A housing for a bearing includes a radially inner annular surface extending around a central axis and adapted to receive a radially outer surface of a bearing, a cooling passage extending through the housing and around the radially inner annular surface, an inlet for fluid to flow into the cooling passage, and an outlet for fluid to flow out of the cooling passage, wherein the cooling passage has a profiled surface.

A housing for a bearing includes a radially inner annular surface extending around a central axis and adapted to receive a radially outer surface of a bearing, a cooling passage extending through the housing and around the radially inner annular surface, an inlet for fluid to flow into the cooling passage, and an outlet for fluid to flow out of the cooling passage, wherein the cooling passage has a profiled surface.

A sealed and lubricated rotatable track engaging element includes a roller and a roller shaft extending through the roller to support the roller for rotation about a major axis. A first thrust surface is fixed relative to the roller, and a second thrust surface is fixed relative to the roller shaft. A seal cavity extends between the roller and the roller shaft and is formed in part by each of the first thrust surface and the second thrust surface, and a thrust washer stack is within the seal cavity and trapped between the first thrust surface and the second thrust surface. The thrust washer stack includes an inner thrust washer contacting the roller to rotate at a first fractional speed of a speed of rotation of the roller, and an outer thrust washer contacting the inner thrust washer and the collar to rotate at a second fractional speed that is less than the first fractional speed.

A bearing isolator seal provides enhanced coupling and stability of the rotor to the shaft, without undue seal enlargement, by including a plurality of drive O-rings in a common retention groove. In embodiments, the isolator seal accommodates axial rotor misalignment up to a maximum permitted axial misalignment, which can be at least 0.025″. Embodiments include a labyrinth passage between the rotor and the stator configured to expel fluid by centrifugal force. Embodiments include a shut off feature that takes advantage of axial misalignment. Some embodiments include a unitization feature that holds the rotor and stator together during assembly. The unitization feature can include chamfers on rotor and stator extensions that facilitate assembly and disassembly when sufficient force is applied.

A bearing seal provides a first flinger and a second flinger. A first sealing body formed on the first flinger is configured to form sealing engagement with a corresponding surface of the second flinger and/or the second bearing ring, and a second sealing body formed on the second flinger is configured to form sealing engagement with a corresponding surface of the first flinger and/or the first bearing ring. The seal has a lean structure formed at least within a partial scope thereof that faces the rolling elements and/or the cage, which lean structure allows axial space to be released to the interior of the bearing, such that a ratio W/H of the axial size W within the partial scope of the seal to the spacing H between the first and second bearing ring shoulders falls within a range of W/H ≤ 0.5. The invention also provides a rolling bearing with standard boundary dimensions, with the bearing seal provided on its axial side.

In an outer race rotation bearing in which an outer race rotates, a mounting portion is fitted in each annular groove of the outer race. A pair of seals are provided which close the respective axial ends of an annular space defined between a fixed inner race and the outer race. Each of the seals has an elastic lip which protrudes toward the interior of the bearing, and which is kept in close contact with a groove edge portion of the annular groove from the inner peripheral side of the outer race. In this arrangement, when the seals are pressed axially outwardly by grease to which centrifugal force is applied, the grease leakage preventing lips of the respective seals function as lids to close the gaps generated between the mounting portions and the annular grooves, thereby making it possible to prevent grease from leaking through these gaps.

A slewing bearing providing a first ring, a second ring, the rings being concentric around a central axis (X1), at least one row of rolling elements arranged between the rings in order to form an axial thrust that can transmit axial forces, at least one row of rolling elements arranged between the rings in order to form a radial thrust that can transmit radial forces, and at least one sealing assembly arranged between the first ring and the second ring. The sealing assembly provides first sealing means being arranged outside second sealing means, an annular sealed chamber being defined between the first sealing means and second sealing means.

A procedure for mounting a hub bearing assembly including a rotatable hub, and a bearing unit having a stationary radially outer ring, and two rolling bodies disposed between the radially outer ring and the hub, and executing the steps of hammering a first seal on the hub, mounting a cage on the seal seat, providing the outer ring assembly in axially offset manner relative to the hub, mounting the rolling bodies axially externally from the axially inner side, combining the hub to the outer ring, positioning the outer ring inclination at a predetermined angle, mounting the rolling bodies from the axially inner side, aligning the hub to the radially outer ring, snap insertion of the cage, on rolling bodies from the axially outer side and the cage, on rolling bodies from the axially inner side, hammering a second seal on its seat, from the axially inner side.

A procedure for mounting a hub bearing assembly including a rotatable hub, and a bearing unit having a stationary radially outer ring, and two rolling bodies disposed between the radially outer ring and the hub, and executing the steps of hammering a first seal on the hub, mounting a cage on the seal seat, providing the outer ring assembly in axially offset manner relative to the hub, mounting the rolling bodies axially externally from the axially inner side, combining the hub to the outer ring, positioning the outer ring inclination at a predetermined angle, mounting the rolling bodies from the axially inner side, aligning the hub to the radially outer ring, snap insertion of the cage, on rolling bodies from the axially outer side and the cage, on rolling bodies from the axially inner side, hammering a second seal on its seat, from the axially inner side.

A method includes providing a bearing housing configured to house a bearing, the bearing housing enclosing a free volume for receiving a lubricant and including a shaft in a shaft opening, filling the free volume with the lubricant, providing an exclusion seal between the shaft opening and the shaft, the exclusion seal being repeatably and non-destructively shiftable from a sealing state and a release state, the exclusion seal being shiftable from the sealing state to the release state by increasing a pressure in the bearing housing to above a first level and being shiftable from the release state to the sealing state by decreasing the pressure to below the first level; and continuously maintaining a film of the lubricant between the exclusion seal and the shaft by repeatedly causing the pressure of the lubricant in the free volume to rise above and fall below the first level.