DE102006058978A1 - Vane pump, for motor vehicles, has a structured base plate and/or cover plate at the pump chamber to prevent snagging by the rotor impellers - Google Patents

Abstract

The vane pump (1) has a pump chamber with a base plate and a cover plate. The base plate (4) and/or the cover plate (8) are structured so that, when the pump is operating, the impellers (6) at the rotor (5) cannot snag at the fluid inflow and/or outflow. The fluid inflow opening (24) has at least one chamfer to guide the rotor impeller during rotation.

Description

The The present invention relates to a vane pump according to the preamble of claim 1.

Vane pumps, which are often referred to as rotary vane pumps, are already known from the prior art in different embodiments. Vane pumps of the type mentioned, which can be used in particular in motor vehicles, are for example in the DE 100 24 669 A1 as well as in the DE 199 36 644 B4 disclosed.

at the known from the prior art vane pumps is often the Problem that it leads to slide breaks and thus also damage The rotor may come when one of the sliders at the fluid inlet or entangled at the fluid outlet of the pump chamber, since both the rotor as well as the guide slots slidable therein arranged slider made of a comparatively brittle material consist.

Here uses the present invention.

Of the The present invention is based on the object, a vane pump to disposal to make, which is designed such that slide and thus also rotor breaks can be easily prevented.

These Task is by a vane pump solved with the features of claim 1. The dependent claims relate advantageous developments of the present invention.

According to claim 1, a vane pump according to the invention is characterized by that the base plate and / or the cover plate are / is designed, that while the operation of the vane pump snagging one of the sliders on the at least one fluid inlet and / or prevents at least one fluid outlet of the pump chamber can be. Due to the inventive design of the base plate and / or the cover plate may increase the risk of slide and thus also rotor breaks in comparison to the known from the prior art solutions in be reduced particularly advantageous.

In a preferred embodiment it is proposed that the fluid inlet comprises at least one fluid inlet opening, which is formed in the base plate and has at least one chamfer, suitable, a guide the slider during the rotation of the rotor available to deliver. With the help of at least one chamfer of Fluid inlet opening can catch the slider during the rotation of the rotor can be prevented, since such chamfer a guide for the slide of the rotor provides.

There It has been shown that a snagging of the slide often after the passing the fluid inlet opening at the transition to the base plate is, in a particularly preferred embodiment proposed that the at least one bevel of the at least one fluid inlet opening in Direction of rotation of the rotor viewed at a rear end of the fluid inlet opening is arranged.

Around to simplify the production of the at least one chamfer, is in an advantageous embodiment provided that the at least one chamfer integrally formed with the base plate is.

In a particularly advantageous embodiment is provided the fluid outlet comprises at least one fluid outlet opening, which is formed in the cover plate and has at least one chamfer, suitable, a guide of Slide during the rotation of the rotor available to deliver. By the measure, that the fluid outlet opening has at least one chamfer, can be prevented in an advantageous manner that is one of Slide during the rotation of the rotor at the at least one fluid outlet opening of the Can catch the cover plate.

It In an advantageous embodiment, it is possible to that the at least one chamfer the at least one fluid outlet opening in the direction of rotation of Rotor viewed at a rear end of the fluid outlet opening is arranged.

Preferably is the at least one chamfer is integrally formed with the cover plate to thereby manufacture the bevel to simplify.

There is also the possibility that the at least one fluid inlet opening of the base plate and / or the at least one fluid outlet opening of the cover plate viewed in the direction of rotation of the rotor both at a front end and at the rear end each have a chamfer. It has been found that the additional bevelling of the at least one fluid inlet opening of the base plate and / or the at least one fluid outlet opening of the cover plate can positively influence the acoustic behavior of the vane pump during the rotation of the rotor, so that the operation the vane pump can be quieter.

In an advantageous embodiment it can be provided that the fluid inlet at least one fluid inlet channel includes, which is formed in the cover plate and at least a chamfer has, suitable, a guide the slider during the rotation of the rotor available to deliver. In this variant, this can be done during operation of the vane pump sucked fluid, for example, first by one or more Fluid inlet channels the base plate and then through one or more fluid guide channels of the pump ring flow into the at least one fluid inlet channel of the cover plate and then through the at least one fluid inlet channel, for example may be formed as a recess, directed into the pump chamber become.

In In a particularly advantageous embodiment, the at least a chamfer viewed in the direction of rotation of the rotor at a rear end of the rotor Fluid inlet channel may be arranged.

Based the attached Drawings, the invention is explained in more detail below. Showing:

1 an exploded view of a vane pump according to a first embodiment of the present invention;

2 a perspective view of the vane pump according to 1 after assembly;

3 a partially sectioned plan view of a pump head of the vane pump according to 1 ;

4 a plan view of a base plate of a pump chamber of the vane pump according to 1 ;

5 a plan view of the base plate according to 4 after mounting a pump ring and a rotor;

6 a plan view of a cover plate of the pump chamber of the vane pump according to 1 ;

7 a plan view of the cover plate according to 6 after mounting the pump ring and the rotor;

8th an exploded view of a vane pump according to a second embodiment of the present invention;

9 a partially sectioned plan view of a pump head of the wing cell pump according to 8th ;

10 a perspective view of a cover plate of a pump chamber of the vane pump according to 8th ;

11 a further perspective view of the cover plate of the pump chamber of the vane pump according to 8th ;

12 a transparent representation of the pump chamber of the vane pump according to 8th ,

First, it will open 1 and 2 Reference is made in which an exploded view and a perspective view of a vane pump 1 are shown according to a first embodiment of the present invention. The vane pump 1 can be designed in particular as a vacuum pump for generating a vacuum, which operates on the so-called displacement principle.

The vane pump 1 comprises an electric drive unit comprising an electric motor with a motor shaft 13 includes. The electric drive unit is inside a housing 12 the vane pump 1 accommodated. Furthermore, the vane pump includes 1 in this embodiment, a mounting plate 15 on the case 12 fastened by means of suitable fastening means, which are not explicitly shown here. The mounting plate 15 has a central opening through which the motor shaft 13 of the electric motor after assembly extends therethrough.

It can also be seen on the outer circumference of the mounting plate 15 an intake manifold 20 through which during the operation of the vane pump 1 For example, air or other fluid can be sucked. The mounting plate 15 also has a fluid outlet opening 23 on that with the intake manifold 20 is in fluid communication. In operation, this flows over the intake manifold 20 sucked fluid through the fluid outlet opening 23 in a pump chamber of the vane pump 1 one. The pump chamber comprises a base plate 4 , a pump ring 7 and a cover plate 8th which are arranged one above the other. The pump ring 7 has in this embodiment, as in particular 3 . 5 and 7 to recognize a substantially circular inner contour.

Inside the pump chamber is a rotor 5 eccentrically arranged to receive a number of sliders 6 suitable is. In this embodiment, the rotor 5 a total of four shots about 6 on, each in corresponding guide slots 61 of the rotor 5 which is substantially cylindrical in this embodiment, are arranged displaceably. The eccentric arrangement of the rotor 5 in the pump chamber as well as the guide slots 61 in which the sliders 6 are arranged displaceably and are guided, in particular in 5 and 7 to recognize.

The rotor 5 becomes during operation of the vane pump 1 from the motor shaft 13 driven by the electric motor and thereby set in rotation. For this purpose, the rotor 5 via a correspondingly shaped driver 19 into a receiving opening 50 of the rotor 5 engages, with the motor shaft 13 connected. The driver 19 is in turn rotationally fixed to the motor shaft 13 attached to the electric motor.

Between the base plate 4 and the mounting plate 15 is also in the area of the outlet opening 23 a seal 3 arranged. It can be seen that the shape of the seal 3 essentially the outer contour of the fluid outlet opening 23 the mounting plate 15 corresponds so that it can be effectively sealed after assembly.

The pump chamber, which is the base plate 4 , the pump ring 7 and the cover plate 8th includes, is by means of several mounting screws 9 , which during assembly in corresponding threaded holes 18 the mounting plate 15 can engage, on the mounting plate 15 attached. During assembly, the seal 3 thus between the base plate 4 and the mounting plate 15 fixed in a clamping, thereby the fluid outlet opening 23 effectively seal.

In addition, the vane pump includes 1 a sealing ring 2 , when mounting on the mounting plate 15 is put on. The sealing ring 2 is for sealing a substantially cap-like muffler 10 suitable, which the vane pump 1 terminates at the end. The silencer 10 is with the help of suitable fixing screws 11 on the mounting plate 15 attached. For this purpose, the mounting plate 15 several threaded holes 17 on, in which the fixing screws 11 of the muffler 10 intervene during assembly. In addition, the mounting plate points 15 a recess 14 on, with a fluid outlet not shown here of the vane pump 1 is in fluid communication.

During operation of the vane pump 1 the fluid flows through the intake manifold 20 and from there through the fluid outlet opening 23 the mounting plate 15 and then through a fluid inlet opening 24 the base plate 4 in the pump chamber. The fluid leaves the pump chamber through at least one fluid outlet opening 25 in the cover plate 8th is formed, and then flows into the substantially cap-shaped muffler 10 and then through the recess 14 to the fluid outlet opening of the vane pump 1 ,

In 4 is a plan view of the base plate 4 the vane pump 1 shown. It can be seen in this illustration, the fluid inlet opening 24 the base plate 4 connected to the fluid outlet opening 23 the mounting plate 15 corresponds, so that the sucked fluid during operation of the vane pump 1 from the fluid outlet opening 23 the mounting plate 15 through the fluid inlet opening 24 the base plate 4 can flow into the pump chamber. The fluid inlet opening 24 extends in sections in the circumferential direction of the rotor 5 ,

With further reference to 5 in which the base plate 4 together with the attached pump ring 7 , the rotor 5 as well as the sliders 6 is shown, it is clear that the rotor 5 is arranged eccentrically in the pump chamber. As a result, the slides form 6 together with an inner wall 70 of the pump ring 7 different sized chambers. The direction of rotation of the rotor 5 is in 5 indicated by an arrow.

To during the operation of the vane pump 1 Fractures of the slides 6 or the rotor 5 , which consist of comparatively brittle materials to prevent, has the base plate 4 , as in 4 and 5 to recognize, in the direction of rotation of the rotor 5 considered at the rear end of the fluid inlet opening 24 a chamfer 26 on, which is integral with the base plate 4 is trained. This chamfer 26 at the rear end of the fluid inlet opening 24 is suitable for hooking it to it during rotation of the rotor 5 passing slider 6 to prevent. It becomes clear that at the rear end of the fluid inlet opening 24 trained bevel 26 a guide for the sliders 6 of the rotor 5 can provide and thereby catching the slider 6 can prevent. In this embodiment, the fluid inlet opening 24 the base plate 4 in the direction of rotation of the rotor 5 also looks at its front end a bevel 26 ' on. Through this further bevel 26 ' can the running noise of the rotor 5 during operation of the vane pump 1 be reduced.

In 6 which is a top view of the cover plate 8th the pump chamber shows, it can be seen that the cover plate 8th a fluid outlet opening 25 through which the fluid during operation of the vane pump 1 can flow out. The fluid outlet opening also extends in sections in the circumferential direction of the rotor 5 , With further reference to 7 in which the cover plate 8th after mounting the pump ring 7 and the rotor 5 from the direction of the base plate 4 is shown, it is clear that the fluid outlet opening 25 in the direction of rotation of the rotor 5 considered, which in turn is indicated by an arrow, at a rear end a chamfer 27 having. This chamfer 27 also provides a guide for the slides 6 of the rotor 5 during operation of the vane pump 1 available and can thus in the same way as the bevel described above 26 the fluid inlet opening 24 the base plate 4 a snagging of the slide 6 during the rotation of the rotor 5 prevent.

In this embodiment, the fluid outlet opening 25 the cover plate 8th in the direction of rotation of the rotor 5 also looks at its front end a bevel 27 ' on. Through this further bevel 27 ' can the running noise of the rotor 5 during operation of the vane pump 1 be reduced.

In 8th is an exploded view of a vane pump 1 according to a second embodiment of the present invention. The basic operating principle and thus also the essential components of the embodiment of the vane cell pump shown here 1 correspond to those of the first embodiment. Identical or functionally identical components of the vane pump 1 were therefore provided with the same reference numerals as in the first embodiment. The main focus will be on the differences from the first embodiment.

An essential difference from the first embodiment is that the pump ring 7 the vane pump 1 , in particular in 9 and 12 to recognize, having a substantially elliptical inner contour. The rotor 5 has in this embodiment a total of eight slides 6 on that in corresponding guide slots 61 of the rotor 5 are slidably mounted. As will be explained in more detail below, the flow guidance of the fluid in the vane cell pump shown here also differs from the flow guidance of the first exemplary embodiment. With reference to 12 in which the pump head of the vane pump 1 is shown transparent, you can see that the slider 6 of the rotor 5 in the guide slots 61 slidably disposed together with the inner wall 70 of the pump ring 7 training different sized chambers.

The mounting plate 15 which the housing 12 , in which the drive unit is housed with the electric motor, terminates at the end, in this embodiment has a more open design than in the first embodiment. You can see the motor shaft again 13 in an engine mount 80 is rotatably mounted. The rotor 5 is about a driver 19 at the motor shaft 13 attached. The vane pump 1 does not have a separate sealing ring for the muffler in this embodiment 10 on. Rather, in this embodiment, a sealing element 3 provided, which also serves to seal the muffler 10 is suitable, and thus the sealing ring 2 and the sealing element 3 of the first embodiment replaced.

In 10 is the muffler 10 facing side of the cover plate 8th the pump chamber shown in perspective. It can be seen that the cover plate 8th two fluid outlet openings 25 which equidistant from the center of the cover plate 8th and are arranged diametrically opposite. Through these two fluid outlet openings 25 can during operation of the vane pump 1 a fluid flow out of the pump chamber.

With reference to 11 in which the rotor 5 facing side of the cover plate 8th is shown in perspective, it can be seen that the fluid outlet openings 25 one bevel each 27 have to guide the slider 6 of the rotor 5 during operation of the vane pump 1 to provide and thereby catching the slider 6 to prevent. The chamfers 27 are as further reference to 12 to recognize, in the direction of rotation of the rotor 5 considered, which runs in this display plane counterclockwise, at a rear end of the fluid outlet openings 25 arranged.

In this embodiment, the fluid outlet opening 25 the cover plate 8th in the direction of rotation of the rotor 5 also looks at its front end a bevel 27 ' on. Through this further bevel 27 ' can the running noise of the rotor 5 during operation of the vane pump 1 be reduced.

The essentially disc-shaped cover plate 8th indicates at her the rotor 5 after assembly facing base on two opposite edge regions each have a fluid inlet channel 34 on, the sections in the circumferential direction of the rotor 5 extends. The two fluid inlet channels 34 are formed in this embodiment, for example, as recesses and thus penetrate the cover plate 8th Not. Through the fluid inlet channels 34 can during operation of the vane pump 1 a fluid, in particular air, are directed into the pump chamber. The two fluid inlet channels 34 each have a bevel 36 on, which - as in 12 to recognize - in the direction of rotation of the rotor 5 considered at a rear end the fluid inlet channels 34 are arranged. The chamfers 36 at the fluid inlet channels 34 are designed and adapted to guide the slider 6 during operation of the vane pump 1 be available, thereby a hooking during the rotation of the rotor 5 passing slider 6 counteract.

Below is the flow guidance of the fluid in the vane pump shown here 1 be explained in more detail. During operation of the vane pump 1 that flows over the intake manifold 20 sucked fluid through two oppositely disposed fluid inlet channels 37 the base plate 4 that, like in 8th to recognize, sections in the circumferential direction of the base plate 4 extend and thus are formed substantially part-ring-shaped. Subsequently, the fluid flows through two fluid guide channels 38 of the over the base plate 4 arranged pump ring 7 , The two fluid guide channels 38 are the fluid inlet channels 37 the base plate 4 assigned and designed so that they are aligned with them. After flowing through the two fluid guide channels 38 of the pump ring 7 the fluid passes to the cover plate 8th and then through the fluid inlet channels 34 passing over the fluid guide channels 38 of the pump ring 7 are arranged to flow into the pump chamber. The fluid leaves the pump chamber through the two fluid outlet openings 25 in the cover plate 8th is formed, and then flows into the substantially cap-shaped muffler 10 and then through the recess 14 to the fluid outlet opening of the vane pump 1 ,

1

Vane pump

2

seal

3

poetry

4

baseplate

5

rotor

6

pusher

7

pump ring

8th

cover

9

fixing screw

10

silencer

11

fixing screw

12

casing

13

motor shaft

14

recess

15

mounting plate

17

threaded hole

18

threaded hole

19

takeaway

20

intake

23

Fluid outlet opening

24

Fluid inlet opening

25

Fluid outlet opening

26 26 '

bevel

27 27 '

bevel

34

Fluid inlet channel

36

bevel

37

Fluid inlet channel

38

Fluid guide channel

50

receiving opening

61

guide slot

70

inner wall

80

motor bearings

Claims (10)

Vane pump ( 1 ), comprising: - a housing ( 12 ), in which an electric drive unit is accommodated, - a pump chamber, a base plate ( 4 ), a pump ring ( 7 ), a cover plate ( 8th ) and at least one fluid inlet and at least one fluid outlet, - a rotor ( 5 ) with a number of sliders ( 6 ) which is rotatably disposed within the pump chamber and operably connected to the electric drive unit, characterized in that the base plate ( 4 ) and / or the cover plate ( 8th ) are designed so that during operation of the vane pump ( 1 ) a hooking of one of the slides ( 6 ) can be prevented at the at least one fluid inlet and / or at the at least one fluid outlet of the pump chamber. Vane pump ( 1 ) according to claim 1, characterized in that the fluid inlet at least one fluid inlet opening ( 24 ), which in the base plate ( 4 ) is formed and at least one bevel ( 26 . 26 ' ), suitable, a guide of the slide ( 6 ) during the rotation of the rotor ( 5 ) to provide. Vane pump ( 1 ) according to claim 2, characterized in that the at least one bevel ( 26 . 26 ' ) of the at least one fluid inlet opening ( 24 ) in the direction of rotation of the rotor ( 5 ) viewed at a rear end of the fluid inlet opening ( 24 ) is arranged. Vane pump ( 1 ) according to claim 2 or 3, characterized in that the at least one chamfer ( 26 . 26 ' ) integral with the base plate ( 4 ) is trained. Vane pump ( 1 ) according to one of claims 1 to 4, characterized in that the fluid outlet at least one fluid outlet opening ( 25 ), which in the cover plate ( 8th ) is formed and at least one bevel ( 27 . 27 ' ), suitable, a guide of the slide ( 6 ) during the rotation of the rotor ( 5 ) to provide. Vane pump ( 1 ) according to claim 5, characterized in that the at least one chamfer ( 27 . 27 ' ) of the at least one fluid outlet opening ( 25 ) in the direction of rotation of the rotor ( 5 ) viewed at a rear end of the fluid outlet opening ( 25 ) is arranged. Vane pump ( 1 ) according to claim 5 or 6, characterized in that the at least one chamfer ( 27 . 27 ' ) integral with the cover plate ( 8th ) is trained. Vane pump ( 1 ) according to one of claims 1 to 7, characterized in that the at least one fluid inlet opening ( 24 ) of the base plate ( 4 ) and / or the at least one fluid outlet opening ( 25 ) of the cover plate ( 8th ) in the direction of rotation of the rotor ( 5 ) considers both at a front end and at the rear end in each case a chamfer ( 26 . 26 ' . 27 . 27 ' ) exhibit. Vane pump ( 1 ) according to one of claims 1 to 8, characterized in that the fluid inlet at least one fluid inlet channel ( 34 ), which in the cover plate ( 8th ) is formed and at least one bevel ( 36 ), suitable, a guide of the slide ( 6 ) during the rotation of the rotor ( 5 ) to provide. Vane pump ( 1 ) according to claim 9, characterized in that the at least one chamfer ( 36 ) in the direction of rotation of the rotor ( 5 ) viewed at a rear end of the fluid inlet channel ( 34 ) is arranged.