WO2013139525A1 - Device for phase shifting the rotational angle of a drive wheel with respect to an output shaft - Google Patents

Abstract

Various devices are known for phase shifting the rotational angle of a drive wheel with respect to an output shaft, in particular for adjusting the phase between a crankshaft and a camshaft, which adjustment takes place via a usually electrically operated actuator which interacts with a gear mechanism which is connected in between. The gear mechanism (12) has a drive gearwheel (16) which is connected to the drive wheel (10) and an output gearwheel (24) which is connected to the output shaft (14), and at least one double gearwheel (20), the first gearwheel (18) of which meshes with the drive gearwheel (16) and the second gearwheel (22) of which meshes with the output gearwheel (24). The double gearwheel or gearwheels (20) is/are fastened rotatably on a pivot-pin support (26), the pivot pins of which extend radially and which pivot-pin support (26) can be rotated via an actuator. In order to produce zero backlash and wear compensation in the gear mechanism, it is proposed according to the invention that the drive gearwheel (16) is prestressed axially in the direction of the double gearwheel (20).

Description

 5 Device for phase shifting the angle of rotation of a drive wheel to an output shaft

The invention relates to a device for phase shifting the angle of rotation of a drive wheel to an output shaft with a

10 gear with a drive gear connected to the drive gear and an output gear connected to the output gear and at least one double gear whose first gear meshes with the drive gear and the second gear meshes with the output gear, and which on a rotary axis support

15 is rotatably mounted, the axes of rotation extend radially and an actuator, via which the rotary axis carrier is rotatable.

Such devices are known in particular for phase shifting between a crankshaft and a camshaft of a combustion engine. The phase shift is used for variable valve timing to improve the combustion process in the engine. For example, vane-type cam phaser, camshaft chain adjuster or axially displaceable toothing elements are known for phase shifting the camshaft. The use of electrical phase adjusters, which work with a planetary gearbox, has proven to be particularly advantageous. These offer the possibility of a stepless adjustment, so that a high variability is achieved. o Thus, DE 10 2008 060 219 AI discloses a device for phase shifting between a camshaft and a crankshaft with a planetary gear. Here, the rotation of the Crankshaft via a chain or a belt on a drive wheel, which is fixedly connected to a drive gear, transmitted, which is coupled via the planetary gear with the camshaft, which in turn is fixedly connected to an output gear. drive gear

5 and driven gear are formed as crown gears, which are arranged on axially opposite sides of the planet gears formed as double gears, whose axes of rotation extend radially from a planet carrier, which is rotatably mounted on a bushing which surrounds the camshaft. A phase adjustment is carried out by o rotation of the planet gears by axial displacement of a force acting on the planet gears rack.

However, such a cam shaft phaser has the problem that the arrangement of the sprockets to each other is difficult, so that either no sufficient meshing engagement or unwanted inhibition occurs.

Furthermore, from US 5,680,836 a planetary gear for phase adjustment is known in which the axes of the planet gears are parallel to the axis of the camshaft and the ring gear and the sun gear. For correct adjustment of the backlash either the teeth are formed with growing flank widths or conical gears used, in each case via coil springs, the Pianetenräder in the direction of the growing flanks width of the sun gear or the ring gear are charged.

However, such a design is very complicated, since a large number of springs must be used and the production of the gears is much more expensive than cylindrical gears with constant tooth flank widths. 2013/052561

 3

It is therefore the object to provide a device for phase shifting the angle of rotation between a drive wheel and an output shaft, in which a backlash between the tooth flanks can be adjusted without jamming or wedging of the tooth flanks to 5 is to be feared. However, the simplest possible structure and small space of the phaser with high durability should be ensured.

This object is achieved by a device for phase shifting of the l o rotation angle between a drive wheel and an output shaft having the features of the main claim.

Characterized in that the drive gear is biased axially in the direction of the double gear, a backlash between the drive gear and the first gear of the double gear is ensured in a simple manner by loading a einzel5 component of the transmission. It is on the size of the bias voltage, the force of the tooth flanks adjustable. Preferably, the driven gear is biased in the direction of the double gear, so that a backlash between the second gear and the driven gear via only a single loaded component is achieved. Again, the desired force between the tooth flanks can be adjusted via the biasing force.

5

In an advantageous embodiment of the invention, the drive gear and the output gear are axially on the same side of the double gear and the drive gear is disposed radially outside of the driven gear. This design allows for suitable dimensioning of the gears an adjustment with translations in a wide range by 1: 100, so that an extremely fine adjustment is created. PT / EP2013 / 052561

 4

Preferably, a cover is arranged on the drive gear and driven gear axially opposite side of the double gear, which is connected to the drive gear, so that the 5 gearbox is largely closed to the outside, whereby the ingress of contaminants can be prevented.

It is advantageous if the rotary axis carrier is at least rotationally fixedly arranged on an adjusting shaft which can be actuated via the actuator. So o can be connected directly to the actuator and dispense with upstream transmission gear. This also allows a very accurate bearing feedback.

It is particularly preferable to arrange a first spring between the cover and the rotary axis support, by means of which the drive gear wheel is biased against the double gear wheel. Thus, in a simple manner by means of only one spring, which bears against the axially fixed axis of rotation axis, the bias voltage can be produced. Assembly and setup remain very easy.

In a preferred embodiment of the invention, a radially inwardly facing annular projection is formed on the drive gear against the axially abuts a second spring on the axially opposite side of a rear of the output gear rests and by means of which the output gear is biased against the double gear. So again with just one additional component, the desired bias can be generated. Again, there is a simple installation.

To ensure that the biasing force of the second spring does not push the drive gear away from the first gear of the double gear, the biasing force of the first spring is greater than that EP2013 / 052561

 5

Preload force of the second spring. This ensures that, although the second spring is supported on the drive gear, this is still biased to the double gear. In a preferred embodiment, the first and / or the second spring are designed as a corrugated spring, whereby over the entire circumference a uniform pressing force is generated.

Preferably, a needle bearing is disposed between the axis of rotation and the first spring spring, whereby a wear of the spring in the phase shift is thus excluded in a relative movement between the axis of rotation support and the cover.

In the same way, a wear of the second spring is advantageously prevented in relative movement between the drive gear and the driven gear by a sliding ring is disposed between the driven gear and the second spring.

For positionally accurate and secure arrangement of an annular groove is formed on the cover, in which the first spring is arranged. This also simplifies assembly, since the spring can be placed with the cover.

Preferably, an annular groove is also formed on the annular projection of the drive gear, in which the second spring is arranged, whereby this is easy to assemble and to position accurately.

In a preferred embodiment, the driven gear has an axially extending annular shoulder against which abuts a radial seal, rests on the radially opposite side of the annular projection of the drive gear. In this way, an ingress of contaminants into the interior of the transmission and 3 052561

 6 ensured in particular in the area between the drive and the driven gear.

A complete seal against the ingress of contaminants but also of liquids such as oil and the like is ensured in a simple manner by a radial shaft seal is arranged radially between the cover and the adjusting.

There is thus provided a device for phase shifting the angle of rotation of a drive wheel to an output shaft, which is simple in construction and to assemble, while ensuring a backlash between the gear stages, without the complexity of the device increases significantly. A long life is ensured by a good seal and good sliding properties between the relatively moving parts.

An embodiment of a device according to the invention is shown in the figure and will be described below.

The figure shows a sectional view of a device according to the invention for the phase shift of the rotational angle of a drive wheel to an output shaft in a perspective view.

The inventive device for phase adjustment consists of a driven by a chain or a toothed belt drive wheel 10, the movement of which is transmitted via a gear 12 to the output shaft 14 serving as the camshaft.

The transmission 12 has a drive gear 16 which is fixedly connected to the drive gear 10 radially surrounding the drive gear 16. This drive gear 16 is designed as a crown wheel, so that teeth of the drive gear 16 are formed on the axial side of the drive gear 16.

The drive gear 16 meshes with three first gears 18 of three double gears 20, the radially inner second gears 22 mesh with an output gear 24, which in turn is designed as a crown, so that its teeth are axially to the three second gears 22. Accordingly, this output gear 24 is located radially inside the drive gear 16 and axially on the same side.

The double gears 20 are arranged uniformly at a distance of 120 ° over the circumference of a rotary axle carrier 26, on which the radially extending axes of rotation are formed, on which the double gears 20 are rotatably mounted. A movement of the rotary axle carrier 26 to the output gear 24 is made possible by a ball bearing 27, the inner ring is disposed on one of two opposite stages of a otherwise hollow cylindrical axis of rotation 26 and the outer ring abuts against a radially delimiting wall 29 of an annular recess of the output gear 26. The Drehachsenträger 26 is mounted on an adjusting shaft 28 which is connected to an actuator, not shown, which consists for example of an electric motor.

The adjusting shaft 28 is arranged axially in extension of the camshaft 14, on which the output gear is screwed by a screw 30 prior to attachment of the adjusting Wefle 28.

Axially, the side of the transmission 12, from which the adjusting protrudes 28, largely closed by a cover 32, which in turn is secured to the drive gear 10 on the drive gear 16 and the output gear 24 axially opposite side of the Doppeizahnräder 20. To the transmission 12 against ingress of To protect liquids or solid impurities, a radial shaft seal 34 is disposed between the inner diameter of the cover 32 and the adjusting shaft 28, the radial outer side abuts against an annular projection 36 of the cover 32.

A corresponding seal by means of a further radial shaft sealing ring 38 is also provided on the axially opposite side between the fixedly arranged on the camshaft 14 driven gear 24 and the drive gear 16. This radial shaft sealing ring 38 is arranged radially between an axially extending annular shoulder 40 of the output gear 24 and a radially inwardly facing annular projection 42 of the drive gear 16, the hnrades 24 axially opposite a rear side 44 of the toothed part of the Abtriebsza.

In order to ensure a play-free engagement of the gears 16, 20, 24 into each other and simultaneously generate relative to each other at a low rotation friction, in an annular axially extending groove 46 in the region of the radially inner diameter of the cover 32 is formed as a wave spring first spring 48, which presses against a needle bearing 50, the axially opposite side rests against a shoulder 52 at the second stage of the rotary axis carrier 26. The radially inner region of the cover 32 bears against the radial shaft sealing ring 34 on the opposite side. The corrugated spring 48 pushes the cover 32 away from the rotary axis support 26. Since the cover 32 is connected via the drive wheel 16 fixed to the drive gear 16, this is biased in the direction of the double gears 20, so that a clearance in the meshing area deleted. In addition, an annular axially extending groove 54 is formed on the radially inwardly facing annular projection 42 of the drive gear 16 on the side facing the axis of rotation of the gear 26, in the also designed as a wave spring second spring 56 is arranged, which abuts against a sliding ring 58 which abuts against the back 44 of the output gear 24, so that a bias voltage of the output gear 24 in the direction of the double gears 20 is generated. 5 This spring 56 has a lower biasing force than the first spring 48, otherwise the bias of the first spring 48 would be lifted to the double gears 20. The slip ring 58 and the needle bearing 50 provide a low-friction adjustment. o The present transmission 12 has a self-locking, which means that in normal operation, the adjusting shaft 28 is largely entrained when driving the drive wheel 10. Accordingly, a transmission of the rotational movement from the drive wheel 10 via the drive gear 16 to the double gears 20 and the output gear 24 is formed on the attached camshaft 14, wherein all parts rotate together.

For phase shift between the drive wheel 10 and the output shaft 14, the adjusting shaft 28 is either held or rotated at a different speed or direction than the drive wheel 10. As a result, the rotational axis carrier 26 and with this via the double gears 20, the output gear 24 is rotated relative to the drive wheel 10 , In this transmission design, ratios in the range of 1: 100 can be realized, so that a full rotation of the adjusting shaft 28 would result in a rotation of the camshaft 14 to the drive wheel 10 of only about 4 ° compared to the rotation of the drive wheel 10. Accordingly, a very accurate phase adjustment is possible.

Such a device for phase shifting the angle of rotation of a drive wheel 10 to an output shaft 14 accordingly has a backlash between the individual gear stages, without the number of components or the effort during assembly worth mentioning climb. It is achieved a play and wear compensation with adjustable escapement. The result is a low-noise, durable and sensitive device for phase adjustment with unlimited

Displacement.

It should be clear that various design modifications are possible in comparison to the described embodiments, without departing from the scope of the main claim. For example, different numbers of double gears can be used or the attachment of the springs can be done differently. Also, other elements for improving the sliding properties are usable,

Claims

P A T E N T A N S P R E C H E

, Device for phase shifting the angle of rotation of a drive wheel (10) to an output shaft (14) with

 a transmission (12) with

 a drive gear (16) connected to the drive wheel (10) and an output gear (24) connected to the output shaft (14) and

 at least one double gear (20) whose first gear (18) meshes with the drive gear (16) and whose second gear (22) meshes with the output gear (24) and which is rotatably mounted on a Drehachsenträger (26) whose axes of rotation extend radially and an actuator over which the rotary axis carrier (26) is rotatable,

 characterized in that

 the drive gear (16) is biased axially in the direction of the double gear (20).

Device for phase shifting the angle of rotation of a drive wheel to an output shaft according to claim 1,

 characterized in that

 the driven gear (24) is biased toward the double gear (20).

Device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 1 or 2,

 characterized in that

the drive gear (16) and the output gear (24) are arranged axially on the same side of the double gear (20) and the Drive gear (16) is arranged radially outside of the output gear (24).

4. A device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of the preceding claims,

 characterized in that

 on the drive gear (16) and driven gear (24) axially opposite side of the double gear (20) a cover (32) is arranged, which is connected to the drive gear (16).

5. Device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of the preceding claims,

 characterized in that

 the axis of rotation of the support (26) at least rotatably on an adjusting shaft (28) is arranged, which is actuated via the actuator.

6. Apparatus for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 4 or

5,

 characterized in that

 between the cover (32) and the rotary axis support (26) a first spring (48) is arranged, by means of which the drive gear (16) is biased against the double gear (20).

7. An apparatus for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 2 to

6

characterized in that on the drive gear (16) has a radially inwardly facing annular projection (42) is axially against a second spring (56) abuts, against the axially opposite side of a rear side (44) of the driven gear (24) and by means of which the output gear (24) is biased against the double gear (20).

8. A device for phase shifting the angle of rotation of a drive wheel to an output shaft according to claim 7,

 characterized in that

 the biasing force of the first spring (48) is greater than the biasing force of the second spring (56).

9. A device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 6 to

8th,

 characterized in that

 the first and / or the second spring (48, 56) are designed as corrugated springs.

10. A device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 6 to

9

 characterized in that

 between the rotary axis support (26) and the first spring (48) a needle bearing (50) is arranged.

11. A device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 7 to 10,

 characterized in that

between the driven gear (24) and the second spring (56) a sliding ring (58) is arranged.

12. An apparatus for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 6 to 11,

 characterized in that

 on the cover (32) an annular ut (46) is formed, in which the first spring (48) is arranged.

13. A device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 7 to 12,

 characterized in that

 on the annular projection (42) of the drive gear (16) an annular groove (54) is formed, in which the second spring (56) is arranged.

14. Device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 7 to

13

 characterized in that

 the output gear (24) has an axially extending annular shoulder (40) against which bears a radial shaft seal (38), on the radially opposite side of the annular projection (42) of the drive gear (16).

15. Device for phase shifting the angle of rotation of a drive wheel to an output shaft according to one of claims 5 to

14

 characterized in that

 a radial shaft sealing ring (34) is arranged radially between the cover (32) and the adjusting shaft (28).