CS229314B1 - Bearing positioning on a testing machine - Google Patents

Description

The invention relates to the bearing arrangement of bearings, in particular antifriction bearings, in a test device under axial loading.

When testing roller bearings, in particular their dynamic load rating, a device is used in which the bearings are subjected to specified conditions. These are precisely determined load and limited speed. When applying axial loading, it is problematic to uniformly load all the tested bearings, depending on their bearing, so as to ensure the axial displaceability of the outer rings in all modes during the test.

In the prior art, this problem is solved essentially in two ways. In the first case, the test bearings are supported by their outer rings in bushings with sufficient clearance to ensure their axial displaceability even at varying temperature of the test device. In this case, however, the outer rings are rotated and, in addition, they are ruptured by the fatigue effect.

In the second device used, the test bearings are fixedly fixed by outer rings in the inner sleeves of the superstructure arranged in the outer sleeves mounted in the test device. However, such devices are difficult to manufacture and do not allow use for a larger dimensional range of the bearings being tested.

These disadvantages are largely eliminated by bearing placement in a tester with at least one center and two side bushings axially displaceable in the tester body of the tester, with a two-part drive shaft on which they are pressed - inner rings of test bearings whose outer rings are pressed into the center and the two lateral bushings according to the invention, characterized in that - at the edges of the middle bushing, the outer diameter of which is smaller than the outer diameters of the lateral bushings, recesses engaging with tolerances between the centering and axial displacement are formed into corresponding recesses on the facing faces side sleeves. 229 314

In particular, the bearing according to the invention achieves high accuracy when axial loading of the tested bearings, as well as eliminating atypical bearing failures. In addition, it is possible to use a significant portion of the test tool used hitherto, including existing drawings.

The bearing according to the invention is shown in the drawing, in which the cross-section is an overall arrangement for axial loading of the tested bearings.

Storing consists of a central sleeve 2 with a smaller diameter than the outer diameters of the two side housings 2, 3. On the edges of the central sleeve JL recesses 4 are formed extending into the recess 5 to the inner faces of the side housings 2, 3. The tolerance on the recesses 4 ^d pov ^classes ajíc ^{s y} st in ^{row and DE} N ^and enables displacements axtel.ní.mu st ^AL ou displaceability all housings and JS orders of magnitude larger than the accuracy of the test bearings. The sleeves are secured against circumferential rotation. drawn pins. In the middle bushing 2 as well as in the side bushings 2, 3, the tested bearings, in this case angular contact ball bearings, are pressed with their outer rings 6. The inner bearing rings 7 are pressed onto the driving shaft 8, which is divided into two parts in the middle of the bearing assembly connected by a connecting part 9. The two lateral bushings 2, 3 are axially guided in the test body stand 10, an axially acting load pressure is exerted by the member 11. The second side sleeve 3 abuts against the bottom 12 of the two guides. side sleeves.

Claims (1)

Bearings in test equipment, for axial loading, with at least one central and two lateral bushings axially movable in the test rig body, with two-part drive shaft on which the inner rings of the test bearings are pressed, the outer rings being pressed into the middle and both lateral Sleeves, characterized in that at the edges of the central sleeve (1) the outer diameter of which is smaller than the outer diameters of the side sleeves (2, 3), recesses (4) are provided which extend within the limits of centering and axial displacement into corresponding recesses (5) on the facing faces of the side bushes (2.3).