DE102021106986A1 - Dual mass flywheel with additional mass - Google Patents

Abstract

In a dual-mass flywheel (1) with a primary side (2) and a secondary side (3) which can be rotated relative to one another about a common axis of rotation (R) against a restoring moment of an arc spring (4), with a mass ring ( 27), an additional mass can be detachably mounted without through-bores in the primary flywheel, in that the mass ring (27) has an at least partially circumferential inner diameter that is fixed radially to an at least partially circumferential outer diameter of a receiving means (26) and axially by a Circlip (31) is fixed.

Description

The invention relates to a dual mass flywheel with a primary side and a secondary side, which can be rotated relative to one another about a common axis of rotation against a restoring torque of an arc spring, a mass ring being arranged on the secondary side.

In order to save installation space and costs, the sheet metal thickness of the primary flywheel is often reduced as far as possible in double clutch dampers. If the through bores, which are provided for producing the main riveting of the secondary subassembly, are dispensed with, the sheet metal thickness can be further reduced. In this case, the secondary side must be pre-assembled and assembled with the primary side after the main riveting has already been carried out. An additional ground ring must be welded to the output flange.

It is therefore an object of the invention to provide a dual-mass flywheel in which an additional mass can be detachably mounted in the primary flywheel without through-holes.

This problem is solved by a dual mass flywheel according to claim 1. Preferred embodiments, refinements or developments of the invention are specified in the dependent claims.

The above-mentioned problem is solved in particular by a dual-mass flywheel with a primary side and a secondary side, which can be rotated relative to one another about a common axis of rotation against a restoring torque of an arc spring, a mass ring being arranged on the secondary side, the mass ring comprising an at least partially circumferential inner diameter , which is fixed radially on an at least regionally circumferential outer diameter of a receiving means and axially fixed by a locking ring.

In one embodiment of the invention, the ground ring has at least one extension which protrudes into a corresponding recess in the receiving means. Preferably, several extensions and corresponding recesses are arranged distributed over the circumference. These cause a positive connection of the ground ring with the receiving means in the axial direction and in the circumferential direction.

In one embodiment of the invention, the locking ring is fastened in a groove in the receiving means. A groove can be manufactured easily and inexpensively and causes a reliable fixing of the locking ring, which can also be dismantled again.

In one embodiment of the invention, the receiving means is a receiving disk which is riveted to a secondary flange. In one embodiment of the invention, this comprises a fastening flange and a receiving flange. The mounting disk is riveted to the other parts of the secondary side during assembly, so that the secondary flange and in particular the output hub can be taken over unchanged from existing series.

In an alternative embodiment of the invention, the receiving means is part of an output flange which is riveted to the secondary flange so that the receiving disk can be dispensed with as an additional component.

In one embodiment of the invention, the receiving means comprises an axial stop. The extensions of the ground ring are preferably pressed against the axial edges of the recesses. This means that additional slings such as exhibited areas or the like can be dispensed with.

In one embodiment of the invention, the locking ring is designed as a plate spring or in the manner of a plate spring. The disc spring rests with its inner edge at least in some areas on the mass ring and with its outer circumference lies in the groove of the receiving means. As a result, the ground ring is pressed axially into its seat or the stop means.

In one embodiment of the invention, this has a centrifugal pendulum device on the secondary side, which increases the damper effect.

• - Montage von zumindest Primärschwungscheibe, Bogenfeder, vormontierter Sekundärflanschbaugruppe und Primärmassendeckel,
• - Aufsetzen des Masserings auf die Sekundärflanschbaugruppe,
• - Montage des Sicherungsringes.

The problem mentioned at the beginning is also solved by a method for assembling a dual mass flywheel according to the invention, comprising the steps:

• - Assembly of at least the primary flywheel, bow spring, pre-assembled secondary flange assembly and primary mass cover,
• - placing the ground ring on the secondary flange assembly,
• - Assembly of the locking ring.

The secondary flange assembly includes all parts that are connected to one another by the main riveting, i.e. secondary flange, output flange, disk spring sealing membrane and, if applicable, the receiving disc and, if applicable, a spacer ring and, if applicable, other components.

The inventive solution to the problem provides for the mass ring to be attached to the damper with the aid of a locking ring, which also exerts an axial force on the mass ring, and to be able to dismantle it again if necessary. A locking ring produced by a stamping process is set up like a disc spring. This is able to be reduced in diameter during installation like a locking ring according to DIN 472 and brought into position axially. It is pretensioned axially like a disc spring. In the final position, the assembly tool is relaxed (as with DIN472) and the locking ring engages in the intended groove and can be supported in this and the part to be joined (the mass ring), whereby its axial force is also supported on the part to be joined.

• 1 ein erstes Ausführungsbeispiel eines erfindungsgemäßen Zweimassenschwungrades 1 in einer Schnittdarstellung,
• 2 das Ausführungsbeispiel der 1 in einer Draufsicht,
• 3 ein Ausführungsbeispiel eines Sicherungsringes in einer Draufsicht,
• 4 den Sicherungsring der 3 in einem Axialschnitt,
• 5 einen weiteren Schnitt durch das Ausführungsbeispiel der 1,
• 6 ein zweites Ausführungsbeispiel eines erfindungsgemäßen Zweimassenschwungrades 1 in einer Schnittdarstellung,
• 7 einen weiteren Schnitt durch das Ausführungsbeispiel der 6.

Embodiments of the invention are explained in more detail below with reference to the accompanying drawings. Show:

• 1 a first embodiment of a dual mass flywheel according to the invention 1 in a sectional view,
• 2 the embodiment of 1 in a plan view,
• 3 an embodiment of a locking ring in a plan view,
• 4th the locking ring of the 3 in an axial section,
• 5 a further section through the embodiment of 1 ,
• 6th a second embodiment of a dual mass flywheel according to the invention 1 in a sectional view,
• 7th a further section through the embodiment of 6th .

1 shows an arrangement of a dual mass flywheel according to the invention 1 in a radial section. The dual mass flywheel 1 comprises a primary mass or primary side 2 as well as a secondary mass or secondary side 3 going against the force of a bow spring 4th are rotatable relative to one another about an axis of rotation R. In the following, unless otherwise stated, the axial direction is understood to mean the direction parallel to the axis of rotation R, the radial direction is understood to mean a direction perpendicular to the axis of rotation R, and the circumferential direction is understood to mean a rotation about the axis of rotation R.

The primary mass 2 includes a primary flywheel 5 and a primary mass cover 6th . The primary flywheel 5 and the primary mass cover 6th close a bow spring mount 7th one in which the bow feather 4th , possibly also several bow springs 4th , is or are arranged. The bow feather 4th is supported by one spring end on the primary mass 2 from, for example, in the bow spring receptacle 7th pressed stops. The bow spring is supported by the other end of the spring 4th on the flange wings of a secondary flange 8th away. The flange wings extend radially outward and grasp the spring ends of the bow springs 4th one.

On the secondary flange 8th is a centrifugal pendulum device 9 arranged. This includes several pendulum masses 10 , the pendulum masses that are permanently connected to each other 11th , 12th include, via pendulum rollers, not shown, in kidney-shaped tracks of the secondary flange 8th and the pendulum part masses 11th , 12th are added, pendulum-like with respect to the secondary flange 8th are stored.

The secondary flange 8th is by means of rivets 13th a main rivet with an output hub 15th firmly riveted. Between the secondary flange 8th and the output hub 15th is a spacer ring 14th arranged. The rivet 13th are distributed on a main rivet circle. With the main rivet is a disc spring sealing membrane 16 on the secondary side 3 attached. The disc spring sealing membrane 16 is with its outer area with the primary mass cover 6th in contact, and thus seals the bow spring receptacle 7th towards the environment. The contact area between the disc spring sealing membrane 16 and primary mass cover 6th is with a slip ring 17th provided, this can be glued or clipped in, for example.

On the outer circumference of the bow spring 4th is a sliding cup 18th on the primary flywheel 5 arranged what friction and wear of the bow spring 4th opposite the primary flywheel 5 reduced. On the outer circumference of the primary flywheel 5 is a starter ring gear 19th attached, for example shrunk on or welded on. A cover disk 20th is by means of a caulking 21 on the primary flywheel 5 attached. The output hub 15th includes a spline 22nd for connection to a transmission input shaft. The primary flywheel 5 is with a flexplate 23 riveted, which can be connected in a manner known per se to a crankshaft of an internal combustion engine.

With the rivets 13th the main rivet is a receiving washer 24 with the secondary flange 8th , the spacer ring 14th and the output hub 15th riveted. The receiving disk 24 includes an annular mounting flange 25th and a substantially hollow cylindrical receiving flange 26th . On the mounting flange 26th is a mass ring 27 postponed. The mass ring 27 knows how in 2 shown centering seats in areas of its inner circumference 28 and between the centering seats 28 processes running inwards 29 on that in corresponding recesses 30th in the receiving flange 26th protrude. The centering seats 28 lie on the outer circumference of the mounting flange 26th and put the ground ring 27 fixed in the radial direction. Towards the secondary flange 8th becomes the ground ring 27 by appendages 29 that are in the recesses 30th at the edges of the recesses on the secondary flange side 30th concern, determined. The definition in the opposite direction, that is, against being pulled off the receiving flange 26th is done by a locking ring 31 in a circumferential groove 32 in the receiving flange 26th is arranged.

2 shows the dual mass flywheel 1 the 1 in a top view, the 3 and 4th show individual views of the locking ring 31 . This has a constant outer diameter R _A , which is the inner diameter of the groove bottom of the groove 32 is equivalent to. The inside diameter is variable, so that the radial height of the locking ring changes over the circumference and opposite an opening on which there are bores on both sides 33 are arranged to receive an assembly tool, is the largest. The locking ring can be removed by means of the holes 33 like a snap ring in the groove 32 assemble. The locking ring 31 is like in 4th shown, shaped like a disc spring. 5 shows the embodiment of 1 in a section through one of the projections 29 . The recess 30th forms an axial stop 34 to which the ground ring 27 or the extensions 29 by the spring action of the locking ring 31 is pressed.

the 6th and 7th show alternative embodiments of a dual mass flywheel according to the invention 1 . In this case, the output hub 15th a radially outwardly extended mounting flange 25th on that of the mounting flange 26th wearing. Instead of an additional component, the ground ring is here on the output hub 15th attached.

List of reference symbols

1

Dual mass flywheel

2

Primary side

3

Secondary side

4th

Bow feather

5

Primary flywheel

6th

Primary mass cover

7th

Bow spring mount

8th

Secondary flange

9

Centrifugal pendulum device

10

Pendulum mass

11th

Pendulum part mass

12th

Pendulum part mass

13th

rivet

14th

Spacer ring

15th

Output hub

16

Belleville spring sealing membrane

17th

Slip ring

18th

Sliding cup

19th

Starter ring gear

20th

Cover disk

21

Caulking

22nd

Splines

23

Flexplate

24

Mounting disc

25th

Mounting flange

26th

Mounting flange

27

Mass ring

28

Centering seat

29

Appendix

30th

Recess

31

Circlip

32

Groove

33

Hole in locking ring

34

attack

Claims (10)

Dual mass flywheel (1) with a primary side (2) and a secondary side (3) which can be rotated relative to one another about a common axis of rotation (R) against a restoring torque of an arc spring (4), a mass ring (27) on the secondary side (3) is arranged, characterized in that the mass ring (27) comprises an at least regionally circumferential inner diameter which is fixed radially on an at least regionally circumferential outer diameter of a receiving means (26) and axially fixed by a locking ring (31). Dual mass flywheel after Claim 1 , characterized in that the ground ring (27) has at least one extension (29) which protrudes into a corresponding recess (30) in the receiving means (26). Dual mass flywheel after Claim 1 or 2 , characterized in that the locking ring (31) is fastened in a groove (32) in the receiving means (26). Dual mass flywheel according to one of the preceding claims, characterized in that the receiving means (26) is a receiving disk (24) which is riveted to a secondary flange (8). Dual mass flywheel after Claim 1 , characterized in that the receiving disk (24) comprises a fastening flange (25) and a receiving flange (26). Dual mass flywheel according to one of the Claims 1 until 3 , characterized in that the receiving means (26) is part of an output flange (15) which is riveted to the secondary flange (8). Dual mass flywheel according to one of the preceding claims, characterized in that the receiving means (26) comprises an axial stop (34). Dual mass flywheel according to one of the preceding claims, characterized in that the securing ring (31) is a plate spring. Dual mass flywheel according to one of the preceding claims, characterized in that it has a centrifugal pendulum device (9) on the secondary side. Method for assembling a dual mass flywheel according to one of the preceding claims, comprising the steps: - Assembly of at least the primary flywheel (5), bow spring (4), pre-assembled secondary flange assembly (8, 9, 13, 14, 15, 16, 26) and primary mass cover (6), - placing the ground ring (27) on the secondary flange assembly (8, 9, 13, 14, 15, 16, 26), - Assemble the circlip (31).

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