Disclosed is a bearing race comprising a surface having a plurality of pores formed therein. A lubricant is provided in the pores. The race has a body having a porous volume contiguous with the surface. The surface includes a load bearing zone configured to be in contact with a rolling element of a bearing, the pores being distributed on the surface to provide the lubricant to the load bearing zone.

The present invention achieves construction for a seal ring-equipped ball bearing (1a) that allows the outer-diameter dimension of a load-bearing surface (35a) to be made large, allows a large contact area with a transmission gear (16) to be secured, and allows dynamic torque to be reduced. Seal lips (14a) of seal rings (4a) that cover opening sections on both sides of the seal ring-equipped ball bearing (1a) have a substantially horizontal V-shaped cross-section and are configured so that an outer-diameter-side inclined section (25) and an inner-diameter-side inclined section (26) are connected by a continuous portion (27). The inner-circumferential edge section of the inner-diameter-side inclined section (26), which is the tip-end edge of the seal lip (14a), is made to slide over the entire circumference of the outer peripheral surfaces of both end sections of an inner ring (8a), the end sections being cylindrical surfaces (30) without seal grooves. The angle (α.sub.1) of an inside-continuous surface (29) of the continuous portion (27) is at least 104°, and the overall length of the inner-diameter-side inclined section (26) is kept long by the continuous portion (27) entering radially inward into a wave-shaped retainer (10a).

A rolling-element bearing for an electromagnetic solenoid includes a hollow cylindrical cage with a plurality of spherical pockets formed around a first circumference and a second circumference of the cage. The pockets around the first circumference are offset from the pockets around the second circumference. Spherical rolling elements are provided in the spherical pockets and are captured for free rotation in the first pockets and second pockets.

To provide a deep groove ball bearing used under a lean lubrication condition or a non-lubrication condition, the deep groove ball bearing being capable of achieving a long lifetime without generating break of a retainer due to delay and progress of balls. The deep groove ball bearing includes an inner ring, an outer ring, a plurality of balls interposed between the inner ring and the outer ring, and a riveted corrugate steel plate retainer that retains the balls, the deep groove ball bearing being used under a lean lubrication condition or a non-lubrication condition. The retainer includes a fluroresin coating film having a thickness of 15 m or more formed on at least a raceway surface of the inner ring or the outer ring, or an inner portion of the retainer slid on the balls. The fluororesin coating film is preferably formed of a baked polytetrafluoroethylene resin or the like.

A bearing cage for retaining rolling elements of a rolling element bearing. The bearing cage is made of a sheet metal element. The cage provides at least one cage pocket configured to receive at least one rolling element. The at least one cage pocket is formed by two abutting cage bars that extend axially between a first and a second axially displaced ring element. The bearing cage is made of a one-piece sheet metal element and the first and the second ring element is undivided in its circumference without any joints or connections for joining an interrupted ring element. Furthermore, a rolling element bearing and a method of producing the bearing cage is provided.

To provide a rolling bearing retainer formed as a metal retainer and being capable of suppressing wear of a guide surface of a pocket that retains a ball served as a rolling element even in a case in which a lubrication function by a lubricant is deteriorated. A rolling bearing 1 is provided with an inner ring 2, an outer ring 3, a ball 4 interposed between the inner ring 2 and the outer ring 3, and a retainer 5 that retains the ball 4. The retainer 5 is formed as a metal retainer including pockets 6, each of which retains the ball 4, formed at positions in a circumferential direction and including a resin coating film formed on at least an inner surface of each of the pockets 6 served as a rolling element guide surface. The resin coating film 7 is formed of a resin composition including an aromatic polyether ketone based resin as a matrix resin and including a solid lubricant.

When conveying a rolling bearing from a ball collection operation position to a block division operation position or/and when conveying the rolling bearing from the block division operation position to an equal distribution operation position, a positional misalignment prevention member is inserted into a circumferential gap existing between rolling elements, so that the rolling elements are prevented from rolling and being thus dispersedly scattered and positionally misaligned.

When conveying a rolling bearing from a ball collection operation position to a block division operation position or/and when conveying the rolling bearing from the block division operation position to an equal distribution operation position, a positional misalignment prevention member is inserted into a circumferential gap existing between rolling elements, so that the rolling elements are prevented from rolling and being thus dispersedly scattered and positionally misaligned.

A rolling-element bearing for an electromagnetic solenoid includes a hollow cylindrical cage with a plurality of spherical pockets formed around a first circumference and a second circumference of the cage. The pockets around the first circumference are offset from the pockets around the second circumference. Spherical rolling elements are provided in the spherical pockets and are captured for free rotation in the first pockets and second pockets.

Provided is a retainer (7), including a pair of annular members (8, 8), the pair of annular members (8, 8) being coupled to each other so that semispherical bulging portions (9, 9) which are opposed to each other form pockets (11) configured to retain balls (6). The pockets (11) each include a ball-opposed surface (12) having a ball non-contact portion (14) that is recessed toward a side opposite to the ball side. The ball non-contact portion (14) is formed outside a predetermined region (A) of the ball-opposed surface (12), which includes an intersection (P) of a pitch circle (PCD) of the balls (6) and a straight line (L) extending in a radial direction through a central portion of the ball-opposed surface (12) in a circumferential direction, and has an end portion on a radially outer side which is opened in a radially outer surface (8a) of the annular member (8).