DE102004013230A1 - Vane pump - Google Patents

Abstract

It is proposed a vane pump, with a rotor (2) and wings (3) and with a suction, delivery and pressure chamber (7, 8, 9), wherein the volume in the delivery chamber (8) is precompressible. DOLLAR A According to the invention, a device (13) is provided in the vane pump, which adjusts an equally high pressure in the delivery chamber (8) and in a pressure chamber (6). DOLLAR A application in motor vehicles, especially passenger cars.

Description

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

From the publication DE 198 29 726 A1 a vane pump is known which allows a reduced noise due to pressure pulsation. In order to allow a flat pressure increase from the suction to the pressure side overflow channels are provided in the form of chamfers, which allows a backflow of the hydraulic fluid from the pressure side into a delivery chamber. Thus, a pressure jump between the delivery chamber and the pressure side is weakened, whereby pressure pulsations, especially at a high air content in the oil, are reduced.

The patent DE 196 26 211 C2 describes a vane pump whose contour ring is designed such that the hydraulic fluid is pre-compressible due to a reduction in the volume of the delivery chamber. A pressure jump between the delivery chamber and the pressure side of the pump can thus be eliminated, at least for one operating point.

task the invention it is in contrast, a Vane pump with precompression in the delivery chamber, the above a wide working range of the pump improves the noise behavior.

These Task is by a vane pump solved with the features of claim 1.

The inventive vane pump has a device which, in a delivery chamber and in a pressure chamber set an equally high pressure. For example, is the pressure higher in the precompression chamber As in the pressure chamber, so the device lowers the pressure in the Pre-compression chamber to the level of pressure in the pressure chamber from. When coupling the volume of the delivery chamber in the pressure range thus occur no pressure oscillations, causing a noise is avoided. Advantageously, the device avoids the noise even with changing pressures in the pressure range, to be supplied by a working pressure of a Systems are determined.

In Embodiment of the invention corresponds to the achievable pre-compression pressure a maximum working pressure of a system to be supplied. is the delivery chamber designed so that the pressure achievable by the precompression corresponds to the maximum working pressure of the system to be supplied, so is over in an advantageous way the entire working range of the system to be supplied equal pressure in the funding and pressure chamber in conjunction with low noise gewährleistbar.

In Another embodiment of the invention, the device comprises a Valve showing the pressure in the delivery chamber lowered by a connection with the suction area. Is the pressure in the delivery chamber above the Pressure in the pressure chamber, so the valve controls hydraulic fluid in the suction chamber off. The valve has a slider and a spring on. The pressure relief valve must have high dynamics, therefore, a spool of the pressure relief valve is preferable in aluminum. Since the volume flows over the Valve are very low, the slide is accordingly small dimensioned.

In In another embodiment of the invention, the device comprises delivery chamber bounding wings, those with an under wing pressure can be acted upon. Is the precompressed pressure of the delivery chamber above the Pressure of the pressure chamber, so flows between a contour ring and a wing, the hydraulic fluid of the delivery chamber in the suction and / or pressure chamber. This is an under wing print, the pressure of the wings determined on the contour ring, adjust so that the pressure in the delivery chamber lowers to the level in the pressure chamber. Once the from the underwing pressure resulting force on an end face of between conveyor and Suction chamber positioned wing smaller than that from the pressure in the suction and delivery chamber resulting force on the opposite end of the wing, raises the wing from the contour ring and a reduction of the delivery chamber pressure is through an overflow of the Hydraulic fluids from the conveyor allowed in the suction chamber. After the same principle, a reduction of the pressure in the delivery chamber by overflow of the Hydraulic fluids from the conveyor in the pressure chamber. Once the force resulting from the under wing pressure on a front side of the positioned between the delivery and pressure chamber wing smaller is as the resulting from the pressure in the delivery and pressure chamber Force on the opposite Front of the wing, raises the wing from the contour ring and a pressure balance between the chambers is allows.

In Advantageously, by this embodiment, a device according to the invention economical represented.

In a further embodiment of the invention, the device has a relative to the suction and pressure pocket rotatable contour ring, whereby the pressure in the delivery chamber to an equal pressure as in the pressure range is adjustable. About the rotation of the contour ring relative to the suction and pressure pocket, the height of the Vor Compression of the hydraulic fluid in the delivery chamber determinable. The wings of the vane pump sweep the inner radius of the contour ring. A delivery chamber transports the hydraulic fluid from the suction to the pressure pocket, wherein the delivery chamber is separated from both the suction and the pressure pocket in the region of a structurally determinable angle of rotation. Decreases in the determined by the rotation angle range of the radius of the contour ring, so takes place due to a reduction in volume of the delivery chamber precompression, this radius is constant, the volume and the pressure level in the delivery chamber constant. According to the invention, the contoured ring rotates in such a way that an equally high pressure is established in the delivery chamber as in the pressure chamber. As a result, pressure fluctuations are effectively avoided when coupling the delivery into the pressure chamber.

In Another embodiment of the invention, the contour ring over a Piston-cylinder unit rotatable. A piston-cylinder unit twisted the contour ring opposite the suction and pressure bag. The piston-cylinder unit is supported on the contour ring and on the housing the suction and pressure bag off. By pressurizing the piston-cylinder unit is a fast rotation of the contour ring feasible.

In Further embodiment of the invention, the contour ring twists due to the pressure differences in the suction and the pressure chamber. The contour ring is rotatably mounted. Place in the suction and pressure area each have different levels of pressure. The pressures in the suction and pressure range as well as the pressures in the delivery chamber act on the areas of the contour ring that bound these areas. are For example, the effective areas, on the pressure in the circumferential direction acts the same size and is the pressure in the pressure chamber is much higher than in the suction chamber, Thus, a force acting on the contour ring, the rotation of the contour ring across from the suction and pressure pocket is usable. Since the in the circumferential direction effective area the delivery chamber, with the pressure in the delivery chamber is charged the effective surfaces In the suction and pressure range is very small, this force component be largely neglected. Advantageously, the delivery chamber is with this device without an additional Rotatable actuator.

In Another embodiment of the invention, a spring is provided, which positions the contour ring in a defined position. The feather is for example as a coil spring, leaf spring, plate spring or executable as air spring. The spring supports on the contour ring and on the housing of the suction and pressure pocket spring force is a force twisting the contour ring, For example, a force of the piston-cylinder unit, opposite. About the Spring characteristic of the twist angle of the contour ring can be influenced.

In Another embodiment of the invention is the piston-cylinder unit connected to a control device. The control device has one in a housing arranged slide and a spring. The control device controls the piston-cylinder unit such that in the delivery chamber sets the same pressure level as in the pressure chamber. The control device derives the pressure for the piston-cylinder unit from the pressure in the pressure pocket from. Here is the height the pressure in dependence regulated the difference of the pressure in the delivery and the pressure chamber. From the slider abgeregeltes hydraulic fluid is to avoid Hydraulic losses and cavitation again zugesteuert the intake pocket.

In Further embodiment of the invention, the vane pump two suction, conveying and pressure chambers. Advantageously, by this arrangement a compact vane pump with high flow rate represented.

Further Features and combinations of features result from the description as well as the drawings. Specific embodiments of the invention are shown in simplified form in the drawings and in the following Description explained in more detail.

It demonstrate

1 an illustration of a vane pump,

2 a representation of a portion of a developed contour ring of the vane pump from 1 with a first embodiment of a device according to the invention,

3 a representation of a portion of a developed contour ring of the vane pump from 1 with a further embodiment of a device according to the invention,

4 a representation of a portion of a developed contour ring of a vane pump from 1 with a further embodiment of a device according to the invention,

5 a representation of a portion of a developed contour ring of a vane pump from 1 with a further embodiment of a device according to the invention,

6 a modification of the device 5

7 a modification of the device 6 and

8th an arrangement for increasing the wing contact pressure.

Same components in the 1 to 8th are denoted by the same reference numerals below.

Vane pumps are used in a variety of applications such as steering systems, brake systems, active suspension systems or transmissions due to the compact and cost-effective design. In 1 is an example of the construction of a two-stroke vane pump 1 shown. A rotor 2 with radially movable wings 3 is within a contour ring 4 arranged. The vane pump 1 has two intake areas 5 and two pressure ranges 6 on, each not shown suction and pressure channels, suction and pressure pockets 11 . 12 and suction, pressure chambers 7 . 8th include. Two side panels, not shown, seal from the wings 3 and the contour ring 4 formed chambers 7 . 8th . 9 axially. In these side plates are the intake pockets 11 and printed bags 12 , which are connected to the suction and pressure channels incorporated. A shaft turns the rotor 2 with the wings 3 in the direction of rotation 10 , The function of the vane pump 1 is described below with reference to a lift side. By increasing the volume of the chamber 7 sucks the vane pump 1 Hydraulic fluid on. A delivery chamber 8th promotes the aspirated hydraulic fluid volume direction pressure range 6 , the delivery chamber 8th then stands neither with the suction nor with the duck area 5 . 6 in connection. Once the trailing edge 17 in the direction of rotation 10 lying wing 3 the delivery chamber 8th the pressure pockets 12 reached, the hydraulic fluid volume is in the pressure range 6 coupled. In the pressure chamber 9 the volume decreases, causing the hydraulic fluid to overflow the pressure pocket 12 is conveyed in a pressure channel.

Is the pressure in the pressure range 6 significantly higher than in the delivery chamber 8th , In the phase of coupling pressure oscillations occur, which increases the noise emission of the vane pump 1 cause. Especially if the delivery chamber 8th due to air bubbles is not completely filled with hydraulic fluid, takes place in the coupling in conjunction with a correspondingly high pressure difference between the delivery and pressure chamber 8th . 9 a spontaneous compression of the delivery chamber volume 8th , This results in disturbing flow and pressure fluctuations. Advantageously, such spontaneous compression is avoided by ensuring that the pressures in the pressure range 6 or in the pressure chamber 9 and in the delivery chamber 8th assume an approximately equal value.

2 shows a vane pump 1 , which is a first embodiment of a device according to the invention 13 having. The circumference of the contour ring 4 , the wings 3 and the suction and pressure bag 11 . 12 are shown in the diagram in a development, hereby is about a twist angle φ the volume of the chambers 7 . 8th . 9 represented. The arranged in the real part in the side panels pockets 11 . 12 are as in the following figures in a schematic representation of the chambers 7 . 8th . 9 arranged. The radius changes of the contour ring 4 are exaggerated for better understanding. Analogous to 1 enlarges the chamber 7 and in the direction of rotation 10 upstream chamber the volume, whereby hydraulic fluid flows into the chambers. The suction process is completed as soon as the rotor continues to turn 2 the volume of the chamber 7 not with the suction bag anymore 11 communicates. In the delivery chamber 8th the hydraulic fluid undergoes a pre-compression, which is to be matched to the maximum working pressure of the system to be supplied. This is the contour ring 4 designed such that the volume in the delivery chamber 8th reduced. This design allows for the coupling of the delivery chamber 8th in the printing area 6 no pressure pulsation occurs. Supplies the vane pump 1 a system with fluctuating working pressure, so lowers a device 13 the pressure in the delivery chamber 8th to the level of the pressure chamber 9 from. The device 13 in the form of a pressure relief valve comprises one in a housing 16 arranged piston 14 and a spring 15 , A first face 25 of the piston 14 is with the pressure of the delivery chamber 8th applied to a second end face 26 the pressure of the pressure chamber acts 9 and the power of the spring 15 , Due to the pressure in the delivery chamber 8th acts on the piston, a first force component, due to the pressure in the pressure chamber 9 results in a second force component. If the first force component is greater than the second force component plus spring force, the piston shifts 14 to the right towards the spring 15 , This is the delivery chamber 8th with the intake pocket 11 connected, whereby the pressure in the delivery chamber degrades until the second force component and the spring force is greater than the first force component and the piston 14 shifts to the left again.

The feather 15 The task is to hold the piston in a defined position. The spring force is very low, therefore, the pressures in the chambers take 8th . 9 almost equal values. The device 13 reduces according to the invention, if necessary, the pressure in the chamber 8th on the one in the chamber 9 pending pressure level. By pressure pulsations verur Gentle sounds are also with fluctuating pressures in the pressure pocket 12 or in the pressure channel 6 effectively avoidable.

In 3 is a second embodiment of a device according to the invention 13 shown, the same high pressure in the Vorkompressionskammer 8th and in the pressure chamber 9 established. The device 13 includes a piston-cylinder unit 20 , a feather 21 , a control device 22 and a rotatable contour ring 4 , The piston-cylinder unit 20 is with the contour ring 4 connected. By pressurizing the piston-cylinder unit 20 is the contour ring 4 opposite the suction and pressure pocket 11 . 12 rotatable. By twisting in or against the direction of the arrow 27 the amount of precompression of the hydraulic fluid is adjustable.

For example, precompression increases when the contour ring 4 in 3 in the direction of the arrow 27 emotional. A feather 21 ensures a defined positional positioning of the contour ring 4 and provides a restoring force. The feather 21 is between the housing of the suction and pressure pockets 11 . 12 can be arranged, alternatively, this can also be in the piston-cylinder unit 20 be arranged. To compensate for temperature fluctuations, the spring can 21 also temperature-sensitive, ie be designed as a bimetallic spring or as a spring with shape memory. Similarly, different springs in a parallel or series connection can be combined with each other. A control device 22 determines the operating pressure for the piston-cylinder unit 20 , The control device 22 has a slider 23 and a spring 24 in a housing 25 are arranged on. As pilot pressure is the slide 23 on a first face 25 the pressure from the pressure pocket 12 connected, a second end face 26 is the pressure of the delivery chamber 8th and the power of the spring 24 switched.

The following is the operation of the device according to the invention 13 described. For example, if the working pressure of the system to be supplied low, so should in the delivery chamber 8th no pre-compression done. The feather 24 push the slider 23 in a position in which the line to the piston-cylinder unit with the suction area 11 is connected, so the spring 21 the contour ring 4 in the direction of the arrow 27 can twist. The contour ring 4 is designed so that in this position, the volume of the delivery chamber 8th does not change. As soon as due to an increase in the working pressure, the force at the first end face 25 is greater than the spring force and the pressure force on the second end face 26 , the slider moves 23 and blocks the connection to the suction side. At the same time a connection is established between the pressure in the pressure pocket 12 and the piston-cylinder unit 20 , Due to the pressurization of the piston-cylinder unit 20 the contour ring twists 4 by an angle Δφ against the direction of the arrow 27 in the position 4 ' , so that an increase in the precompression of the delivery volume takes place. The contour ring 4 twisted so far or the pressure in the delivery chamber 8th rises until the pressure and spring force on the second end face 26 the slider 23 moved back again, so that the connection to the piston-cylinder unit 20 is interrupted again. The slider 23 regulates constantly a balance of the first and second front page 25 . 26 acting forces. With a very small spring force is thus approximately on both end faces 25 . 26 regulated an equal high pressure. Advantageously, also follows for the delivery chamber 8th and the pressure chamber 9 an equally high pressure, whereby a pressure pulsation and associated noise is effectively avoided even with fluctuating working pressures.

In 4 is a third embodiment of a device according to the invention 13 shown. The device 13 includes a spring 21 and a contra-rotating by an angle Δφ contour ring 4 , The contour ring 4 is at the spring 21 supported with the housing of the suction and pressure pockets 11 . 12 connected is. The contour ring 4 is thus against the power of the spring 21 relative to the suction and pressure pocket 11 . 12 rotatable. Unlike the execution in 3 is not a piston-cylinder unit 20 intended. The contour ring 4 twisting force results directly from the pressures in the suction, delivery and pressure chambers 7 . 8th . 9 ,

P7

Druck in der Ansaugkammer 7,

A7

die in Umfangsrichtung wirksame Druckfläche am Konturring 4, auf den der Ansaugdruck p7 wirkt,

P8

Druck in der Förderkammer 8,

A8

die in Umfangsrichtung wirksame Druckfläche am Konturring 4 in der Förderkammer 8,

P9

Druck in der Druckkammer 9 und

A9

die in Umfangsrichtung wirksame Druckfläche am Konturring 4 in der Druckkammer 9.

One on the contour ring 4 acting force can be determined according to the following equation: Fk = -A7. P7 + p8. A8 + p9. A9 Where:

P7

Pressure in the suction chamber 7 .

A7

the circumferentially effective pressure surface on the contour ring 4 to which the suction pressure p7 acts,

P8

Pressure in the delivery chamber 8th .

A8

the circumferentially effective pressure surface on the contour ring 4 in the delivery chamber 8th .

P9

Pressure in the pressure chamber 9 and

A9

the circumferentially effective pressure surface on the contour ring 4 in the pressure chamber 9 ,

The areas A7 to A9 are calculated in each case from the effective chamber height multiplied by a chamber depth, not shown. If the working pressure of a system to be supplied is low, the spring pushes 21 the contour ring 4 in a position that does not precompression in the delivery chamber 8th allows. In this position, the area A8 has the Value zero, the areas A7 and A9 are the same size. The force Fk resulting from the difference of the pressures p7 and P9 is from the spring 21 supported.

As the system working pressure increases, the force Fk increases due to the increasing pressure P9 and the contour ring 4 twists around an angle Δφ. In this position is the contour ring with 4 ' designated. The twist causes the delivery chamber 8th around a volume 8th' increased. In the delivery chamber 8th the hydraulic fluid undergoes precompression, since the volume of the delivery chamber 8th until coupling into the pressure pocket 12 around the volume 8th' reduced. Due to a low compressibility of the hydraulic fluid, for example oil at 3 · 10 ^-5 / bar, is the required compression volume 8th' small. With loss-free calculation for a coupling pressure of 135 bar, this is less than 1% of the volume of the delivery chamber 8th , At a rotation of the contour ring 4 Therefore, the surfaces A7 and A8 change only slightly by an angle Δφ, so that this change to the force Fk plays a subordinate role.

The system is tunable so that the pressure in the delivery chamber 8th in the coupling corresponds exactly to the system working pressure and disturbing noises in connection with pressure pulsations even with changing system working pressures, ie fluctuating pressures in the pressure range 6 , are preventable. The vote is essentially on the design of the contour ring 4 and the spring 21 , To represent a suitable spring characteristic, a plurality of springs can also be connected in parallel and / or behind one another.

In a modified, not shown embodiment is for adjusting the Vorkompressionsdruckes in the delivery chamber 8th the suction bag 11 and / or the printing bag 12 rotatable relative to the contour ring. For example, the side plates rotate via a suitable device such that an equally high pressure is established in the delivery chamber and the pressure chamber. Similarly, in the suction bag 11 and / or pressure bag 12 For example, a displaceable element providable that a shift of in 1 . 2 shown control edges 18 allows. About an adjustment of the control edges 18 the amount of precompression is adjustable, so that when coupling the delivery chamber 8th in the pressure chamber 9 no pressure surges occur.

In 5 a vane pump is shown in which the device 13 a wing 3 and a throttle device for controlling the underfloor pressure comprises. A grand piano 3 is in the position shown with 3 ' designated. The setting of the pressure in the delivery chamber 8th to the level of pressure in the pressure chamber is by an overflow of hydraulic fluid between the wing 3 ' and contour ring 4 allows. The wings 3 are with an underfloor pressure equal to the pressure in the pressure chamber 9 applied. For this purpose, the pressure from arranged in a side plate pressure pocket 12 via a channel, not shown in the side plate in the lower wing area 36 directed. The pressure is between the rotating rotor 2 and a standing, with the contour ring 4 and the side plate connected stator ring 33 at. The one with the reference number 3 ' designated wing borders the suction and delivery chamber 7 . 8th from each other. On the with the contour ring 4 in contact face of the wing 3 ' Due to the shape of the blade on one half of the end face, the pressure in the suction chamber acts 7 and on the other half the pressure of the delivery chamber 8th , Since the suction pressure has a small value, the resulting force component is on the wing 3 ' negligible. About a throttle device with the throttles 28 . 29 . 30 is the lower wing side of the wing 3 ' delivered a pressure that is half the pressure in the pressure chamber 9 , This lifts the grand piano 3 ' from the contour ring 4 as soon as the pre-compressed pressure in the delivery chamber 8th the pressure in the pressure chamber 9 exceeds. The over the throttle 3 Outflowing hydraulic fluid flows through a return line 31 in the intake pocket 11 back.

Hydraulic fluid flows from the pump to the suction chamber 8th . 7 until equal pressure in the delivery and pressure chamber 7 . 9 is reached.

The throttle device is constructed so that the under wing pressure of the wings 3 a hydraulic volume flow branches off and via the first and second throttle 28 . 29 in the underwing area of the wing 3 ' flows. From this area, the hydraulic volume flow flows through the third throttle 30 in a pipe, with the suction bag 11 connected is. Are the flow resistances of the throttles 28 . 29 twice as large as the flow resistance of the throttle 30 , so turns in the lower wing area of the wing 3 ' a pressure that is half the pressure in the pressure chamber 9 ,

By changing the flow resistance of the chokes 28 . 29 . 30 Of course, other under wing pressures are adjustable. For example, this is a Vorkompressionsdruck in the delivery chamber 8th adjustable, the below or above the pressure level in the pressure chamber 9 lies. Furthermore, pressure losses due to leakage are also due to variation of the under wing pressure on the wing 3 ' compensated.

In the 6 a device is shown which dispenses with a throttle device. The with the contour ring 4 in contact face is designed so that, for example, on the front page of the grand piano 3 ' the pressure of the delivery chamber 8th acts. Throughout the under wing area 36 is the pressure of the pressure chamber 9 at. This lifts the grand piano 3 ' from the contour ring 4 as soon as the pre-compressed pressure in the delivery chamber 8th the pressure in the pressure chamber 9 exceeds, thus adjusting the pressure in the delivery chamber 8th to the level of pressure in the pressure chamber 9 he follows.

The wings of in 7 shown variant are designed such that on the with the contour ring 4 contacting face of the wing 3 '' one from the in the delivery chamber 8th resulting pressure acting force. The one with the reference number 3 '' designated wings 3 borders the delivery and pressure chamber 8th . 9 from each other. The under wing area 36 is with the pressure from the pressure chamber 9 applied. If the pressure in the delivery chamber rises 8th about the pressure in the pressure chamber 9 on, that raises the wing 3 '' from the contour ring 4 so that in the delivery and pressure chamber again a pressure of the same height can be set.

In 8th an arrangement for amplifying the wing contact pressure is shown. The area 35 at which the pressure of the pressure chamber 9 is pending, is about the arrangement of a boost piston 34 increased. This increases the power with which the wings 3 against the contour ring 4 are pressed. The space on the opposite side of the boost piston is with the intake pocket 11 connected, so that builds on this page no counterforce. The arrangement can be used, for example, if due to leaks in the delivery chamber 8th and / or pressure chamber 9 can not build up a sufficiently high pressure.

The devices described above 13 for setting a pressure of the same height in the delivery and pressure chamber 8th . 9 Of course, they can also be combined with each other. All devices are in single-stroke and / or regulated vane pumps 1 used.

1

Vane pump

2

rotor

3

wing

3 '

suction and delivery chamber delimiting wing

3 ''

Promotional and Pressure chamber delimiting wing

4

contour ring

4 '

twisted contour ring

5

suction

6

pressure range

7

suction

8th

delivery chamber

8th'

precompression

9

pressure chamber

10

direction of rotation

11

intake pocket

12

Printed bag

13

contraption

14

piston

15

feather

16

casing

17

trailing edge wing

18

control edges Suction bag

19

20

Piston-cylinder assembly

21

feather

22

control device

23

pusher

24

feather

25

First face

26

Second face

27

arrow

28

First throttle

29

Second throttle

30

third throttle

31

Return line in suction bag

32

33

stator

34

intensifier piston

35

With Pressure chamber pressure applied piston area

36

Under the wing area

Claims (10)

Vane pump, with - a rotor ( 2 ) and wings ( 3 ) and with - a suction, delivery and pressure chamber ( 7 . 8th . 9 ), wherein - the volume in the delivery chamber ( 8th ) pre-compressible is characterized in that the vane pump ( 1 ) a device ( 13 ), which in the delivery chamber ( 8th ) and in a pressure chamber ( 6 ) sets an equally high pressure. Vane pump according to claim 1, characterized in that the recoverable Vorkompressionsdruck in the delivery chamber ( 8th ) corresponds to a maximum working pressure of a system to be supplied. Vane pump according to one of claims 1 or 2, characterized in that the device ( 13 ) comprises a valve which controls the pressure in the delivery chamber ( 8th ) by a connection to the suction area ( 5 ) lowers. Vane pump according to one of claims 1 or 2, characterized in that the device, the conveying chamber bounding wings ( 3 ' . 3 '' ), which are acted upon by an underfloor pressure includes. Vane pump according to one of claims 1 or 2, characterized in that the device ( 13 ) one relative to the suction and pressure pocket ( 11 . 12 ) rotatable contour ring ( 4 ), whereby the pressure in the delivery chamber ( 8th ) to the same pressure as in the pressure range ( 9 ) is adjustable. Vane pump according to claim 5, characterized in that the contour ring ( 4 ) via a piston-cylinder unit ( 20 ) is rotatable. Vane pump according to one of claims 5 or 6, characterized in that the contour ring ( 4 ) due to the pressure differences in the suction, delivery and pressure chamber ( 7 . 8th . 9 ) twisted. Vane pump according to one of claims 5 to 7, characterized in that a spring ( 21 ) the contour ring ( 4 ) positioned in a defined position. Vane pump according to claim 6, characterized in that the piston-cylinder unit ( 20 ) with a control device ( 22 ) connected is. Vane pump according to one of claims 1 to 9, characterized in that the vane pump ( 1 ) two suction, delivery and pressure chambers ( 7 . 8th . 9 ) having.