DE102011004071A1 - 3-shaft variable speed gearbox with integrated overload clutch - Google Patents

Abstract

The invention relates to a 3-shaft adjusting gear, comprising a drive part that can be connected in a rotationally fixed manner to a drive shaft, an output part that can be connected in a rotationally fixed manner to an output shaft and an actuator that can be connected in a rotationally fixed manner to an adjustment shaft, with a first mechanical stop between two of the three shafts to limit an adjustment angle between Drive shaft and output shaft is provided. According to the invention, an overload clutch integrated into the actuator is provided between the actuator and the drive part or the driven part.

Description

The invention relates to a 3-shaft adjusting according to the preamble of claim 1 with a rotatably connected to a drive shaft driving part, a rotatably connected to an output shaft driven part and a rotatably connected to an adjusting actuator.

3-shaft adjusting are used for example in internal combustion engines for adjusting phase angles, primarily for adjusting the opening and closing times of the gas exchange valves used (camshaft adjuster, phaser for actuator shafts in variable valve trains). The phase adjuster is arranged as an actuator in a 3-shaft system. Primarily, the drive power is supplied to the 3-shaft system via the drive shaft (sprocket), which is output again via the output shaft (eg camshaft). The actuator is arranged as a link between the drive shaft and the shaft to be driven in the power flow. It allows a third shaft (adjusting shaft) superimposed on the drive power additionally coupled mechanical power into the shaft system or remove it. As a result, the predetermined by the drive shaft movement function (phase angle) can be changed to the output shaft.

Examples of such 3-shaft adjusting gear are swash plate gear and Innenexzentergetriebe which, for example, in the WO 2006/018080 are described. This includes the from the WO 2005/080757 known wave gear and in the US 2007/0051332 A1 and US 2003/0226534 A1 contained gear.

Various phasers are known in the art. For example, in DE 10 2004 009 128 A1 . DE 10 2005 059884 A1 and DE 10 2004 038 681 A1 electromechanical camshaft adjuster described.

From the DE 102 48 351 A1 an electromechanical camshaft adjuster is known in which the adjusting motor is connected by means of a releasable coupling with the adjusting gear. By an appropriate design of the coupling transmittable to the adjusting torque can be limited. This then acts as a safety clutch.

A special case of a 3-shaft variable speed is a 2-shaft arrangement in adjusting drives, in which the drive shaft is fixed to the housing, d. H. only power is transferred between the adjusting shaft and the output shaft. Such a device serves to convert a high-speed and low-load drive power of an actuator into a low-speed, high-load output, and finds application in, for example, automotive type reduction drives as well as in industrial applications, e.g. B. robotics.

In order to protect the periphery in the event of control errors of the actuators from undesired collisions of components, the adjustment range or the drive range is limited by limiting the angle of rotation of one of the three shafts relative to a second shaft or relative to the housing. For this purpose, a mechanical stop is used as an integral part of the device. In the known state of the art of the camshaft adjuster, the stop between the output shaft and the drive shaft is provided because the adjusting shaft usually covers an angle of more than 360 °.

In such an embodiment, the adjustment shaft, which is not limited directly in the adjustment angle or drive angle, is then braked in the case of the stop via the transmission kinematics and the rigidity of the transmission elements as soon as the output side reaches the limit of the rotation angle. As a result of the extremely high loads gear parts can deform so much that they collide with each other and bring the actuator to jamming. Furthermore, gear parts can tire early or must be oversized for normal operation to endure even the high loads in the case of unbraked stop.

The object of Einfindung is to form a 3-shaft adjustment such that the pulse loads occurring when reaching a stop in the actuator are so attenuated in their effect that a deadlock or damage to the transmission is prevented.

The solution of the problem is achieved with a 3-shaft adjusting with the features of claim 1, through which a decoupling of the gear parts is achieved in the case of a stop.

A 3-shaft adjusting initially comprises in a known manner with a drive shaft rotatably connectable drive part, a rotatably connected to an output shaft driven part and a rotatably connected to an adjusting shaft of an actuator actuator. Between two of the three shafts, usually between the drive part and the output part, a first mechanical stop for limiting an adjustment angle between the drive shaft and the output shaft is provided.

According to the invention, an overload clutch integrated in the actuator is provided between the actuator and the drive part or between the actuator and the output part.

In the following description is assumed by an electromechanical camshaft adjuster with a wave gear as a particularly preferred embodiment in flat construction. Of course, the solutions are transferable to wave gear in pot design as on other types of transmissions. The invention is also applicable to other types of transmissions in which the actuator has a spur gear.

The advantages of the invention are to be seen in particular in that a complete decoupling without an additional transmission component is possible. Due to the high speeds of the adjusting shaft occur at this only small loads, so that an "oversensing", so a snapping the adjusting shaft, as an inexpensive and space-saving solution for a slip clutch appears.

In a particularly preferred embodiment, the overload clutch is formed by the fact that the actuator has a spur gear in the radial direction with an elasticity.

The elasticity may be formed for example by an elastic layer or by elastic rolling elements, wherein as elastic rolling elements z. B. hollow balls or sleeves or rolling elements of a material with a lower modulus of elasticity can be used.

The concept according to the invention is based on a torsionally soft toothing of the actuator. Due to the inertia of the adjusting and the electric motor creates a so-called collision torque in the attack case, which causes in addition to the tangential force a radial tooth force in the teeth in analogy to the normal engagement angle.

The radial stiffness of the actuator normally counteracts this force. According to the invention, the radial elasticity is to be dimensioned such that, starting from a certain amount of the radial force component of the transmitted torque (for example, the collision moment), the teeth of two corresponding toothed wheels radially dodge one another. The teeth then move tangentially together under high radial tension on the tooth heads until they are pushed back into the tooth space and snap over the adjusting shaft.

Preferred embodiments of the invention are explained below with reference to the figures.

Show it:

1 : a schematic diagram of oversensing as a principle of overload clutch;

2 a overload clutch according to the invention on a wave generator as an actuator of a 3-shaft variable speed drive in a first embodiment;

3 a overload clutch according to the invention on a wave generator as an actuator of a 3-shaft variable speed drive in a second embodiment;

1 shows the contact conditions in a gearbox at the time of over-snapping (oversensing). Shown are a ring gear 01 with an internal toothing 02 and a spur gear 03 with an external toothing 04 , The spur gear 03 here forms an actuator of a 3-shaft variable speed, not shown, while the ring gear 01 which may be part of a drive part or driven part.

The direction of rotation of the spur gear 03 is by an arrow 05 shown. It can be seen that the tooth tips of the spur gear 03 yield in the radial direction and on the tooth tips of the internal toothing 02 glide along, before the teeth dive back into each other by the elasticity.

By a deliberate lowering of the radial stiffness of the spur gear 03 becomes an over snapping (oversensing) in the gearing 02 . 04 is approved for overload and reduces the occurring stresses on the gear elements. The rigidity, and thus the radial strain in case of overload, is chosen so that the oversensing of the affected transmission components can be tolerated at least time within the required life of the actuator. In addition, no damage may occur in the toothing or in the bearings, which could impair the function. The time-stable design is permissible since the operating state shown will only occur under boundary conditions. On the other hand, the rigidity must be high enough to transmit the operating moments.

The snapping inside the toothing 02 . 04 can be considered as complete cyclic decoupling. The decoupling is cyclical, since the tooth heads jump back into a tooth gap as soon as they have slipped past each other, and the transmission is then no longer decoupled.

2 shows an overload clutch according to the invention to a wave generator as an actuator of a 3-shaft variable speed drive in a first embodiment. Shown is a detail of the wave generator with an elliptical inner ring 06 one elliptical outer ring 07 and arranged therebetween rolling elements 08 , The outer ring 07 carries in a known manner a spur gear teeth 09 , which in a ring gear, not shown (see 1 ) rolls.

Between the outer ring 07 and the gearing 09 is an elastic layer 11 arranged that the radial compliance of the spur gear 09 guaranteed. The elastic layer 11 may be a separately made ring or a coating of an elastomer. The necessary thickness and elasticity of the elastic layer 11 the expert can determine based on the given material and transmission data.

In 3 an overload clutch according to the invention is shown on a wave generator as an actuator of a 3-shaft variable speed drive in a second embodiment. Unlike the in 2 the embodiment shown is the elastic layer by a corrugated metal sleeve 12 formed, are imprinted in the corrugations. Such sheet metal sleeves are also known as tolerance rings for clearance compensation during bearing mounting.

It has proven to be advantageous in terms of noise that the elastic layer is dimensioned so that during normal operation of the gear members, the teeth are slightly braced radially against each other.

LIST OF REFERENCE NUMBERS

01

ring gear

02

internal gearing

03

spur gear

04

external teeth

05

06

inner ring

07

outer ring

08

rolling elements

09

external teeth

10

11

elastic layer

12

corrugated sheet metal sleeve

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

• WO 2006/018080 [0003]
• WO 2005/080757 [0003]
• US 2007/0051332 A1 [0003]
• US 2003/0226534 A1 [0003]
• DE 102004009128 A1 [0004]
• DE 102005059884 A1 [0004]
• DE 102004038681 A1 [0004]
• DE 10248351 A1 [0005]

Claims (10)

3-shaft adjusting, comprising a rotatably connected to a drive shaft drive member, a rotatably connected to an output shaft output member and a rotatably connectable with an adjusting actuator, wherein between two of the three waves provided a first mechanical stop for limiting a Verstellwinkels between the drive shaft and output shaft is, characterized in that between the actuator and the drive part or the driven part is provided in the actuator integrated overload clutch. 3-shaft adjusting mechanism according to claim 1, characterized in that the actuator has a spoked in the radial direction with an elastic spur gear as overload clutch. 3-shaft adjusting mechanism according to claim 2, characterized in that it is an adjusting gear with a wave generator as an actuator. 3-shaft adjusting mechanism according to claim 3, characterized in that the elasticity by an elastic layer ( 11 . 12 ) is provided between an outer ring and an outer toothing of the wave generator. 3-shaft adjusting mechanism according to claim 4, characterized in that the elastic layer is an elastomer ( 11 ) contains. 3-shaft adjusting mechanism according to claim 5, characterized in that the elastic layer ( 11 ) is a coating or a ring. 3-shaft adjusting mechanism according to claim 4, characterized in that the elastic layer by a sheet metal sleeve ( 12 ) is formed, are imprinted in the corrugations. 3-shaft adjusting mechanism according to claim 7, characterized in that the sheet metal sleeve ( 12 ) consists of spring steel. 3-shaft adjusting mechanism according to claim 3, characterized in that the elasticity is formed by elastic rolling elements of the wave generator. 3-shaft adjusting mechanism according to claim 3, characterized in that the elasticity is formed by an elastic inner ring of the wave generator.

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