DE2616918A1 - Sintered radial and axial bearing - has part spherical end with spiral grooves formed in area of increased sintering density - Google Patents

Abstract

The sintered bearing has a half spherical end, against which the spherical end of a shaft or a ball mounted at the end of a shaft bears. The cylindrical radial and spherical axial bearing are formed in one part. The half spherical end of the bearing is provided with spiral grooves, so that the bearing is hydrostatic. The density of the sintered material is increased over the area of the axial bearing. Slight misalignment of the shaft in the bearing, does not affect the axial bearing capacity.

Description

Sintered bearings for radial and axial loads

The invention relates to a sintered bearing bush with a blind hole iiir radial and axial loads.

The absorption of axial loads is a problem in sintered plain bearing constructions a difficult problem that has not yet been satisfactorily solved.

There are known solutions in which low axial forces by the The end face of the bearing sleeve can be accommodated. The necessary smoothing of the face is difficult from a manufacturing point of view, so that usually an unavoidable blow to the forehead occurs.

Suitable counter-rotating materials are also required, which provide a corresponding Must have surface quality.

To improve the absorption of axial forces by the face, it was also proposed to provide the end face with grooves that did the job have to hold the Ö1 on the face.

However, this design does not have a satisfactory solution in practice brought.

Another way of absorbing axial forces is achieved by that one grinds the shaft spherically or a steel ball into a cone that is in the Shaft is attached, uses. This ball or the convex surface then runs counter to it a steel, plastic or hardened sintered iron disk. Separate sintered metal disks one has already provided spirals.

There are also known dome-shaped axial bearings with spiral grooves, which are deep-drawn from a sheet. This camp is in a special recording attached. The spherically ground shaft or an intermediate shaft runs in this bearing Sphere arranged shaft and axial layer. In this as well as in the one previously described Design: the bearing arrangement needs to be used to absorb radial forces through another Radial plain bearing bush to be completed.

It is the object of the invention to provide a sintered metal plain bearing bush create that can absorb both radial forces and axial forces. It belongs further to the task of manufacturing such a sintered metal plain bearing bush to manufacture in a simple manner and inexpensively.

The object is achieved according to the invention by a sintered bearing bush type described above solved, in which the spherical bottom of the blind hole is provided with spiral grooves.

The sintered bearing bushing according to the invention is produced in simple way in such a way that first a sintered bearing bush with a blind hole is pressed in a known manner and that then with the help of the calibration process a calibration needle is used to provide the bottom of the blind hole with spiral grooves, which allow a much higher axial load than when running against the face of the camp are possible.

In addition to the favorable manufacturing process, another advantage should be stated, that the bearing assembly can be manufactured inexpensively, since only a one-piece Bearing element to absorb the radial as well as the axial forces is required. the Sintering production of the bearing bush gives the possibility in the area of Spiral grooves to increase the compression of the material so much that a pressure build-up can take place, whereby increased axial loads are possible. Another The advantage of the bearing bush according to the invention is to be seen in the fact that a slight Canting of the shaft to the bearing bore does not have a decisive negative influence has the absorption of the axial forces, in contrast to the case in which the axial forces must be absorbed by the end face of the bearing of the bearing bush.

It is emphasized that the protection applies to all possible embodiments from sintered bearing bushes. The invention is applicable, for example with cylindrical bearing bushes, with flange bearing bushes, with flanged bearing bushes and with spherical bearing bushes.

The invention is in the drawing in several embodiments shown. IIier shows: Fig. 1 - a cylindrical bearing bush Fig. 2 - a spherical bearing bush Fig. 3 - a flange bearing bush Fig. 4 - a flange flange bearing bush The one shown in Fig. 1 - 4 shown bearing bushes show all closed end bearings with a blind hole 1 and a spherical design of the bottom 2. In the bottom 2 there are spiral grooves 3 (not shown).

Fig. 5 shows a plan view of the base 2 with the spiral grooves 3.

Fig. 5 shows only one embodiment without affecting the invention should be limited to this version.

There are various possibilities for the execution of the spiral grooves in question, which, however, cannot be presented separately here. Often is to determine the suitable arrangement for the special application by means of tests.

Claims (2)

Claims (1.) Sintered bearing bush with a blind hole for radial and axial loads, d a d u r c h g e k e n n n z e i c h -n e t that the spherical bottom of the blind hole is provided with spiral grooves. 2. A method for producing a sintered bearing bush according to claim 1, that the bottom of the blind hole of the Sintered bearing bush pressed in a known manner during the calibration process with the aid of a The calibration needle is provided with spiral grooves.