidirectional transmission functions of the first one-way bearing and the second one-way bearing are adverse to each other. The first driving member is disposed in the rotating shell by the first one-way bearing. The second driving member is disposed in the rotating shell by the second one-way bearing. The third driving member is disposed in the rotating shell and is connected to the first driving member and the second driving member.

A sensor is used in measuring the torque applied to a slew drive. The slew drive includes a worm gear and a worm wheel and the sensor is coupled with a securing device that is used to secure the worm gear to the slew drive housing. The sensor generates a signal which is indicative of the torque on the worm wheel. The worm gear is secured to the slew drive housing by a first bearing and a second bearing. Two end plates and eight bolts are also used to further secure the worm gear and the bearings to the slew drive housing. By tightening the bolts, a compressive force is applied on the worm gear through the bearings. The applied torque on the worm wheel causes an axial force on the worm gear. The axial force is transmitted through the worm gear, the bearings, the end plates, and the bolts. One or more sensors can be embedded in one or more of the end plates or the bolts to measure the strain, in the end plates or the bolts, due to the axial force. A control device receives the signal from the sensor and stores, analyses, and/or communicates the signal.

A planet wheel assembly includes a planet shaft, a planet wheel having radial contact surfaces and axial contact surfaces, bushings connected to the planet shaft, radial sliding elements between radial contact surfaces of the bushings and the radial contact surfaces of the planet wheel, and axial sliding elements between axial contact surfaces of the bushings and the axial contact surfaces of the planet wheel. The planet wheel is shaped to constitute a circumferential projection which protrudes radially towards the planet shaft, is axially between the radial sliding elements, and forms the first and second axial contact surfaces of the planet wheel. This arrangement, where the radial sliding elements are axially outmost and the axial sliding elements are on the middle, improves the ability of the radial sliding elements to act against forces tilting the planet wheel.

A mounting of an intermediate shaft of a gearbox includes a gear element disposed between a first shaft end and a second shaft end of the intermediate shaft. A first radial bearing is disposed at the first shaft end of the intermediate shaft, a second radial bearing is disposed at the second shaft end of the intermediate shaft, a first axial bearing is disposed at the first shaft end of the intermediate shaft, and a second axial bearing is disposed at the second shaft end of the intermediate shaft.

A method of replacing components of a gearbox and a gearbox of the wind power plant for a wind turbine includes a gearbox with a sun gear couplable to a rotor of a wind power plant. The sun gear is arranged rotatably about a rotor axis. The gearbox has a plurality of satellite units and a plurality of generators. Each satellite unit has two gear shafts and one output shaft. The two gear shafts are respectively in engagement with the sun gear and the output shaft. Each generator is associated with one of the plurality of satellite units. The plurality of satellite units are arranged and distributed over a periphery of the sun gear and are operatively connected with the sun gear. The plurality of satellite units have a modular configuration design and are releasably arranged at the sun gear.

This assembly (400) has a housing (402) for high speed components and a collar (404) located at the output end of the housing and extending radially inward from an outer surface of the housing (402), where the collar retains lubricant (406) in the gearbox when the gearbox is stationary. The collar includes a gap (502), such that one or more of the high speed components can pass through the gap in the collar and such that components offset from the central axis of the gearbox are not impeded by the collar. The high speed components include a high speed shaft (408) and a mechanical pump (410), both of which are offset from the central axis of the gearbox. The housing comprises a cover (410) having one or more holes (510) such that one or more of the high speed components can pass through the gap in the collar.

An assembly includes a first planetary stage, a second planetary stage, and at least one retainer plate. The first planetary stage has a planet carrier and the second planetary stage has a ring gear. The planet carrier and the ring gear are configured to be rotated about a common axis of rotation. The retainer plate is attached to the ring gear and engages in a groove in the planet carrier. The groove and the axis of rotation are at least partially skewed to each other. The retainer plate is arranged at least partially on a first side of a first plane and on a first side of a second plane. The first plane and the second plane intersect along the axis of rotation. All planet bolts fixed in the planet carrier each lie on a second side of the first plane and/or the second plane.

A wind turbine is provided. The wind turbine comprises a blade; a shaft which rotates in response to the rotation of said blade; a generator; and a star compound gear train disposed between said shaft and said generator.

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), and pumping 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 wind turbine transmission including a first planetary stage and a second planetary stage, wherein a sun gear of the first planetary stage and a planet carrier of the second planetary stage are interconnected for conjoint rotation by means of a spline joint, the sun gear integrally forms an internal toothing, and a first web of the planet carrier or a sun shaft integrally connected to the first web integrally forms an external toothing of the spline joint.