DE821887C - Multi-row ball bearing - Google Patents

Description

Multi-row ball bearing The invention relates to a multi-row ball bearing Ball bearings, especially on high shoulder bearings. So far one has the races of this kind Bearing made from a solid ring, with the manufacturing of the running surface being special is difficult. In order to significantly simplify the production and thereby the bearings To be able to produce cheaper, it is proposed according to the invention, the races made of corrugated bushings with pressed-in ball grooves, their bulges support themselves on the shaft or in the housing. This makes it possible to use the Bending races either from a band after pressing into a ring or but to emboss a tubular sleeve with the ball grooves. After the pressing process If the ball grooves are ground, the outer beads of the outer sleeve can also be machined and grind the inner beads of the inner liner to the exact size. The outer sleeve has in each groove bead a filling opening to be closed for the balls, so that you can arrange any number of rows of balls in such a camp. The ball cage advantageously consists of two side rings with between the balls lying sheet metal webs that can contain recesses for the balls.

To simplify the assembly of a multi-row ball bearing the liners can also consist of individual rings, their contact surfaces perpendicular or at an angle to the axial direction in the ball centers. With strong axial Loading of such a bearing will make the parting surfaces perpendicular, at essentially inclined radial load.

A bearing according to the invention can be advantageous for the storage of conical Tool shafts, lathe tips or the like. Can be used. With conical shaft and cylindrical inner bore can be the space between the conical, corrugated Inner sleeve and the cylindrical corrugated outer sleeve by balls of miscellaneous Diameter to be filled in. The same is the case if the inner bore is conical, but the tool shank is cylindrical. Is both the tool shank and If the inner bore is conical, it is expedient to use conically corrugated Race rings with balls of the same diameter. The rifles can be on their edges be provided with beaded contact faces, so that the axial pressure of the corresponding construction parts can be easily added. The beaded When using spring steel o Cause direction.

In the drawing, various exemplary embodiments are multi-row Bearing shown, namely Fig. I shows a longitudinal section, Fig. 2 shows a cross section, Fig. 3 is a plan view of an outer sleeve, Fig. 4 and 5 cross sections through divided Bushings, Fig. 6 to 8 bearings of conical lathe tips, Fig. 9 the top view on a ball cage and Fig. io a modification of the ball cage.

According to FIGS. I and 2, according to the invention, a is on the steering knuckle io Corrugated inner sleeve ii pulled up around the correspondingly corrugated outer sleeve 12 is arranged. These two cans have z. B. three grooves for the balls 13, the beads 14 and 15 of these grooves on the steering knuckle io and support in the housing 16. The stub axle io is for example with a collar 17 provided, which rests against the face of the inner sleeve ii. The outer sleeve 12 rests with its end face against the side wall 18 of the housing, so that the axial pressures from the collar 17 via the inner ring and the balls on the outer ring and are properly transferred from this to the housing. Between the balls there are sheet metal strips i9, which are attached to the two end faces of the bearing with rings 2o and 21 are riveted and thus form the ball cage. According to Fig. 3 are in the Outer sleeve 12 arranged openings 22 through which the balls 13 are filled. After filling, these openings 22 are closed again in a suitable manner. It goes without saying that such a bearing can also have more than three rows of balls Mistake.

According to Fig. 4, the outer sleeve consists of several rings 23, 24 and 25, the contact surfaces of which are perpendicular to the axial direction in the center of the sphere. Such a split warehouse can be filled with balls very easily, one will use it with heavy axial load, because in this case the balls are not about run on the dividing line of the individual rings. According to FIG. 5, these dividing lines are located obliquely, with individual rings 26 also being used again. This camp will should be installed especially with radial loads.

FIGS. 6 to 8 show the mounting of a lathe point with a conical shaft 27 as an application for such multi-row ball bearings. In FIG. Here, a cylindrical, corrugated outer sleeve 3o is installed together with a conical inner sleeve 31 and the space between these two sleeves is filled by balls 32 of different diameters. The inner sleeve is provided with a bead 33 which rests against the end face of the cone 27, while the outer sleeve 30 has a bead 34 which rests against the end face of the quill 29. In this way, the axial pressure can be transmitted from the cone 27 to the housing.

According to FIG. 8, balls 35 with the same diameter can also be used find, and the slope of the contact surfaces can be arranged between the rows of balls, specially shaped shafts 36 and 37 of the inner and outer sleeves are balanced. If spring steel or the like is used for the liners in these designs, then achieved by the beaded edges 33 and 34 a suspension in the axial direction. According to FIG. 7, the inner bore 38 of the quill 29 is also made conical, in this case Both the outer sleeve 39 and the inner sleeve 40 for the balls 41 are conical shaped.

With these constructions, too, between the individual rows of balls Sheet metal webs 42 (Fig. 9) may be arranged with corresponding recesses for the balls are provided. These metal strips are on the two front sides of the Bearing riveted to rings 43 and 44, so that in the simplest possible way a ball cage arises. According to Fig. IO you can also use a drum screen 45, the whole Length of the multi-row ball bearing inserted between the outer and inner sleeve and holds the balls 46 at equal distances from one another.

Claims (9)

PATENT CLAIMS: i. Multi-row ball bearings, especially high shoulder bearings, characterized in that the races consist of corrugated bushings (11, 12) with correspondingly incorporated ball grooves, the beads (14, 15) of which are supported on the shaft (io) or in the housing (16). 2. Ball bearing according to claim i, characterized characterized in that the outer sleeve (12) has a lockable in each grooved bead Filling opening (22) for the balls (13) has (Fig. 3). 3. Ball bearing according to claim i and 2, characterized in that the ball cage consists of two side rings (20, 21, 43, 44) with sheet metal webs (19, 42) lying between the balls (13, 4). 4th Ball bearing according to claims i and 3, characterized in that the bushings consist of individual rings (23, 24, 25, 26) exist whose contact surfaces are perpendicular or at an angle to the axial direction in the centers of the balls. 5. Ball bearings, especially for Conical tool shafts or the like, according to Claims 1 to 4, characterized in that that with a conical shaft (27) and cylindrical inner bore (28) or, conversely, the space between the conical; corrugated inner liner (3i) and the cylindrical outer sleeve (30) or vice versa by balls (32) different Diameter is filled (Fig. 6). 6. Ball bearing according to claim i to 4, characterized characterized in that the conical shaft (27) and the conical inner bore (38) are conical corrugated races (39, 40) are used (Fig. 7). 7. Ball bearing according to claim i to 6, characterized in that the liners with flanged contact surfaces (33, 34) are provided. B. Ball bearing according to claim 7, characterized in that the sleeves through the beaded edges (33, 34), e.g. B. when using spring steel o. The like., Are designed to be resilient in the axial direction. 9. Ball bearing according to claim i to 8, characterized in that the balls (46) are arranged in a drum screen (45) are. ok Ball bearing according to Claims i to 9, characterized in that the different Diameter of the conical shaft (27) and the cylindrical inner bore (28) or the other way around formed annulus when using balls (35) Diameter by between the balls (35) arranged, the rising or falling Diameters of the annular space adapted, forming part of the inner and outer sleeves Intermediate shafts (36, 37) are balanced (Fig. 8).