DE663734C - Adjustable bearing - Google Patents

Description

It is already known to change the game from bearings to balls guided To use wedges, which act on one bearing half via further wedge bodies. if the adjustability of the first-mentioned wedges can also be facilitated by the balls may, this advantage is canceled out by the fact that the wedge surfaces of the other parts interact with sliding friction. Besides, this is well known The arrangement is cumbersome and expensive because of its many parts, and at most for special purposes usable; and finally it is bound to a two-part bearing body, permitted thus not a radially symmetrical deformation of the race.

It is also known that the bearing clearance with the help of two conical, displaceable one inside the other Adjust bushings. Here these bushings work exclusively with sliding friction each other, which is disadvantageous and also complicates the setting.

The camp according to the invention is also used to adjust the bearing play two nested, conical bushings; the shortcomings of the previously known arrangements are thereby avoided that rolling elements run between the conical surfaces of the bushes. The latter are functional like that resulted in the fact that when rotating a sleeve relative to the other at the same time the mutual Axial movement takes place.

In the figures, the idea of the invention is shown schematically in three, for example Embodiments reproduced, namely shows

Fig. Ι a version for a plain bearing, completely cut at the top, partially cut at the bottom,

Fig. 2 a version for a ball bearing on average,

Fig. 3 shows another embodiment for sliding or roller bearings in section. In Fig. Ι sits in a bearing body, ι a sleeve 2, which is held with screws 3 in the bearing body ι. The inner bore of the sleeve is conical. In this conical bore there is bush 6 with a matching counter cone, but with a smaller diameter. Between the conical surfaces of the sleeves 2 and 6, distributed over the entire circumference, rollers 4 are arranged, which are guided, for example, in a cage 5 so that the roller axes are set with respect to the shaft axis by a generally small angle α . The recesses of the cage can be designed so that two or more rollers can be accommodated in one recess. Instead of the cage S, another device securing the set position of the rollers can also be provided.

The actual bearing shell 7, in which the shaft 12 is mounted, is seated in the bush 6. The bush 6 and the bearing shell 7 can also be made in one piece. '-

The sleeve 6 carries teeth 8, in the gaps of which corresponding opposing teeth of a disk 9 fit. The disk 9 can be held in place by clamping screws 10, for example. The disk 9 and the clamping screw 10 together form a safeguard against rotation of the bush 6. This safeguard can also be replaced by another device known per se. The sleeve 6 and the bearing shell 7 can also be divided. .

In special cases, several cages 5 with several rows of rollers can be used be arranged side by side.

If the securing parts 9 and 10 are removed and the bush 6 is rotated in the direction of the arrow 13, the bush 6 rolls on the rollers 4 against the inner cone of the bush 2. As a result of the offset α of the rollers 4 relative to the shaft axis, an axial displacement of the bushing 6 in the direction of the arrow 11 takes place at the same time. As a result of the conical shape of the sleeves 2 and 6, pressures arise between the conical surfaces and the rollers which are so great that the sleeve 6 and the bearing shell 7 are thereby radially compressed. This reduces the play between the bearing shell 7 and the shaft 2.

In Fig. 2, a bushing 2 is seated in a bearing body 1, with screws 3 in the bearing body ι is recorded. The inner bore of the sleeve 2 is conical. In this conical Bore balls 14 are arranged, which in helical grooves 1S of a matching tapered sleeve 16 are performed. These grooves can also be found in the sleeve 2 otter arranged in the two cans 2 and 16 be. The sleeve 16 is provided with teeth '.'3O through a washer 9 and screws 10 secured against twisting. Bushing 16 and race 17 can also be made from one piece be made.

If you turn the sleeve 16 in the direction of the arrow after removing the securing parts 9 and 10, so it rolls on the balls 14 against the sleeve 2, which accordingly the slope of the grooves 15 is connected to an axial displacement, which in turn the Formation of large pressures between the rolling surfaces of the sleeves 2 and 16 and the balls 14 results.

These pressures cause radial deformation of the sleeve 16 and the race ring 17 and thus change the game in the rolling bearing. The arrangement of grooves 15 and balls 14 according to Fig. 2 can also be provided for plain bearings, as can the arrangement of rollers 4 and cage 5 according to Fig. 1 also for roller bearings.

The effect is with both arrangements the same. The rotation of the sleeves 6 and 16 is with relatively small forces possible because only rolling friction has to be overcome.

In Fig. 3, another embodiment, namely above for plain bearings, below for roller bearings, is indicated. A bushing 2, which in the figure above is designed as a bearing shell and below as an outer race ring, is firmly seated in a bearing body.

A sleeve 21, above as a liner, Serving as an inner race below, sits at 1 °° a sleeve 22 with a tapered bore ·. Sit in this hole, similar to in Fig. I, set rollers 23 on a sleeve 24, which is firmly attached to the shaft 25 is.

Instead of the set roles, as in Fig. 2, guided in grooves Balls are used.

The sleeve 24 and the shaft 2 5 on the one hand as well as the sleeves 21 and 22 on the other hand no can also be made from one piece each.

A threaded ring 26, which can be pulled against the bushing, is used here, for example, as a safety device.

If the locking ring 26 is loosened and the bush 22 is rotated, an axial one occurs Displacement of this sleeve against the sleeve 14 a. The forces that this creates increase the diameter of the sleeve 22 and the sleeve 21. The play of the sliding or The rolling bearing is changed as a result.

The bearing according to the invention can be used especially where to secure the exact running of a shaft or spindle, the play is always as small as possible must be kept.

Claims (8)

Patent claims: 1. Bearing, its game by means of two conical bushings that can be moved into one another is adjustable, characterized in that between the conical surfaces of the sleeves Rolling elements run. 2. Bearing according to claim i, characterized in that that the rolling elements are guided so that when a sleeve rotates relative to the other at the same time mutual axial movement takes place. 3. Bearing according to claim 1 and 2, characterized in that as rolling bodies Rollers (4) are used, which are guided by a device known per se that their axes are skewed to the axis of the bearing (Fig. 1). 4. Bearing according to claim 1 to 3, characterized in that the skew The position of the rollers (4) is secured by a cage (5) (Fig. 1). 5. Bearing according to claim 1 and 2, characterized in that "at least one the conical surfaces at least one helical groove (15) for guidance the rolling element has (Fig. 2). 6. Bearing according to claim 1 and 5, characterized in that as rolling elements Balls (14) are used (Fig. 2). 7. Bearing according to claim 1 to 6, characterized characterized in that the bearing element to be deformed and the deformation pressure consist of one piece, which is under the pressure of the rolling elements and which transfers to the bearing element. 8. Bearing according to claim 1 to 7, characterized by the mutual position the device (26) (Fig. 3) which secures the bushes carrying the conical surfaces. 1 sheet of drawings