DE102010053250A1 - Device i.e. dual-mass flywheel, for damping torsional vibration in drive train of motor vehicle, has energy storage device designed in single-side oscillating manner based on neutral position in which storage device has maximum potential - Google Patents

Abstract

The device has an input element (3) and an output element (4) that are rotatable relative to each other against the effect of an energy storage device (5). Another energy storage device has an inverse effect on partial areas of a rotating path between the input and output elements. The latter storage device is designed in a single-side oscillating manner based on a neutral position in which the latter storage device has maximum potential. The latter storage device has springs that are clamped radially between a retainer and a flange that is connected with the output element.

Description

The invention relates to a device for damping torsional vibrations, in particular for the drive train of a motor vehicle.

Device for damping torsional vibrations, also called torsional vibration dampers, are known in the prior art and serve to compensate for torque peaks which occur in the relative rotation of two flywheels against each other. In the drive train of a motor vehicle, one of the flywheel masses is non-rotatably connected to a drive shaft of an internal combustion engine, while the other flywheel is coupled to the transmission side.

In order to reduce a potential transmission of irregularities in an assignment of the first flywheel to the second flywheel, it is known to provide a second energy storage device which at least partially unfolds an inverse spring action between the two flywheel masses. Such a device is for example in the EP 1 953 411 A2 disclosed. The second energy storage device, that is the inverse spring, supports the insulation, since it gives off energy during the deflection. According to the known prior art, the inverse spring is composed of a plurality of springs which are set in the radial direction between two coaxial flywheel masses. In a relative rotational movement of the two masses to each other vibrates the inverse spring symmetrically about a zero point of the deflection.

Inverse springs generally suffer from the disadvantage of a finite oscillation angle, since for energy conservation reasons no unrestricted release of energy can occur from one spring. Thus, the inverse spring over a larger range of the main characteristic, so the spring characteristic of the energy storage device, can be effective, usually the second energy storage device is stored adjustable. According to the EP 1 953 411 A2 this adjustability is realized by a hydraulic system.

The previously known concepts for the realization of the adjustment have the disadvantage that the switching point is designed to be too soft at the respective end portions of the oscillation angle. This has the consequence that the effect of the inverse spring is reversed at the end regions mentioned to the contrary.

It is an object of the invention to provide a device for damping torsional vibrations, in which the above-described disadvantage can be avoided and switches at the end portions of the oscillation angle of the inverse spring clean.

This object is achieved by a device according to claim 1. Preferred embodiments are specified in the subclaims.

According to embodiments of the invention, the device for damping torsional vibrations, in particular in the drive train of a motor vehicle, an input element and an output element, which are rotatable relative to each other against the action of a first energy storage device, and a second energy storage device which at least over portions of a rotational path between the Input element and the output element has an inverse spring action, wherein the second energy storage device for a one-sided oscillation, starting from a neutral position in which the potential of the second energy storage device has a maximum, is designed.

Unlike in known energy storage devices which have an inverse or degressive spring action, therefore, the second energy storage device according to the invention does not oscillate on both sides about a zero point, but starting from a neutral position, only to one side, preferably against a tensile load between the input element and the output element. In other words, in the embodiments of the invention, the second energy storage device releases its energy when the input element and the output element are in the tensile region, so that energy is supplied to the first energy storage device.

The device is for example part of a dual-mass flywheel (ZMS) which is constructed from a first flywheel and a second flywheel, wherein the two flywheels are coupled via the device for damping torsional vibrations. In operation, the input member is connected to or constitutes part of the first or primary flywheel while the output member is connected to or integral with the second or secondary flywheel.

According to one embodiment of the invention, the second energy storage device is constructed of a number of springs which are radially tensioned between a receptacle coupled to the input member and a flange concentric with the receptacle and rotatably connected to the output member. The radial springs are at a relative rotation of the Recording and the flange loaded to each other, and that according to the invention in one direction, releasing their stored energy. In this embodiment, the spring force and thus the capacity of the second energy storage device can be easily adjusted by adding or removing one or more springs. In addition, the device is easy to maintain because the springs are individually interchangeable.

For example, the springs may be arranged in groups, with circumferential distances between each group of springs being the same. The number of springs of each group is limited only by the available space. Without limitation, for example, there may be 2 to 4 groups of about 2 to 10 springs each. The grouping makes it possible to use additional elements, which will be discussed in more detail later, for a specific number of springs.

One way of achieving the aforementioned coupling between the receptacle and the input element is that the receptacle rests against a cover which is rotatably connected to the input member. In this case, the mentioned restriction of the second energy storage device to a one-sided oscillation can be carried out in a particularly simple manner by providing means which decouple the receptacle from the cover during shear loading.

As already mentioned, an energy storage device with inverse spring action can only release energy over a certain angle of rotation. For this reason, it makes sense to limit the springs even after the vibration side (train side) back to ensure a clean circuit. For this purpose, according to an exemplary embodiment, a limiting element is provided, which defines a maximum deflection of the radial springs of the second energy storage device.

The limiting element may be formed, for example, as a tie rod, which can not be stretched beyond a predetermined length. This creates a sharp defined limit to the possible tensile load.

For example, when the springs are arranged in groups as described above, each group of radial springs may be associated with a tie rod located at one end of the group. In this embodiment, a particular uniformity of the restriction is ensured.

According to an advantageous embodiment of the invention, an engagement device is provided, which is designed to decouple the receptacle from the cover when idling. This makes it possible, in an adjustment of the springs in the context of an extension of the deflection region (displacement of the construction unit "inverse spring" along the main characteristic of the spring), these in an idle position in which they do not contribute to the vibration isolation, but possibly even harmful, to decouple. In other words, only the first energy storage device is in the idle position.

Said engagement means may for example consist of a finger element, which is placed together with the springs between the receptacle and the flange, and a cam which keeps it idling with the finger element and keeps the receptacle decoupled from the cover. In this way, the mentioned decoupling is realized in the idle with simple means.

Embodiments of the invention will be described with reference to FIGS 1 to 5c explained in more detail. Showing:

1a and 1b a device according to the invention for damping torsional vibrations at different positions in longitudinal section;

2 a plan view of the device of 1a and 1b on average;

3a a spring characteristic of a device for damping torsional vibrations of the prior art;

3b a detailed view of a section of the 3a ;

3c a spring characteristic of a device according to the invention for damping torsional vibrations;

4a and 4b Detailed views of an embodiment of the invention in various positions; and

5a to 5c Detailed views of another embodiment of the invention in different positions.

It should be noted that in all the figures, elements which correspond to each other are given the same reference numerals.

In the 1a and 1b is a device for damping torsional vibrations in shown two different longitudinal sections. The device is a dual mass flywheel with a first flywheel 1 which is fixed in operation, for example, to a crankshaft of an internal combustion engine of a motor vehicle, and a second flywheel 2 , which is assigned to a transmission side.

The first flywheel 1 is about an input element 3 which may be integral with it, connected to the device while the second flywheel 2 via an initial element 4 connected to the device. The second flywheel 2 For example, as shown, via a riveted joint 2a to the starting element 4 be coupled.

As you can see, this is the input element 3 in a radially outer area 3a arcuately curved, so that a chamber for receiving a first energy storage device 5 , which is realized here in the form of bow springs is formed. The bow springs are circumferentially compressible to prevent vibrations between the input member 3 and the output element 4 take.

In the 1b is a second energy storage device 6 shown, which serves the improved vibration isolation. The second energy storage device 6 includes radial springs 6a of which only one can be seen in the longitudinal section view shown. The radial springs 6a are in a radially outer area with a receptacle 7 coupled, which against a lid 8th is present, the rotationally fixed to the input element 3 connected is. In their radially inner region are the springs 6a connected with a flange, which only in the 1a is shown.

With reference now to the 2 is there a cross-sectional view of the embodiment of the 1a and 1b shown perpendicular to the plane of those figures. The outer boundary of here through the radially outer area 3a of the input element 3 educated. In the area through them 3a limited space is the first energy storage device 5 recorded in the form of bow springs. The flange 9 engages the bow springs to compress or relieve them. Between the flange 9 and the recording 7 are the springs in the radial direction 6a curious, here each two groups of six feathers 6a , The recording 7 engages with frictional engagement on the (in the 2 not shown) cover 8th at.

In the right part of the 2 are the radial springs 6a in its neutral position, that is to say in the position which contains a maximum energy storage. On the contrary, on the left side are the 2 the feathers 6a in their maximum deflection, hence in the position in which they have given all the energy. The feathers 6a have their maximum inclination in this position.

The 3a is a diagram showing the stored energy of a conventional inverse spring plotted against the angle of rotation α. Since an inverse spring can only release energy to a limited degree, it is necessary to adjust it each time the end points of its oscillation range are reached. In the 1a two oscillation areas are represented, which are represented by the short straight lines. An adjustment of the springs in practice means a displacement of the straight line along the main characteristic of the spring represented by the broken line.

In the 3b is a detail of the representation of 3a shown enlarged. The detail shows an end point of the oscillation range, once with hard circuit a and once with soft circuit b. In the second case results for certain oscillation angle, a higher increase in the characteristic, whereby the insulation effect of the energy storage device deteriorates.

In contrast, in the 3c the characteristic curve for an inverse spring, as used in the context of the embodiments according to the invention shown. As can be seen, the end points of the oscillation are shifted to the right, which means that the spring no longer oscillates on both sides about its zero point, but only on one side from a neutral position, as on the right side of the 2 is shown.

The 4a and 4b show in detail a further embodiment of the device according to the invention. It is a group of radial springs 6a shown between the recording 7 and the flange 9 are curious. At the left edge of the group of feathers 6a is a boundary element 10 fastened in the same way as the springs 6a , At the boundary element 10 in this case it is a tension rod, which is stored with play.

In the 4a are the springs 6a in its neutral position, the recording 7 on the lid 8th is present, or is in frictional engagement with this. In contrast, the springs 6a in the 4b in their maximum deflection, so that the tension rod reaches the stop. The relaxation of the springs 6a is limited in this way. In this position, the recording 7 from the lid 8th solved. This way the recording can be done 7 against the lid 8th be twisted, what a Adjustment of the inverse spring (displacement along the main characteristic) is equal.

Finally, the show 5a to 5c the effect of an engagement device, through which idle, the second energy storage device 6 can be turned off, so that only the first energy storage device 5 is effective. In the 5a is in turn the neutral position of the springs 6a shown. Get a spring 6a in this position, finger elements grip 11 , here are two finger elements 11 per group, with more finger elements 11 may be present in the recording 7 and pull them in another twist from the neutral position (in the thrust direction) inward, that is from the lid 8th path. This setting is in the 5b shown. It should be noted that the finger elements 11 in the oscillation range of the springs 6a not in the recording 7 intervention. For the intervention are attacks 7a at defined intervals at the intake 7 educated. Recoupling of the recording 7 and the lid 8th occurs when turning the input element 3 and the starting element 4 against each other automatically on the centrifugal force.

In the 5a to 5c is also a cam 12 shown, which acts as a switching element. Idle is the cam 12 with the finger element 11 coupled, as in the 5c is shown. At idle (as well as in thrust) are the input element 3 and the starting element 4 arranged at a certain angle of rotation to each other. In this angle of rotation sits so the finger element 11 firmly on the cam 12 , Only when the springs 6a again subjected to a tensile load, finger element decouple 11 and cams 12 so the recording 7 one again with the lid 8th can attack. In this way, the second energy storage device 6 completely decoupled during idling.

LIST OF REFERENCE NUMBERS

1

first flywheel

2

second flywheel

2a

rivet

3

input element

3a

radially outer area

4

output element

5

first energy storage device

6

second energy storage device

6a

radial springs

7

admission

7a

attack

8th

cover

9

flange

10

limiting element

11

finger member

12

cam

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

• EP 1953411 A2 [0003, 0004]

Claims (9)

Device for damping torsional vibrations, in particular in the drive train of a motor vehicle, comprising an input element ( 3 ) and an output element ( 4 ), which counteract the effect of a first energy storage device ( 5 ) are rotatable relative to each other, and a second energy storage device ( 6 ), which at least over portions of a rotational path between the input element ( 3 ) and the output element ( 4 ) has an inverse effect, characterized in that the second energy storage device ( 6 ) for a unilateral oscillation starting from a neutral position, in which the potential of the second energy storage device ( 6 ) has a maximum is designed. Apparatus according to claim 1, characterized in that the second energy storage device ( 6 ) of a number of springs ( 6a ), which radially between a receptacle ( 7 ) connected to the input element ( 3 ) and one with the recording ( 7 ) concentric flange ( 9 ), which with the output element ( 4 ) is rotatably connected, are curious. Device according to claim 2, characterized in that the springs ( 6a ) are arranged in groups, with circumferential distances between each group of springs ( 6a ) are the same. Device according to claim 2 or 3, characterized in that the receptacle ( 7 ) against a lid ( 8th ) which is connected to the input element ( 3 ) is rotatably connected, whereby the coupling between the recording ( 7 ) and the input element ( 3 ) is realized. Device according to one of claims 2 to 4, characterized in that a limiting element ( 10 ), which has a maximum deflection of the radial springs ( 6a ) of the second energy storage device ( 6 ) Are defined. Apparatus according to claim 5, characterized in that the limiting element ( 10 ) is designed as a pull rod. Apparatus according to claim 6 when dependent on claim 3, characterized in that each group of radial springs ( 6a ) is associated with a tie rod, which is arranged at one end of the respective group. Device according to one of claims 4 to 7, characterized in that an engagement device is provided, which is designed, at idle and under thrust load recording ( 7 ) from the lid ( 8th ) to decouple. Apparatus according to claim 8, characterized in that the engagement means of a finger element ( 11 ), which with the springs ( 6a ) between the recording ( 7 ) and the flange ( 9 ) and a cam ( 12 ), which gives it no load and when thrust load with the finger element ( 11 ) and the receptacle ( 7 ) from the lid ( 9 ) decoupled, is constructed.

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