DE102014207334A1 - Phaser - Google Patents

Abstract

Proposed is a camshaft adjuster (1) with a drive element (2), an output element (3), a locking cover (4), and a spring (5), wherein the locking cover (4) has a locking link (6) into which a Abtriebselement (3) arranged locking piston can lock, wherein the locking cover (4) by means of fastening means (7) to the drive element (2) is rotatably connected and the spring (5) to the locking cover (4) is arranged axially adjacent, characterized in that between the spring (5) and the locking cover (4) a spacer element (8) for axially spacing the spring (5) is arranged to the locking cover (4), which with its outer contour (9) of the outer contour (10) of the locking lid ( 4) deviates and both the fastening means (7) and the locking link (6) projects.

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 an improved spring system.

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

Camshaft adjuster having a drive element, an output member, a locking cover, and a spring, wherein the locking cover has a locking link into which a locking member disposed in the driven locking piston can lock, wherein the locking cover is rotatably connected by means of fastening means with the drive element and the spring axially adjacent to the locking cover is arranged, characterized in that between the spring and the locking cover, a spacer element for axial spacing of the spring is arranged to the locking cover, which deviates with its outer contour of the outer contour of the locking cover and projects around both the fastening means and the locking link.

This ensures that an axially projecting locking link does not collide with the resilient windings of the spring. At the same time, the spacer element is designed so that the additional weight is minimized. In particular, materials such as light metal or plastics lend themselves to the formation of the spacer element. Also, lock cover and / or spacer can be made Sintered steel or sintered aluminum. Furthermore, locking cover and / or spacer element can have a thread for the fastening means, in particular screws, or a compacted support region for a screw head.

The spacer element may be formed as a rib, dome or as a raised plane surface. In the case of a plurality of spacer elements, the abovementioned shapes of the spacer elements may be arranged regularly or irregularly patterned over the circumference. The axial dimensioning of all spacer elements can be the same size or irregular size. Advantageously, the occurring voltage is distributed in such a way that the service life is increased.

In one embodiment of the invention, the locking cover has a central opening, wherein the spacer element has an inner contour which deviates from the inner contour formed by the central opening of the locking cover. Advantageously, in this case the additional weight is minimized.

The contour of the spacer element and its arrangement on the locking cover can be designed such that imbalances can be compensated or moments of inertia can be reduced.

In an advantageous embodiment, the spacer element is formed by the locking cover as a separate component and engages around the locking link of the locking cover and is so releasably or permanently connected to the locking lid. The spacer element comes in the joining process with the locking cover in contact and is positively fixed, for example by the locking link. The contact between the locking cover and the spacer can be achieved by force (for example thread, press fit, etc.), shape (for example cup, depressions in the base body, etc.) and / or integral bonding (for example sintering, gluing, soldering, welding, etc.) connections are secured.

If the spacing element and the locking cover are made of sintered material, then both components can be baked together during the sintering process or can be joined together later by a calibration process.

It may be advantageous according to the invention if one of the two parts to be joined together, for example the locking cover, has a type of rib structure which engages in a correspondingly corresponding structure of the other part, for example of the spacer element.

Furthermore, spring suspensions, for example. In the form of pins or bolts, may be surrounded by the spacer.

In a particularly preferred embodiment, in addition to the spacer element further spacer elements for axial spacing of the spring to the locking cover are arranged. The spacers may advantageously have different dimensions in the axial direction in order to limit certain resilient turns or turns regions in their axial clearance.

In one embodiment of the invention, the locking cover in addition to the spacer further spacer elements for axial spacing of the spring to the locking lid, said further spacer elements are formed as einmaterialiger part of the locking lid. The spacers can take over additional functions such as increasing the stiffness of the locking lid.

The tolerance of the axial dimension of the component unit of locking cover and spacer can be significantly improved by means such as calibration or grinding.

The inventive arrangement of the spacer on the locking cover, in particular with the locking link, a weight-saving, controllable axial restriction of the resilient windings of the spring is achieved.

Brief description of the drawings

Embodiments of the invention are illustrated in the figures.

Show it:

1 a camshaft adjuster according to the invention,

2 an exploded view of a unit consisting of locking cover, locking link and spacer element,

3 a section through the unit after 1 , wherein the assembly is completed and

4 an alternative embodiment of the assembly with integrally formed on the locking cover spacers.

Detailed description of the drawings

1 shows a camshaft adjuster according to the invention 1 , The camshaft adjuster 1 has a drive element 2 , an output element 3 , a feather 5 , a locking lid 4 with the spacers 8th and a plurality of fastening means designed as fastening screws 7 on. Furthermore, the locking lid 4 a central opening 11 , The locking lid 4 is by means of circumferentially distributed fastening screws with the drive element 2 fixed. On the drive element 2 opposite side of the locking lid 4 are the spacers 8th arranged, which is the spring 5 from the locking lid 4 spacing. The spacers 8th can be made in one piece from the locking lid 4 be formed, or present as a separate component.

2 shows an exploded view of a unit of locking lid 4 , Locking mechanism 6 and spacer 8th , locking cover 4 , Locking mechanism 6 and spacer 8th are formed as separate components and are joined together in the axial direction. This is how the locking mechanism works 6 in a specially designated opening of the locking lid 4 inserted and secured captive by means of a force, material and / or positive connection. The locking mechanism 6 protrudes in the axial direction from the locking lid 4 out. This protruding part of the locking link 6 is from the spacer element 8th surmounted and for fixing it with the locking link 6 and the locking lid 4 used. The locking lid 4 has a cylindrical outer contour 10 and a cylindrical inner contour 13 , which are in the area of the central opening 11 of the locking lid 4 is trained. The spacer element 8th on the other hand, has an outer contour deviating from a cylindrical shape 9 on and one of a cylindrical shape deviating inner contour 12 on.

3 shows a section through the unit after 1 , wherein the assembly is completed. Well recognizable is that the outer contour 10 of the locking lid 4 not with the outer contour 9 of the spacer element 8th matches. The same is true for the inner contour 13 of the locking lid 4 and the inner contour 12 of the spacer element 8th recognizable. The spacer element 8th surrounds both the locking link 6 , as well as the openings for the fasteners 7 , wherein the spacer element 8th even openings for the fasteners 7 having, which with those of the locking lid 4 aligned.

4 shows an alternative embodiment of the unit with one piece to the locking lid 4 molded spacers 8th and 14 , The spacer element 8th This embodiment has a self-contained outer contour 9 on which both the locking link 6 and an adjacently disposed opening for a fastener 7 , The locking lid 4 has further spacers 14 on, which are formed as rods or ribs and from the center of the central opening 11 Radially directed, directly to the inner contour 13 then in the direction of the outer contour 10 extend and with the outer contour 10 to lock. Other further spacers 14 annularly project around each of the openings for the fastening means 7 of the locking lid 4 ,

LIST OF REFERENCE NUMBERS

1

 Phaser

2

 driving element

3

 output element

4

 locking cover

5

 feather

6

 locking link

7

 fastener

8th

 spacer

9

 outer contour (spacer element)

10

outer contour (locking cover)

11

central opening

12

inner contour (distance element)

13

inner contour (locking cover)

14

additional spacers

Claims (5)

Camshaft adjuster ( 1 ) with a drive element ( 2 ), an output element ( 3 ), a locking lid ( 4 ), and a spring ( 5 ), wherein the locking lid ( 4 ) a locking link ( 6 ), in which a in the output element ( 3 ) arranged locking piston can lock, wherein the locking cover ( 4 ) by means of fastening means ( 7 ) with the drive element ( 2 ) is rotatably connected and the spring ( 5 ) to the locking lid ( 4 ) is axially adjacent, characterized in that between the spring ( 5 ) and the locking lid ( 4 ) a spacer element ( 8th ) for the axial spacing of the spring ( 5 ) to the locking lid ( 4 ), which with its outer contour ( 9 ) from the outer contour ( 10 ) of the locking lid ( 4 ) and both the fastening means ( 7 ) as well as the locking link ( 6 ). Camshaft adjuster ( 1 ) according to claim 1, characterized in that the locking cover ( 4 ) a central opening ( 11 ) and the spacer element ( 8th ) an inner contour ( 12 ), which extends from the through the central opening ( 11 ) of the locking lid ( 4 ) formed inner contour ( 13 ) deviates. Camshaft adjuster ( 1 ) according to claim 1 or 2, characterized in that the spacer element ( 8th ) from the locking lid ( 4 ) is formed as a separate component and means Encompassing the locking link ( 6 ) with the locking cover ( 4 ) is releasably or permanently connected. Camshaft adjuster ( 1 ) according to one of the preceding claims, characterized in that in addition to the spacer element ( 8th ) on the locking cover ( 4 ) further spacer elements ( 14 ) for the axial spacing of the spring ( 5 ) to the locking lid ( 4 ) is arranged. Camshaft adjuster ( 1 ) according to one of claims 1 to 3, characterized in that in addition to the spacer element ( 8th ) further spacer elements ( 14 ) for the axial spacing of the spring ( 5 ) to the locking lid ( 4 ) is arranged and these other spacers ( 14 ) as einmaterialiger part of the locking lid ( 4 ) are formed.

Images