DE102013203245A1 - Statortopf with insert disc to reduce the axial bearing play - Google Patents

Abstract

The invention relates to a stator assembly (1) for a camshaft adjuster (2), with a stator (3) which has teeth (4) on its outside (5) in order to absorb torque provided by a crankshaft, the stator ( 3) has a wall (6) integrally forming the toothing (4) with a cavity (7) extending in the axial direction for receiving a rotor (9), at least one radially inwardly projecting integrally formed flange section (8) of the stator (3 ) forms an axial stop for the rotor, a spacer (10) separate from the stator (3) and from the rotor (9) being provided in the cavity (7) and in sealing contact with the flange section (8). The invention also relates to a hydraulic camshaft adjuster of the vane cell type, with a rotor and such a stator assembly.

Description

Field of the invention

The invention relates to a stator assembly for a camshaft adjuster, comprising a stator, which preferably has on its outside a toothing to receive torque provided by a crankshaft, wherein the stator preferably integrally forming a toothing wall with an axially extending cavity for Receiving a rotor, wherein at least one radially inwardly projecting, integrally formed flange portion of the stator directly or indirectly forms an axial stop for the rotor.

Such stator assemblies are used in camshaft phasers that are part of a timing drive of internal combustion engines. Such timing drives may include traction drives such as chain and belt drives for both gasoline and diesel engines. Special camshaft adjusters, in which the stator unit is made in one piece of stator and lid, are known per se.

Known prior art is, for example, from the DE 10 2010 008 003 A1 in which a cellular wheel of a device for the variable adjustment of the timing of gas exchange valves of an internal combustion engine having a cylindrical peripheral wall is disclosed. The device further comprises a drive wheel, which is arranged on an outer circumferential surface of the peripheral wall, a sealing cover, which extends radially inwardly from an inner circumferential surface of the peripheral wall and a plurality of projections, starting from the inner circumferential surface of the peripheral wall radially inwardly and extend from the sealing cover in the axial direction.

The US 6,457,447 B1 further discloses a sealing plate in a phaser, but which abuts both the top of the rotor and one side of the stator while being in sealing contact with a gear.

In the current state of the art, the inner bottom surface of the stator pot is usually post-machined to meet the high flatness requirements of the thrust bearing. The better the flatness at this point, the lower the axial bearing play and thus the leakage can be kept.

However, the processing of this surface is complicated, especially at the transition between the top surface and the wall of the stator problematic. Namely, here creates a chamfer or a radius, due to the special tool geometry. This bevel or the radius must be held on the rotor and on the sealing strips, so that the rotor and the stator have sufficient clearance and the adjustment process can be performed. This inevitably creates a circumferential leakage point on the camshaft adjuster, but this should be avoided. Ultimately, a stator assembly is to be provided which avoids the known disadvantages.

It is therefore an object of the present invention to remedy the known disadvantages and to provide a cost-manufacturable stator assembly available, which in turn can find application in a hydraulic camshaft adjuster, at the same time a leakage is to be effectively avoided.

Elaborate, fun post-processing steps of the Statorbodenfläche should be avoided.

Disclosure of the invention

This object is achieved in a generic stator assembly characterized in that a separate spacer from the stator and the rotor is present in the cavity, such as between the stator and the rotor, and is preferably arranged in sealing engagement with the flange portion.

The additional use of a spacer, which is joined in the Statortopf, a complex processing of Statorbodenfläche can be avoided. The spacer allows the provision of a minimum axial clearance.

Advantageous embodiments are claimed in the subclaims and are explained in more detail below.

So it is advantageous if the spacer has at least one extending from its outer side to the interior of the spacer recess, which extends approximately in the direction of the center of the spacer, wherein the recess dimensioned for coming into positive connection with the stator and / or provided , wherein the stator for this purpose has at least one inwardly projecting nose. In this way, using a positive connection, a relative rotation of the spacer, which can also be formed as a sealing disc can be prevented with the stator. A stator assembly, which provides the conditions for a precision use, can be created thereby. While the preferred connection of the spacer on the stator via a positive connection, non-positive and / or material-locking connections have other advantages.

If a plurality of approximately rectangular recesses are uniformly distributed over the circumference, preferably 2, 3, 4, 5, 6, 7 or 8 recesses are present, the security against rotation is ensured to a particular extent.

In order to improve an elasticity of the spacer in the radial direction and / or axial direction, it is advantageous if a central passage opening and between the central passage opening and the outer periphery of the spacer a plurality of axially extending recesses are provided in the spacer.

It is advantageous if the recesses are formed as pockets and / or through holes. In the case of through-holes, the weight of the spacer is also effectively reduced, whereas the pockets still have a targeted Ölleitwirkung when using oil as the hydraulic medium. Other fluids are conceivable as hydraulic means.

To be particularly advantageous, it has been found that the recesses are formed on the side facing the flange portion of the spacer and / or the pockets on the side facing away from the flange portion of the spacer are present.

If at least one nip extending in the axial direction, preferably a multiplicity of identically distributed nubs, is / are formed in the recess, then the axial elasticity of the spacer, which can also be designed as a sealing disk, can be improved. The spacer may be made of metallic material, such as a light metal alloy, but also a steel alloy or plastic. In addition to the use of plastic or metal for the spacer, rubber has also proven to be sufficiently resilient.

The sealing effect can be improved if a Hydraulikmittitelitloch, such as a hole is formed in the pocket.

It is also advantageous if each pocket is surrounded by a plan, raised edge of the distance / sealing disc, as this also the sealing effect is improved.

The invention also relates to a hydraulic camshaft adjuster of the vane type with a rotor and a stator assembly according to the invention.

It is also advantageous if the spacer on its outer side a chamfer or rounding (concavity), which is adapted to a present between the wall of the stator and the transition region between the wall and flange chamfer or rounding (convexity). In this way, a production-related circumferential chamfer or a corresponding radius can be accepted on Statortopf, without requiring a machining post. The Statortopf is the integral combination / one-piece design of Statorwandung and flange (s) of the stator.

The elastic design of the spacer in the radial direction for adaptation to the stator contour is also advantageous to ensure a circumferentially existing, high sealing function.

It is also effective if the spacer underside is configured with an elastic profiling, which adapts to the surface and flatness errors of the stator bottom surface when an axial force is exerted.

Further, it is possible to realize oil passages in the spacer for supplying the pressure chambers and the locking unit.

The design of the spacer with recesses on the spacer underside, in order to realize a contact pressure on the oil pressure and thereby a minimum axial play during operation, is also expedient.

In other words, in order to avoid a complicated machining finishing of the stator bottom surface, a spacer is inserted into the stator cup. By the separate machining of the spacer or a plurality of spacers, for example. By machining only the spacer (s), such as by grinding, a high accuracy of the flatness and the parallelism of the surface can be achieved.

If this spacer, which can also be referred to as a sealing disc, joined in the Statortopf, the flatness errors of the unprocessed Statorbodens be compensated. The production-related bevel on the stator-cover transition is collected by a corresponding chamfer on the nearest spacer. In addition, a sharp edge design between the rotor and the stator can be realized, resulting in a lower internal leakage result.

The spacer can be made elastic at its outer diameter by removing material. As a result, the spacer adjusts to the vane diameter on the stator and seals here optimally. Likewise, the circumferential leakage point can be sealed at a radial bearing become. Due to the elastic adaptation of the disc to the stator diameter, coarser manufacturing tolerances of the two individual parts can be permitted, which minimizes the cost pressure.

In order to compensate for large surface or flatness errors on the stator bottom, an elastic, finely structured / profiled underside of the pane can be designed. During assembly, the disc is pressed onto the bottom surface via a punch. The profiling is deformed and optimally adapts to the floor surface. Due to the elastic springback of the soil structure, a minimal axial play can be implemented. This has a positive effect on the leakage.

An additional possibility to limit the thrust bearing play is to provide the disc on the back with recesses which fill with oil during operation and thus press the disc against the rotor.

In addition, oil passages for supplying the pressure chamber or the locking unit can be realized via the disc.

The invention will be explained in more detail below with the aid of a drawing. In this case, different embodiments are shown.

Show it:

1 a longitudinal section through a camshaft adjuster according to the invention according to a first embodiment,

2 an insulated spacer, in a first, simple embodiment,

3 a section through the spacer 2 along the line III,

4 a perspective view of the spacer of 2 and 3 .

5 a plan view of a second embodiment of a spacer with recesses in order to realize elastic adjustments to the stator surfaces, which is particularly suitable for use in wide rotor blades,

6 a view of the spacer 5 according to a section along the line VI 5 .

7 a perspective view of the spacer of 5 and 6 .

8th a third embodiment of a spacer according to the invention with a profiling on the underside, in order to realize an elastic adaptation to the stator bottom surface,

9 a section through the spacer 8th along the line IX,

10 a view from the Flanschabschnittseite on the spacer 8th and 9 .

11 a fourth embodiment of a spacer according to the invention with recesses on the underside of the disc and at least one oil delivery hole per trained on the disc top pocket to press the spacer axially using the oil pressure against the rotor, which is also conducive to minimizing the axial play, and

12 a section through the spacer of the embodiment 11 along the line XII in 11 ,

The figures are merely schematic in nature and are only for the understanding of the invention. The same elements are provided with the same reference numerals.

In 1 is a stator assembly 1 in a first embodiment for a hydraulic phaser 2 of the wing cell type. In this case, the stator assembly includes 1 a stator 3 that is a gearing 4 on its outside 5 having.

About the gearing 4 is by means of a traction mechanism, not shown, such as a chain or belt drive, from a crankshaft torque to the stator 3 transfer. The gearing 4 is an integral part of the wall 6 of the stator 3 which has the shape of a Statortopfes.

The stator 3 has an axially extending cavity 7 on, being from the wall 6 of the stator 3 flange 8th radially inward into the cavity 7 stick out to a stop for a rotor 9 and an intermediate spacer 10 train. The spacer 10 can also be referred to as a sealing washer. The flange sections 8th thus form the bottom of the Statortopfes and have a central passage.

Under in investment condition of the rotor 9 with the flange sections 8th of the stator 3 also the Zwischengeschaltensein another object is understood.

The spacer 10 is axial between the rotor 9 and the stator 3 located. The spacer 10 points to her the flange sections 8th facing side in the peripheral region a chamfer 11 put on a chamfer 12 of the stator 3 is adjusted. The two bevels 11 and 12 can also be equipped as curves.

The spacer 10 is preferably made of plastic and inserted into the stator to minimize axial play.

In the 2 to 4 is a first embodiment of a spacer according to the invention 10 represented in a first particularly simple embodiment. There are four recesses 13 on the outer circumference towards a center 14 the sealing washer / spacer 10 protruding trained.

In the 5 to 7 is a second embodiment of a spacer according to the invention 10 shown, with different sized wells 15 in the material of the spacer 10 are formed. The wells 15 are everywhere here as through holes 16 formed, not all depressions 15 as through holes 16 should be formed, but also as an undermined depressions 15 can remain designed.

In the 8th to 10 a further embodiment of a spacer is formed, wherein on the upper side a flat surface is configured and on the underside one up to an edge 17 completely extending recess 15 is formed, further inside the recess 15 in the direction of the flange sections 8th axially protruding / protruding and in a common plane equally distributed pimples 18 available.

In a further modification is another embodiment in the 11 and 12 reproduced, where there on the flange sections 8th facing away from the top of the spacer 10 the wells 15 the shape of bags 19 exhibit. However, there is a fluid supply passage, such as a hydraulic fluid passage 20 intended. This hydraulic fluid idler hole 20 provides a hydraulic fluid passage from the top of the spacer 10 to the bottom of the spacer 10 sure to press the spacer 10 on the rotor 9 to improve.

The spacer 10 , seals as a sealing disk to externally, ie that caused by leakage hydraulic fluid loss from the interior of the stator assembly 1 is prevented.

LIST OF REFERENCE NUMBERS

1

stator

2

Phaser

3

stator

4

gearing

5

outside

6

wall

7

cavity

8th

flange

9

rotor

10

spacer

11

Chamfer of the spacer

12

Chamfer of the stator

13

recess

14

center

15

deepening

15

Through Hole

17

edge

18

burl

19

bag

20

Fluid supply passage / Hydraulikmittelleitloch

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010008003 A1 [0003]
• US 6457447 B1 [0004]

Claims (10)

Stator assembly ( 1 ) for a camshaft adjuster ( 2 ), with a stator ( 3 ) to receive torque provided by a crankshaft, wherein the stator ( 3 ) a wall ( 6 ) with a cavity extending in the axial direction ( 7 ) for receiving a rotor ( 9 ), wherein at least one radially inwardly protruding integrally formed flange portion ( 8th ) of the stator ( 3 ) forms an axial stop for the rotor, characterized in that one of the stator ( 3 ) and from the rotor ( 9 ) separate spacer ( 10 ) in the cavity ( 7 ) between the stator ( 3 ) and the rotor ( 9 ) is available. Stator assembly ( 1 ) according to claim 1, characterized in that the spacer ( 10 ) at least one from its outside to the inside of the spacer ( 10 ) extending recess ( 13 ) which come into positive engagement with the stator ( 3 ) is dimensioned. Stator assembly ( 1 ) according to claim 2, characterized in that a plurality of approximately rectangular recesses ( 13 ) are evenly distributed over the circumference. Stator assembly ( 1 ) according to one of claims 1 to 3, characterized in that in the spacer ( 10 ) a central passage opening and between the central passage opening and the outer periphery of the spacer ( 10 ) a plurality of axially extending depressions ( 15 ) available. Stator assembly ( 1 ) according to claim 4, characterized in that the depressions ( 15 ) as bags ( 19 ) and / or as through holes ( 16 ) are formed. Stator assembly ( 1 ) according to one of claims 4 or 5, characterized in that the depressions ( 15 ) on the flange portion ( 8th ) facing side of the spacer ( 10 ) and / or bags ( 19 ) on the flange portion ( 8th ) facing away from the spacer ( 10 ) available. Stator assembly ( 1 ) according to one of claims 4 to 6, characterized in that at least one axially extending nubs ( 18 ) in the depression ( 15 ) is trained. Stator assembly ( 1 ) according to one of claims 5 to 7, characterized in that a hydraulic fluid idler hole ( 20 ) in the bag ( 19 ) is trained. Stator assembly ( 1 ) according to one of claims 5 to 8, characterized in that each pocket ( 19 ) of a plan formed, raised edge ( 17 ) of the spacer ( 10 ) is surrounded. Hydraulic camshaft adjuster ( 2 ) of the wing cell type, with a rotor ( 9 ) and a stator assembly ( 1 ) according to any one of the preceding claims.

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