EP0146741B1 - Disc bearing - Google Patents

Description

The invention relates to a support disk bearing for the shaft of an open-end spinning rotor which is mounted in a wedge gap formed by support disks and is driven directly by a tangential belt, an axial thrust being exerted on the shaft via the support disks in order to press it against an axial bearing, and the support disks Have a tread made of an elastic covering against which the shaft is pressed.

It is known to radially support the shaft of an open-end spinning rotor in the wedge gap formed by support disks and to press it against the support disks by means of a tangential belt (DE-A-2.112.913). To secure the shaft axially, an axial force is exerted on the shaft by setting the axes of the support disks, which force presses the free shaft end against a thrust bearing. The support discs are provided with coverings made of damping material, such as plastic, in order to avoid harmful vibrations of high Avoid speeds rotating spinning rotor and also to reduce the noise. In operation, the tread is exposed to considerable stress due to the rapidly rotating shaft pressed against the tread with the pressure required for the drive, which is exacerbated by an existing imbalance and in particular also by the axial thrust on the shaft generated by the support disks. This stress leads to a relatively rapid wear and destruction of the tread and thus the rotor bearing. It is necessary to replace the support disks, which, due to the large number of spinning positions, incurs considerable costs for material, assembly and the loss of machine production time.

An open-end spinning device with a support roller bearing is also known, in which the rotor shaft is guided between liners provided with support rings and is driven indirectly via one of these liners. The axial position of the rotor shaft is secured by the force of a permanent magnet (DE-A-2.206.264). For this type of bearing and drive it is proposed to provide the linings of the support rings pressed onto the liners from abrasion-resistant, non-metallic material with one or more ring grooves, the width and depth of which depend primarily on the width of the support surfaces and during operation or when braking the device should cause good heat dissipation. No details are given on the generation of heat and the corresponding design of the groove for heat dissipation.

The object of the present invention is to improve a support disk bearing according to the preamble of claim 1 in such a way that the service life of the treads and thus the entire rotor bearing is increased.

The object is achieved by the features of claim 1.

Advantageous developments of the invention are described in the subclaims.

Figur 1

ein Stützscheibenlager für einen von einem Tangentialriemen angetriebenen Rotorschaft, von vorn gesehen;

Figur 2

Stützscheiben mit rillenförmigen Aussparungen in der Lauffläche, in der Draufsicht;

Figur 3

weitere Möglichkeiten der Unterbrechung der Lauffläche durch Aussparungen, in der Draufsicht und teilweise im Schnitt.

The invention is explained below with reference to the drawings. It shows:

Figure 1

a support disc bearing for a rotor shaft driven by a tangential belt, seen from the front;

Figure 2

Support discs with grooved recesses in the tread, in top view;

Figure 3

further options for interrupting the tread by recesses, in plan view and partly in section.

According to FIG. 1, a shaft 1 of an open-end spinning rotor, for which the support disk bearing is intended in particular, is mounted in the wedge gap of freely rotatable support disks 4 and 5 arranged in pairs on axes 2 and 3. The support disks 4 and 5 are provided on their circumference with an elastic covering, which consists of plastic, for example polyurethane, or also of another suitable material and forms a running surface 40, 50 for the shaft 1. A tangential belt 6 presses the shaft 1 with a predetermined pressure against the tread 40 and 50 and drives it. Such a bearing is generally known and therefore does not require any further explanation, in particular also not with regard to the axial thrust exerted on the shaft 1 via the support disks during operation, in order to press it against an axial bearing.

As already explained at the beginning, the plastic covering is subjected to a high stress starting from the shaft 1 in this mounting, which leads to wear and destruction of the tread 40 and 50. To counteract this and to increase the service life of the tread 40 and 50, the tread is interrupted by cutouts. These recesses can be designed and arranged in various ways.

However, a groove-shaped recess is preferred, which runs in the direction of rotation of the support disks 4 and 5 and is arranged in the middle of the running surface 40 and 50 (FIG. 2). The The shape of such an endless groove 7 can be different. As the versions a to d in FIG. 2 show, the groove 7 can have, for example, a wedge-shaped, a rectangular, a semicircular or a trapezoidal shape. In the embodiment e in FIG. 2, two further grooves 7 ′ running parallel to the central groove are provided in addition to the centrally arranged groove 7, so that the running surface 40 or 50 is interrupted on its circumference by a total of three recesses.

In operation, the shaft 1 rests on the running surfaces 40 and 50 on both sides of the groove 7 and 7 ', whereby its line of contact, which can also become the contact surface when the shaft 1 is pressed against the elastic covering, bridges the groove freely. The support of the shaft 1 on both sides of the recess ensures that the shaft 1 rolls off smoothly.

In Figure 3, other ways of forming recesses to interrupt the tread are shown. Cutouts to interrupt the tread are shown. In version a, a groove 70 runs spirally over the circumference of the tread. The embodiment b shows a running surface which is interrupted by a plurality of grooves 71 arranged at an angle to the direction of rotation of the support disk and at a distance from one another. The angle and the width of the grooves 71 are chosen so that the shaft 1 is not selected in the grooves 71 so that the shaft 1 cannot fall into the grooves, but bridges them. The course of the grooves 71 as well as the groove 70 in the embodiment a in FIG. 3 to the edge of the running surface, according to previous knowledge, makes the spinning rotor run smoothly not affected, since the tread for the shaft is sufficiently large in the area in which the groove runs out at the edge. If necessary, however, the groove 71 or 70 can also end in front of the tread edge, should this prove to be necessary.

It is also possible to insert ribs 8 made of plastic at a distance from one another in the base body of the support disk, which likewise results in a running surface interrupted by cutouts.

In design e, the base body of the support disk is provided with a web 41 which extends into the vicinity of the running surface and forms a recess together with the elastic covering.

The effect of the invention seems to be based on the fact that, as a result of the rotation of the support disks, an air flow is generated in the cutouts, which cools the elastic covering and thereby reduces wear caused by excessive heating, for better heat dissipation and thus for preventing Destruction of the covering leading to heat build-up, the recess must have an appropriate dimension. Experiments with a covering of 6 mm thickness have shown, for example, that a recess with a depth of approximately up to a third of the covering thickness is particularly effective. With the width of the recess, it should also be noted that effective ventilation and thus heat dissipation is guaranteed.

Claims (7)

1. A supporting-disc bearing for the shaft of an open-end spinning rotor, which shaft is supported in a wedge-shaped gap formed by supporting discs and is driven directly by a tangential belt, an axial thrust being exerted on the shaft via the supporting discs in order to press it against an axial bearing, and the supporting discs having a running surface made of a resilient coating, against which the shaft is pressed, characterised in that the running surface (40, 50) of the coating is interrupted by at least one recess (7, 7') - which is bridged freely by the line of contact of the rotor shaft - so that ventilation is brought about in the recess (7, 7') in order to cool the resilient supporting-disc coating.
2. A supporting-disc bearing according to Claim 1, characterised in that the recess has a depth of up to approximately one third of the coating thickness where the coating has a thickness of 6 mm.
3. A supporting-disc bearing according to Claim 1 or 2, characterised in that the recess is formed by a continuous groove (7, 7').
4. A supporting-disc bearing according to Claim 1 or 2, characterised in that the recess is formed by a groove (70) extending spirally over the periphery of the running surface (40, 50).
5. A supporting-disc bearing according to Claim 1 or 2, characterised in that the recesses are formed by several grooves (71) arranged at an angle to the direction of rotation of the supporting discs (4, 5) and at a distance from one another.
6. A supporting-disc bearing according to any one of Claims 1 to 5, characterised in that the running surface (40, 50) of the supporting discs (4, 5) is formed by coating ribs (8) arranged at a distance from one another.
7. A supporting-disc bearing according to any one of Claims 1 to 5, characterised in that the basic body of the supporting disc (4, 5) is provided with a web (41) which extends into the vicinity of the running surface (40, 50) and forms a recess together with the coating.

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