WO2010015541A1

WO2010015541A1 - Device for variable adjustment of the timing of gas exchange valves of an internal combustion engine

Info

Publication number: WO2010015541A1
Application number: PCT/EP2009/059668
Authority: WO
Inventors: Boris PÜTZ; Ali Bayrakdar
Original assignee: Schaeffler Kg
Priority date: 2008-08-02
Filing date: 2009-07-27
Publication date: 2010-02-11
Also published as: EP2321501B1; CN102112707B; DE102008036182A1; ATE542984T1; US20110132303A1; CN102112707A; EP2321501A1

Abstract

The invention relates to a device (11) for the variable adjustment of the timing of gas exchange valves (9, 10) of an internal combustion engine (1), comprising a hydraulic phase shifting device (12), a camshaft (6, 7) and a pressurizing means distributor (13), wherein the phase shift device (12) can be caused to come into drive linkage with a crankshaft (2) and is rigidly connected to the camshaft (6, 7), wherein a phase position of the camshaft (6, 7) relative to the crankshaft (2) can be variably adjusted by way of the phase shift device (12), wherein the interior of the camshaft (6, 7) comprises a cavity (49) that communicates with one or more camshaft bearings (50) designed to be separate from a rotating pressurizing means conveyor (39), wherein the pressurizing means distributor (13) is disposed in a receiving area (37) of the camshaft (6, 7), wherein the camshaft (6, 7) comprises an opening (38) in the area of the pressurizing means distributor (13), said opening communicating on the one hand with the interior of the camshaft (6, 7) and on the other hand with the rotating pressurizing means conveyor (39), wherein a pressurizing means path (40) is designed inside the camshaft (6, 7), said path communicating on the one hand with the opening (38) and on the other hand with the hydraulic phase shift device (12).

Description

Name of the invention

Device for the variable adjustment of the timing of gas exchange valves of an internal combustion engine

description

Field of the invention

The invention relates to a device for variably setting the timing of gas exchange valves of an internal combustion engine with a hydraulic phase adjusting device, a camshaft and a pressure medium distributor, wherein the phase adjusting device can be brought into drive connection with a crankshaft and rotatably connected to the camshaft, wherein a phase angle of the camshaft relative to Crankshaft is variably adjustable by means of the phase adjusting device, wherein the interior of the camshaft has a cavity communicating with one or more camshaft bearings, which are formed separately to a pressure medium rotary transformer, wherein the pressure medium distributor is arranged in a receiving area of the camshaft, wherein the camshaft in the area of the pressure medium distributor has an opening which communicates on the one hand with the interior of the camshaft and on the other hand with the pressure medium rotary transformer, wherein within the camshaft a Druc kmittel path is formed, which communicates on the one hand with the opening and on the other hand with the hydraulic phase adjusting device.

Background of the invention

In modern internal combustion engines devices for variable adjustment of the timing of gas exchange valves are used to make the phase relation between the crankshaft and the camshaft in a defined angular range, between a maximum early and a maximum late position variable. The device usually consists of a Ckenwelle, a hydraulic phase adjusting device, by means of which by pressure medium supply or discharge a phase relationship between the crankshaft and the camshaft can be selectively changed, and a pressure medium distributor, by means of the phase adjusting means pressure medium can be supplied or discharged from this. For this purpose, the phase adjusting device is integrated in a drive train, via which torque is transmitted from the crankshaft to the camshaft. This drive train can be realized for example as a belt, chain or gear drive.

Such a device is known for example from DE 10 2005 052 481 A1. The device comprises a phase adjusting device, a central screw and a camshaft which is mounted in the cylinder head of the internal combustion engine by means of a plurality of camshaft bearings. The phase adjusting device has an output element, which is arranged rotatably to a drive element. The drive element is in drive connection with the crankshaft. In the axial direction, the device is limited by a respective side cover. The output element, the drive element and the two side covers define a plurality of pressure chambers, wherein each of the pressure chambers is divided by a wing into two counteracting pressure chambers. By supplying pressure medium to or pressure fluid removal from the pressure chambers, the wings are moved within the pressure chambers, whereby a targeted rotation of the output element to the drive element and thus the camshaft can be effected to the crankshaft. The phase adjusting device is non-rotatably connected to the camshaft by means of the central screw. In this case, the central screw passes through a central opening of the output element and is supported on its side facing away from the camshaft side surface on the driven element. Within the central screw, a control valve is arranged in the region of the central opening, to which pressure medium is supplied via a camshaft bearing. By means of the Steuerven- tils the pressure medium flows to or from the pressure chambers and thus the phase relation between the crankshaft and camshaft are controlled. A disadvantage of this embodiment is that per camshaft bearing complex lubricant supply lines must be formed within the cylinder head to supply the camshaft bearings lubricant. This considerably increases the complexity and the production costs of the cylinder head.

Object of the invention

The invention has for its object to provide a device for variable adjustment of the timing of gas exchange valves of an internal combustion engine, the lubricant supply of the camshaft bearing should be simplified.

The object is achieved according to the invention in that a second pressure medium channel is provided, which communicates on the one hand with the opening and on the other hand with the cavity, wherein the second pressure medium channel is at least partially formed by the pressure medium distributor.

It can be provided that the pressure medium distributor is provided with a threaded section, by means of which the phase adjusting device can be fastened to the camshaft.

In one development of the invention, the pressure medium distributor has a control valve, by means of which the phase adjusting device can be supplied with pressure medium.

In this case, the pressure medium distributor can pass through a central opening of the phase adjusting device.

The second pressure medium channel can be formed, for example, within the pressure medium distributor. Alternatively it can be provided to form the second pressure medium channel at an interface between the cavity and the pressure medium distributor. It can be provided, for example, that the second pressure medium channel as a longitudinal groove on an outer circumferential surface of the pressure central distributor or is formed on an inner circumferential surface of the camshaft in the region of the pressure medium distributor.

The pressure medium rotary transformer may be formed, for example, as a camshaft bearing.

Furthermore, it can be provided that the pressure medium path is at least partially formed by the pressure medium distributor.

The device has at least one hydraulic phase adjusting device on a camshaft and a pressure medium distributor. The phase adjusting device comprises at least one drive element and an output element. The drive element is in the assembled state of the device via a traction drive, such as a belt or chain drive, or a gear drive, with the crankshaft in drive connection. The output member is pivotally mounted in an angular range relative to the drive element and rotatably secured to the camshaft.

Within the device, at least one pressure chamber is provided by the pressurization of which the output element relative to the drive element and thus the camshaft can be pivoted relative to the crankshaft. Advantageously, one or more pairs of mutually acting pressure chambers are provided.

The camshaft is designed as a hollow shaft with a cavity. This can be realized, for example, in that the camshaft consists of a tube, whose one end is closed and force-fit, positive-locking or cohesively fixed on the cam. But also conceivable are solidly executed camshafts, which have an axial channel, in the form of a blind hole, which opens into a receptacle in which the pressure medium distributor is arranged. The camshaft is mounted in a plurality of camshaft bearings, wherein the hollow space communicates with at least one of the camshaft bearings via radial openings in the camshaft. The pressure medium distributor is received in a receptacle of the camshaft, said receptacle communicating with the cavity. The receptacle may be part of the cavity, for example. The camshaft has an opening in the region of the receptacle in which the pressure medium distributor is arranged. In this area, a pressure medium rotary transformer is arranged. This can surround the camshaft, for example, completely in the circumferential direction. In this case, the pressure medium rotary transformer can be designed as a camshaft bearing or as a separate component. About the pressure medium rotary transformer and the opening is supplied to the interior of the camshaft during operation of the internal combustion engine permanently or at intervals pressure medium. Within the camshaft, the pressure medium distributor separates a pressure medium path which is provided for supplying the phase adjusting device by a second pressure medium channel which opens into the cavity of the camshaft and via which the camshaft bearing separate from the pressure medium rotary transformer is supplied with lubricant. The pressure medium distributor closes the cavity, apart from the second pressure medium channel, pressure-tight to the outside. In addition, a filter element can be integrated in the second pressure medium channel, which keeps foreign bodies in the lubricant or pressure medium away from the camshaft bearings and thus reduces the wear of the bearing points. Since all camshaft bearings are supplied with lubricant / pressure medium via the second pressure medium channel, only a single filter element is required in this embodiment. The Druckmitteldre- prettyertrager can fulfill other functions in addition to the leadership of the lubricant / pressure medium flows. For example, a threaded portion may be formed on this, by means of which the phase adjusting device, such as the output member, rotatably connected to the camshaft can be connected. It is also conceivable that the pressure medium distributor has a control valve, via which the pressure medium flows can be controlled to and from the pressure chambers of the phase adjusting device. Thus, several functionalities can be represented by a component, whereby the number of components and thus the assembly costs, the space requirement of the device and their costs decrease. The second pressure medium channel, which communicates on the one hand with the opening and thus with the pressure medium rotary transformer and on the other hand with the cavity of the camshaft is at least partially formed by the pressure medium distributor. It is conceivable, for example, a pressure medium distributor, in the interior of a Bore is provided, which branches off from the pressure medium path, which supplies the phase adjusting device with pressure medium. In this case, the second pressure medium channel is formed solely by the pressure medium distributor. Likewise conceivable are embodiments in which the second pressure medium channel is formed at an interface between the pressure medium distributor and the camshaft, for example an inner lateral surface of the camshaft and an outer lateral surface of the pressure medium distributor. This can be realized for example by a longitudinal groove which is formed on the outer circumferential surface of the pressure medium distributor or the inner circumferential surface of the camshaft.

Advantageously, a minimum flow area of the second pressure medium channel is made smaller than a minimum flow area of the pressure medium path between the opening and the phase adjusting device. For example, the second pressure medium channel may have a throttle point. The throttle point may for example be realized by means of a separate component, which is arranged in the second pressure medium channel. Thus, the pressure medium flow to the camshaft bearings can be reduced to the required degree, whereas the phase adjusting means the pressure medium can be fed unthrottled. The high pressure medium flow to the phase adjusting device leads to a high response and high adjustment speeds. At the same time, the required volume flow is limited by the fact that the camshaft bearings, a lower flow rate is supplied. This relieves the pressure medium pump of the internal combustion engine.

Brief description of the drawings

Further features of the invention will become apparent from the following description and from the drawings in which embodiments of the invention are shown in simplified form. Show it:

FIG. 1 shows very schematically an internal combustion engine, FIG. 2 shows a longitudinal section through a first embodiment according to the invention of a device for changing the control times of gas exchange valves of an internal combustion engine,

FIG. 3 shows a cross section through the phase adjusting device from FIG. 2 along the line III-III,

FIG. 4 shows a longitudinal section through a second embodiment according to the invention of a device analogous to FIG. 2, with only the camshaft and the pressure medium distributor being shown,

Figure 5 shows a longitudinal section through a third embodiment according to the invention of a device analogous to Figure 2, wherein only the camshaft and the pressure medium distributor are shown.

Detailed description of the drawings

1 shows an internal combustion engine 1 is sketched, wherein a seated on a crankshaft 2 piston 3 is indicated in a cylinder 4. The crankshaft 2 is in the illustrated embodiment via a respective traction drive 5 with an intake camshaft 6 and exhaust camshaft 7 in combination, with a first and a second device 11 for a relative rotation between the crankshaft 2 and the camshafts 6, 7 can provide. Cams 8 of the camshafts 6, 7 actuate one or more inlet gas exchange valves 9 or one or more Auslassgaswechselventile 10. Likewise, it may be provided only one of the camshafts 6, 7 with a device 11, or provide only a camshaft 6, 7, which with a Device 11 is provided.

Figures 2 and 3 show a first embodiment of a device 11 according to the invention in longitudinal or in cross section. The device 11 has a phase adjusting device 12, a camshaft 6, 7 and a pressure medium distributor 13. The phase adjusting device 12 comprises a drive element 14 and a drive element 16. The drive element 14 has a housing 15 and two side covers 17, 18, which are arranged on the axial side surfaces of the housing 15. The output element 16 is designed in the form of an impeller and has a substantially cylindrical hub element 19, from the outer cylindrical surface of which in the illustrated embodiment, five wings 20 extend in the radial direction outward. Starting from an outer peripheral wall 21 of the housing 15, five projections 22 extend radially inwardly. In the illustrated embodiment, the projections 22 and the wings 20 are integrally formed with the peripheral wall 21 and the hub member 19, respectively. The drive element 14 is arranged by means of radially inner circumferential walls of the projections 22 relative to the output member 16 rotatable thereto.

On an outer lateral surface of the first side cover 17, a sprocket 23 is formed, via which by means of a chain drive, not shown, torque can be transmitted from the crankshaft 2 to the drive member 14. The output member 16 is rotatably connected to the camshaft 6,7. For this purpose, in the illustrated embodiment, the pressure medium displacement 13 is provided with a threaded portion 24 which engages in a threaded portion 25 of the camshaft 6, 7. The pressure medium distributor 13 passes through a central opening 16a of the output element 16. A shoulder of the pressure medium distributor 13 rests against the side surface of the output element 16 facing away from the camshaft 6, 7.

Depending on one of the side covers 17, 18 is arranged on one of the axial side surfaces of the housing 15 and rotatably fixed thereto. For this purpose, an axial opening 26 is provided in each projection 22. Furthermore, five openings each are provided in the side covers 17, 18, which are arranged in such a way that they are aligned with the axial openings 26. In each case, a screw 27 passes through an opening of the second side cover 18, an axial opening 26 and an opening of the first side cover 17. In this case engages a threaded portion of the screw 27 in a threaded portion which in the Opening of the first side cover 17 is formed.

Within the device 11, a pressure space 28 is formed between each two circumferentially adjacent projections 22. Each of the pressure chambers 28 is circumferentially bounded by opposing, substantially radially extending boundary walls 29 of adjacent projections 22, in the axial direction of the side covers 17, 18, radially inwardly of the hub member 19 and radially outwardly of the peripheral wall 21. In each of the pressure chambers 28 protrudes a wing 20, wherein the wings 20 are formed such that they rest against both the side covers 17, 18, and on the peripheral wall 21. Each wing 20 thus divides the respective pressure chamber 28 into two counteracting pressure chambers 30, 31.

The output member 16 is rotatably arranged in a defined Winkeibreich to the drive member 14. The angular range is limited in one direction of rotation of the driven element 16 in that the wings 20 come into contact with a corresponding boundary wall 29 (early stop 32) of the pressure chambers 28. Similarly, the angular range in the other direction of rotation is limited by the fact that the wings 20 come to rest on the other boundary walls 29 of the pressure chambers 28, which serve as a late stop 33.

By pressurizing a group of pressure chambers 30, 31 and pressure relief of the other group, the phase position of the drive element 14 to the output element 16 (and thus the phase angle of the camshaft 6, 7 to the crankshaft 2) can be varied. By pressurizing both groups of pressure chambers 30, 31, the phase position can be kept constant.

To supply the phase adjusting device 12 with pressure medium, the pressure medium distributor 13 is provided with a control valve 34. The control valve 34 comprises a substantially hollow cylindrical valve housing 35 and a

Control piston 36, the axially displaceable within the valve housing 35 to is ordered. The valve housing 35 is provided with an inlet port P, a drain port T, and two working ports A, B. The pressure medium distributor 13 passes through the central opening 16a of the output element 16, wherein its camshaft-facing portion is arranged in a receptacle 37 of the hollow camshaft 6, 7. The camshaft 6, 7 has in the region of the receptacle 37 a plurality of openings 38, on the one hand with a pressure medium rotary transformer 39, which at least partially surrounds the camshaft 6, 7, and on the other hand with the interior of the camshaft 6, 7 communicate. In the illustrated embodiment, the pressure medium rotary transformer 39 is simultaneously designed as a camshaft bearing 50. About the pressure medium rotary transformer 39 and the openings 38 is supplied to the interior of the camshaft 6, 7 during operation of the internal combustion engine 1 pressure medium from the lubricant circuit. Also conceivable are embodiments in which the pressure medium rotary transformer 39 is designed separately from the camshaft bearings 50 and only the pressure medium transfer between the cylinder head fixed components and the camshaft 6, 7 allows.

The pressure medium distributor 13 is designed and arranged such that a pressure medium path 40 is formed, which communicates on the one hand with the openings 38 and on the other hand with the inlet port P. In the illustrated embodiment, the pressure medium path 40 consists of a first pressure medium channel 41 between the outer lateral surface of the pressure medium distributor 13 and the inner lateral surface of the camshaft 6, 7, which communicates with radial openings 42, which in turn communicate with the interior of the pressure medium distributor 13. From there, the pressure medium passes through a check valve 43 and an axial channel 44 to the inlet port P.

Depending on the axial position of the control piston 36 to the valve housing 35, the pressure medium reaches either the first or second working port A, B and from there via radial pressure medium lines 45, 46 to the first and second pressure chambers 30, 31. At the same time the pressure medium from the other pressure chambers 30, 31 is returned via the pressure medium lines 45, 46 to the control valve 34 and discharged via the discharge port T SEN. The axial position of the control piston 36 relative to the valve housing 35 is selectively adjustable by means of an electromagnetic actuator 47.

Inside the pressure medium distributor 13, a second pressure medium channel 48 is provided, which communicates on the one hand via the radial openings 42 and the first pressure medium channel 41 with the openings 38 and on the other hand with a cavity 49 of the hollow camshaft 6, 7. The second pressure medium channel 48 is formed in the embodiments shown in Figures 2 and 4 as an axial bore, which passes through the threaded portion 24. The cavity 49 extends, as shown in Figure 4, over the entire length of the camshaft 6, 7, wherein the phase adjusting device 12 remote from the side formed closed and limited by the pressure medium distributor 13 in the other direction. In this case, the pressure medium distributor 13 seals the cavity 49, apart from the second pressure medium channel 48, to the outside. The camshaft 6, 7 is rotatably mounted in the cylinder head of the internal combustion engine 1 by means of one or more camshaft bearings 50. In the area of each of these camshaft bearings 50, at least one, advantageously a plurality, radial openings 51 are provided, which communicate on the one hand with the cavity 49 and on the other hand with the bearing surface of the camshaft bearing 50. Thus, the camshaft bearings 50 via the pressure medium rotary transformer 39, the openings 38, the first pressure medium channel 41, the radial openings 42, the second pressure medium channel 48, the cavity 49 and the radial openings 51 lubricant supplied. Furthermore, a filter element 54 is provided, which frees the pressure fluid / lubricant flow to the camshaft bearings and the phase adjusting device 12 of impurities. In the illustrated embodiment, the filter element 54 is formed as a ring filter.

In order to ensure a high response speed and a high adjustment speed of the phase adjusting device 12, it is necessary to allow a high volume flow to the phase adjusting device 12. At the same time, it is advantageous to limit the volume flow to the camshaft bearings 50 to a minimum guaranteeing their functionality. Thereby the required volume flow, which must be provided via the pressure medium rotary transformer 39, can be lowered, at the same time a high response and adjustment speed of the phase adjusting device 12 is ensured. For this purpose, a throttle 52 is provided within the second pressure medium channel 48, which limits the pressure medium flow from the pressure medium rotary transformer 39 to the bearing surfaces of the camshaft bearings 50 without hindering the pressure medium flow to the phase adjusting device 12. In the embodiment shown in Figure 4, the throttle 52 is formed separately from the pressure medium manifold 13 and stationary in the second pressure medium channel 48, for example by a positive, material or non-positive connection attached. Likewise conceivable are embodiments in which the diameter of the second pressure medium channel 48 is designed such that the throttle function is caused by this (Figure 2) or in which the throttle 52 is formed on the pressure medium manifold 13. In all cases, the minimum flow area of the second pressure medium channel 48 is smaller than the minimum flow area between the pressure medium rotary transformer 39 and the pressure chambers 30, 31.

FIG. 5 shows a further embodiment of the device 11 according to the invention, which is essentially identical to the first two embodiments. In contrast to the first two embodiments, the second pressure medium channel 48 is formed at the interface between the inner circumferential surface of the camshaft 6, 7 and the outer circumferential surface of the pressure medium distributor 13. For this purpose, a longitudinal groove 53 is provided, which communicates on the one hand with the cavity 49 and on the other hand with the first pressure medium channel 41. The longitudinal groove 53 may be formed, for example, on the inner circumferential surface of the camshaft 6, 7 or the outer circumferential surface of the pressure medium distributor 13. In any case, therefore, the second pressure medium channel 48 is partially limited by the pressure medium distributor 13. Also in this embodiment, it is provided to throttle the pressure medium flow to the camshaft bearings 50. This can be achieved for example, as shown in Figure 5 via a suitable design of the cross section of the longitudinal groove 53. there For example, the longitudinal groove 53 may have a constant small cross section or a local throttle point.

By means of the invention, one or more camshaft bearings 50 which are separate from the pressure medium rotary transmitter 39 can be supplied with lubricant. Thus, the usual in the cylinder head structures for supplying lubricant to each individual camshaft bearing 50 can be omitted, whereby the complexity and the cost of the cylinder head can be reduced. Due to the pressure medium supply of all camshaft bearing 50 via the hollow space 49 of the camshaft 6, 7, only a pressure medium supply to the camshaft 6, 7 is necessary, via which the phase adjusting device 12 is simultaneously supplied. The formation of the second pressure medium channel 48 through the pressure medium distributor 13 significantly reduces the costs and complexity of the device 11. Thus, the supply of the phase adjusting device 12 and the camshaft bearings 50 can be realized by means of a single component, whereby the assembly cost drops considerably.

reference numeral

1 internal combustion engine

2 crankshaft

3 pistons

4 cylinders

5 traction drive

6 intake camshaft

7 exhaust camshaft

8 cams

9 inlet gas exchange valve

10 outlet gas exchange valve

11 device

12 phase adjusting device

13 pressure medium distributor

14 drive element

15 housing

16 output element

16a central opening

17 side covers

18 side covers

19 hub element

20 wings

21 peripheral wall

22 lead

23 sprocket

24 threaded section

25 threaded section

26 axial opening

27 screw

28 pressure chamber

29 boundary wall 30 first pressure chamber

31 second pressure chamber

32 early stop

33 Late stop

34 control valve

35 valve housing

36 control piston

37 recording

38 openings

39 pressure medium rotary transformer

40 pressure medium path

41 first pressure medium channel

42 radial openings

43 non-return valve

44 axial channel

45 first pressure medium line

46 second pressure medium line

47 control unit

48 second pressure medium channel

49 cavity

50 camshaft bearings

51 radial opening

52 throttle

53 longitudinal groove

54 filter element

A first work connection

B second work connection

P inlet connection

T drain connection

Claims

claims

1. Device (11) for variably setting the timing of gas exchange valves (9, 10) of an internal combustion engine (1) with - a hydraulic phase adjusting device (12), a camshaft (6, 7) and a pressure medium distributor (13),

- Wherein the phase adjusting device (12) in drive connection with a crankshaft (2) can be brought and non-rotatably connected to the camshaft (6, 7), - wherein a phase angle of the camshaft (6, 7) relative to the crankshaft (2) by means of the phase adjusting device (12) is variably adjustable,

- wherein the interior of the camshaft (6, 7) has a cavity (49) which communicates with one or more camshaft bearings (50) which are formed separately from a pressure medium rotary transformer (39), - wherein the pressure medium distributor (13) in one Receiving area (37) of the camshaft (6, 7) is arranged,

- wherein the camshaft (6, 7) in the region of the pressure medium distributor (13) has an opening (38) which communicates on the one hand with the interior of the camshaft (6, 7) and on the other hand with the pressure medium rotary transformer (39),

- wherein within the camshaft (6, 7) a pressure medium path (40) is formed, which communicates on the one hand with the opening (38) and on the other hand with the hydraulic phase adjusting device (12),

- characterized in that a second pressure medium channel (48) is provided which communicates on the one hand with the opening (38) and on the other hand with the cavity (49),

- Wherein the second pressure medium channel (48) is at least partially formed by the pressure medium distributor (13).

2. Device (11) according to claim 1, characterized in that the pressure medium distributor (13) with a threaded portion (24) is provided, by means of which the phase adjusting device (12) on the camshaft (6, 7) can be fastened.

3. Device (11) according to claim 1, characterized in that the pressure medium distributor (13) has a control valve (34) by means of which the phase adjusting device (12) can be supplied with pressure medium.

4. Device (11) according to claim 1, characterized in that the pressure medium distributor (13) passes through a central opening (16a) of the phase adjusting device (12).

5. Device (11) according to claim 1, characterized in that a minimum flow area of the second pressure medium channel (48) is made smaller than a minimum flow area of the pressure medium path (40) between the opening (38) and the phase adjusting device (12).

6. Device (11) according to claim 1, characterized in that the second pressure medium channel (48) is formed within the pressure medium distributor (13).

7. Device (11) according to claim 1, characterized in that the second pressure medium channel (48) at an interface between the cavity

(49) and the pressure medium distributor (13) is formed.

8. Device (11) according to claim 7, characterized in that the second pressure medium channel (48) as a longitudinal groove (53) on an outer circumferential surface of the pressure medium distributor (13) is formed.

9. Device (11) according to claim 7, characterized in that the second pressure medium channel (48) as a longitudinal groove (53) on an inner circumferential surface of the camshaft (6, 7) in the region of the pressure medium distributor (13) is ausgebil det.

10.Vorrichtung (11) according to claim 1, characterized in that the second pressure medium channel (48) has a throttle (52).

11. Device (11) according to claim 10, characterized in that the throttle (52) is realized by means of a separate component which is arranged in the second pressure medium channel (48).

12. Device (11) according to claim 1, characterized in that the pressure medium rotary transformer (39) is designed as a camshaft bearing (50).

13. Device (11) according to claim 1, characterized in that the pressure medium path (40) is at least partially formed by the pressure medium distributor (13).

14. Device (11) according to claim 1, characterized in that in the second pressure medium channel (48) a filter element (54) is arranged.