A hydrodynamic bearing assembly includes a first member including a first engaging surface. The first member is stationary in a non-operating mode of the bearing assembly and rotates about an axis in an operational mode of the bearing assembly. The first member includes a first bore and a shaft positioned within the first bore and including an end surface. The hydrodynamic bearing assembly also includes a second member including a second bore and a second engaging surface positioned adjacent the first engaging surface. The second member is stationary in both the non-operating mode and the operational mode of the bearing assembly. The hydrodynamic bearing assembly further includes a spacer member positioned within the second bore and is configured to engage the first member to define a first gap between the first engaging surface and the second engaging surface in the non-operational mode.

Tapered roller bearings are disclosed. The bearing may include an inner ring defining an inner raceway and an outer ring defining an outer raceway. A plurality of tapered rollers may be disposed between the inner and outer rings and a cage may be configured to retain the plurality of tapered rollers. The inner ring may include a rib at a first axial end configured to retain a larger diameter end of the tapered rollers but not have a rib at a second axial end that is proximate a smaller diameter end of the tapered rollers. A gap may be defined between the cage and the inner ring at the second axial end, the gap configured to control a lubricant flow to the plurality of tapered rollers.

Tapered roller bearings are disclosed. The bearing may include an inner ring defining an inner raceway and an outer ring defining an outer raceway. A plurality of tapered rollers may be disposed between the inner and outer rings and a cage may be configured to retain the plurality of tapered rollers. The inner ring may include a rib at a first axial end configured to retain a larger diameter end of the tapered rollers but not have a rib at a second axial end that is proximate a smaller diameter end of the tapered rollers. A gap may be defined between the cage and the inner ring at the second axial end, the gap configured to control a lubricant flow to the plurality of tapered rollers.

An integrated journal bearing (IJB) includes a shaft extending in an axial direction, a housing through which the shaft extends in the axial direction, the housing surrounding the shaft in a radial direction, an active magnetic bearing (AMB) arranged within the housing and surrounding the shaft in the radial direction, and at least a first fluid film journal bearing (JB) arranged within the housing and surrounding the shaft in the radial direction. The first JB is axially adjacent to the AMB such that first JB and the AMB do not share a common radial clearance, while both are commonly flooded with oil. A controller in signal communication with the AMB can be variously configured to supply current thereto to operate the AMB by controlling a magnetic force generated thereby.

The column portions of the cage includes roller holding portions which restrain the cylindrical roller on an outer diameter side and an inner diameter side thereof. The roller holding portions are formed such that a radial movement amount of the cage with respect to the cylindrical roller from a state where a revolution center of the cylindrical roller coincides with an axial center of the cage is configured so that an outer diameter side movement amount<an inner diameter side movement amount, and an outer diameter side opening width of the pocket portion>an inner diameter side opening width of the pocket portion. The column portion includes an inner diameter side protrusion which protrudes to an inner diameter side than inner circumferential surfaces of the annular portions and which configures the roller holding portions.

A motor according to an embodiment of the present invention includes a rotary shaft; a rotor mounted on the rotary shaft; a stator surrounding an outer periphery of the rotor; an impeller mounted on the rotary shaft to be spaced apart from the rotor; a bearing housing positioned between the impeller and the rotor and formed with a through-hole through which the rotary shaft passes; and a gas bearing disposed in the bearing housing, wherein a thickness of the gas bearing is equal to or greater than 50% of a gap between an inner surface of the bearing housing and an outer peripheral surface of the rotary shaft and is equal to or less than 0.3 mm.

A sanitary mixing tank steady bearing is replaceable without lifting a mixing tank shaft. The steady bearing is insertable into and removable from the bottom of a bearing support attached inside the base of the sanitary mixing tank. The steady bearing may thus be replaced by a service technician working through a man way/man hole on the top of the tank allowing service without lifting the mixing tank shaft. Gaps are provided between the bearing support and steady bearing allowing flushing material from around the steady bearing to easily maintain a sanitary environment.

A motor includes a rotor including a shaft that is disposed along a central axis extending vertically, a stator disposed to face the rotor in a radial direction, a first bearing that is disposed above the stator and supports the rotor so as to be rotatable about the central axis with respect to the stator, and a motor housing that houses at least a portion of the stator. The motor housing includes a first cylindrical portion that is disposed radially outward of the first bearing, extends downward, and has a cylindrical shape, a first top plate portion that extends radially inward from a lower end of the first cylindrical portion, and a second cylindrical portion that extends downward from a radially inner end of the first top plate portion and includes a cylindrical shape. The radially inner surface of the second cylindrical portion is positioned such that a gap is defined between the radially inner surface of the second cylindrical portion and the radially outer surface of the shaft in the radial direction.

Two hybrid ball bearings and a compressor bearing arrangement with two hybrid ball bearings for a rotatable support of a rotor of the compressor versus a stator of the compressor. The two hybrid ball bearings are arranged face-to-face or back-to-back, are designed with an optimal axial clearance depending on the inner diameter of a ring-shaped inner raceway element one of the hybrid ball bearings respectively a pitch diameter of one of the two hybrid ball bearings for a long bearing life in connection with an optimal compressor operating performance.

A rolling bearing includes an inner ring, an outer ring, a plurality of balls, and a cage in which a plurality of pockets that accommodate the balls are formed along the circumferential direction. The cage is a snap cage that has an annular body provided on one side in an axial direction, and a plurality of prongs provided so as to extend from the annular body toward the other side in the axial direction. Spaces on the other side of the annular body in the axial direction and between the prongs which are adjacent to each other in the circumferential direction serve as the pockets. A pocket surface of the pocket that faces the ball is a part of a spherical surface. The cage can contact the inner peripheral side of the outer ring for positioning in the radial direction.