DE102016109335A1 - DISPLACEMENT PUMP AND GEARBOX FOR A MOTOR VEHICLE - Google Patents

Abstract

The invention relates to a displacement pump (10), in particular a vane pump for conveying a fluid (F) for a consumer (6) of a motor vehicle, wherein the end plate (14) at least partially forms an axial end portion (10a) of the positive displacement pump (10). The invention further relates to a transmission (100) for a motor vehicle.

Description

The invention relates to a displacement pump, in particular a vane pump for conveying a fluid for a consumer of a motor vehicle. The invention further relates to a transmission for a motor vehicle.

State of the art

Displacement pumps with housing, which fix the inner parts of the positive displacement pump to the closing cover or einhausen, and positive displacement pumps without housing in so-called cartridge design, are considered prior art. Displacement pumps with housing traditionally completely house the internal parts and merely provide openings for a suction oil feed, pressure oil discharge and a shaft passage. Likewise, the bearing of the drive shaft of the positive displacement pump is usually integrated in the housing in housing designs.

The oil flows from a housing opening via an end plate opening into a suction-side delivery cell and is delivered by the rotation of the rotor at a further pressure-side end plate opening and a pressure-side housing opening. A variable displacement pump does not have a functional principle, such as charging. Constant pumps, and must therefore provide the suction-side filling by pure suction work. In addition, in displacement pumps with a high volume flow to be dispensed, the delivery cell may not be completely filled, and also gas fractions bound in the oil counteract optimal cell filling. This has the consequence that the positive displacement pump kavitiert above a certain limit speed and deteriorates an acoustic behavior.

For pumps with a high volumetric requirement, the delivery cell can no longer be adequately filled by the abovementioned suction-side openings and the gas fractions bound in the oil at a certain speed, the so-called suction control speed, and the cells in the positive-displacement pump therefore become deficient. In this case, the positive displacement pump does not reach the quantity delivery defined at a specific speed. Likewise, due to the high angular velocity caused by high rotational speeds of the rotor, triggering of the gas components dissolved in the oil leads to microjet formation and the positive displacement pump cavitates as a result. This cavitation has an effect on component damage and deteriorated acoustic behavior. In order to avoid component damage due to cavitation on the positive displacement pump, as well as to improve the acoustic behavior and / or to shift both into a higher speed range, it is necessary to optimize the suction-side behavior or the suction-side oil supply of the positive displacement pump to the delivery cells of the rotor set to fill as optimally as possible.

The DE 10 2007 006 716 A1 discloses a positive displacement pump for a motor vehicle with a housing supporting a set of rotors, which is formed by a rotor and locking elements, a working space which is divided by the locking elements in working cells, wherein the working space is bounded laterally by end faces, and a Pumpensaugöffnung and a pump pressure opening. The internal parts of the positive displacement pump are completely enclosed by the closing lid.

The invention is therefore based on the object to improve a positive displacement pump, in particular a vane pump, to optimize the suction-side behavior or the suction-side oil supply of the positive displacement pump to optimally fill the delivery cells of the rotor set, so that cavitation and / or a Deterioration of the acoustic behavior of the pump is avoided.

The object is achieved with a positive displacement pump having the features of patent claim 1. Furthermore, the object is achieved with a transmission for a motor vehicle having the features of claim 9.

Disclosure of the invention

The present invention provides a positive displacement pump, in particular a vane pump for delivering a fluid for a consumer of a motor vehicle, with a housing, in which a cam ring is inserted and a drive shaft is mounted with a rotor, wherein between the cam ring and the rotor, a working chamber is formed, which is bounded in the axial direction by the housing, and an end plate, wherein the housing fixes the end plate, wherein the end plate at least partially forms an axial end portion of the positive displacement pump.

The present invention further provides a transmission for a motor vehicle with at least one consumer and a positive displacement pump for delivering a fluid for the at least one consumer of the transmission.

One idea of the present invention is to modify the conventional construction of the positive displacement pump in such a way that the housing still captively secures the pump internal parts, but at least sections of the bottom section of the housing are removed in order to be able to obstruct a thicker end plate. This will make the suction and pressure-side openings of housing and face plate in the component of the face plate united. Thus, a deeper and thus larger suction kidney can be integrated in the new thicker face plate, which brings the advantage of better cell filling by optimized inflow cross sections in the suction side with it.

Furthermore, more material is present due to the thicker end plate, whereby the corner and edge design of the suction opening can be made streamlined. In addition to the thicker face plate has the advantage that this is much stiffer and thus has a lower deformation during operation of the positive displacement pump, which in turn positively affects the hydraulic efficiency of the positive displacement pump. Another advantage is that the conventionally existing sealing point between face plate and housing deleted. In classic housing design, at least two sealing points, one between faceplate and pump housing and another between pump housing and transmission components, are required. According to the present invention, however, only one sealing point between end plate and transmission components is needed. This advantageously reduces the number of components and sealing points, which simplifies assembly and reduces potential sources of error and has a positive influence on the hydraulic efficiency of the positive displacement pump.

Advantageous embodiments and further developments emerge from the dependent claims and from the description with reference to the figures.

According to a preferred embodiment, it is provided that the housing at least partially forms the axial end portion of the positive displacement pump, wherein the housing has a latching nose extending at least partially in the radial direction of the positive displacement pump at a gear-side axial end portion, which engages in a recess formed in the end plate. Thus, the housing advantageously fixes the face plate, but does not have to completely encompass it.

According to a further preferred embodiment, it is provided that the transmission-side axial end portion of the housing and a transmission-side axial end portion of the end plate in the radial direction of the positive displacement pump are flush with each other. The end plate thus preferably forms an axial end portion of the positive displacement pump.

According to a further preferred development, it is provided that a fluid flow can be supplied axially to a suction zone of the working chamber, wherein a suction opening of the positive displacement pump is formed exclusively in the end plate. Due to the comparison with conventional end plates thicker version of the face plate and the exclusive design of the suction opening of the positive displacement pump in the face plate, a cross section of the suction opening can thus be preferably carried out aerodynamic.

According to another preferred embodiment, it is provided that the fluid flow from a pressure zone of the working chamber is axially discharged, wherein a pressure port of the positive displacement pump is formed exclusively in the face plate. As on the suction side, the exclusive design of the pressure opening in the end plate has the advantage that there are no cross-sectional jumps in the pressure opening of the positive displacement pump, as is conventionally the case. Thus, the discharge of the fluid from the pressure zone of the working chamber may be preferably designed streamlined.

According to a further preferred development, it is provided that the suction opening formed in the end plate has a first cross section at the axial end portion of the positive displacement pump and a second cross section at a rotor side axial end portion of the end plate, wherein the second cross section is smaller than the first cross section, and wherein Suction opening has a between the axial end portion of the positive displacement pump and the rotor-side axial end portion of the end plate substantially linearly reducing cross-section. Thus, preferably, the supply of the fluid through the suction opening can be made aerodynamic.

According to a further preferred development, it is provided that the pressure opening formed in the end plate has a first cross section at a rotor-side axial end section of the end plate and a second cross section at the axial end section of the positive displacement pump which is substantially identical to the first section, the pressure opening being between the axial end portion of the positive displacement pump and the rotor-side axial end portion of the end plate has a substantially constant cross-section. Thus, the discharge of fluid from the pressure port of the end plate can be performed aerodynamically.

According to a further preferred embodiment it is provided that a bearing of the drive shaft is integrated in the end plate. Due to the fact that the end plate supports the drive shaft, the end plate is preferably guided precisely in the housing by means of a fit in order to prevent a radial deflection of the shaft and thus an acoustic and wear influence.

The described embodiments and developments can be combined with each other as desired.

Further possible refinements, developments and implementations of the invention also include combinations, not explicitly mentioned, of features of the invention described above or below with regard to the exemplary embodiments.

Brief description of the drawings

The accompanying drawings are intended to provide further understanding of the embodiments of the invention. They illustrate embodiments and, together with the description, serve to explain principles and concepts of the invention.

Other embodiments and many of the stated advantages will become apparent with reference to the drawings. The illustrated elements of the drawings are not necessarily shown to scale to each other.

Show it:

1 a longitudinal sectional view of a positive displacement pump for delivering a fluid for a consumer of a motor vehicle according to a preferred embodiment of the invention;

2 a schematic representation of a housing portion of the positive displacement pump according to the preferred embodiment of the invention; and

3 a transmission for a motor vehicle with the positive displacement pump for delivering the fluid to a consumer according to the preferred embodiment of the invention.

In the figures of the drawings, like reference characters designate like or functionally identical elements, components or components unless otherwise indicated.

1 shows a longitudinal sectional view of a positive displacement pump for delivering a fluid for a consumer of a motor vehicle according to a preferred embodiment of the invention.

a longitudinal sectional view of a positive displacement pump for delivering a fluid for a consumer of a motor vehicle according to a preferred embodiment of the invention;

The positive displacement pump 10 is designed as a vane pump. Alternatively, the positive displacement pump 10 be formed by another suitable pump. In the case 12 is an outer ring 19 and a curve ring 20 used and a drive shaft 22 with a rotor 24 stored. Between the curve ring 20 and the rotor 24 a working chamber is formed. The working chamber is in the axial direction through the housing 12 and a face plate 14 limited. The housing 12 fixes the face plate 14 , The face plate 14 forms at least in sections an axial end portion 10a the positive displacement pump 10 ,

The housing 12 forms at least partially the axial end portion 10a the positive displacement pump 10 , The housing 12 further includes a gear-side axial end portion 12a an at least partially in the radial direction R of the positive displacement pump 10 extending latch 15 on. The directional nose 15 preferably engages in a in the face plate 14 trained recess 16 one.

The transmission-side axial end portion 12a of the housing 12 and a transmission-side axial end portion 14b the face plate 14 are advantageously in the radial direction R of the positive displacement pump 10 flush with each other. Alternatively, the axial end portion of the end plate and the axial end portion of the housing may be arranged offset from each other, for example.

A fluid flow is a suction zone 28 the working chamber 26 preferably axially fed. Alternatively, the fluid flow may be supplied to the suction zone of the working chamber in another suitable manner. A suction opening 17 the positive displacement pump 10 is preferably exclusively in the face plate 14 educated. The fluid flow from a pressure zone 29 the working chamber 26 is preferably axially removable from this. Alternatively, the fluid flow can be removed from the pressure zone of the working chamber, for example in another suitable manner. A pressure opening 18 the positive displacement pump 10 is preferably exclusively in the face plate 14 educated.

The in the face plate 14 trained suction opening 17 has at the axial end portion 10a the positive displacement pump 10 preferably a first cross-section 17a and at a rotor-side axial end portion 14a the face plate 14 a second cross section 17b on. The second cross section 17b is preferably less than the first cross section 17a , The suction opening 17 preferably has a between the axial end portion 10a the positive displacement pump 10 and the rotor-side axial end portion 14a the face plate 14 essentially linearly reducing cross section. Alternatively, for example, the decreasing cross section may not decrease linearly.

The in the face plate 14 trained pressure opening 18 has at the rotor-side axial end portion 14a the face plate 14 preferably a first cross-section 18a and at the axial end portion 10a the positive displacement pump 10 a second cross section 18b on. The second cross section 18b is preferably the first cross section 18a essentially identical. The pressure opening 18 points between the axial end portion 10a the positive displacement pump 10 and the rotor-side axial end portion 14a the face plate 14 preferably a substantially constant cross section. A storage 23 the drive shaft 22 is preferably in the face plate 14 integrated.

A seal 30 is at the transmission-side axial end portion 14b the face plate 14 arranged. With classic housing design, at least two seals, one between end plate 14 and housing 12 as well as another between housing 12 and in 1 not shown) transmission components needed. According to the invention, however, only one seal between face plate 12 and the (in 1 not shown) transmission components needed.

2 shows a schematic representation of a housing portion of the positive displacement pump according to the preferred embodiment of the invention.

The housing 12 points to the transmission-side axial end portion 12a preferably at least partially in the radial direction of the (in 2 not shown) displacement pump extending latch 15 on. Due to the hollow cylindrical design of the in 2 shown housing portion of the housing 12 the supply of the fluid flow into the working chamber and the discharge of the fluid flow from the working chamber is effected exclusively by the (in 2 not shown) end plate, wherein a cross section of the inflow and outflow of the end plate is thus aerodynamically executable.

3 shows a transmission for a motor vehicle with the positive displacement pump for delivering the fluid for a consumer according to the preferred embodiment of the invention.

The gear 100 is located in a motor-driven vehicle, in particular in a passenger car or a commercial vehicle. The positive displacement pump 10 is preferably designed as a vane pump. The positive displacement pump 10 generates a hydraulic pressure for the consumer 106 ,

Although the present invention has been described above with reference to preferred embodiments, it is not limited thereto but is modifiable in a variety of ways. In particular, the invention can be varied or modified in many ways without deviating from the gist of the invention.

For example, a shape, size and / or geometry of the end plate or the housing at the axial end portion of the positive displacement pump can be adapted to the respective structural requirements of the positive displacement pump.

LIST OF REFERENCE NUMBERS

10

displacement

10a

axial end portion of the positive displacement pump

12

casing

12a

transmission side axial end portion of the housing

14

faceplate

14a

rotor-side axial end portion of the end plate

14b

Transmission side axial end portion of the face plate

15

locking lug

16

recess

17

suction opening

17a

first cross section of the suction opening

17b

second cross section of the suction opening

18

pressure opening

18a

first cross section of the pressure opening

18b

second cross section of the pressure opening

19

outer ring

20

cam ring

22

drive shaft

23

storage

24

rotor

26

working chamber

28

suction zone

29

pressure zone

30

poetry

F

fluid

R

radial direction

100

transmission

106

consumer

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007006716 A1 [0005]

Claims (10)

Positive displacement pump ( 10 ), in particular a vane pump for delivering a fluid (F) to a consumer ( 106 ) of a motor vehicle, with a housing ( 12 ) into which a cam ring ( 20 ) and a drive shaft ( 22 ) with a rotor ( 24 ) is mounted, wherein between the cam ring ( 20 ) and the rotor ( 24 ) a working chamber ( 26 ) is formed in the axial direction through the housing ( 12 ), and a face plate ( 14 ) is limited, wherein the housing ( 12 ) the face plate ( 14 ), characterized in that the face plate ( 14 ) at least in sections an axial end portion ( 10a ) of the positive displacement pump ( 10 ). Positive displacement pump according to claim 1, characterized in that the housing ( 12 ) at least in sections, the axial end portion ( 10a ) of the positive displacement pump ( 10 ), wherein the housing ( 12 ) at a transmission-side axial end portion ( 12a ) at least partially in the radial direction (R) of the positive displacement pump ( 10 ) extending latch ( 15 ), which in one in the front plate ( 14 ) formed recess ( 16 ) intervenes. Positive displacement pump according to claim 1 or 2, characterized in that the transmission-side axial end portion ( 12a ) of the housing ( 12 ) and a transmission-side axial end portion ( 14b ) of the front plate ( 14 ) in the radial direction (R) of the positive displacement pump ( 10 ) are flush with each other. Positive displacement pump according to one of the preceding claims, characterized in that a suction zone ( 28 ) of the working chamber ( 26 ) a fluid flow can be fed axially, wherein a suction opening ( 17 ) of the positive displacement pump ( 10 ) only in the front plate ( 14 ) is trained. Positive displacement pump according to claim 4, characterized in that the fluid flow from a pressure zone ( 29 ) of the working chamber ( 26 ) is axially dischargeable, wherein a pressure port ( 18 ) of the positive displacement pump ( 10 ) only in the front plate ( 14 ) is trained. Positive displacement pump according to claim 4 or 5, characterized in that in the end plate ( 14 ) formed suction opening ( 17 ) at the axial end portion ( 10a ) of the positive displacement pump ( 10 ) a first cross section ( 17a ) and at a rotor-side axial end portion ( 14a ) of the front plate ( 14 ) a second cross section ( 17b ), wherein the second cross-section ( 17b ) smaller than the first cross section ( 17a ), and wherein the suction opening ( 17 ) one between the axial end portion ( 10a ) of the positive displacement pump ( 10 ) and the rotor-side axial end portion ( 14a ) of the front plate ( 14 ) has a substantially linear reducing cross-section. Positive displacement pump according to claim 6, characterized in that in the end plate ( 14 ) formed pressure opening ( 18 ) at the rotor-side axial end portion ( 14a ) of the front plate ( 14 ) a first cross section ( 18a ) and at the axial end portion ( 10a ) of the positive displacement pump ( 10 ) a second cross section ( 18b ), which leads to the first cross-section ( 18a ) is substantially identical, wherein the pressure opening ( 18 ) between the axial end portion ( 10a ) of the positive displacement pump ( 10 ) and the rotor-side axial end portion ( 14a ) of the front plate ( 14 ) has a substantially constant cross-section. Positive displacement pump according to one of the preceding claims, characterized in that a bearing ( 23 ) of the drive shaft ( 22 ) in the face plate ( 14 ) is integrated. Transmission ( 100 ) for a motor vehicle, comprising: at least one consumer ( 106 ); and a positive displacement pump ( 10 ) according to one of claims 1 to 8 for conveying a fluid (F) for the at least one consumer ( 106 ) of the transmission ( 100 ). Transmission according to claim 9, characterized in that the positive displacement pump ( 10 ) is formed by a vane pump.

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