DE102010054250A1 - hydraulic control - Google Patents

Abstract

The invention relates to a hydraulic control with a control plate arrangement and with a hydraulic conveying device for conveying a hydraulic medium. The invention is characterized in that the hydraulic delivery device is integrated into the control plate arrangement.

Description

The invention relates to a hydraulic control with a control plate assembly and with a hydraulic conveyor for conveying a hydraulic medium.

In automatic transmissions, such as step machines, CVT transmissions or dual clutch transmissions, with hydraulic control, ie actuator control, such as clutch actuator or switch actuator control, and cooling / lubricating oil supply an oil supply (usually pump with pump drive) is necessary. In most cases, the pump drive is a mechanical pump drive, which is coupled to the combustion engine.

In modern transmissions, this mechanical pump drive can be supplemented by an E-pump arrangement (that is to say electric motor with pump).

Furthermore, oil supplies are known that do not require a mechanically driven pump for the gear and Kupplungsaktorik. However, due to the design of the clutch as a dry clutch, there is no need for cooling oil here.

If a mechanical drive is to be dispensed with, in particular with wet-running clutches, the hydraulic power required for this purpose must be provided completely by the electrically driven pump in the known systems. However, the operating conditions occurring are very different. Thus, situations with high volume flow and low pressure requirements as well as situations with high pressure and low volume flow requirements are given. These completely different boundary conditions require in a conventional E-motor / pump arrangement (variable speed drive) very large electric motors (cost, weight, vehicle electrical system load) to represent the different operating conditions in an oil supply system.

The object of the invention is to provide a simple way of supplying different supply areas with hydraulic medium.

The object is achieved in a hydraulic control with a control plate assembly and with a hydraulic conveyor for conveying a hydraulic medium, characterized in that the hydraulic conveyor is integrated into the control plate assembly. The control plate assembly includes at least one control plate, which includes, for example, hydraulic channels and hydraulic connections for hydraulic valves. The inventive placement of the hydraulic conveyor in the control plate assembly of the available space can be used optimally, since otherwise required hydraulic connections between the hydraulic control and the hydraulic conveyor can be omitted.

A preferred embodiment of the hydraulic control is characterized in that a first hydraulic pump is integrated in a first control plate of the control plate assembly. The first hydraulic pump is used, for example, to supply an actuator system of a parallel shift transmission with hydraulic oil. The actuator system is preferably equipped with a pressure accumulator which is filled or charged with the aid of the first hydraulic pump. The first hydraulic pump preferably delivers a relatively low hydraulic medium volume flow, but with a relatively high pressure.

A further preferred embodiment of the hydraulic control is characterized in that a second hydraulic pump is integrated in a second control plate of the control plate assembly. The second hydraulic pump is used, for example, to supply a wet clutch with cooling medium, in particular cooling oil. The second hydraulic pump delivers a relatively large hydraulic medium volume flow, but with a relatively low pressure.

A further preferred embodiment of the hydraulic control is characterized in that the two hydraulic pumps are driven by a single electric motor. An otherwise required second electric motor for driving the second hydraulic pump can be omitted. The electric motor is preferably mounted on the outside of the first control plate. The two hydraulic pumps are preferably arranged completely in the two control plates of the control plate arrangement. Thus, no additional space, especially no housing needed for the hydraulic pumps.

Another preferred embodiment of the hydraulic control is characterized in that the two hydraulic pumps are connected in series. The two hydraulic pumps are preferably arranged adjacent to one another in the two control plates. In this case, the hydraulic pumps are preferably arranged so that they have a common drive rotational axis, which coincides with the drive rotational axis of the electric motor.

A further preferred embodiment of the hydraulic control is characterized in that the two hydraulic pumps are drivingly coupled to each other via a switchable coupling. Due to the switchable coupling the two hydraulic pumps can be used with the Electric motor are coupled so that they are driven simultaneously by the electric motor. If required, one of the hydraulic pumps can be decoupled from the electric motor by means of the switchable clutch. Then only one of the hydraulic pumps is driven by the electric motor. When the electric motor is switched off, then none of the hydraulic pumps is driven.

Another preferred embodiment of the hydraulic control is characterized in that the control plates are pump housings for the hydraulic pumps. As a result, the available space can be used optimally.

A further preferred embodiment of the hydraulic control is characterized in that the two hydraulic pumps are designed as gear pumps, in particular external gear pumps. All pump gears of the two gear pumps are arranged in the control plates. The storage of the pump gears is also integrated in the control plates.

A further preferred embodiment of the hydraulic control is characterized in that the two hydraulic pumps are driven by a common pump shaft. The common pump shaft is, preferably coupled via an Oldham coupling with the common electric motor, that is drivingly connected. The Oldham coupling is preferably located at one end of the common pump shaft. At the other end of the common pump shaft, the shiftable clutch is preferably arranged.

Another preferred embodiment of the hydraulic control system is characterized in that an intermediate plate is arranged between the two control plates, through which a pillow block extends from the first to the second control plate. The plummer block includes, for example, a plummer block sleeve which is fixedly connected to, for example, pressed into the first control plate, and protrudes into a receiving space for the second hydraulic pump, which is recessed in the second control plate.

Further advantages, features and details of the invention will become apparent from the following description in which, with reference to the drawings, an embodiment is described in detail. Show it:

1 the representation of a first section by a hydraulic control according to the invention with actuated clutch;

2 the representation of a second section through the hydraulic control 1 with actuated clutch and

3 the same cut as in 1 with non-actuated clutch.

In the 1 to 3 is a hydraulic control 1 for a parallel transmission of a motor vehicle in various sectional views and states shown. The hydraulic control 1 includes a control plate assembly 10 with a first control plate 11 and a second control plate 12 , Between the two control plates 11 and 12 is an intermediate plate 13 arranged.

In the control plate assembly 10 is a hydraulic conveyor 14 integrated, which is a first hydraulic pump 15 and a second hydraulic pump 16 includes. The two hydraulic pumps 15 . 16 Both are powered by a single electric motor 18 driven.

The electric motor 18 is at the second control panel 12 opposite side of the first control plate 11 grown. On the first control panel 11 opposite side of the second control plate 12 is a receiving space for the hydraulic conveyor 14 in the two control plates 11 . 12 through a cover 19 finished with a corresponding seal hydraulic tight.

The two hydraulic pumps 15 . 16 Both are via a common pump shaft 20 through the electric motor 18 drivable. The common pump shaft 20 extends in the two control plates 11 and 12 through the intermediate plate 13 therethrough. One end of the pump shaft 20 is about an Oldham clutch 22 with a drive shaft of the electric motor 18 rotatably connected.

Both hydraulic pumps 15 . 16 are designed as external gear pumps in which hydraulic medium, in particular hydraulic oil, taken in tooth gaps and is conveyed along a control panel inner wall of a suction chamber to a pressure chamber. The engagement of gear teeth prevents unwanted backflow of the hydraulic medium. During operation of the external gear pumps, a negative pressure is created on one suction side and an overpressure on one pressure side.

The common pump shaft 20 is over a cross pin 23 rotatably with a pump gear 24 the first hydraulic pump 15 connected. That through the pump shaft 20 driven pump gear 24 meshes with another pump gear 28 the first hydraulic pump 15 , The further pump gear 28 the first hydraulic pump 15 is through another cross pin 29 rotatable with a pump axis 30 connected. The pump axis 30 is, as well as the pump shaft 20 , rotatable in two bearing glasses 25 . 26 stored.

The two pump gears 24 . 28 are with the help of the bearing glasses 25 . 26 in the first control panel 11 stored. The two bearing glasses 25 . 26 provide axial contact surfaces for the pump gears 24 . 28 to disposal. For gap compensation at least one sealing ring is provided. The second hydraulic pump 16 has a much lower pressure level than the first hydraulic pump 15 and is without bearing glasses directly between the intermediate plate 13 and the second control plate 12 built-in.

For storage of the second hydraulic pump 16 serves a pillow block 34 comprising a plummer block sleeve having one end in the first control plate 11 is attached. The plummer block sleeve is preferably in the control plate 11 pressed in and protrudes into a receiving space for the second hydraulic pump 16 in the second control panel 12 , At the the electric motor 18 opposite end of the pump shaft 20 is a clutch 35 provided that has a gearing 36 at the end of the pump shaft 20 rotatably with the pump shaft 20 is connectable.

The clutch 35 is by positive engagement, for example by two lugs, permanently rotatable with a pump gear 32 the second hydraulic pump 16 connected, even when not actuated clutch 35 , This has the advantage that when a non-actuation of the clutch 35 , ie with the pump gear stopped 32 , also the clutch 35 and an associated sealing ring 37 , which serves to seal a pressure chamber, performs no rotational movement and thus produces no power losses. In addition, due to the permanent positive connection between the clutch 35 and the pump gear 32 the clutch 35 not every time you switch to the pump gear 32 be threaded.

The pump gear 32 the second hydraulic pump 16 meshes with another pump gear 38 , with the help of another pillow block 39 rotatable in the second control plate 12 is stored. The pillow block 39 includes a plummer block sleeve with one end in the first control plate 11 is pressed and with the other end in the second control plate 12 protrudes.

In the 1 and 2 is the clutch 35 shown in the actuated state, in which the pump shaft 20 over the cross pin 23 drivingly with the pump gear 24 the first hydraulic pump 15 and on the actuated clutch 35 drivingly with the pump gear 32 the second hydraulic pump 16 connected is. The clutch 35 is actuated by a hydraulic switching signal via a hydraulic channel 40 hydraulically to the clutch 35 is transmitted.

When the clutch 35 is not hydraulically actuated, then how to get in 3 sees, the rotatable connection between the teeth 36 at the end of the pump shaft 20 and a complementary trained gearing 42 the clutch 35 interrupted. In the unactuated state of the clutch 35 is the pump gear 32 the second hydraulic pump 16 not driven. Thus, only the first hydraulic pump 15 through the electric motor 18 driven. When the electric motor 18 is switched off, then both hydraulic pumps 15 and 16 not driven.

The execution of the two hydraulic pumps 15 . 16 As external gear pumps provides advantages especially at low temperatures, since the external gear pumps then have lower power losses compared to other pump concepts. The use of the Oldham clutch 22 provides the advantage that axial and radial offset between the drive shaft of the electric motor 18 and the pump shaft 20 can be compensated. Due to the complete integration of the two hydraulic pumps 16 and 15 in the control plate assembly 10 Additional pump housings and otherwise required hydraulic lines can be completely eliminated.

LIST OF REFERENCE NUMBERS

1

hydraulic control

10

Control panel assembly

11

control plate

12

control plate

13

intermediate plate

14

Conveyor

15

first hydraulic pump

16

second hydraulic pump

18

electric motor

19

End cover

20

pump shaft

22

Oldham coupling

23

cross pin

24

pump gear

25

bearing rest

26

bearing rest

28

pump gear

29

cross pin

30

pump axis

32

pump gear

34

Plummer

35

clutch

36

gearing

37

seal

38

pump gear

39

Plummer

40

channel

42

gearing

Claims (10)

Hydraulic control with a control plate arrangement ( 10 ) and with a hydraulic conveyor ( 14 ) for conveying a hydraulic medium, characterized in that the hydraulic conveyor ( 14 ) in the control plate assembly ( 10 ) is integrated. Hydraulic control according to claim 1, characterized in that a first hydraulic pump ( 15 ) in a first control plate ( 11 ) of the control plate assembly ( 10 ) is integrated. Hydraulic control according to claim 2, characterized in that a second hydraulic pump ( 16 ) in a second control plate ( 12 ) of the control plate assembly ( 10 ) is integrated. Hydraulic control according to claim 3, characterized in that the two hydraulic pumps ( 15 . 16 ) by a common electric motor ( 18 ) are driven. Hydraulic control according to claim 3 or 4, characterized in that the two hydraulic pumps ( 15 . 16 ) are connected in series. Hydraulic control according to one of the preceding claims 3 to 5, characterized in that the two hydraulic pumps ( 15 . 16 ) drivingly via a switchable coupling ( 35 ) can be coupled together. Hydraulic controller according to one of claims 3 to 6, characterized in that the control plates ( 11 . 12 ) Pump housing for the hydraulic pumps ( 15 . 16 ). Hydraulic control according to one of claims 3 to 7, characterized in that the two hydraulic pumps ( 15 . 16 ) are designed as gear pumps, in particular external gear pumps. Hydraulic control according to one of claims 3 to 8, characterized in that the two hydraulic pumps ( 15 . 16 ) by a common pump shaft ( 20 ) are driven. Hydraulic control according to claim 9, characterized in that between the two control plates ( 11 . 12 ) an intermediate plate ( 13 ) is arranged, through which a pillow block ( 34 ) from the first ( 11 ) in the second ( 12 ) Control plate extends.

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