DE102019101164A1 - Torsional vibration damper - Google Patents

Abstract

The invention relates to a torsional vibration damper (1) with an input part (2) and with an output part (3), which are arranged such that they can be rotated relative to one another, with a spring damper device (4) with spring elements (5, 6), the input part (2) being relative to the output part (3) is rotatably arranged against the restoring force of the spring elements (5, 6) of the spring damper device (4), the spring damper device (4) having a chamber (11) in which the spring damper elements are arranged, the chamber (11) is covered by a spring membrane (14), the input part (2) being limited relative to the output part (3) in a radial direction and / or in an axial direction in terms of its displaceability by at least one stop (15).

Description

The invention relates to a torsional vibration damper, in particular for the drive train of a motor vehicle.

Torsional vibration dampers are widely known in the prior art, for example as a dual-mass flywheel or as a clutch damper for the drive train of a motor vehicle. A torsional vibration damper usually has an input part and an output part, a spring damper device, for example, being provided in the torque flow between the input part and the output part, which transmits a torque between the input part and the output part. The spring damper device dampens, for example, the torsional vibrations that come from a drive motor on the input side, so that they are only passed in a damped manner to the unit downstream of the output part.

Such torsional vibration dampers can also have further torsional vibrations damping or compensating devices, such as a centrifugal pendulum device or the like.

In particular for the spring damper device, a chamber is formed by the input part, which is possibly also filled with a lubricant, which is sealed from the output part by a spring membrane. For this purpose, the membrane lies close to the input part and is sealed to the output part. When the input part is rotated relative to the output part, the membrane optionally also serves as a friction damping device. Such a membrane can in principle also be provided without sealing tasks in order to serve as a friction damping device. For this purpose, the membrane lies against its contact surface with axial prestress.

When assembling or transporting such a torsional vibration damper, it can happen that the torsional vibration damper is gripped at the output part and pulled off the input part, which deforms the membrane. When reassembled, however, the membrane remains deformed and therefore no longer generates the originally intended axial pressure or contact, so that the friction no longer assumes the desired level. This affects the entire torsional vibration damping, which can lead to the torsional vibration damper becoming unusable overall.

It is the object of the present invention to provide a torsional vibration damper which better protects the membrane in order to avoid damage to the membrane.

The object of the invention is achieved with the features of claim 1.

An embodiment of the invention relates to a torsional vibration damper with an input part and with an output part, which are arranged rotatably with respect to one another, with a spring damper device with spring elements, the input part being rotatable relative to the output part against the restoring force of the spring elements of the spring damper device, the spring damper device being a chamber has, in which the spring damper elements are arranged, the chamber being covered by a spring membrane, the entry part being limited relative to the exit part in a radial direction and / or in an axial direction in its displaceability by at least one stop. This limits the displaceability from the input part to the output part or vice versa in the radial direction and / or the axial direction, so that an inadmissible deformation of the spring membrane cannot occur.

It is also advantageous if the spring diaphragm is connected on the one hand to the output part and on the other hand abuts the input part or the spring diaphragm is connected on the one hand to the input part and on the other hand bears on the output part. As a result, the spring membrane can serve as a friction element. So it can also be advantageous if the spring membrane rests on the input part or the output part with the interposition of a friction body.

It is also advantageous if, on the one hand, the spring membrane is connected in a sealed manner to the output part and, on the other hand, is sealingly connected to the input part or the spring membrane is connected in a sealed manner to the input part and, on the other hand, is sealingly connected to the output part. As a result, it is additionally or mainly achieved that a sealing function is present in order to seal the chamber. This is advantageous if the chamber is filled with lubricant, for example.

It is also advantageous if an element connected to the output part is overlapped radially and / or axially by an element connected to the input part in order to serve as a stop for the radial and / or axial mobility of the output part relative to the input part. This effectively limits the mobility from the input part to the output part in the radial and / or axial direction in order to avoid damaging the spring membrane.

It is also advantageous if an element connected to the input part is overlapped radially and / or axially by an element connected to the output part in order to serve as a stop for the radial and / or axial mobility of the input part relative to the output part. This effectively limits the mobility from the input part to the output part in the radial and / or axial direction in order to avoid damaging the spring membrane.

It is also advantageous if the element connected to the input part and / or the element connected to the output part is a ring element and / or a disk which extends essentially in the radial direction. As a result, an existing component which is advantageously already used elsewhere is also used for the purpose of forming the stop, which helps to save an additional component.

It is also advantageous if the element connected to the input part and / or the element connected to the output part is a centrifugal pendulum device and / or a flange element of a centrifugal pendulum device and / or a pendulum mass of a centrifugal pendulum device. This also makes it possible to use an existing component which is advantageously already used elsewhere, also for the purpose of forming the stop, which helps to save an additional component.

It is particularly advantageous if the ring element or the disk is riveted, caulked or welded to the input part or to the output part, and thus in particular becomes part of the input part or the output part.

It is also advantageous if the ring element or the disk is connected radially inside or radially outside to the input part or to the output part.

In another exemplary embodiment, it is also expedient if the spring diaphragm itself serves as a stop. This means that additional components are not required.

The present invention is explained in more detail below on the basis of preferred exemplary embodiments in conjunction with the associated figures:

• 1 eine schematische Halbschnittdarstellung eines Ausführungsbeispiels eines erfindungsgemäßen Drehschwingungsdämpfers, und
• 2 eine schematische Halbschnittdarstellung eines alternativen Ausführungsbeispiels eines erfindungsgemäßen Drehschwingungsdämpfers.

Show:

• 1 is a schematic half-sectional view of an embodiment of a torsional vibration damper according to the invention, and
• 2nd is a schematic half-sectional view of an alternative embodiment of a torsional vibration damper according to the invention.

The 1 shows in a half section a torsional vibration damper 1 , as it can be designed for example as a double clutch damper, clutch damper, dual mass flywheel etc. The torsional vibration damper 1 is designed to be rotatable about axis xx.

The torsional vibration damper 1 has an input part 2nd and an output part 3rd on. The entrance part 2nd can for example be designed as a primary flywheel and the output part 3rd can be designed as a secondary flywheel mass.

The entrance part 2nd is, for example, with a crankshaft of an internal combustion engine or the like. connectable as screwable. The input part points to this 2nd radially inside screw openings 17th on through which screws are feasible to the input part 2nd to be able to screw on a crankshaft.

With the torsional vibration damper 1 are the input part 2nd and the output part 3rd arranged rotatable relative to each other.

It is a spring damper device 4th provided which with spring elements 5 , 6 is provided. The spring elements 5 , 6 are supported in the circumferential direction on the input part 2nd and on one with the output part 3rd connected flange 7 from what, however, in 1 is not recognizable. So with the interposition of the spring elements 5 , 6 a torque from the input part 2nd to the output part 3rd be transmitted. Here is the input part 2nd relative to the output part 3rd against the restoring force of the spring elements 5 , 6 the spring damper device 4th rotatably arranged.

On the flange 7 is also optional a centrifugal pendulum device 8th trained so that the flange 7 the spring damper device 4th for example at the same time as a flange element 9 the centrifugal pendulum device 8th is formed on which pendulum masses 10th are arranged relocatable.

The entrance part 2nd forms a chamber 11 from that of the spring damper device 4th can be assigned because in the chamber 11 the spring elements 5 , 6 are arranged.

Here is the chamber 11 mostly from discs 12th , 13 formed of the input part, the chamber laterally also by a spring membrane 14 is covered.

For possible damage to the spring membrane 14 to avoid is the entrance part 2nd relative to the output part 3rd in a radial direction and / or in an axial direction in its displaceability by at least one stop 15 limited.

Here is in 1 to recognize that the spring diaphragm 14 on the one hand with the output part 3rd is firmly connected and on the other hand is the spring membrane 14 at the entrance part 2nd or on the disc 13 on. Alternatively, the spring membrane 14 on the one hand also with the input part 2nd be connected and on the other hand at the output part 3rd issue. So there can be an immediate investment or, as in 1 shown a system with the interposition of a friction ring 16 Etc.

It can also be caused that the spring membrane 14 on the one hand with the output part 3rd is connected in a sealed manner and, on the other hand, sealingly on the input part 2nd is present. Alternatively, the spring membrane 14 on the one hand also with the input part 2nd be connected in a sealed manner and, on the other hand, sealingly on the output part 3rd issue.

The 1 also shows that one with the output part 3rd connected element, i.e. the pendulum mass 10th from one with the input part 2nd connected element, the disc 13 is overlapped radially and axially to act as a stop for the radial and axial mobility of the output part 3rd relative to the entrance part 2nd to serve. In this case, only a radial or axial overlap could be provided in order to form a radial or axial stop. In this case, the pendulum mass forms 10th together with the friction ring 16 or with the disc 13 the attack.

Alternatively, one with the input part 2nd connected element from one to the output part 3rd connected element radially and / or axially overlapped to act as a stop for the radial and / or axial mobility of the input part 2nd relative to the output part 3rd to serve.

So this is the front part 2nd and / or that with the output part 3rd connected element, washer 13 or friction ring 16 , a ring element and / or a disc which extends substantially in the radial direction.

This is also the case with the entrance part 2nd and / or that with the output part 3rd connected element a centrifugal pendulum device 8th and / or a flange element 9 a centrifugal pendulum device 8th and / or a pendulum mass 10th a centrifugal pendulum device 8th .

For example, the ring element or the disk, for example the disk 13 , with the input part 2nd or alternatively with the output part 3rd riveted, caulked or welded. In principle, the ring element or the disk can be arranged radially on the inside or radially on the outside with the input part 2nd or with the output part 3rd be connected.

Alternatively, the spring membrane could be used 14 even serve as a stop.

The 2nd shows a further alternative embodiment, in which the stop 15 is formed by the axial and radial overlap of the disc 13 opposite the pendulum mass 10th . The remaining features are essentially the same as the 1 designed, which is why reference should be made in this regard.

Reference list

1

Torsional vibration damper

2nd

Entrance part

3rd

Output part

4th

Spring damper device

5

Spring element

6

Spring element

7

flange

8th

Centrifugal pendulum device

9

Flange element

10th

Pendulum mass

11

chamber

12th

disc

13

disc

14

Spring membrane

15

attack

16

Friction ring

17th

Screw opening

Claims (10)

Torsional vibration damper (1) with an input part (2) and with an output part (3), which are rotatably arranged relative to one another, with a spring damper device (4) with spring elements (5, 6), the input part (2) relative to the output part (3 ) against the restoring force of the spring elements (5, 6) of the spring damper device (4) is rotatably arranged, the spring damper device (4) having a chamber (11) in which the spring damper elements are arranged, the chamber (11) being separated by a spring membrane ( 14) is characterized , characterized in that the input part (2) relative to the output part (3) is limited in a radial direction and / or in an axial direction in its displaceability by at least one stop (15). Torsional vibration damper (1) after Claim 1 , characterized in that the spring membrane (14) is connected on the one hand to the output part (3) and on the other hand rests against the input part (2) or the spring membrane (14) is connected on the one hand to the input part (2) and on the other hand to the output part (3 ) is present. Torsional vibration damper (1) after Claim 2 , characterized in that the spring membrane (14) is connected to the output part (3) in a sealed manner and on the other hand is sealingly connected to the input part (2) or the spring membrane (14) is connected to the input part (2) in a sealed manner and is sealingly connected to the other side the output part (3). Torsional vibration damper (1) according to one of the preceding claims, characterized in that an element connected to the output part (3) is overlapped radially and / or axially by an element connected to the input part (2) in order to act as a stop (15) for the radial one and / or to serve axial mobility of the output part (3) relative to the input part (2). Torsional vibration damper (1) according to one of the preceding Claims 1 to 4th , characterized in that an element connected to the input part (2) is overlapped radially and / or axially by an element connected to the output part (3) in order to act as a stop (15) for the radial and / or axial mobility of the input part (2 ) to serve relative to the output part (3). Torsional vibration damper (1) according to one of the preceding Claims 1 to 5 , characterized in that the element connected to the input part (2) and / or the element connected to the output part (3) is a ring element and / or a disk which extends essentially in the radial direction. Torsional vibration damper (1) according to one of the preceding Claims 1 to 6 , characterized in that the element connected to the input part (2) and / or the element connected to the output part (3) has a centrifugal pendulum device (8) and / or a flange element (9) of a centrifugal pendulum device (8) and / or a pendulum mass (10) a centrifugal pendulum device (8). Torsional vibration damper (1) according to one of the preceding Claims 1 to 7 , characterized in that the ring element or the disc is riveted, caulked or welded to the input part (2) or to the output part (3). Torsional vibration damper (1) after Claim 6 , 7 or 8th , characterized in that the ring element or the disk (12, 13) is connected radially inside or radially outside to the input part (2) or to the output part (3). Torsional vibration damper (1) according to one of the preceding claims, characterized in that the spring diaphragm (14) itself serves as a stop (15).

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