DE102014221189A1 - Phaser - Google Patents

Abstract

Proposed is a camshaft adjuster (1) having a drive element (2) and an output element (3), drive element (2) and output element (3) being rotatable within an angular range relative to each other, the output element (3) having a thin-walled centering sleeve (4). has, which can center the output member (3) to a camshaft.

Description

Field of the invention

The invention relates to a camshaft adjuster.

Background of the invention

Camshaft adjusters are used in internal combustion engines for varying the timing of the combustion chamber valves in order to make the phase relation between a crankshaft and a camshaft in a defined angular range, between a maximum early and a maximum late position, variable. Adjusting the timing to the current load and speed reduces fuel consumption and emissions. For this purpose, camshaft adjuster are integrated into a drive train, via which a torque is transmitted from the crankshaft to the camshaft. This drive train may be formed for example as a belt, chain or gear drive.

In a hydraulic camshaft adjuster, the output element and the drive element form one or more pairs of mutually acting pressure chambers, which can be acted upon by hydraulic fluid. The drive element and the output element are arranged coaxially. By filling and emptying individual pressure chambers, a relative movement between the drive element and the output element is generated. The rotationally acting on between the drive element and the output element spring urges the drive element relative to the output element in an advantageous direction. This advantage direction can be the same or opposite to the direction of rotation.

One type of hydraulic phaser is the vane phaser. The vane cell adjuster comprises a stator, a rotor and a drive wheel with an external toothing. The rotor is designed as a driven element usually rotatably connected to the camshaft. The drive element includes the stator and the drive wheel. The stator and the drive wheel are rotatably connected to each other or alternatively formed integrally with each other. The rotor is coaxial with the stator and located inside the stator. The rotor and the stator are characterized by their, radially extending wings, oppositely acting oil chambers, which are acted upon by oil pressure and allow relative rotation between the stator and the rotor. The wings are either formed integrally with the rotor or the stator or arranged as "inserted wings" in designated grooves of the rotor or the stator. Furthermore, the vane cell adjusters have various sealing lids. The stator and the sealing lids are secured together via several screw connections.

Another type of hydraulic phaser is the axial piston phaser. Here, a displacement element is axially displaced via oil pressure, which generates a helical gear teeth relative rotation between a drive element and an output element.

Another design of a camshaft adjuster is the electromechanical camshaft adjuster having a three-shaft gear (for example, a planetary gear). One of the shafts forms the drive element and a second shaft forms the output element. About the third wave, the system by means of an adjusting device, such as an electric motor or a brake, rotational energy supplied or removed from the system. A spring may additionally be arranged, which supports or returns the relative rotation between the drive element and output element.

Summary of the invention

The object of the invention is to provide a camshaft adjuster, which has a particularly accurate and economical connection to the camshaft.

According to the invention, this object is solved by the features of claim 1.

This ensures that the output element can be centered very accurately to the camshaft. The centering sleeve is also very economical to produce and reduces imbalances, which can be caused by the connection. Furthermore, the total weight of the camshaft adjuster is only minimally increased. The centering sleeve may be formed of a metal, for example. Sheet metal, or a plastic.

In one embodiment of the invention, the centering sleeve is mounted in a camshaft-facing receiving the output element. This receptacle may be a circumferential groove on the end face of the output element or an undercut built with such a groove and a cover element, in which the centering sleeve or tabs formed therefrom or the like. intervention.

In an advantageous embodiment, a drive element-fixed component, for example a cover, or a drive wheel is supported on the outer lateral surface of the centering sleeve. Thus, the drive element can advantageously be stored at the same time on the centering. The inner surface of the Centering preferably surrounds one end of the camshaft.

In a particularly preferred embodiment, the centering sleeve has a spring suspension and / or an anti-twist device. The centering, which is provided with an anti-rotation to the output element, advantageously has a groove or a tab in which a spring end is suspended.

In one embodiment of the invention, the centering sleeve has a toothing. By means of this toothing, the centering sleeve can be connected captively to the output element and at the same time be rotationally secured in the circumferential direction to the output element, so that, for example, a spring end can be absorbed by the centering.

The inventive arrangement of the centering on the output element a particularly accurate connection to the camshaft is achieved. Thus, unbalance at the camshaft end are avoided and life is increased.

Brief description of the drawings

Embodiments of the invention are illustrated in the figures.

Show it:

1 a detail of a cut camshaft adjuster with the centering sleeve according to the invention,

2 the detail view A from 1 with the first embodiment of the attachment of the centering sleeve with the receptacle,

3 a second embodiment of the attachment of the centering sleeve with the receptacle,

4 a third embodiment of the attachment of the centering sleeve with the receptacle,

5 a first embodiment of the centering sleeve,

6 a second embodiment of the centering sleeve and

7 the third embodiment of the attachment of the centering sleeve with the receptacle and a bearing of the drive wheel on the centering sleeve.

Detailed description of the drawings

1 shows a section of a cut camshaft adjuster 1 with the centering sleeve according to the invention 4 ,

The camshaft adjuster 1 has a drive element 2 and an output element 3 on. The drive element 2 and the output element 3 are coaxial with the axis of rotation 14 of the camshaft adjuster 1 arranged, wherein the drive element 2 and the output element 3 have a plurality of radially directed and not shown here wings, wherein the drive element 2 and the output element 3 form oppositely acting working chambers, each working chamber by a pair of wings from a wing of the drive element 2 and a wing of the output element 3 is defined and the working chambers are pressurizable with hydraulic fluid to a relative rotation between the drive element 2 and the output element 3 to reach.

The drive element 2 has a one-piece molded drive wheel 8th and a the drive element 2 flanking and with the drive element 2 rotatably connected, designed as a lid, component 7 on. The output element 3 has a central recording 5 for fastening a thin-walled centering sleeve 4 , By means of the centering sleeve 4 becomes the output element 3 to - not shown here - camshaft centered, so that imbalances in the operation of the camshaft adjuster 1 be avoided.

2 shows the detail view A from 1 with the first embodiment of the attachment of the centering sleeve 4 with the recording 5 ,

The centering sleeve 4 has an outer circumferential surface 6 and an inner circumferential surface 10 on. The outer circumferential surface 6 is with the peripheral surface 14 the recording 5 so joined that the centering sleeve 4 captive with the output element 3 connected is. This is here via a press fit between the outer circumferential surface 6 and the peripheral surface 14 achieved. Between the centering sleeve 4 or the outer circumferential surface 6 and the drive element fixed component designed as a cover 7 is a gap 11 intended. The centering of the output element 3 to the camshaft can thus on the contact between the outer surface 6 with the peripheral surface 14 and between the inner circumferential surface 10 the centering sleeve 4 done with the camshaft.

3 shows a second embodiment of the attachment of the centering sleeve 4 with the recording 5 ,

According to 3 is the inner lateral surface 10 with the peripheral surface 14 opposite peripheral surface 15 the recording 5 so joined that the centering sleeve 4 captive with the output element 3 connected is. This is here via a press fit between the inner circumferential surface 10 and the peripheral surface 15 achieved. Between the centering sleeve 4 or the outer circumferential surface 6 and the drive element fixed component designed as a cover 7 is a gap 11 intended. Between the outer surface 6 and the peripheral surface 14 the recording 5 is also a gap 16 provided, which to the gap 11 is formed almost the same size, whereby the peripheral surface 14 to the inner peripheral surface of the lid 7 flees. The centering of the output element 3 to the camshaft can thus via the contact between the inner circumferential surface 10 with the peripheral surface 15 and between the inner circumferential surface 10 the centering sleeve 4 done with the camshaft. Advantageously, according to this embodiment, only the inner circumferential surface 10 be made very accurate so that on the one hand, the press-fit can be formed and on the other hand, the centering can be done with the camshaft. By training the recording 5 As a circumferential groove, the clamping length can be extended by the central screw, which can reduce the preload force in Schraubverbund.

4 shows a third embodiment of the attachment of the centering sleeve 4 with the recording 5 ,

According to 4 has the centering sleeve 4 a covenant 13 on top of one end of the centering sleeve 4 is trained. The Bund 13 engages behind the lid 7 , The Bund 13 is in the recording 5 of the output element 3 , The lid 7 partially covers the recording 5 and thus secures the covenant 13 the centering sleeve 4 in the axial direction. The diameter of the peripheral surface 14 is larger than the inner diameter of the lid 7 , Between the centering sleeve 4 or the outer circumferential surface 6 and the drive element fixed component designed as a cover 7 is a gap 11 intended. Between the outer surface 6 and the peripheral surface 14 the recording 5 is also a gap 16 provided, which to the gap 11 is formed almost the same size, whereby the peripheral surface 14 to the inner peripheral surface of the lid 7 flees. Additionally or alternatively to the formed fit between the fret 13 and the recording 5 with the lid 7 can be a press fit between the inner surface 10 and the peripheral surface 15 be educated. The centering of the output element 3 to the camshaft can thus via the contact between the inner circumferential surface 10 with the peripheral surface 15 and between the inner circumferential surface 10 the centering sleeve 4 done with the camshaft. Advantageously, according to this embodiment, only the inner circumferential surface 10 be made very accurate so that on the one hand, the press-fit can be formed and on the other hand, the centering can be done with the camshaft. By training the recording 5 As a circumferential groove, the clamping length can be extended by the central screw, which can reduce the preload force in Schraubverbund.

5 shows a first embodiment of the centering sleeve 4 , The centering sleeve 4 has several on the outer peripheral surface 6 arranged radially protruding anti-rotation 12 , These anti-rotation devices 12 are in principle parts of a covenant 13 However, due to the circumferential spacing an anti-rotation between the centering 4 and the recording 5 be achieved. This is advantageous if a spring is present, which the drive element 2 with the output element 3 clamped in the circumferential direction, with the centering sleeve 4 should be attached. These anti-rotation devices shown here 12 can analogously to the embodiment of the attachment according to 4 Part of a positive connection, which is the centering sleeve 4 secures in the axial direction. The anti-rotation devices 12 may additionally or alternatively to this embodiment on the inner circumferential surface 10 be arranged. The anti-rotation devices 12 can in an undercut of the output element 3 intervention. A training as a bayonet lock is conceivable to this centering 4 with the output element 3 connect to.

6 shows a second embodiment of the centering sleeve 4 , The centering sleeve 4 points to the outer peripheral surface 6 a gearing 9 on. This gearing 9 can, for example, with the peripheral surface 14 or 15 be engaged to the centering sleeve 4 with the output element 3 to fix. Advantageously, the toothing acts 9 in the circumferential direction as rotation, wherein also in this embodiment of the centering sleeve 4 a spring can be attached. The gearing 9 may additionally or alternatively to this embodiment on the inner circumferential surface 10 be arranged. This centering sleeve 4 can be formed of sheet metal or plastic. The training of the gearing 9 Made of plastic is advantageous because the teeth 9 when joining the centering sleeve 4 with the recording 5 can be pushed and thus forms a particularly reliable hold.

7 shows the third embodiment of the attachment of the centering sleeve 4 with the recording 5 and a bearing of the drive wheel 8th on the centering sleeve 4 , This embodiment is similar to that in FIG 4 , but with the difference that as drive element fixed component 7 a drive wheel 8th is provided. The drive wheel 8th is engaged with a chain, belt or gear drive. The inner peripheral surface of the drive wheel 8th is in contact with the outer circumferential surface 6 the centering sleeve 4 , The centering sleeve 4 in turn, when the camshaft adjuster is installed with the camshaft, it is above its inner lateral surface 10 in contact with an outer circumferential surface of the camshaft. This is the drive wheel 8th advantageously directly supported on the camshaft. The centering of the output element 3 to the camshaft can thus via the contact between the inner circumferential surface 10 with the peripheral surface 15 and between the inner circumferential surface 10 the centering sleeve 4 done with the camshaft. In addition, with this embodiment, the drive wheel 8th centered to the camshaft. The contact between the drive wheel 8th and the centering sleeve 4 Can also be designed oil-tight, so that no leakage oil can escape and no foreign matter from the environment in the camshaft adjuster 1 can reach.

LIST OF REFERENCE NUMBERS

1

 Phaser

2

 driving element

3

 output element

4

 centering

5

 admission

6

 Outer casing surface

7

 drive element-resistant component

8th

 drive wheel

9

 gearing

10

Inner surface area

11

gap

12

twist

13

Federation

14

peripheral surface

15

peripheral surface

16

gap

Claims (5)

Camshaft adjuster ( 1 ) with a drive element ( 2 ) and an output element ( 3 ), wherein drive element ( 2 ) and output element ( 3 ) within an angular range rotatable relative to one another, characterized in that the output element ( 3 ) a thin-walled centering sleeve ( 4 ), which the output element ( 3 ) can center to a camshaft. Camshaft adjuster ( 1 ) according to claim 1, characterized in that the centering sleeve ( 4 ) in a camshaft-facing receptacle ( 5 ) of the output element ( 3 ) is attached. Camshaft adjuster ( 1 ) according to claim 1, characterized in that on the outer circumferential surface ( 6 ) of the centering sleeve ( 4 ) a drive element-fixed component ( 7 ) or a drive wheel ( 8th ) is supported. Camshaft adjuster ( 1 ) according to claim 1, characterized in that the centering sleeve ( 4 ) a spring suspension or anti-twist device ( 12 ) having. Camshaft adjuster ( 1 ) according to claim 1, characterized in that the centering sleeve ( 4 ) a gearing ( 9 ) having.

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