WO2010115518A2

WO2010115518A2 - Bearing sleeve, toothed wheel machine, and method for producing a bearing sleeve

Info

Publication number: WO2010115518A2
Application number: PCT/EP2010/001823
Authority: WO
Inventors: Ulrich Lendl
Original assignee: Robert Bosch Gmbh
Priority date: 2009-04-08
Filing date: 2010-03-24
Publication date: 2010-10-14
Also published as: WO2010115518A3; DE102009016915A1

Abstract

The invention relates to a bearing sleeve for a toothed wheel machine having an inner shell surface as a sliding surface, and an outer shell surface as a retaining surface for inserting into a bearing housing. In order to improve the bearing seat, the outer shell surface is provided with a groove arrangement.

Description

description

Laqerhülse. Gear machine and method for producing a bearing sleeve

The invention relates to a bearing sleeve according to the preamble of claim 1, a gear machine with such a bearing sleeve according to the preamble of claim 5 and a method for producing such a bearing sleeve according to the preamble of claim. 7

The document EP 0 683 807 B1 describes the structure of such a bearing sleeve. This has an inner bearing race, which is accommodated on a metal carrier, wherein the running layer consists of a metal-polymer composite material. The bearing sleeve is free of lead.

Document DE 26 01 647, however, discloses a bearing sleeve having lead components.

The document DE 199 24 057 A1 shows an external gear machine with bearing sleeves which, for example, correspond to the abovementioned bearing sleeves. The external gear machine has a pair of gears mounted in a housing, wherein the gears are each fixedly connected to a gear shaft. The gear shafts are slidably mounted on the bearing sleeves pressed into housing bores of the housing.

The document DE 10 2006 021 815 A1 represents an external gear machine in which the bearing sleeves are pressed into bearing bushes that are movable for the axial force compensation of the gears.

A disadvantage of the above-mentioned documents is that the bearing sleeves can be solved in the housing or in the bearing bushes in use of the external gear machine. A loosening of the bearing sleeves may cause them to move with the rotating gear shafts, which causes consequential damage, such as example, damage of Axialfelddichtungen, the housing or the bushings, to the total failure of the gear machine.

In contrast, the invention has for its object to provide a bearing sleeve with a tight fit and a cost-effective method for producing such a bearing sleeve.

Another object of the invention is to provide a gear machine which enables safe use and has a long service life.

These objects are achieved by a bearing sleeve according to the features of patent claim 1, a gear machine with such a bearing sleeve according to the features of patent claim 5 and a method for producing such a bearing sleeve according to the features of patent claim 7.

According to the invention has a bearing sleeve, in particular a plain bearing made of a metal-polymer composite material for a hydraulic displacement unit, an inner circumferential surface as a sliding surface and an outer circumferential surface as a holding surface for insertion into a bearing receptacle. In the outer circumferential surface a groove arrangement for improving the bearing seat is introduced.

In the installed state of the bearing sleeve, for example in a hydraulic displacer unit, the scoring arrangement leads to a much safer sleeve seat compared to the prior art with little additional manufacturing costs.

Advantageously, the groove arrangement is diamond-shaped, whereby forces in the circumferential and axial direction of the bearing sleeve can be absorbed by this.

Preferably, the scoring arrangement is introduced to reduce the manufacturing costs in a limited area of the outer circumferential surface.

A hydraulic displacement unit, in particular an external gear machine, has a housing for receiving two intermeshing gears, which are axially between two bearing bodies and radially in each case via a bearing receptacles of the bearing body slidably received bearing shaft are mounted. Advantageously, bearing bushes according to the invention are arranged between the bearing bodies and the bearing shafts in the bearing receptacles. As a result, an extremely safe operation of the displacer unit is achieved because a release of the bearing sleeves as in the prior art is hardly possible.

The bearing body of the displacer unit may consist of a softer material than the bearing sleeve, whereby the scoring arrangement can penetrate firmly into the material of the bearing body.

In order to increase the seating strength of the bearing sleeve even more, the scoring arrangement can be arranged in the loaded area of the bearing receptacles, as a result of which it is additionally pressed into the material of the bearing bodies via the bearing shafts.

In a cost-effective method for producing a bearing sleeve for a displacer unit, a scoring arrangement is introduced into a metal sheet and subsequently the sheet is rolled into a sleeve shape.

The scoring arrangement can be made with little effort with a tool that is also used for the production of finishing files with one-stroke, crosscut or rasp.

Other advantageous developments of the invention are the subject of further subclaims.

In the following, a preferred embodiment of the invention is explained in more detail with reference to schematic drawings. Show it:

1 shows a longitudinal section of an external gear machine according to an embodiment; and FIG. 2 is a perspective view of a bearing sleeve of the external gear machine from FIG. 1.

Figure 1 shows an inventive, as Außenenzahnrahpumpe, running gear machine 1 with a housing 2, which has an inner space 4, which is bounded by two attached to the housing 2 covers 6, 8, according to one embodiment. In the interior 4 of the housing 2, a gear arrangement 10 is arranged, which has two meshing with each other in external engagement gears 12, 14.

The gear 12 is rotatably connected to a drive shaft 16 and mounted on this in the housing 2. The drive shaft 16 is guided on a drive side 18 by the cover 6 designed as a bearing cover to the outside and sealed by a shaft seal 20 which limits a shaft seal chamber 22. The second gear 14 is rotatably connected to a bearing axis 24.

The gear wheels 12, 14 are mounted in bearing receivers 30, 32 via the drive shaft 16 or the bearing axle 24 in two bearing bushes 26, 28 arranged opposite one another in the interior of the housing 2. To reduce the bearing friction and improve the emergency running properties, the bearing receivers 30, 32 are each provided with a bearing sleeve 34. The bushings 26, 28 may also be in several parts, for example, in two parts with one of the shaft 16 and one of the axle 24 associated bearing part executed in a non-illustrated embodiment.

Between the covers 6, 8 on the one hand and the housing 2 and the bearing bodies 26, 28 on the other hand, an axial field seal 36, 38 is arranged with a substantially rectangular cross section, wherein between a bearing body side support surface 40 for the Axialfelddichtungen 36, 38 and the inside 42 of the lid 6, 8 an axial play Y exists. Outside the Axialfelddichtungen 36, 38, an annular housing seal 44, 46 is provided in each case, which seals the housing 2 to the outside. In the illustrated embodiment, the Axialfelddichtungen 36, 38 and the housing seals 44, 46 in grooves 48, 49 of the cover 6, 8 are arranged. Figure 2 shows in a perspective view, the bearing sleeve 34 of Figure 1 according to the Ausf darhrungsbeispiel. This is a metal-polymer composite existing sliding bearing. The metal-polymer composite is based, for example, on a polytetrafluoroethylene (PTFE) base, in particular DU® or DP31 ™. Bushings 34 made of DP31 ™ have a higher load capacity than bearing bushings 34 made of DU® and free of lead (Pb).

The bearing sleeves 34 have a metal back with an outer circumferential surface 52 and an inner intermediate layer of porous sintered bronze. Pores of the bronze are filled in a rolling process with a mixture of PTFE and Gleitzuskätzen and covered. While the metal backing ensures a high mechanical strength and stability, the intermediate layer provides a firm clamping with a running surface or sliding surface 54.

In the bearing sleeves 34 a scoring arrangement 56 is introduced from the outer lateral surface 52 forth. This has two Riefenfelder 58, 60 with each approximately parallel to each other and employed to a longitudinal axis of the bearing sleeve 34 grooves 62, wherein the Riefenfelder 58, 60 are approximately cross-shaped or diamond-shaped one above the other. The individual roughly rectilinear grooves 62 each extend over the entire width of the bearing sleeve 34.

During assembly, the bearing sleeves 34 are pressed into the bearing receivers 30, 32 of the bearing bushes 26, 28 of Figure 1 form, force and / or frictionally engaged in a known manner. During the pressing process and / or in use of the gear machine 1, with a radial loading of the bearing sleeves 34 via the drive shaft 16 and the bearing shaft 24, the scoring arrangement 56 of the bearing sleeves 34 penetrates into the bearing bushes 26, 28, in particular because the bearing bushes 26, 28 of a softer material (for example, aluminum) than the metal back of the bearing sleeves 34 (for example steel) consists. By the groove arrangement 56 is thus an increased positive, non-positive and / or frictional connection between the bearing sleeves 34 and the bearing bushes 26, 28 as in the above-described prior art. The scoring arrangement 56 additionally counteracts forces in the circumferential direction and in the axial direction. The groove arrangement 56 is introduced in FIG. 2 in a limited area of the outer lateral surface 52 of the bearing sleeves 34. In the mounted state of the bearing sleeves 34, the groove arrangement 56 is arranged in the highly loaded region of the bearing bushes 26, 28. This is located at an external gear pump approximately on the suction side in the low pressure region of the gears 12, 14th

Strict requirements with respect to mass, shape and position tolerances of the gear machine 1 are essentially unaffected by the additional scoring arrangement 56.

The bearing sleeves 34 are made for example of a metal strip. This is provided in a first step with the groove assembly 56, for example by a sizing file and then cut. The cut sheet metal parts are then rolled into the shape of the bearing sleeve 34.

Alternatively, the scoring arrangement 56 can be introduced over the entire area of the outer lateral surface 52 of the bearing sleeves 34.

Disclosed is a bearing sleeve for a gear machine with an inner circumferential surface as a sliding surface and an outer circumferential surface as a holding surface for insertion into a bearing receptacle. To improve the bearing seat, a scoring arrangement is introduced into the outer circumferential surface.

Claims

8/9 claims

1. bearing sleeve, in particular a plain bearing made of a metal-polymer composite material, for a hydraulic displacement unit, wherein an inner lateral surface as a sliding surface and an outer lateral surface are formed as a holding surface for insertion into a bearing receptacle, characterized in that in the outer lateral surface of a groove arrangement for improving Bearing seat is introduced.

2. bearing sleeve according to claim 1, wherein the groove arrangement is diamond-shaped.

3. bearing sleeve according to claim 1 or 2, wherein the groove arrangement is introduced in a limited area of the outer circumferential surface.

4. Hydraulic displacer unit, in particular external gear machine, with a housing for receiving two intermeshing gears, which are mounted axially between two bearing body and radially via a bearing receptacles of the bearing body slidably received bearing shaft, characterized in that between the bearing bodies and the bearing shafts in the Bearing mounts bearing sleeves are arranged according to one of claims 1 to 3.

5. Displacer unit according to claim 4, wherein the bearing body consists of a softer material than the bearing sleeve and the bearing sleeve is pressed into the bearing receptacle of the bearing body.

6. displacer unit according to claim 4 or 5, wherein the scoring arrangement is arranged in the loaded area of the bearing receptacles.

7. A method for producing a bearing sleeve for a displacer unit, characterized in that a scoring arrangement is placed on a metal sheet and subsequently the sheet is rolled into a sleeve shape. 9/9

8. The method of claim 7 wherein the scoring arrangement is made with a tool used for the manufacture of sizing files.