DE102019120001A1 - 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), the input part (2) being rotatably mounted relative to the output part (3), with a spring damper device (9) in the torque flow between the input part and the output part (3), wherein the spring damper device (9) has spring elements (10) which are supported on the one hand on the input part (2) and on the other hand can be acted upon by an output-side flange (11) of the spring damper device (9), the input part (2) has two shells, a first shell (13) and a second shell (14), which are designed to be connected to one another and form a chamber (15) in which the spring elements (10) of the spring damper device (9) are received, only on the first shell (13) of the two shells (13, 14) projections (16) are provided on which the spring elements (10) of the spring damper device (9) extend in the circumferential direction support.

Description

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

Torsional vibration dampers are known in many ways in the prior art, for example as dual mass flywheels. They are used to dampen torsional vibrations such as those that occur in the drive train of a motor vehicle. Two-mass flywheels have an input part as a primary flywheel and an output part as a secondary flywheel, which are rotatably mounted relative to one another at least by a defined angle of rotation and which can be rotated relative to one another against the restoring force of a spring damper device.

The input part of two sheet metal shells forms a pocket in which the spring elements of the spring damper device are arranged. The spring elements are supported on the one hand axially and radially on the two shells, with projections embossed on both shells being provided for force transmission of the spring elements in the circumferential direction. On the output side, a flange engages the chamber typically from the inside radially, so that the spring elements can on the other hand also be supported on the flange in the circumferential direction. If a torque is transmitted from the input part to the output part, the torque path runs from the input part via the embossed projections to the provided spring elements and from these to the flange and from the flange to the output part.

The two shells of the input part must have the necessary strength and wear resistance, because the projections embossed on the shells must transmit the torque to the spring elements and the spring elements moving relative to the shells cause a considerable amount of friction on the shells. These requirements mean that the two shells must meet the necessary material thickness and material requirements, which leads to considerable costs for the two shells.

It is the object of the present invention to create a torsional vibration damper which can be produced more simply and cost-effectively compared to the prior art.

The object is achieved with the features of claim 1.

One embodiment of the invention relates to a torsional vibration damper with an input part and with an output part, the input part being rotatably mounted relative to the output part, with a spring damper device in the torque flow between the input part and the output part, the spring damper device having spring elements, which are located on the one hand on the input part and which, on the other hand, can be acted upon by an output-side flange of the spring damper device, the input part having two shells, a first shell and a second shell, which are designed to be connected to one another and form a chamber in which the spring elements of the spring damper device are received, with only on the first shell of the two shells projections are provided on which the spring elements of the spring damper device are supported in the circumferential direction. This means that the second shell can be designed more simply, which reduces the manufacturing costs. The second shell can also be produced with lower material costs.

It is particularly advantageous because the second shell is free of projections for supporting the spring elements in the circumferential direction. This simplifies the manufacture of the second shell and reduces costs.

It is also advantageous if the first shell has a greater material thickness than the second shell. Costs can be saved by reducing the material thickness of the second shell.

It is also advantageous if the first shell has a material thickness that is more than a factor of 2 greater than the second shell. The material costs for the second shell are correspondingly reduced.

It is also advantageous if the first shell is essentially L-shaped in section. As a result, the shape of the first shell allows a stable base to be formed for the chamber.

It is advantageous if the second shell has an essentially I-shaped cross-section, with an arcuate course optionally being provided for the second shell to nestle against spring elements. A ring which is easy to manufacture and which forms the second shell can thus be formed.

It is also advantageous if a wear protection shell is arranged radially on the outside between the first shell and at least one spring element. As a result, when the spring elements move relative to the first shell, the first shell is better protected against friction and wear caused thereby.

It is also advantageous if between the second shell and the flange of the Spring damper device is arranged a membrane which closes the chamber. As a result, lubricant provided in the chamber, such as, for example, grease, cannot escape unhindered from the chamber, which in case of doubt could cause the dual-mass flywheel to fail.

It is also advantageous if the diaphragm is connected to the flange and / or to the output part in a rotationally fixed manner radially on the inside and the diaphragm is supported on the second shell so as to be rotatable radially on the outside, in particular sealingly supported on the second shell with a ring element in between. In this way a permanent seal is achieved, possibly with a defined friction.

It is also advantageous if the input part is rotatably mounted relative to the output part via a bearing, the bearing being received on the one hand on a bearing seat of the input part, which is formed in one piece with the input part or is non-rotatably connected and on the other hand the bearing is mounted on a bearing seat of the Output part is added.

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

• 1 eine schematische Halbschnittdarstellung eines Ausführungsbeispiels eines erfindungsgemäßen Drehschwingungsdämpfers.

It shows:

• 1 a schematic half-sectional view of an embodiment of a torsional vibration damper according to the invention.

The 1 shows a half section of a torsional vibration damper 1 , which can be rotated in relation to the axis xx. The torsional vibration damper 1 is designed as a two-mass flywheel in the embodiment shown.

The torsional vibration damper 1 has an input part 2 and an output part 3 on, being the input part 2 relative to the starting part 3 is rotatably mounted.

This is the input part 2 about a warehouse 4th relative to the starting part 3 rotatably mounted. The warehouse 4th is on the one hand at a bearing seat 5 of the input part 2 recorded. Here is the bearing seat 5 optionally with the input part 2 in one piece or, as in 1 shown with the input part 2 non-rotatably connected. Here is the bearing seat 5 on a ring element 7th attached, which with the input part 2 can be screwed, see the screws 8th . On the other hand, the camp is 4th at a bearing seat 6 of the output part 3 recorded.

The torsional vibration damper 1 is with a spring damper device 9 formed, which in the torque flow between the input part 2 and the output part 3 arranged spring elements 10 having. The spring elements are supported for torque transmission 10 on the one hand at the entrance part 2 in the circumferential direction and on the other hand they are supported in the circumferential direction on an output-side flange 11 the spring damper device 9 from. This makes the spring elements 10 from the entrance part 2 and / or from the output part 3 can be acted upon in the circumferential direction.

The flange 11 is with the output part 3 non-rotatably connected, in particular by means of at least one rivet element 12th or by means of rivets 12th . Alternatively, the flange 11 also be connected in other ways, such as screwed or welded etc.

The entrance part 2 has two bowls 13 , 14th on, in particular only two shells 13 , 14th , so a first bowl 13 and a second bowl 14th . The first bowl 13 is the starting part 3 arranged facing away and the second shell 14th is the starting part 3 arranged facing. The two bowls 13 , 14th are connected to one another radially on the outside, as if welded.

The two bowls 13 , 14th form a chamber 15th from which the spring elements 10 the spring damper device 9 are included.

For torque transmission are only on the first shell 13 of the two bowls 13 , 14th Ledges 16 provided on which the spring elements 10 the spring damper device 9 Support in the circumferential direction. This allows torque from the input part 2 on the spring elements 10 transferred or vice versa. The second bowl 14th is free of protrusions to support the spring elements 10 in the circumferential direction.

With this configuration according to the invention, the first shell 13 be designed such that it has a greater material thickness than the second shell 14th . In particular, the first shell 13 one by more than the factor 2 have a higher material thickness than the second shell 14th . This allows the material thickness of the first shell 13 can be adapted to the mechanical loads caused by the torque transmission, while the material thickness of the second shell 14th can be kept lower because they do not have any torque on the spring elements 10 transmits. The weight and cost of the second shell can thus be optimized 14th be made.

The 1 also shows that the first shell 13 is substantially L-shaped in section. It can also be seen that the second shell 14th is essentially I-shaped in section, optionally an arcuate course 17th to nestle the second shell 14th on spring elements 10 can be provided. By the respective course of the bowls 13 , 14th , viewed in section, the required installation space of the bag 15th for the spring elements 10 be created.

It is still off 1 to see that between the first shell 13 and at least one spring element 10 a wear protection shell radially on the outside 18th is arranged. This is used for the wear resistance of the first shell 13 because on this first shell 13 the spring elements 10 radially on the outside under centrifugal force, since there is virtually constant friction when the spring elements or their coils move.

It can also be seen that between the second shell 14th and the flange 11 the spring damper device 9 a membrane 19th is arranged which the chamber 15th closes to the outside. Is in the chamber, for example 15th for the spring elements 10 the diaphragm prevents lubrication provided by lubricant 19th the leakage of the lubricant. For example, grease or the like can be provided as the lubricant.

Here is the membrane 19th radially inside with the flange 11 and / or with the output part 3 rotatably connected, the membrane 19th rotates radially outward on the second shell 14th sealingly supported, in particular with the interposition of a ring element 20th .

List of reference symbols

1

Torsional vibration damper

2

Input part

3

Output part

4th

camp

5

Bearing seat

6th

Bearing seat

7th

Ring element

8th

screw

9

Spring damper device

10

Spring element

11

flange

12

Rivet element

13

first shell

14th

second bowl

15th

Chamber / pocket

16

head Start

17th

arched course

18th

Wear protection shell

19th

membrane

20th

Ring element

Claims (10)

Torsional vibration damper (1) with an input part (2) and with an output part (3), the input part (2) being rotatably mounted relative to the output part (3), with a spring damper device (9) in the torque flow between the input part (2) and the output part (3), the spring damper device (9) having spring elements (10) which are supported on the one hand on the input part (2) and on the other hand can be acted upon by an output-side flange (11) of the spring damper device (9), the input part ( 2) has two shells, a first shell (13) and a second shell (14), which are designed to be connected to one another and form a chamber (15) in which the spring elements (10) of the spring damper device (9) are received, thereby characterized in that projections (16) are provided only on the first shell (13) of the two shells (13, 14) on which the spring elements (10) of the spring damper device (9) are attached in the circumferential direction abs support. Torsional vibration damper (1) Claim 1 , characterized in that the second shell (14) is free of projections (16) for supporting the spring elements (10) in the circumferential direction. Torsional vibration damper (1) Claim 1 or 2 , characterized in that the first shell (13) has a greater material thickness than the second shell (14). Torsional vibration damper (1) Claim 3 , characterized in that the first shell (13) has a material thickness that is more than a factor of 2 higher than the second shell (14). Torsional vibration damper (1) according to one of the preceding claims, characterized in that the first shell (13) is essentially L-shaped in section. Torsional vibration damper (1) according to one of the preceding claims, characterized in that the second shell (14) is essentially I-shaped in section, with an optional arcuate course (17) for the second shell (14) to nestle against spring elements (10 ) is provided. Torsional vibration damper (1) according to one of the preceding claims, characterized characterized in that a wear protection shell (18) is arranged radially on the outside between the first shell (13) and at least one spring element (10). Torsional vibration damper (1) according to one of the preceding claims, characterized in that a membrane (19) which closes the chamber (15) is arranged between the second shell (14) and the flange (11) of the spring damper device (9). Torsional vibration damper (1) Claim 8 , characterized in that the membrane (19) is connected to the flange (11) and / or to the output part (3) in a rotationally fixed manner radially on the inside and the membrane (19) is supported in a sealing manner on the second shell (14) so that it can be rotated radially on the outside, in particular with the interposition of a ring element (20) on the second shell (14) in a sealing manner. Torsional vibration damper (1) according to one of the preceding claims, characterized in that the input part (2) is rotatably mounted relative to the output part (3) via a bearing (4), the bearing (4) on the one hand on a bearing seat (5) of the Input part (2) is received, which is formed in one piece with the input part (2) or connected in a rotationally fixed manner and wherein the bearing (4) on the other hand is received on a bearing seat (6) of the output part (3).

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