DE1039790B - Single or multi-row rolling bearing - Google Patents

Description

Single or multi-row rolling bearings The invention relates to a single or multi-row rolling bearing, the two support rings of which are supported on the same or different number of in alternating order in one and balls and cylindrical rollers arranged in the same ring.

Wire ball bearings and wire roller bearings are known. Wire ball bearings but are not suitable for high speeds, because the ball tracks to the axis of rotation of the balls are inclined in all designs and, consequently: a sliding friction or T-table friction occurs, which at high speeds causes impermissible heating of the bearings :produce.

The object of the invention is to create a wire ball roller bearing, r, in which the radial forces are controlled by a wire roller bearing that can be adjusted without play and the axial forces are absorbed by a wire ball bearing, such that axial forces only be supported when there is a slight axial displacement of the inner to the outer Bearing ring has occurred in the direction of the axial forces occurring. To this end The new rolling bearing is characterized by the combination of the radial pressure absorbing flat wire rings and the axial pressure absorbing round wire rings or the like, which are designed and arranged so that the axial pressure of two diagonally opposite wires is absorbed without sliding friction, while the intermediate, diagonally opposite edge wires are relieved of axial pressure and the axis of rotation of the balls.

The wire roller bearing can be free of play by suitable means set and readjust. With this adjustment of the wire roller bearing you can at the same time the pre-ground raceways for the balls are also re-rolled. Become to it If balls 0.1 mm larger than those used later are used, the result is that the wire ball bearing remains relieved under the action of radial forces and these radial forces can only be absorbed by the wire roller bearing.

If, on the other hand, there are axial forces, such forces are each diagonally opposite wires added, with the balls around a Rotate the axis of rotation inclined by about 45 ° to the printing direction, i.e. without the known one Wire ball bearings occurring sliding friction. If there is one from time to time The balls come into contact with the wires lying in the direction of the axis of rotation of the ball, so it is harmless, because between these wires as a result of the play mentioned above of 0.1 mm there is no load between the balls and the wires. For the amount of The outer ring can move 0.1 mm in the axial direction compared to the inner ring, in each case depending on. the direction of the axial load. This low Movement cannot harm the wire roller bearing.

However, when adjusting the wire reel bearing, the for the wire ball bearing inserted certain balls and these for simultaneous re-rolling of the ball tracks are used on the round wires .. In this state is then the wire ball bearing participates in the support of radial forces and can also Absorb axial and tilting forces. The axis of rotation of the balls is no longer there inclined, but lies parallel to the bearing axis of rotation.

The first-mentioned 'method asked for preference in the sense of the invention, because high demands on the speed of the bearing can thus be met, because with both rolling elements there is practically pure rolling without any sliding friction component instead of.

The fact that both the balls and the cylindrical rollers in one Wreath are housed and are kept at a distance by a cage, results a space-saving arrangement.

The number of cylindrical rollers housed in a wire ball roller bearing and balls can be chosen according to the load. It can - for example thus 50% cylindrical rollers and 50% balls, but also 75% cylindrical rollers and 2511/9 balls can be accommodated.

The wire ball roller bearing according to the invention can both as a loose Component as well as in connection with a rotary joint application.

Several embodiments of the invention are in. The drawing shown. 1 shows a cross section through: a rotary joint with a Wire ball roller bearing according to the invention, Fig: g.2 a partial view of the balls and; the cage accommodating the cylindrical rollers, 3 shows a longitudinal section by the cage receiving the balls and the rollers according to FIGS. 1 and 2 (the running surfaces on the wires are drawn out in black), FIG. 4 shows a partial cross-section by a wire ball roller bearing according to the invention, in which the flat wire rings the raceway for the cylindrical rollers are replaced by flattened round wires, Fig. 5 shows a cross section through a rotary joint with a ball roller bearing with smaller, but longer rollers, Fig.6 is a partial view of the balls and the cylindrical rollers according to FIG. 5 receiving cage, FIG. 7 shows a cross section through an embodiment corresponding to Fig. 1, Fig. 8, a cross section through a rotary joint with two ball roller bearings arranged next to one another, FIG. 9 shows a cross section through a Rotary connection with a wire ball roller bearing for one-sided axial loads.

In the figures, the balls are labeled 1 and the rollers are labeled 2. Both the balls 1 and the rollers 2 are supported by a cage ring 3, which also can be composed of several sections, kept at a distance from each other.

For this purpose, the cage has cylindrical bores 4 in a radial direction Direction for receiving the balls 1 and also receives millings 5 in the axial direction to accommodate the rolls 2.

In a preferred embodiment, the cage ring is exposed to 3 two mirror-image parts 31 and 32 together. Both halves are through between the balls and ratchets inserted bolts 33 held together.

The balls 1 run on spring steel wires 6 or shaped steel wires, while the rollers run or roll over flat wire rings 7 or half rings. Instead of the flat steel rings, a number of circular, juxtaposed, Round or shaped wires provided with surfaces ground on both sides are used will. The wire rings 6 for the balls 1 and the flat wire rings 7 for the rollers 2 are preferably in recesses of the outer support ring 8 and in recesses of the inner support ring 9 housed.

The production of such a rotary joint with the new ball roller bearings can preferably be done by manufacturing the outer support ring 8 as a one-piece ring is then annealed, then on the outer periphery in the circumferential direction with each other opposite millings for connecting screws 10 is provided, then after securing the position of the two ring halves to be separated to each other by means of Pins 11 is separated transversely into two halves between the millings. Means of the screws 10 the bearing is set after the wire rings 6 and 7, the cage 3 and the balls 1 and cylindrical rollers 2 are introduced. After this the space between the interfaces is measured and correspondingly strong The ring halves are screwed together again.

The advantage of such a new bearing is that the wire ball bearing is almost relieved of the action of radial forces by queuing of the wire roller bearing for clearance by tightening the adjusting screws 10 at the same time rolling the ball raceways onto the wires - with a pre-ground raceway - is carried out, with balls that are slightly larger. Be after the somewhat smaller balls intended for the bearing are introduced into this rolling-in process, the wire roller bearing is free of play and, if necessary, preloaded, the wire ball bearing but without bias.

The wire ball bearing is therefore no longer exposed to radial stress, so that the balls move in the direction of arrow 13 around the axis of rotation 6 "to 63 or, if the stress is from the other side, about the corresponding axis of rotation 61 to 64 Without the sliding friction part occurring in the known wire ball bearings. Intermittent contact of the balls on the wires 6 2 and 63 and an associated disturbance of the rotary movement of the ball around the axis of rotation 62 to 63 are harmless because with this stress on the bearing between the Wires 62 and 63 as a result of the game no forces can occur.

Due to the known rolling-in, a maximum of raceway widths of up to to a third of the wire thickness can be achieved, because with further rolling to the A damaging ridge would arise on the edges of the career path.

A much more advantageous method is therefore obtained when the Wires have to be pre-ground before use. This z. B. the steel wires with a circular or any other cross-section to the intended dimension in rounded horizontal plane, straightened flat according to the teaching and then by grinding flattened under the desired angle of inclination in the cross-section.

The wires pre-processed in this way are then inserted and only re-rolled similar to the known rolling-in process. The required plastic Deformation of the wires on the respective spherical radius is reduced to such an extent that that you can achieve track widths of 60% of the track wire diameter and above permit. The flattening on the running wire must be as perpendicular as possible to the connecting line be attached to the center of the ball and track wire. This creates torsional stresses in the running wires and uneven running of the balls avoided.

If rolling is dispensed with, roughly the same effect can be achieved by pre-grinding wide ball tracks and by providing one at the same time little play between balls and wires can be achieved.

The roller tracks on the flat steel wires 7, which can consist of about a third softer material than the ball tracks, can be re-rolled a little, so that an exact rolling of the cylindrical rollers on the flat steel wires g 1 e is ensured.

So that the balls and kodlen introduced into the camp for the good running of the balls Lubricant cannot flow out through the parting line of the support rings and thus on the other hand, the dust cannot enter the store through this joint Sealing means 12 across the joint, preferably with the formation of a labyrinth seal, used.

In Fig. 4 are the roller tracks that were previously made of flat steel wires 7, formed from individual stringer wires 107. These are flattened on both sides. Since these are open rings, 'are the joints of the individual rings offset from one another, so that the rollers run smoothly is secured. Even with the track of the flat steel rollers; raht settles the Track preferably made of at least two flat wires arranged next to one another together; here, too, should be avoided by offsetting the wires against each other, that faults could be caused by a single separation point.

While the load capacity in the radial direction corresponds to the width the Flachs.tah-ldrraht 7 in the previous embodiments of the wire ball roller bearing rotary connections has been limited by the distance between the wires 6 of the ball tracks, is the Limitation of the load-bearing capacity of the connection according to Fig. 5 is canceled. Here are the Flat steel wires 207, which form the raceway of the rollers 102, not between the Ball running wires, but arranged on both sides outside the same. The cylindrical rollers 102 are made correspondingly long, they extend over the ball diameter on both sides out. Since both the flat steel wires 207 and the cylindrical rollers according to this Design can be extended arbitrarily, it is possible that much higher Radial loads can be supported with this connection.

The ball and roller cage 103 is not axial in this design, but arranged radially, so that only holes with for its production the diameters suitable for balls and rollers must be introduced.

FIG. 7, which corresponds in construction to that of FIG. 1, serves to explain the following problem: When an arrangement of balls and Cylindrical rollers in a rolling circle in alternating order must be avoided that one rolling element wants to overtake the other and thus an undesirable one Friction of the leading rolling element can occur.

Such an advance of one rolling element over the other is avoided in that the roller radii y2 and r3 are designed to be of different sizes, according to the function where R denotes the radius of the roller circle, y denotes the radius of the cylindrical rollers and r2 and r3 denote half the distance between the ball running surfaces on both sides.

This function can be easily fulfilled because of the ball race rings can be arranged at any distance from the center of the sphere and the differences of r2 and r3 are not large.

A wire ball roller bearing slewing ring with a full diameter for example 980 mm, a ball size of 35 mm and a roller diameter of 36 mm would give a value of about 12.37 mm for y2 and 12.65 mm for r3.

In a design that from the outset a game between balls and Providing wires, a lead of the vain type of rolling elements can only occur affect an axial load on the balls.

Fig. 8 shows a wire ball roller bearing rotary connection in interchangeable bearing design, which is particularly suitable for unilaterally acting high axial loads and also tipping loads to record. The outer support ring 308 takes a threaded ring 315 for each bearing and 315 'on. The threaded rings are fixed by a known Klenimung. The clamping is z. B. generated by introducing a tangential saw cut 25 in the ring. The flap 26 produced by this incision is made by means of a Screw 320 is tightened and thereby clamps the ring 315. The course of forces in this embodiment is eir. others like that of the embodiment according to FIG. 1. While the axial forces in the embodiment of FIG. 1 from one in the inner ring arranged raceway diagonally over the ball to only one arranged in the outer ring Career can be transferred, the transfer takes place after the execution in FIG. 8 from two raceways arranged in the inner ring to both arranged in the outer ring Careers.

Since the load absorbed decreases with increasing support angle can be recorded at a support angle of 45 ° (according to FIG. 1) Load should only be smaller than that which can be absorbed at a much smaller support bracket, as shown in the embodiment of FIG. Since in the latter the load is also passed on from both tracks to turn two tracks, very high axial loads can be absorbed with this design. In the embodiment according to FIG. 9, too, the axial load is transmitted by two Wires in the inner ring over the ball to two wires in the outer ring. Of this Design can only absorb axial forces from one direction.

In Fig. 1, the support of axial forces takes place in alternating directions of two diagonally opposite wires, while in Fig. 8 there are again axial forces are supported in alternating directions by four wires each.

Fig.9 shows an embodiment in which the wires are perpendicular have been moved towards the direction of the load ', so that the support angle a1 and a2 becomes correspondingly smaller. The wires are also arranged so that the points of contact 341, 342, 343 and 344 between balls 301 and wires 306 on the imaginary rolling cone327 come to rest with the roll-off angle ß. Are the raceways for the balls as possible kept narrow, the security is that no inadmissible bearing heating occur can, increased. The outer ring 308 can, as shown, consist of two halves, however, it can also consist of a full ring without radial adjustability. In the latter case, the wire roller bearing must be tolerated closely. By pushing it warm the wires of the roller track can be given a bias.

Claims (10)

PATENT CLAIMS: 1 .. Single or multi-row rolling bearing, both of which Support rings are supported on the same or different numbers of in alternating sequence in one and the same ring arranged balls and cylindrical rollers, characterized by the combination of the radial pressure-absorbing flat wire rings and the axial pressure-absorbing round wire rings or the like, which are arranged and are designed that the axial pressure of two diagonally opposite wires Sliding friction is included, while the intermediate, diagonally opposite Round wires are relieved of axial pressure and designate the axis of rotation of the balls. 2. Rolling bearing according to claim 1, characterized in that the shorter the length Cylindrical rollers (2) as the diameter of those arranged in the same ring with them Balls (1) the flac.wire rings (7) (running surfaces of the cylindrical rollers) between the Tread wires (6) of the balls (1) are arranged. 3. Rolling bearing according to claim 1, characterized in that if the length of the cylindrical rollers (102) is greater than the diameter of the balls (1) arranged with them in the same ring, the Flachdralitringe (7) are arranged on both sides and outside the ball races. 4. Rolling bearing according to claims 1 to 3, characterized in that the Wires of the taps are formed from Fassondräten. 5. Rolling bearings according to the claims 1 to 4, characterized in that the game between the ball tracks and the balls is slightly larger than that between the roller tracks and the roles of the same ring. 6. Rolling bearing according to claims 1 to 5, characterized characterized in that the material of the flat wires (7) is softer than that of the Wires (6) for the ball track is. 7. Rolling bearing according to claims 1 to 6, in particular for radially loaded rotary joints, characterized in that the distances between the raceways from the axially extending diameter of the balls (1) are different on both sides of the rollers, according to the function B. Rolling bearing according to Claims 1 to 7, characterized in that in a support ring Several wire ball roller bearings installed next to or one above the other in a slewing ring are. 9. Rolling bearing according to claims 1 to 8, in particular for slewing rings, which are exposed to particularly high axial loads, characterized in that the running tracks to the axis are moved together so much that the points of contact (341, 342, 343 and 344) between the balls (301) and the wires (306) on one imaginary rolling cone (327) are located. 10. A method for producing rotary joints with a roller bearing according to one or more of the preceding claims, characterized in that the outer support ring (8) is manufactured as a one-piece ring, then is annealed. is then provided on the outer circumference in the circumferential direction with mutually opposite millings for connecting screws (10), then after securing the position of the two halves of the ring to be separated from each other by means of pins (11) between the millings, it is cut transversely into two halves, whereby by means of the screws ( 10) the shelf life is set. then the space between the separating surfaces is measured and correspondingly thick shims are inserted and the ring halves are screwed again. References considered: U.S. Patent Nos. 997,829, 2,283,312, 2,581,722; Swiss patent specification No. 241 985.