A silk hat-type strain wave gear device has a crossed roller bearing for supporting an internal gear and an external gear so as to allow relative rotation. A first gap part between the inner and outer rings of said bearing is sealed by an oil seal and a second gap part thereof is in communication with a gear-side gap part on the outside of the external gear. A bearing seal separates the second gap part from the gear-side gap part. The bearing seal prevents excessive inflow of lubricant from the gear-side gap part into the second gap part. Excess lubricant that has flowed into the bearing can flow back from the second gap part to the gear-side gap part. Excess lubricant in the bearing is prevented from leaking through the oil seal to the outside.

An arrangement for mounting an output shaft (1) designed as a spider shaft of the planetary gear set of a transmission includes an axial needle bearing (6) arranged between an output-side spider plate (4) of the output shaft (1) and a housing (5) of the transmission, a radial needle bearing (7) for the radial mounting of the output shaft (1) in the housing (5), a thrust washer (8) attached to the output shaft (1) with the aid of a snap ring (9), and a shaft sealing ring (10) arranged on the side of the thrust washer (8) facing the output, into the interior space of which the thrust washer (8) and the snap ring (9) for attaching the thrust washer (8) extend.

A cup-shaped strain wave gearing has an externally toothed gear formed with a cylindrical extension portion extending from an end of an external tooth forming portion of the externally toothed gear. A space between the external peripheral surface of the cylindrical extension portion and an end face of an internally toothed gear is sealed by an oil seal. A space between an outer-side lubrication portion on the outer side of the externally toothed gear and an inner-side lubrication portion on the inner side of the externally toothed gear is blocked by a lubricant-mixing-prevention part configured from the cylindrical extension portion and the oil seal. The mixing of different types of lubricants supplied to the outer-side and inner-side lubrication portions can be effectively prevented.

A wind turbine drive train component (22) comprising a rotating shaft (61) with a radial seal (50) is provided. The radial seal (50) comprises a stationary part and a rotating part. The stationary part comprises a ring (51) with an inner edge and an outer edge, the inner edge being configured for contactlessly surrounding the shaft (61). The rotary part comprising a disc (52), coaxially connected to the shaft (61) for rotation therewith and comprising a flange (53) that wraps around the outer edge of the ring (51). The radial seal (50) further comprises an annular air lock gap (55) for containing an amount of lubrication fluid (64) and thereby closing off the air lock gap (55) when the rotary part rotates at a rotational speed above a predetermined threshold speed, the annular air lock gap (55) being formed by an inner surface of the flange (53), an outer part of the opposing parallel surface of the disc (52) and the outer edge of the ring (51).

A silk hat-type strain wave gear device has a crossed roller bearing for supporting an internal gear and an external gear so as to allow relative rotation. A first gap part between the inner and outer rings of said bearing is sealed by an oil seal and a second gap part thereof is in communication with a gear-side gap part on the outside of the external gear. A bearing seal separates the second gap part from the gear-side gap part. The bearing seal prevents excessive inflow of lubricant from the gear-side gap part into the second gap part. Excess lubricant that has flowed into the bearing can flow back from the second gap part to the gear-side gap part. Excess lubricant in the bearing is prevented from leaking through the oil seal to the outside.

Provided is a multiplate wet clutch having capability of preventing damage of an axial groove portion formed in an inner cylindrical portion of a shaft. An inner cylindrical portion 3 of the shaft is formed with an axial groove 75 which is opened to a circumferential groove 53 and with which other members of the multiplate wet clutch for regulating movement of a retaining ring 55 toward axially on the other side are to be engaged. A pressure plate 35 is formed, on a surface 36b axially on the other side thereof, with a recessed portion 77 axially opposed to an opening portion 81 of the axial groove 75 through the retaining ring 55.

An arrangement for mounting an output shaft (1) designed as a spider shaft of the planetary gear set of a transmission includes an axial needle bearing (6) arranged between an output-side spider plate (4) of the output shaft (1) and a housing (5) of the transmission, a radial needle bearing (7) for the radial mounting of the output shaft (1) in the housing (5), a thrust washer (8) attached to the output shaft (1) with the aid of a snap ring (9), and a shaft sealing ring (10) arranged on the side of the thrust washer (8) facing the output, into the interior space of which the thrust washer (8) and the snap ring (9) for attaching the thrust washer (8) extend.

A gear unit includes a shaft and a housing part. A bearing is received in the housing part, and a flange part is connected to the housing part. The flange part is sealed from the shaft using a first and a second labyrinth seal, and the first labyrinth seal is axially spaced apart from the second labyrinth seal. The shaft has an elevation that is arranged axially, e.g., in the axial direction, between the first labyrinth seal and the second labyrinth seal.

A system has an input shaft driving a first gear and supported by at least one input shaft bearing. The first gear drives at least a second gear. The second gear drives an output shaft. The output shaft is supported by at least one output shaft bearing. A gear bearing also supports at least one of the first and second gears. Lubricant movement structure is associated with at least one of the first and second gears for moving lubricant in an axial and in a radial direction to drive the lubricant toward at least one of the shaft bearing and the gear bearing. A spacecraft is also disclosed.

A transmission assembly including a housing, an electric motor, and a baffle is provided. The housing may include first and second drainage channels. The electric motor may be disposed within the housing adjacent the drainage channels and a torque converter. The baffle may be disposed within the housing upon a housing inner surface, and may define an opening to the first and second drainage channels. The baffle may include a baffle flange sized for positioning adjacent the torque converter to minimize contact of oil within the housing to the torque converter. The housing may define first and second partition walls each partially extending over one of the first and second drainage channels. The baffle may further include first and second seal features each disposed at one of two baffle ends.