DE102011121935B4 - Bearing bush with bearing for use in an electrical machine - Google Patents

Abstract

Bearing bush (18; 118) with a bearing (17; 26) for rotatably receiving a shaft (9) or axle, the bearing bush (18; 118) having two axial sections, one bearing section (19, 119) supporting the bearing (17 ) or serves to receive a bearing (26) and wherein a fastening section (20) for fastening the bearing bushing (18; 118), and only this, is formed on an injection-molded part made of plastic of a machine or device, and wherein the inner diameter ( IB) of the fastening section (20) is larger by an oversize (M) than the inner diameter of the bearing (DW), so that the inner surface (23) of the fastening section (20) does not touch a shaft (9) or axis running in the bearing bush,
characterized in that
the oversize (M) is between 5% and 10% of the bearing inner diameter (DW);
the bearing bush (18; 118) has an axial fixation on the fastening section (20); and
the bearing bush (18; 118) has an anti-twist device on the fastening section (20).

Description

The invention describes a bearing bush with a bearing for rotatably receiving a shaft or axle, the bearing bush being attachable to an injection-molded part made of plastic of a machine or device.

For example, such a machine or device can be an electrical machine with an injection-molded housing made of plastic, in which a bearing bush with a bearing is arranged and which has a rotor which is rotatably supported on a shaft in the bearing.

Such an electrical machine is, for example, a fuel pump with an electric motor excited by permanent magnets. Since the engine typically has fuel flowing through it, a bearing with plain bearings is obvious.

The bearing bush can, for example, be designed in one piece with the housing, the sliding bearing being produced directly during the injection molding of the housing. As a result, however, the plain bearing is made of the same material as the housing. However, in order to obtain good bearing properties, it is advisable to use a special bearing material that is, for example, harder and has less friction.

It is therefore sensible to use a separate bearing bush that has to be connected to the housing. This can be done, for example, by means of a flange connection in which the bearing bush serves as part of the housing. However, this is complex, since the bearing bush and the rest of the housing have to be aligned and screwed in a complex manner, which is expensive.

It is therefore known to encapsulate the bearing bush with plastic in the injection molding of the housing. Due to the high injection molding pressure of around 800 bar, however, the bearing bush is deformed. The plain bearing must therefore be adapted to the shaft or axle by machining, which is also time-consuming and expensive. From the pamphlets DE 10 2008 020 330 A1 , DE 10 2008 041 271 A1 , DE 20 41 677 A , US 6 250 809 B1 , US2004 / 0175063 A1 , U.S. 5,938,345 A , U.S. 4,090,746 A , DE 10 2004 041 084 A1 , and DE 73 02 695 U exemplary bearing bushings and corresponding devices according to the preamble of claim 1 are known.

This post-processing cannot be prevented by a mandrel that is inserted into the bearing bush during the injection molding process.

The object of the invention is therefore to create a bearing bush for an electrical machine of the aforementioned type which can be produced more simply and cost-effectively.

According to the invention, this object is achieved by the bearing bushing with the features mentioned in the main claim.

To achieve the effect according to the invention, the bearing bush has two axial sections. The bearing is arranged in a first section, the bearing section. At first it does not matter which type of storage is used. The bearing section can, for example, have a bearing seat into which a roller bearing or a plain bearing is inserted. An inner surface of the bearing section can itself also represent a bearing surface, for example the sliding surface of a sliding bearing or the outer ring of a roller bearing.

A second section, the fastening section, is used to fasten the bearing bush to an injection-molded housing, for example. For this purpose, in particular, only this fastening section is encapsulated during the injection molding of the housing. As a result, the injection molding pressure only acts on this fastening section of the bearing bush. Here, too, deformation of the bearing bush cannot be prevented. The trick of the invention is that the inner diameter of the bearing bush in the fastening section is so large that it is even larger than the diameter of the shaft or axle even after the deformation by the injection molding. This prevents the deformed bearing bushing from touching the shaft or axle.
In contrast, the bearing section is not acted upon by the injection molding pressure, so that a bearing or a bearing seat arranged there is not impaired by the injection molding process. The bearing bush can therefore already be manufactured with a bearing section made to measure and no further reworking is necessary after the injection molding of the housing. There is therefore no need for a complex work step, which means that production is much simpler and more cost-effective.

The oversize of the inside diameter of the fastening section is about 5% to 10% of the inside diameter of the bearing. However, this value can vary depending on the materials and wall thicknesses used for the housing and the bearing bushing and the injection molding pressure, so that smaller or larger oversize can also be sufficient or necessary.

The bearing bush can be overmolded with the plastic of the housing. So that the bearing bush is securely fixed in the housing, the bearing bush has an axial fixation. To do this, points For example, the bearing bush on the outer circumference of the fastening section has at least one protrusion or a recess which causes a form-fitting toothing between the bearing bush and the housing.

In addition, an anti-rotation device is arranged on the fastening section, which prevents rotation of the bearing bush within the housing.

Both can be achieved together, for example, in that a circumferential ring is arranged as an axial fixation on the outer circumference of the fastening section, which ring has several radial projections as an anti-twist device.

In an advantageous embodiment of the invention, the bearing section has a sliding surface which serves as a sliding bearing for the shaft or axle. Thus, besides the bearing bush, no further components are necessary, so that the bearing can be manufactured inexpensively and easily.

In this case, a separate bearing bush is preferably used which, independently of the housing, can consist of a material optimized for a plain bearing. In particular, the bearing bush consists of a plastic, for example a glass fiber reinforced polyphenylene sulfide (PPS) with 65% glass fiber.
The bearing bush is preferably also produced in a separate injection molding process. In particular, the sliding bearing surface can already be dimensioned to measure for the shaft of the rotor.

The invention is explained in more detail using an exemplary embodiment with reference to the accompanying drawings.

• 1 einen Querschnitt durch eine Kraftstoffpumpe mit einem erfindungsgemäßen Elektromotor als Pumpenantrieb,
• 2 eine Schrägansicht einer Lagerbuchse,
• 3 einen Querschnitt der Lagerbuchse und
• 4 eine Vorderansicht der Lagerbuchse.

It shows:

• 1 a cross section through a fuel pump with an electric motor according to the invention as a pump drive,
• 2 an oblique view of a bearing bush,
• 3 a cross section of the bearing bush and
• 4th a front view of the bearing bush.

the 1 shows a fuel pump designated as a whole by 1 as an application example for an electrical machine with a bearing bush according to the invention. The fuel pump 1 has a housing 2 made of plastic that is manufactured in an injection molding process. The fuel pump has an electric machine, preferably an electric motor, as a drive 3 with a stator 4th and a rotor 5 on.

The stator 4th is in the case 2 arranged and is completely encapsulated by plastic. The stator 4th has a stator body in the example 6th made from individual stator laminations 7th is stacked and on which the stator windings 8th are arranged.
The rotor 5 exhibits a wave 9 on which a rotor body 10 Is rotatably arranged. On the rotor body 10 is a permanent ring magnet 11 as a drive magnet opposite the stator body 6th arranged. The rotor body 10 consists for example of plastic or is stacked from individual rotor sheets. Instead of the ring magnet, embedded bar magnets or other permanent magnets can also be used. The configurations of the stator and the rotor do not play a role for the invention, which is why the invention is not limited to the example shown. The invention can also be used with any desired electric motor or generator.
Still on the wave 9 an impeller 12th attached to the fuel, or any other liquid, by the pump 1 promotes. The fuel comes in through an inlet 13th on the inlet side 14th sucked in and through outlets 15th on the outlet side 16 diverted again.
The exact design of the fuel pump 1 and the drive motor 4th do not play a role for the invention and are only shown here by way of example.

The wave 9 is on the exhaust side 16 of the housing 2 in a plain bearing 17th rotatably mounted. On the inlet side 14th Such a plain bearing, any other bearing or even no bearing can also be present.

The plain bearing 17th is in one of the housing 2 separate bearing bush 18th arranged in the 2 until 3 is shown in more detail. The plain bearing surface 24 the plain bearing is directly in the bearing bush 18th arranged. The bearing bush 18th is therefore injection molded from a plastic that has low friction and low abrasion. A suitable material is, for example, glass fiber reinforced PPS, the glass fiber content being 65%, for example. The bearing bushing can, however, also be made from another plastic, a metal, for example sintered bronze, or another plain bearing material.
Instead of the plain bearing, the bearing bush can also have a bearing seat for receiving a roller bearing or a separate plain bearing.

According to the invention, the bearing bush 18th two axial sections. A first section of the warehouse 19th and a second attachment portion 20th . The warehouse section 19th indicates the bearing, in the example the plain bearing 17th , on. That is the plain bearing surface 24 is located on the inner circumference of the bearing section.

The fastening section 20th is used to fasten the bearing bush 18th on the housing 2 . The bearing bush 18th is according to the invention only in the fastening section 20th with the case 2 connected. For this purpose, the fastening section is encapsulated with plastic during the injection molding of the housing.

For axial fixation of the bearing bush 18th in the housing 2 is on the outer circumference of the fastening section 20th a circumferential ring 21 arranged. In the example is the ring 21 about half as wide as the fastening section 20th and is placed in the middle of it. The ring 21 has a larger outer diameter than the rest of the fastening section 20th so that the ring is encompassed radially and has an axial toothing with the housing 2 arises.
Additionally are on the outer circumference of the ring 21 several radial protrusions 22nd arranged as an anti-rotation device, which is the bearing bush 18th in the housing 2 secure against twisting. These two measures result in the injection molding of the housing 2 a form-fitting toothing with the bearing bush 18th .

During the injection molding process, the injection molding pressure, for example 800 bar, only acts on the fastening section 20th . This cannot prevent the bearing bush from moving 18th in the fastening section 20th deformed under the injection molding pressure.
The inside diameter is therefore according to the invention IB the bearing bush 18th in the fastening section 20th larger than the inner diameter of the bearing DW . In particular, the inside diameter is IB so large that even after the injection molding process, the deformed fastening portion 20th not the wave 9 or touches an axis. The excess M. the inside diameter IB to the inside diameter of the bearing DW in the example is about 5% of the inner diameter of the bearing DW .

Due to the axial separation of the bearing bush 18th in the two sections, the storage section remains 19th during the injection molding of the housing 2 completely untouched. The bearing bush 18th can therefore already be done with a dimensionally accurate and ready-to-use plain bearing 17th getting produced. After the housing is injection molded 2 is no reworking of the plain bearing 17th necessary, whereby the production of the electrical machine is much simpler and therefore more cost-effective.

In 4th is an example of a bearing bush 118 with a bearing seat 25th that is in a warehouse section 119 is arranged for receiving a ball bearing 26th shown. Again, only the fastening section is used 20th encapsulated. The warehouse section 119 with the bearing seat 25th stays untouched. Here, too, after the injection molding of the housing 2 directly a roller bearing 26th in the already dimensionally accurate bearing seat 25th can be used without the need for extensive rework. The warehouse 26th but can also be placed in the bearing seat before the injection molding 25th can be used.

The exemplary embodiments shown serve only to illustrate the invention and are in no way restrictive. In particular, the shape of the bearing bush, the shape, number and configuration of the axial fixation and the anti-rotation device can be varied almost as desired without any loss of function.

List of reference symbols

1

Fuel pump

2

casing

3

Electric machine

4th

stator

5

rotor

6th

Stator body

7th

Stator lamination

8th

Stator winding

9

wave

10

Rotor body

11th

Ring magnet

12th

Impeller

13th

inlet

14th

Inlet side

15th

Outlet

16

Outlet side

17th

bearings

18, 118

Bearing bush

19, 119

Warehouse section

20th

Fastening section

21

ring

22nd

Radial projection

23

Inner surface fastening section

24

Plain bearing surface

25th

Bearing seat

26th

ball-bearing

27

Outer ring stop

DW

Bearing inside diameter

IB

Inner diameter mounting section

M.

Excess

Claims (8)

Bearing bush (18; 118) with a bearing (17; 26) for rotatably receiving a shaft (9) or Axis, wherein the bearing bush (18; 118) has two axial sections, wherein a bearing section (19, 119) has the bearing (17) or serves to accommodate a bearing (26) and wherein a fastening section (20) for fastening the bearing bush ( 18; 118), and only this is formed on an injection-molded part made of plastic of a machine or device, and wherein the inner diameter (IB) of the fastening section (20) is an excess (M) greater than the inner diameter of the bearing (DW) so that the inner surface (23) of the fastening section (20) does not touch a shaft (9) or axle running in the bearing bush, characterized in that the oversize (M) is between 5% and 10% of the bearing inner diameter (DW); the bearing bush (18; 118) has an axial fixation on the fastening section (20); and the bearing bush (18; 118) on the fastening section (20) has an anti-twist device. Bearing bush (118) Claim 1 , characterized in that the bearing section (20) has a bearing seat (25) for inserting the bearing (26). Bearing bush (18) Claim 1 , characterized in that the bearing section (20) has a sliding surface (24) which serves as a sliding bearing (17) for a shaft (9) or axle. Bearing bush (18; 118) with a bearing (17; 26) according to one of the Claims 1 until 3 , characterized in that the bearing bush (18; 118) consists of plastic. Bearing bush (18; 118) with a bearing (17; 26) according to Claim 4 , characterized in that the bearing bush (18; 118) is injection molded. Bearing bush (18; 118) with a bearing (17; 26) according to one of the preceding claims, characterized in that a circumferential ring (21) is arranged as an axial fixation on the outer circumference of the fastening area (20), which ring has several radial projections (22) has as an anti-twist device. Electrical machine (3) with a bearing bush (18; 118) according to one of the preceding Claims 1 until 6th , with a rotor (5) which is connected to a shaft (9) or axle which is rotatably mounted in the bearing (17; 26) and a stator (4), characterized in that the stator (4) and the bearing bush (18; 118) are arranged in an injection-molded housing (2) made of plastic. Fuel pump (1) with an electric motor Claim 7 .

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