DE10146260A1 - Hydraulic unit for hydraulic control and regulation device for anti-locking and slip-regulated braking has leakage fluid reservoir incorporated in regulator housing fitted to housing block - Google Patents

Abstract

The hydraulic unit (10) has a hydraulic feed device with a drive (50) and a displacement device fitting into a working space of a housing block (22) and a control and regulation electronic stage contained in a regulator housing (12) attached to the housing block, providing a reservoir (27) for leakage fluid, sealed from the internal space (26) containing the electronic stage and the outside.

Description

The invention relates to a hydraulic unit for a hydraulic control and / or regulating device, especially for anti-lock and / or slip-controlled braking systems, with a hydraulic Conveyor, which is a drive means and a Displacement unit comprises, the Displacement unit in a working area of a housing block engages with one arranged in a controller housing Control and regulating electronics, the regulator housing is attached to the housing block, and with an im Housing block trained in the work space on the one hand, the outlet channel for a leakage fluid, the on the other hand, opens into the controller housing.

State of the art

WO 00/03902 is a generic Hydraulic unit known. There is a hydraulic one Control and / or regulating device with one in one Controller housing arranged control and / or Control electronics provided. A the tax and / or Control electronics housing is with connected to a valve block. Is on the valve block a drive means for a pressure generating element is arranged, one of the pressure generating element assigned cavity leakage fluid of the Receives pressure generator element. There is a with in the valve block the drain channel connected to the cavity for the Leakage fluid formed. The drive means is a Electric motor, the drive shaft of which is an eccentric bears in a known manner with radial pistons interacts.

When it comes to generating pressure, it comes from rotation the eccentric shaft in the area of an eccentric chamber Leakage of fluid flowing over the cavity is derived. This cavity is above the drain channel in connection with the controller housing. The Controller housing consists of two separate, on the Fastening surface between the valve block and controller housing related, successively parallel interiors. On first interior takes mechanical valve elements and a second interior takes the electrical and electronic elements. This version has a pot-like, double-walled version of the Regulator housing result, at the same time a Sealing medium between the interiors is impermeable to fluids must be executed.

A manufacture of such a controller housing is consuming. A separation of electrical and electronic components from the mechanical Elements are only possible with great effort. In addition is disadvantage that in this solution in which the Valve elements receiving the first interior means (Partition) is arranged, which the interior separates into two chambers, one of which separates the Leakage liquid collects. This is about one Opening in the partition with the second chamber connected. About an intended free Fastening surface between the controller housing and valve block the leakage liquid is released into the environment. This arrangement is therefore not desirable complete sealing against the environment.

From DE 197 24 166 is a hydraulic unit known, where leakage rooms as a labyrinth of Leakage receiving channels formed are. A valve spring chamber is the one Leakage absorbing labyrinth using a additional channel as a collecting container Leakage fluid connected. Collecting the Leakage fluid takes place here far from electrical Components, especially the engine, inside the Hydraulic unit.

The disadvantage of this known solution is that a complicated one for taking up the leakage fluid Channel system integrated in the hydraulic unit must become. There are additional angled channels necessary to leakage area in the area of the spring chamber Win feather. Because the leakage space is in vertical and horizontal channels and Storage spaces must have pressure equalization in each Installation position of the hydraulic unit guaranteed his. All areas of the labyrinth system must regardless of the position of the hydraulic unit via a Pressure equalization system can be vented. The complicated structure of the sewer system and its storage spaces leads to a costly production of the Housing block.

Advantages of the invention

The hydraulic unit according to the invention with the Features mentioned claim 1 has the advantage in leakage rooms, so-called reservoirs, to create ones that are easily accessible Interiors of the hydraulic unit are located and opposite the control and regulating electronics as well as the environment are sealed. Because in one Controller housing formed a reservoir for a leakage fluid is, a drain channel and a cross hole opens directly into the reservoir and the reservoir one compared to one the control and regulating electronics receiving interior of the controller housing and The area around the controller housing is sealed advantageously possible, such controller housing in easier and cheaper to manufacture.

By simple, sealing arrangement of the Regulator housing is in accordance with a preferred embodiment of the Invention using either one of the reservoirs the controller housing formed chamber or in formed the controller housing integrated hollow body. In both versions, you can in particularly simple way compared to the tax and Control electronics and the housing block and thus the Achieve a dense arrangement of the reservoir in the vicinity.

The arrangement of the reservoir in the controller housing allows an advantageous simple assembly and Accessibility.

In a further preferred embodiment of the invention a drain channel is arranged, the one Eccentric chamber of the hydraulic unit with the reservoir directly and thus connects in the shortest way. This Drain channel can thus be easily inserted into the Integrate the housing block of the hydraulic unit. It is also advantageously possible that Hydraulic unit both horizontally and vertically rectified management of the drainage channel use.

In addition, in a preferred embodiment Invention a simple positioning system of the Reservoirs and a preferably symmetrical and rotationally symmetrical design of the reservoir intended. These configurations allow a special one simple manufacture while maintaining a high Accuracy of the reservoirs. The volume required for Leakage fluid can be absorbed by the Variability in the design of the reservoirs advantageously be adjusted.

Further preferred configurations of the invention result from the rest, in the subclaims mentioned features.

drawings

The invention is hereinafter in Exemplary embodiments with reference to the accompanying drawings explained. Show it:

Fig. 1 is a sectional view of a housing block of a hydraulic unit with controller housing and internal reservoir in a first embodiment and

Fig. 2 is a sectional view of the housing block of the hydraulic unit with controller housing and internal reservoir in a second embodiment.

Description of the embodiments

The hydraulic unit 10 , which is only shown in detail views required for the description of the invention in FIGS. 1 and 2, essentially comprises, as main components, a housing block 22 , a drive means 50 and a controller housing 12 . The regulator housing 12 is positioned with respect to the housing block 22 on the opposite side to the drive means 50 and is sealingly attached at the pot-like housing block 22nd In the housing block 22 , an eccentric space 18 with an eccentric bore 16 is arranged axially to the drive means 50 . The drive means 50 is, for example, an electric motor, the drive shaft of which carries an eccentric which engages in the eccentric space 18 . The structure and mode of operation of the hydraulic unit 10 and its possible uses, for example for anti-lock and / or slip-controlled brake systems, are generally known, so that they are not dealt with in detail.

The description below is based on the horizontal installation of the hydraulic unit 10 in relation to the drive axle 52 .

The leakage liquid (for example brake fluid) that has entered the eccentric space 18 via a seal (not shown) first drips into a receiving pocket 20 that is introduced into the housing block 22 . An excess amount of leakage fluid that cannot be received by the receiving pocket 20 passes through a transverse bore 70 into a larger blind bore 36 in the housing block 22 .

The following applies to the vertical installation of the hydraulic unit 10 in relation to the drive axle 52 :
The leakage liquid located in the eccentric chamber 18 drips into an outlet channel 14 which is connected to the eccentric chamber 18 and the blind hole 36 . The drain channel 14 is formed by a bore in the housing block 22 and connects the eccentric space 18 with the blind hole 36th The diameter of the blind hole 36 is larger than a diameter of the drain channel 14 , so that it opens into a bottom of the blind hole 36 .

For the horizontal installation of the hydraulic unit, the receiving pocket 20 and the transverse bore 70 and for the vertical installation, the drain channel 14 and the blind bore 36 provide a connection between the leak-prone eccentric space 18 and the regulator housing 12 , in which a reservoir 27 is designed as a leakage collecting space for collecting the leakage. The reservoir 27 is formed within the controller housing 12 , in which control and regulator electronics 24 are arranged. In a first exemplary embodiment, according to FIG. 1, the controller housing 12 is provided with a chamber 28 formed in one piece with the controller housing 12 . The chamber 28 has a circumferential ring groove 60 on the side facing the blind hole 36 and forms a circumferential ring stop 62 above the ring groove 60 . The annular groove 60 receives a sealing device 56 , for example an O-ring.

The controller housing 12 further includes a circumferential annular groove 58 . The controller housing 12 is sealingly connected to the housing block 22 by means of a sealing device 54 , for example an O-ring, which is arranged in the annular groove 58 . The chamber 28 located in the controller housing 12 is sealed against the housing block 22 by means of the sealing device 56 arranged in the annular groove 60 with a ring stop 62 which is adjacent to the housing block. In this way, an interior 26 is created in the controller housing 12 , which houses the control and regulating electronics 24 , not shown here, and the chamber 28 for receiving leakage fluid. The chamber 28 is thus sealed off from the interior 26 and the surroundings of the hydraulic unit 10 . The leakage can remain in the chamber 28 over the entire service life of the hydraulic unit 10 .

A second exemplary embodiment is shown in FIG. 2. The reservoir is formed here by a hollow body 30 , which is arranged in the controller housing 12 . Here, the hollow body 30 is arranged on the one hand sealingly on the housing block 22 and on the other hand sealingly on the controller housing 12 . The hollow body 30 is clamped between the controller housing 12 and the housing block 22 . The hollow body 30 engages in the blind hole 36 via a positioning stop 42 . The positioning stop 42 is formed by an annular bead 46 which projects radially from the hollow body 39 and which at the same time forms a locking flange 38 . A surface of the locking flange 38 facing the housing block 22 serves as a sealing surface 66 .

The hollow body 30 forms a further positioning stop 44 in the region of a receiving flange 34 . The positioning stop 44 is also formed by a radially projecting annular bead 48 , which forms a locking flange 40 . The controller housing 12 comprises a receiving flange 34 for the hollow body 30 . The hollow body 30 engages with its positioning stop 44 in the receiving flange 34 . A surface of the locking flange 40 facing the controller housing 12 serves as a further sealing surface 68 . A wall 32 of the hollow body 32 consists of an elastic material, for example of a plastic membrane or the like that is resistant to the leakage to be absorbed.

The respective locking flanges 38 and 40 and the positioning stops 42 and 44 form-fit the hollow body 30 with the housing block 22 and the controller housing 12 . A frictional connection between the hollow body 30 and the housing block 22 and the regulator housing 12 arises from the elasticity of the wall 32 of the hollow body 30 . In the initial state of the hollow body 30 , the latter has a greater axial extent than a depth of the regulator housing 12 . As a result, the hollow body 30 is non-positively clamped when the controller housing 12 is mounted on the housing block 22 . The sealing surfaces 66 and 68 are subjected to a sealing force and seal the interior of the hollow body 30 . The formation of at least one fold 64 of the wall 32 supports the clamping process and the absorption of the change in length associated with the compression of the hollow body 30 . In particular, this ensures that the compression takes place radially outwards.

This arrangement has created a reservoir 27 in the form of the hollow body 30 , which is arranged between the controller housing 12 and the housing block 22 , but is sealingly separated from the interior 26 and the surroundings of the hydraulic unit 10 .

The hollow body 30 is rotationally symmetrical and symmetrical with respect to an imaginary central-radial plane of the hollow body 30 , which ensures that it is always installed without any confusion.

In this embodiment variant, the leakage can remain in the hollow body 30 over the entire service life of the hydraulic unit 10 . However, intermediate emptying is possible in a simple manner if necessary.

Claims (24)

1.Hydraulic unit for a hydraulic control and / or regulating device, in particular for anti-lock and / or slip-controlled brake systems, with a hydraulic conveying device which comprises a drive means and a displacement unit, the displacement unit engaging in a working space of a housing block, with one in one Control and regulating electronics arranged in the controller housing, the controller housing being fastened to the housing block, and with a drainage channel for leakage fluid which is formed in the housing block and opens into the working space and which, on the other hand, opens into the controller housing, characterized in that the controller housing ( 12 ) has a reservoir ( 27 ) for the leakage fluid, the drain channel ( 14 ) and a transverse bore ( 70 ) opening into the reservoir ( 27 ) and the reservoir ( 27 ) in relation to an interior ( 26 ) of the controller housing ( 24 ) that holds the control and regulating electronics ( 24 ). 12 ) and the area around the hydraulic system gregates ( 10 ) is sealed. 2. Hydraulic unit according to claim 1, characterized in that the controller housing ( 12 ) and the drive means ( 50 ) are arranged on opposite sides of the housing block ( 22 ). 3. Hydraulic unit according to one of the preceding claims, characterized in that the outlet channel ( 14 ) and the transverse bore ( 70 ) open into a blind hole ( 36 ) of the housing block ( 22 ) which in the direction of the interior ( 26 ) of the controller housing ( 12 ) is open. 4. Hydraulic unit according to one of the preceding claims, characterized in that the drain channel ( 14 ) and the transverse bore ( 70 ) have the same axial orientation as a drive axis ( 52 ) of the drive means ( 50 ). 5. Hydraulic unit according to one of the preceding claims, characterized in that the reservoir ( 27 ) is formed by an integrally formed with the controller housing ( 12 ) chamber ( 28 ) which is arranged sealingly on the housing block ( 22 ). 6. Hydraulic unit according to one of the preceding claims, characterized in that the chamber ( 28 ) on the side facing the outlet channel ( 14 ) and the transverse bore ( 70 ) forms a circumferential annular groove ( 60 ). 7. Hydraulic unit according to one of the preceding claims, characterized in that the chamber ( 28 ) above the annular groove ( 60 ) forms a ring stop ( 62 ). 8. Hydraulic unit according to one of the preceding claims, characterized in that at least one sealing device ( 56 ) is arranged between the chamber ( 28 ) and the housing block ( 22 ). 9. Hydraulic unit according to claim 8, characterized in that the sealing device ( 56 ) is an O-ring. 10. Hydraulic unit according to one of claims 1 to 4, characterized in that the reservoir ( 27 ) is formed by a hollow body ( 30 ). 11. Hydraulic unit according to claim 10, characterized in that the hollow body ( 30 ) by means of the controller housing ( 12 ) can be arranged in a form-fitting and sealing manner between the controller housing ( 12 ) and the housing block ( 22 ). 12. Hydraulic unit according to one of claims 10 and 11, characterized in that the hollow body ( 30 ) forms a locking flange ( 38 ) which positively engages in the blind hole ( 36 ). 13. Hydraulic unit according to one of claims 10 to 12, characterized in that the hollow body ( 30 ) forms a positioning stop ( 42 ) assigned to the blind hole ( 36 ). 14. Hydraulic unit according to one of claims 10 to 13, characterized in that the positioning stop ( 42 ) is formed by a radially projecting from the hollow body ( 30 ) first annular bead ( 46 ). 15. Hydraulic unit according to one of claims 10 to 14, characterized in that the controller housing ( 12 ) forms a receiving flange ( 34 ) for the hollow body ( 30 ), in which the hollow body ( 30 ) engages with a second locking flange ( 40 ) in a form-fitting manner. 16. Hydraulic unit according to one of claims 10 to 15, characterized in that the hollow body ( 30 ) forms a second positioning stop ( 44 ) assigned to the receiving flange ( 34 ). 17. Hydraulic unit according to one of claims 10 to 16, characterized in that the positioning stop ( 44 ) is formed by a second annular bead ( 46 ) which projects radially from the hollow body ( 30 ). 18. Hydraulic unit according to one of claims 10 to 17, characterized in that a wall ( 32 ) of the hollow body ( 30 ) is elastically flexible. 19. Hydraulic unit according to one of claims 10 to 18, characterized in that the hollow body ( 30 ) is rotationally symmetrical. 20. Hydraulic unit according to one of claims 10 to 19, characterized in that the hollow body ( 30 ) is symmetrical to an imaginary central-radial plane. 21. Hydraulic unit according to one of claims 10 to 20, characterized in that between the locking flange ( 38 ) and the housing block ( 22 ) and the locking flange ( 40 ) the controller housing ( 12 ) sealing surfaces ( 66 ) and ( 68 ) are formed. 22. Hydraulic unit according to one of claims 10 to 21, characterized in that the wall ( 32 ) of the hollow body ( 30 ) has at least one fold ( 64 ). 23. Hydraulic unit according to one of the preceding claims, characterized in that at least one sealing device ( 54 ) is arranged between the housing block ( 22 ) and the controller housing ( 12 ). 24. Hydraulic unit according to claim 23, characterized in that the sealing device ( 54 ) is an O-ring, which is arranged in an annular groove ( 58 ) of the controller housing ( 12 ) and is supported on the housing block ( 22 ).