A slide bearing pad for a slide bearing arrangement has a bearing surface. On a first circumferential face of the slide bearing pad, a lubricating oil transport groove is configured in the region of the bearing surface. The lubricating oil transport groove may have a radial groove depth and a circumferential groove depth between 10% and 300% of the radial groove depth.

A slide bearing arrangement includes an inner ring element, an outer ring element, and at least one slide bearing element, which is arranged between the inner ring element and the outer ring element. The slide bearing element includes at least two slide bearing pads, wherein the individual slide bearing pads each have a bearing surface that is cambered, viewed in an axial direction, and wherein an apex of the bearing surface has the largest diameter of the bearing surface.

A method of lubricating a main bearing of a wind turbine, the method comprising providing the main bearing. The main bearing comprises a main bearing housing having one or more pre-existing lubrication ports, an outer race, an inner race radially disposed inwardly from the outer race, and a first row of roller bearings and a second row of roller bearings. The first and second rows of roller bearings are radially disposed between the inner race and the outer race. The first row of roller bearings is axially disposed on the upwind side of the second row of roller bearings. The method includes forming one or more alternate lubrication ports in the main bearing housing. The alternate lubrication ports are configured to deliver a lubricant between the first row of roller bearings and the second row of roller bearings. The method includes supplying the lubricant to the alternate lubrication ports.

A union having a rotor shaft having first and second portions, wherein two channels are formed in the second portion of the shaft, and a housing that includes a central bore that extends between the two channels. Two needle roller bearings are disposed, one each, within each of the two channels to rotatably support the rotor shaft within the housing.

A main rotor arrangement for a wind turbine, comprising a shaft which is rotatable within a shaft housing about a rotational axis, a bearing including an inner ring, an outer ring, and a plurality of rolling elements, wherein the bearing is located between the shaft and the housing thereby to enable the shaft to rotate within the shaft housing. The shaft housing includes a first lubrication passage for carrying lubricating fluid through the shaft housing, wherein the outer ring of the bearing includes a second lubricating passage to direct lubricating fluid from the first lubricating passage in the direction of the plurality of rolling elements. The invention provides a space efficient arrangement which avoids the need to fluid delivery nozzles arranged externally to the bearing to direct fluid at the rolling elements, as in the prior art. The arrangement also means that lubrication fluid is delivered right to where it is needed in a more efficient way than in the prior art.

A sealing arrangement of a wind turbine is provided including an axial seal, a stationary member and a generator rotor for sealing a gap between the stationary member and the generator rotor. Accordingly, the stationary member is arranged between a lubricant chamber and an air chamber and the generator rotor is configured to rotate about a rotational axis, wherein the seal is arranged at an end of the stationary member. The seal includes a first lip configured to contact the generator rotor and the first lip is configured to allow a leakage of lubricant at the contact between the first lip and the generator rotor. The seal further includes a second lip arranged radially outwards with respect of the first lip and the rotational axis.

A bearing arrangement for a wind turbine includes a bearing and a bearing housing. The bearing housing defines an interior space wherein the bearing is arranged. The bearing housing includes a drain opening for draining lubricant from the interior space. A chamber includes a fluidic connection with the drain opening and a damping space is formed inside the chamber to throttle a lubricant flow out of the interior space.

A wind turbine planet gear shaft has a shaft body with an outer surface, a segment of the outer surface being a slide bearing surface configured to form a radial slide bearing with an inner opening of a planet gear. The slide bearing surface has a first portion configured as a non-load-bearing zone and a second portion configured as a load-bearing zone and exactly one axially elongate oil pocket in the slide bearing surface, that oil pocket being located in the non-load-bearing zone. An oil supply channel in the shaft body has a first end in communication with the oil pocket, and first and second oil return channels in the slide bearing surface each have a first end at a longitudinal end of the oil pocket and a second end open to ambient air.

A sealing arrangement of a wind turbine is provided including an axial seal, a stationary member and a generator rotor for sealing a gap between the stationary member and the generator rotor. Accordingly, the stationary member is arranged between a lubricant chamber and an air chamber and the generator rotor is configured to rotate about a rotational axis, wherein the seal is arranged at an end of the stationary member. The seal includes a first lip configured to contact the generator rotor and the first lip is configured to allow a leakage of lubricant at the contact between the first lip and the generator rotor. The seal further includes a second lip arranged radially outwards with respect of the first lip and the rotational axis.

A slide bearing pad for a slide bearing arrangement has a bearing surface. On a first circumferential face of the slide bearing pad, a lubricating oil transport groove is configured in the region of the bearing surface. The lubricating oil transport groove may have a radial groove depth and a circumferential groove depth between 10% and 300% of the radial groove depth.