DE102019125659A1 - Torque transmission device - Google Patents

Abstract

The invention relates to a torque transmission device (1) with a first functional body (11) and a second functional body (12), which are connected to a hub body (3) for torque transmission. In order to improve the transmission of torques, in particular large torques, is the first functional body (11) is arranged between the hub body (3) and the second functional body (12) in such a way that at least one deformation area (18) of the first functional body (11) permanently deformed by a shaped projection (10) of the second functional body (12) in a recess (8) of the hub body (3) engages in order to provide a rotationally fixed connection between the two functional bodies (11, 12) and the hub body (3).

Description

The invention relates to a torque transmission device with a first functional body and a second functional body, which are connected to a hub body for torque transmission. The invention also relates to a method for producing such a torque transmission device. The invention also relates to a belt pulley with such a torque transmission device.

From the German Offenlegungsschrift DE 10 2009 039 989 A1 a pulley for diverting mechanical energy of an internal combustion engine by means of a belt is known, with an input part that can be assigned non-rotatably to a crankshaft of the internal combustion engine, an output part that is mounted coaxially and rotatably about an angle of rotation relative to the input part and can be assigned to the belt, and an output part connected between the input part and the output part Spring damper device with at least one arc spring for damping torsional vibrations, the input part having an input damper cage and the output part having an output damper cage, each for enclosing and mounting the at least one arc spring in at least one spring chamber, the input part having a hub that can be assigned to the internal combustion engine and a hub flange assigned to it in a rotationally fixed manner having, the hub flange being associated with the input damper cage in a form-fitting, frictional-locking manner and / or non-rotatably by means of input drive pins, the output part being one of the Rie men has assignable race, wherein the belt race is assigned to the output damper cage in a form-fitting, frictional-locking and / or rotationally fixed manner by means of output driver pins.

The object of the invention is to improve the transmission of torques, in particular large torques, with a torque transmission device with a first functional body and a second functional body, which are connected to a hub body for torque transmission.

In the case of a torque transmission device with a first functional body and a second functional body, which are connected to a hub body for torque transmission, the first functional body is arranged between the hub body and the second functional body in such a way that at least one through a shaped projection of the second Functional body permanently deformed deformation area of the first functional body engages in a recess of the hub body in order to provide a rotationally fixed connection between the two functional bodies and the hub body. The two functional bodies are used, for example, to represent stops for a damper spring device or the like. The damper spring device is, for example, part of a spring decoupling system, in particular a belt pulley. The functional bodies are preferably designed as sheet metal parts. In the assembled state, a torque transmission must be ensured without a relative movement of the functional body to the hub body. The shaped projection of the second functional body is produced in a separate production step before the torque transmission device is assembled. The second functional body with the shaped projection can advantageously be hardened in order to make the second functional body with the shaped projection sufficiently firm or stable. The first functional body is initially not deformed in an area assigned to the shaped projection of the second functional body. After the first functional body has been pre-assembled on or on the hub body, the first functional body is deliberately permanently deformed by the shaped projection of the second functional body. The deformation of the first functional body is achieved, for example, with a suitable pressing tool with which the second functional body with its shaped projection presses the deformation area of the first functional body into the preferably complementary recess of the hub body. The recess of the hub body into which the deformation area of the first functional body is pressed is designed, for example, as a recess, in particular as a blind hole. In this way, a very stable, non-rotatable connection between the two functional bodies and the hub body is made possible in a simple manner.

A preferred exemplary embodiment of the torque transmission device is characterized in that the two functional bodies are designed as annular disk bodies. The annular disk bodies are preferably provided radially on the outside with functional areas that can enable various functions. The first functional body, designed as an annular disk body, is used, for example, to represent a torsional vibration damper. The second functional body, designed as an annular disk body, is used, for example, to represent an arc spring flange of the torsional vibration damper.

Another preferred exemplary embodiment of the torque transmission device is characterized in that the two functional bodies connected to the hub body in a rotationally fixed manner are fixed to the hub body by a third functional body. The third functional body is advantageously used to fix the two functional bodies in the axial direction on the hub body. The first functional body is clamped in the axial direction between the second functional body and the hub body. This prevents undesired loosening of the non-rotatable connection between the two functional bodies and the hub body in a simple manner.

Another preferred exemplary embodiment of the torque transmission device is characterized in that the third functional body is connected to the hub body in a force-locking manner. The third functional body is also advantageously designed as an annular disk and is pressed onto the hub body, for example, to represent the force-locking connection with the latter.

Another preferred exemplary embodiment of the torque transmission device is characterized in that the second functional body has at least one pre-stamped protrusion which serves to represent the shaped projection. The second functional body, like the first functional body, is preferably designed as a sheet metal part. However, after pre-assembly with a suitable pressing tool, the first functional body is permanently deformed by the shaped projection on the second functional body. The second functional body with the shaped projection is therefore preferably hardened. This ensures that the second functional body is not deformed in an undesirable manner when the rotationally fixed connection is established with the shaped projection.

Another preferred exemplary embodiment of the torque transmission device is characterized in that the pre-stamped protrusion on the second functional body is smaller than the recess in the hub body. It is thereby achieved in a simple manner that material of the first functional body can move into the recess of the hub body in the permanently deformed deformation region when the first functional body is deformed as desired. To implement a particularly stable, non-rotatable connection, at least two or more than two shaped projections are preferably provided on the second functional body between the two functional bodies and the hub body. At least two of the shaped projections are advantageously arranged diametrically. According to a further exemplary embodiment, the shaped projections are arranged distributed uniformly on the second functional body in a circumferential direction.

In a method for producing a torque transmission device described above, the above-mentioned object is alternatively or additionally achieved in that the first functional body is preassembled on the hub body before the second functional body with the shaped projection is pressed against the first functional body in such a way that the first functional body is positioned with its deformation area permanently deformed into the recess of the hub body. In this way, a stable, non-rotatable connection between the two functional bodies and the hub body can be established in a simple manner.

A preferred exemplary embodiment of the method is characterized in that the non-rotatable connection between the two functional bodies and the hub body is fixed with one or the third functional body. For this purpose, the two functional bodies that are connected non-rotatably to one another and to the hub body are advantageously clamped in the axial direction between the hub body and the third functional body. In this way, an undesired loosening of the non-rotatable connection between the two functional bodies and the hub body is reliably prevented.

The invention also relates to a belt pulley with a previously described torque transmission device for representing a spring decoupling system. The first functional body is advantageously used to represent a torsional vibration damping device in the belt pulley. The second functional body is advantageously used to represent an arc spring flange of the torsional vibration damping device.

The invention further relates to a functional body and / or a hub body for a torque transmission device described above. The named parts can be traded separately.

• 1 eine Drehmomentübertragungseinrichtung mit einem ersten Funktionskörper und einem zweiten Funktionskörper, die zur Drehmomentübertragung mit einem Nabenkörper verbunden sind, im Längsschnitt; und
• 2 eine Explosionsdarstellung der Drehmomentübertragungseinrichtung aus 1 vor einer Verformung des zweiten Funktionskörpers mit einem Formvorsprung, der an dem ersten Funktionskörper vorgesehen ist.

Further advantages, features and details of the invention emerge from the following description, in which various exemplary embodiments are described in detail with reference to the drawing. Show it:

• 1 a torque transmission device with a first functional body and a second functional body, which are connected to a hub body for torque transmission, in longitudinal section; and
• 2 an exploded view of the torque transmission device 1 before deformation of the second functional body with a shaped projection which is provided on the first functional body.

In the 1 and 2 is a torque transmission device 1 with a hub 2 shown in different views. The hub 2 includes a hub body 3rd , which is connected, for example, to a (not shown) drive shaft of a drive motor. The Torque transmission device 1 is according to a preferred embodiment in a pulley not shown in detail 20th integrated.

In the pulley 20th is the torque transmission device 1 with a torsional vibration damper 19th combined. The torsional vibration damper 19th comprises a first functional body 11 and a second functional body 12th . The second functional body 12th serves, for example, to represent an arc spring flange of the torsional vibration damper 19th .

A third functional body 13th serves the two functional bodies 11 and 12th in an axial direction on the hub body 3rd to fix. The term axial refers to an axis of rotation 16 the torque transmission device 1 . Axial means in the direction or parallel to the axis of rotation 16 .

The hub 2 includes a central through hole 5 . The hub body 3rd comprises a hub pressure body 4th , which essentially has the shape of a straight, hollow circular cylinder section on which a press ring body 6th is pressed on, the third functional body 13th represents. The press ring body 6th has a press inside diameter for this purpose 7th on, the size of which corresponds to the desired press connection between the third functional body 13th and the hub pressure body 4th of the hub body 3rd is selected.

The two functional bodies 11 , 12th are advantageous as well as the third functional body 13th , as an annular disk body 21 , 22nd , 23 executed. The first washer body 21 has an inside diameter 15th which is slightly larger than the inside diameter of the press 7th of the third washer body 23 is. The first washer body 21 has a slightly larger inner diameter 14th than the second washer body 22nd . This enables the two annular disk bodies to be assembled in a simple manner 21 , 22nd on the hub pressure body 4th of the hub body 3rd enables.

In 2 you can see that the second functional body 12th a pre-embossed wart 17th having a shaped projection 10 on the second functional body 12th represents. The lead in shape 10 of the second functional body 12th is a deformation area 18th of the first functional body 11 assigned. In addition, the shape projection 10 of the second functional body 12th and the deformation area 18th a recess 8th of the hub body 3rd assigned. The recess 8th is as a blind hole 9 in the hub body 3rd executed. The blind hole 9 has a larger axial dimension and also a larger diameter than the molding projection 10 .

During assembly, the first functional body is first 11 at the hub 2 assembled. Then the preferably hardened second functional body 12th with the protrusion 10 to the first functional body 11 created. Then the protrusion 10 of the first functional body 11 with a suitable pressing tool against the first functional body 11 pressed that the first functional body 11 , which is preferably not hardened, in the deformation area 18th permanently deformed. This becomes the material of the first functional body 11 how to get in 1 sees in the permanently deformed deformation area 18th of the first functional body 11 into the recess 8th of the hub body 3rd pressed in.

This creates a stable, non-rotatable connection between the two functional bodies in a simple manner 11 and 12th and the hub body 3rd produced. This stable, non-rotatable connection is finally made with the help of the press ring body 6th fixed in the axial direction so on the hub pressure body 4th of the hub body 3rd that the two functional bodies are pressed 11 and 12th between the third washer body 23 and the hub body 3rd be clamped and thus fixed.

At one point 24 it is indicated that the above-described stable, non-rotatable connection without the recess 8th in the hub body 3rd not possible. If necessary, by deliberately omitting the recess 8th a frictional connection between the ring washer bodies 21 and 22nd as well as between the press ring body 6th and the hub body 3rd be improved.

List of reference symbols

1

Torque transmission device

2

hub

3

Hub body

4th

Hub pressure body

5

central through hole

6th

Press ring body

7th

Press inside diameter

8th

Recess

9

Blind hole

10

Protrusion

11

first functional body

12th

second functional body

13th

third functional body

14th

Inside diameter

15th

Inside diameter

16

Axis of rotation

17th

pre-embossed wart

18th

Deformation area

19th

Torsional vibration damper

20th

Pulley

21st

first washer body

22nd

second washer body

23

third washer body

24

Job

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was 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.

Patent literature cited

• DE 102009039989 A1 [0002]

Claims (10)

Torque transmission device (1) with a first functional body (11) and a second functional body (12), which are connected to a hub body (3) for torque transmission, characterized in that the first functional body (11) between the hub body (3) and the second functional body (12) is arranged that at least one deformation area (18) of the first functional body (11), which is permanently deformed by a shaped projection (10) of the second functional body (12), engages in a recess (8) of the hub body (3) in order to achieve a to represent a non-rotatable connection between the two functional bodies (11, 12) and the hub body (3). Torque transfer device according to Claim 1 , characterized in that the two functional bodies (11, 12) are designed as annular disk bodies (21, 22). Torque transmission device according to one of the preceding claims, characterized in that the two functional bodies (11, 12) connected to the hub body (3) in a rotationally fixed manner are fixed to the hub body (3) by a third functional body (13). Torque transmission device according to one of the preceding claims, characterized in that the third functional body (13) is connected to the hub body (3) in a force-locking manner. Torque transmission device according to one of the preceding claims, characterized in that the second functional body (12) has at least one pre-stamped protrusion (17) which serves to represent the shaped projection (10). Torque transfer device according to Claim 5 , characterized in that the pre-embossed protrusion (17) on the second functional body (12) is smaller than the recess (8) of the hub body (3). Method for producing a torque transmission device according to one of the Claims 1 to 6th , characterized in that the first functional body (11) is preassembled on the hub body (12) before the second functional body (12) with the shaped projection (10) is pressed against the first functional body (11) in such a way that the first functional body ( 11) with its deformation area (18) permanently deformed into the recess (8) of the hub body (3). Procedure according to Claim 7 , characterized in that the non-rotatable connection between the two functional bodies (11, 12) and the hub body (3) is fixed with one or the third functional body (13). Belt pulley (20) with a torque transmission device (1) according to one of the Claims 1 to 6th to show a spring decoupling system. Functional body (11,12,13) and / or hub body (3) for a torque transmission device (1) according to one of the Claims 1 to 6th .

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