Abstract: A two-piece plastic ball bearing cage is designed to handle high-speed applications. Posts on one bearing half fit into holes in the other bearing half After the two halves are brought together, ultrasonic vibration is applied to the ends of the posts. The ultrasonic vibration deforms the post end to fit into a widened portion of the holes and welds material, thereby firmly securing the two cage halves to one another.

Abstract: A micro-traction drive unit according to the present invention includes an inner ring, an outer ring, a plurality of rolling elements, a retainer, a micro-traction drive case and a power-transmitting shaft coaxial with the inner ring and incapable of relative rotation around an axis to the retainer. An opposite end of the power-transmitting shaft from the inner ring forms an input end operatively connected to a driving source. An input end of the pump shaft is detachably connected to a central hole of the inner ring in a state incapable of relative rotation around the axis via the access opening of the micro-traction drive case by connecting the micro-traction drive case to the HST case so as to surround the input end of the pump shaft of the HST.

Abstract: Half-cage for forming cages (10) for ball bearings, in which the half-cages (11, 21) comprise semi-spherical recesses (12, 22) arranged at predefined intervals along a circumference. The semi-spherical recesses are spaced out from each other by means of respective planar portions (14, 24), are arranged along the circumference, and comprise at least one rib (31, 41) having a certain width and extending along the circumference over at least the whole surface of said recesses.

Abstract: A bearing cage for retaining rolling elements of a rolling element bearing, the bearing cage having at least one first ring structure to which at least one first cage bar is connected. The bearing cage also comprises a second ring structure to which at least one second cage bar is connected, whereby the at least one second ring structure is arranged to be located radially inwards of the at least one first ring structure.

Abstract: In a manufacturing process of a corrugated cage, an intermediate assembly 17a is configured by press-fitting each of press-fitting portions 24 and 24 respectively provided in base end portions of rod portions 13b and 13b of rivets 9b and 9b into each of through-holes 12a and 12a of a cage element 8a on one side, and nitriding treatment is performed on the intermediate assembly 17a. An axial dimension X of each of the press-fitting portions 24 and 24 is made smaller than an axial dimension Y of each of the through-holes 12a and 12a (X<Y). In this way, portions which do not come into close contact with each other are provided in axial portions of the inner peripheral surface of each of the through-holes 12a and 12a and the outer peripheral surface of each of the rod portions 13b and 13b, and thus a nitrided layer is formed on each of these portions which do not come into close contact with each other.

Abstract: A rolling bearing includes a resin cage. The resin cage includes a pair of split members split in two halves in an axial direction. Each of the split members has pocket portions and coupling portions alternately arranged in a circumferential direction. On a first coupling portion of the coupling portions coupled together, an engagement pawl is formed which protrudes from a coupling surface in the axial direction. On a second coupling portion, an engagement groove is formed which is recessed in the axial direction with respect to the coupling surface and into which the engagement pawl is inserted. The engagement pawl has a base portion and a pawl portion engaging with the second coupling portion. An insertion hole is formed in the first coupling portion so as to pass through the first coupling portion in the axial direction such that a mold is inserted into the insertion hole.

Abstract: A ball bearing cage having a first ring element and a second ring element is provided. The ring elements are each formed from sheet metal, and each include axial bulges separated by support surfaces. Ball guide pockets are formed between facing bulging inner walls by joining the support surfaces of the two ring elements. The ring elements are formed in such a way that the bulging inner walls that define the ball guide pockets define a channel cross-section which is concave in relation to a ball and which has an inner and an outer ball contact zone. The channel cross-section has such a depth in a groove base lying between said inner and outer ball contact zones that, when the ball comes into contact with the ball contact zones, an intermediate space remains between the ball and the groove base lying between the ball contact zones.

Abstract: A ball bearing retainer includes two annular members that face each other in an axial direction. The two annular members have opposed surfaces each including hemispherical pockets that are formed at a plurality of positions in a circumferential direction and configured to receive balls. The opposed surfaces are snap-fitted to each other so as to couple the two annular members to each other with coupling portions provided at both circumferential end portions of each of the hemispherical pockets Inner peripheral surfaces of the hemispherical pockets of the two annular members and the opposed surfaces of the two annular members have recessed grooves that are opened by extending from radially inner surfaces of the two annular members and reaching radially outer surfaces of the two annular members.

Abstract: A cage for a rolling bearing is coupled to a rolling bearing including an inner ring, an outer ring and a plurality of rolling elements rolling between the inner ring and the outer ring to keep intervals of the plurality of rolling elements, wherein the plurality of rolling elements include bodies coupled along a circumference thereof at predetermined intervals, wherein each of the bodies includes a first piece and a second piece which are attachable to each other and detachable from each other. A first coupler and a second coupler configured to be capable of being coupled to each other are respectively formed at the first piece and the second piece, and the first piece and the second piece are primarily coupled by means of a coupling force of the first coupler and the second coupler.

Abstract: A cage for a ball bearing unit comprises two half-cages (51, 52) which are connected to each other and are symmetrical about a mid-plane (P) of the bearing. Each half-cage has an annular body (53) providing two concentric and circumferentially continuous radial ridges (56, 57) extending radially in opposite directions, of which the first ridge (56) extends in a radially outward direction for sealingly engaging a groove (25) formed in the outer ring of the bearing unit, and the second ridge (57) extends in a radially inward direction for sealingly engaging a groove (35) formed in the inner ring of the bearing unit.

Abstract: A rolling element guide for a bearing assembly comprising of a steel or other metal skeleton overmolded with a plastic material.

Abstract: A bearing assembly for a transmission, which is capable of avoiding an ingress of foreign matter, reducing seal torque and reducing shear resistance between a retainer and balls, includes a recessed portion in an inner face of a pocket of the retainer, in which the surface area of contact with a ball is smaller than the surface area of contact when no recessed portion is provided. A sealing member is a contact seal and material of a tip portion of a sealing lip region is highly wearable material which, when the bearing assembly is rotated, wears to define a non-contact or the like. A grease contains a base oil and a thickening agent and the base oil is a mineral oil alone or a mixed oil of mineral oil and poly-?-olefin oil and has base oil kinetic viscosity not higher than 100 mm2/s at 40° C.

Abstract: A retainer for a ball bearing includes two annular members that face each other in an axial direction thereof. The two annular members include opposed surfaces each having hemispherical pockets that are formed at positions in a circumferential direction of each of the two annular members and configured to receive balls. The opposed surfaces are snap-fitted to each other to couple together the two annular members. The hemispherical pockets each have an inner peripheral surface provided with ball contact and ball non-contact surfaces. The ball contact surface is formed at a central portion in a pocket circumferential direction and at least at a central portion in a pocket axial direction of the inner peripheral surface. The ball non-contact surface includes a recess recessed to an opposite side to a corresponding ball across the ball contact surface and is opened in at least one of pocket axial ends.

Abstract: A cage for a ball bearing unit comprises two half-cages (51, 52) which are connected to each other and are symmetrical about a mid-plane (P) of the bearing. Each half-cage has an annular body (53) providing two concentric and circumferentially continuous radial ridges (56, 57) extending radially in opposite directions, of which the first ridge (56) extends in a radially outward direction for sealingly engaging a groove (25) formed in the outer ring of the bearing unit, and the second ridge (57) extends in a radially inward direction for sealingly engaging a groove (35) formed in the inner ring of the bearing unit.

Abstract: A cage for a ball bearing assembly has a pocket for accommodating one of the balls defined at a plurality of locations in a direction circumferentially thereof and each of the pockets has an inner surface so shaped as to represent a concaved spherical surface. A concaved portion extending from an open edge on the cage inner diametric side towards the cage outer diametric side is provided in an inner surface of each of the pockets. The sectional shape of the inner surface of this concaved portion in a cage circumferential direction is represented by an arcuate shape of a radius of curvature smaller than the radius of curvature of the concaved spherical surface defining the inner surface of the respective pocket. The inner surface of each of the pockets may be formed with a film.

Abstract: A method and apparatus is disclosed whereby there is an improvement in the construction of the housing for the balls of a bearing. The benefit of this method of construction is that under certain loading forces, the ball cage, now termed a retaining disk, does not bind the balls. The retaining disk is designed with an elliptical hole that spaces the balls apart but allows them enough freedom to rotate without any binding. More concisely, the ball bearing includes an inner race and an outer race with a plurality of bearing balls movably retained therebetween. A split retaining ring, having upper and lower annular rings, forms a plurality of bearing ball housings. These ball housings include a substantially spherical cavity which is elongated in an arc, or a short linear path, about a rotational center line of the ball bearing.

Abstract: A cage used in a ball bearing assembly is rendered to be of a ring shape having a plurality of pockets defined therein to hold a corresponding number of balls in a circumferential row. The radius of a bore of a circumferentially extending body of the cage as measured from the geometric center of the bore to an inner peripheral surface area of the circumferentially extending body aligned with each of the pockets is chosen to be greater than the radius as measured from the geometric center of the bore to a different inner peripheral surface area of the circumferentially extending body intermediate between the neighboring pockets.

Abstract: A cage (5) for a ball bearing assembly has a pocket (11) for accommodating one of balls defined at a plurality of locations in a direction circumferentially thereof and each of the pockets has an inner surface so shaped as to represent a concaved spherical surface. A concaved portion (13) extending from an open edge on the cage inner diametric side towards the cage outer diametric side is provided in an inner surface of each of the pockets (11). The sectional shape of the inner surface of this concaved portion (13) in a cage circumferential direction is represented by an arcuate shape of a radius of curvature (Rb) smaller than the radius of curvature (Ra) of the concaved spherical surface defining the inner surface of the respective pocket (11). The inner surface of each of the pockets (11) may be formed with a film.

Abstract: A bearing assembly and method includes a two-piece ball bearing retainer. The retainer has a first set of fluid passage apertures penetrating into ball bearing sockets, and has a supplemental set of fluid passage apertures penetrating from one side of the retainer to the other. The two halves can be snap fit together.

Abstract: The present invention provides a method and apparatus for retaining bearing balls in a bearing assembly. For example, a cage assembly may comprise an annular cage having a plurality of pockets in which to snap-in bearing balls via openings having a width less than the diameter of the bearing balls. A retainer ring for the cage may have an inner diameter that is equal to the inner diameter of the cage. The cage assembly may comprise a plurality of cage webs, wherein each cage web is located between two adjacent pockets, and each cage web may be tapered (either radially, axially, or both radially and axially). The plurality of cage webs may be tapered such that the cage webs are tapered towards a distal end of each cage web and away from a proximal end of each cage web. An outer land may pilot the bearing assembly.

Abstract: A retaining device for rolling-element includes the partition and the link-belt. The characteristic of the retaining device for rolling-element is that the partition is linked to form a ring by the link-belt, then the ring is turned in to form a space for retaining the rolling-element, so as to reduce the friction of the rolling-element.

Abstract: To provide a caged roller assembly having an excellent assimilability, capable of providing a relatively large load bearing capacity, excellent in roller guiding function, strength and accuracy, the caged roller assembly includes a cage 1 including an outer member 3 and an inner member 4, and an array of rollers 2. The outer member 3 is made up of an annular body 3a of a diameter greater than the pitch circle diameter PAD of the array of the rollers and collars 3b each formed by bending a corresponding end of the annular body 3a so as to extend radially inwardly therefrom. The inner member 4 is of an annular shape having a diameter smaller than the pitch circle diameter PAD. Pockets 5 and 6 are defined in the outer and inner members 3 and 4 with the rollers 2 supported in part within the pockets 5 in the outer member 3 and in part within the pocket 6 in the inner member 4. The collars 3b may alternatively be provided in the inner member 4, rather than the outer member 3.

Abstract: A cage for ball bearing having pockets 7 the inner surface of which comprises a spherical surface portion 15 and a pair of cylindrical surface portions 16 on the opposite sides of the spherical surface portion 15 connected continuously to the opposite edges of the spherical surface portion 15, the spherical surface portion 15 having a radius of curvature slightly larger than the radius of curvature of the rolling contact surface of the balls to be held in the pockets 7, wherein the area of the spherical surface portion 15 in sliding contact with the rolling surface of the balls is decreased to smoothly supply the pockets 7 with lubricant to decrease the cage sound caused due to friction.

Abstract: A pressed cage for a ball bearing is particularly suited for use in severe lubrication conditions. The pressed cage arrangement reduces seizure, holds lubricant for long periods, and thus prolongs the life of the bearing. In the pressed cage arrangement, two annular holding plates include ball holders and flat portions that alternate at regular intervals. The holding plates have a first recess (that may be spherical or semi-elliptic) that has a radius of curvature larger than the ball's radius of curvature. A second, preferably spherical, recess, with a radius of curvature smaller than that of the ball, is formed in the first recess. The ball rotates, being supported only on the boundaries between the first and second recesses, thereby reducing seizure. Spaces formed in the second recess, and spaces between the front portion of the ball and the junction between the holding plates, function as lubricant sumps.

Abstract: A split bearing cage assembly comprising two cage parts assembled and held together by means of components in the form of dowels (3) extending through and located in apertures through both cage parts. The apertures are located and aligned such that, when the dowels are inserted into the apertures, the relative alignment between the dowels is such as to present resistance to the separation of the two cage parts so assembled. The apertures can be straight drilled holes and the dowels can be aligned so as to lie on the surface of a cone.

Abstract: A split ring antifriction bearing retainer assembled from two mating annular split rings. Each split ring has a plurality of ball pockets. When the two split rings are assembled, the ball pockets of one split ring are aligned with the ball pockets of the other split ring. The ends of one split ring are angularly offset from the ends of the other split ring.

Abstract: A separator or cage for ball bearings has a plurality of pockets. Each pocket has an internal pocket surface toward the ball. At each half of the pitch circle of the pocket around the ball there are two approximately cylindrical first surface sections which are spaced nearer to the ball, a respective spherically curved second pocket surface section which extends over the respective pole of the ball and which has a diameter smaller than the ball, and a respective third pocket surface section which extends over the equator of the ball at each circumferential end of the pocket and which has a larger diameter than the ball. The pocket surface provides good lubrication support for the ball to minimize rubbing of the ball against the separator pocket surface.

Abstract: A separator or cage for a row of ball bearings designed to reduce friction on the balls. The pocket surfaces in the separator have recesses in the region of the axial "poles" of the balls which prevents contact between the balls and the separator pocket walls. Over the rest of the separator, the pocket walls are near enough to the balls to define a hydrodynamic lubricating film. Also over the rest of the separator pockets, the interior surfaces of the pockets are shaped to face the respective balls and to define a wedge-shaped slot with the ball for development of a hydrodynamic lubricating film as the balls rotate in either direction around their axes. The separator is comprised of two strips fastened together. Each strip has a complementary C-shaped pocket half depression, and the two strips joined together define the complete pockets that enclose the balls between the axial poles of the balls.

Abstract: A separator for the balls of a ball bearing assembly, especially of the land riding variety which is constructed of two like parts joined together by ultrasonic welding. The separator is provided with generally cylindrical ball receiving pockets. Skis are provided on the circumference of the separator which ride on the lands of the bearing. Each part of the separator is formed with alternating studs and bores, which, when two parts are assembled, the bores receive the opposing studs. The structure is so formed to insure the flow of lubricant to the raceways.

Abstract: A cage for a ball bearing comprised of two generally ridge-shaped ring parts, the respective axially projecting ridges of which are cooperatively placed to define respective pockets for the balls. The plane of separation between the two ring parts is shifted axially off the center and toward one of the ring parts. In the ring part with the axially larger ridges, the circumferentially opposite ends of the respective ridges are at least nearly flat, in the plane through the centers of the balls. The axially deepest surfaces of the ridges are also at least nearly flat, at the axially opposite sides of the cage, which is generally in the respective axial plane through the center of each ball. This prevents jamming of the balls, even in the case of defective manufacture or defective connection of the ring parts.

Abstract: A ball bearing cage consisting of a pair of annular cage portions having opposing surface portions defining circumferentially spaced radial bores for receiving balls. One of the cage portions is formed with a radially outwardly projecting circumferential lip, while the other cage portion is formed with a radially inwardly projecting circumferential lip adapted to interlock with the outwardly projecting lip to prevent axial separation of the cage portions while permitting relative rotational movement thereof.

Abstract: A cage for a radial ball bearing comprises an annular body of resilient material formed with pockets for reception of the balls as a snap fit and prongs for guiding the balls into the pockets when the annular body is fitted in the bearing from a side thereof. A retainer ring is mounted on the guide prongs to maintain the same cord distance between the prongs and thereby restrict deformation of the annular body so as to prevent ejection of the annular body under the ball-to-cage contact forces in the operation of the bearing.

Abstract: A retainer for ball bearings includes mating plastic members (4,5) having undulating shape and adapted to accommodate a plurality of balls (3) therebetween. One of the mating plastic members (4) has a mating edge provided with recesses (9) formed therein adapted to accommodate corresponding protrusions (10) formed on the other mating plastic member (5). The plastic members (4,5) are secured together, preferably by ultrasonic welding.

Abstract: A cage for the rolling elements of a rolling bearing comprises two preferably equal cage halves with portions enclosing the rolling elements and with areas in which the two cage halves are connected to each other. Elastically deformable, preferably U-shaped portions connect the areas to adjoining portions of the respective cage halves. The areas are suitably arranged so that the cage halves can be connected by being snapped together by axial forces. The cage allows ununiform rolling element movements without overstressing the cage.