DE102016125054A1 - Dual mass flywheel with controllable damping - Google Patents

Abstract

Torque transmission device comprising a dual mass flywheel with a primary side and a secondary side, which are rotatable relative to the restoring force of an energy storage relative to each other, and a damping device for dissipating energy in the relative rotation between the primary side and secondary side, wherein the damping device has a controllable damping.

Description

The invention relates to a torque transmission device comprising a dual mass flywheel with a primary side and a secondary side, which are rotatable relative to the restoring force of an energy storage relative to each other, and a damping device for dissipating energy during relative rotation between the primary side and secondary side and a drive train for a motor vehicle with such a torque transmission device ,

Dual mass flywheels are known from the prior art, for example from the DE 41 17 582 A1 , known. Such dual-mass flywheels are used as vibration absorbers for torsional vibrations in drive trains of motor vehicles, the dual-mass flywheel generally being arranged between the crankshaft of an internal combustion engine driving the motor vehicle and a vehicle clutch located upstream of the manual transmission. By against spring force and possibly also against dry friction relative to each other rotatable primary mass and secondary mass are torsional vibrations, which are caused by the non-uniform drive torque of the engine usually designed as a piston engine, redeemed.

It is known that between the primary side and the secondary side of a dual mass flywheel to produce dry or viscous friction, a friction control disc is arranged, which applies a fixed set friction torque after passing through a clearance angle. This friction torque is intended to reduce the oscillation angle in certain operating states. This may be necessary to avoid damaging over torques in the dual mass flywheel or to improve the run-up characteristics of the dual-mass flywheel when starting the internal combustion engine.

An object of the invention is to improve the damping in a dual mass flywheel.

This problem is solved by a torque transmission device according to claim 1 and a drive train according to claim 10. Preferred embodiments, refinements or developments of the invention are specified in the dependent claims.

The above-mentioned problem is in particular solved by a torque transmission device comprising a dual-mass flywheel with a primary side and a secondary side, which are rotatable relative to the restoring force of an energy storage relative to each other, and a damping device for dissipating energy in the relative rotation between the primary side and secondary side, wherein the damping device a has controllable damping. In this case, a variably controllable coupling between primary and secondary side is provided. The device according to the invention comprises an electrorheological brake between the primary and secondary side in the form of an annular component, arranged in the region of the sliding or roller bearing. The rheological brake consists of two concentric rings, between which the rheological fluid is filled.

In one embodiment of the invention, the damping device comprises primary-side surface elements and secondary-side surface elements, between which at least partially a rheological fluid is arranged. The damping device is thus a viscous friction damper comprising an electrorheological medium. By using the electrorheological medium as a viscous medium in a viscous damper, the viscous damping can be controlled or regulated. The rheological properties of a medium, such as a liquid, are understood to mean its deformation and flow behavior. Electrorheological fluids (ERF) have the ability to change their rheological properties under the influence of mostly an electrical or even a magnetic field. In this case, the apparent viscosity of the electrorheological fluid increases with increasing field strength. This effect sets itself up with a high dynamic and in a short response time. The viscosity of the electrorheological fluid can therefore be controlled by an electrical control signal and a corresponding conversion of the control signal into an electric field very quickly and with a large dynamic range. Electrorheological fluids usually consist of a suspension of polarizable particles and a nonconductive carrier fluid. The size of the particles of relevant liquids is 1 ... 15 and their volume fraction 30 to 50%.

The damping device comprises in one embodiment of the invention a bearing outer ring and a bearing inner ring, between which the rheological fluid is arranged. The bearing outer ring has an internal toothing in one embodiment of the invention, the bearing inner ring has an external toothing in one embodiment of the invention. Internal teeth and external teeth are arranged side by side in different radial planes in one embodiment of the invention. The two rings can thus be rotated arbitrarily relative to each other, so have no stop. The internal and external teeth increase the surfaces in contact with the rheological medium, so that a correspondingly large damping moment can be provided. When applying an electrical voltage, the liquid hardens, so that between the radial cams of the two rings, a heavy effect and a kind of positive engagement arise. About the height of the voltage, the viscosity of the rheological medium can be adjusted continuously and thus the coupling moment between the primary and secondary side can be freely determined.

The torque transmitting device in one embodiment of the invention comprises means capable of generating an electric and / or magnetic field in the rheological fluid.

The means for generating the electric and / or magnetic field are in an embodiment of the invention electrically coupled to a control device comprising a power supply unit. In one embodiment of the invention, physical properties of the electrorheological medium are variable by an electrical output signal provided by a (co-rotating) receiver which is variable with a (body-mounted) transmitter controllable by an electrical input signal or control signal.

The energy supply unit alternatively or additionally comprises a generator which can be driven by the relative rotation between the primary side and the secondary side. The aforementioned problem is also solved by a drive train of a motor vehicle comprising a torque transmission device according to the invention.

• 1 einen Ausschnitt aus einem Ausführungsbeispiel einer erfindungsgemäßen Drehmomentübertragungseinrichtung,
• 2 Innen- und Lageraußenring des Ausführungsbeispiels der 1 in einer Draufsicht.

An embodiment of the invention will be explained in more detail with reference to the accompanying drawings. Showing:

• 1 a section of an embodiment of a torque transmission device according to the invention,
• 2 Inner and outer bearing ring of the embodiment of 1 in a top view.

1 shows a section of a torque transmission device according to the invention 1 , The torque transmitting device 1 is arranged in the installed position in the drive train of a motor vehicle between a crankshaft of an internal combustion engine and a vehicle clutch. The torque generated by the internal combustion engine is transmitted via the torque transmission device 1 and transmit the vehicle clutch to a manual transmission and from there via a differential and other drive shafts on driven wheels of a motor vehicle. The torque transmitting device 1 thus transfers the drive torque of the internal combustion engine to the drive wheels. By means of the vehicle clutch, the drive torque can optionally be interrupted and by means of the vehicle transmission, different ratios can be adjusted. The torque transmitting device 1 is substantially rotationally symmetrical to a rotation axis R. The rotation axis R is also the axis of rotation of the crankshaft of the internal combustion engine, not shown. Hereinafter, the axial direction is understood to mean a direction parallel to the rotation axis R, and in the radial direction, a direction perpendicular to the rotation axis R is understood. The circumferential direction is a rotation about the rotation axis R.

The torque transmitting device 1 essentially comprises a dual-mass flywheel whose primary side 2 has a primary mass and connected to the crankshaft, not shown, for example, is screwed, and its secondary side 3 has a secondary flywheel and is coupled to an input part of the vehicle clutch. The dual mass flywheel 1 includes a spring receiving space defined by a primary mass flange 4 and is formed with this welded primary wet cover and in which one or more bow springs are arranged as energy storage. The primary side 2 is the input part of the torque transmission device 1 and is screwed in installation position with the crankshaft of the internal combustion engine. The bow springs are each supported with a spring end on the primary side and with the other spring end on a secondary flange of the secondary side. The secondary side 2 is against the force of the bow springs as energy storage relative to the primary side 2 rotatable, so that in a relative rotation, the bow springs can absorb and release energy as energy storage and act as a vibration damper.

From the primary side 2 is in 1 only one bearing bush 5 shown with the primary mass flange 4 firmly connected in the installed position, for example, is screwed, the screw at the same time serves to connect both with the crankshaft. In the bearing bush is a hub 6 the secondary side 3 arranged, which is fixedly connected to the secondary flange, for example riveted, is.

Between the bearing bush 5 and the hub 6 are a damping device 7 as well as a ball bearing 8th arranged. The damping device 7 includes a bearing outer ring 9 as well as a bearing inner ring 10 , The bearing outer ring 9 is in the bearing bush 5 pressed in and lies with one axial end on a shoulder 11 the bearing bush 5 at. The bearing inner ring 10 is on an inner bearing thorn 12 the hub 5 pressed on and lies on a paragraph 13 on, which is the transition to an outer one bearing mandrel 14 represents on which a ball bearing inner ring 15 of the ball bearing 8 is pressed. A ball bearing outer ring 16 of the ball bearing 8th is in the bearing bush 5 pressed in and is located on the bearing outer ring 9 at. The ball bearing inner ring 15 lies axially on a flange disc 17 the hub 6 at. The ball bearing 8th centered the hub 6 opposite the bushing 5 and takes axial compressive force of the secondary side 3 on the primary side 2 on.

The bearing outer ring 9 has an internal toothing 18 on, the bearing inner ring 10 has an external toothing 19 on. The gears 18 . 19 do not interlock, but are like in 1 can be seen arranged in different axial planes, so that between both a radial gap 20 remains. On the outer circumference of the external toothing 19 is opposite the bearing outer ring 9 an axial gap 21 , on the inner circumference of the internal toothing 18 is opposite the bearing inner ring 10 an axial gap 22 , The axial column 21 . 22 as well as the radial gap 20 make a total of a gap 23 between bearing inner ring 10 and bearing outer ring 9 with a surface which is enlarged compared with cylindrical coaxial surfaces, so that a viscous liquid located between them has a correspondingly greater frictional force between the bearing inner ring 10 and bearing outer ring 9 causes.

The gap 23 between bearing inner ring 10 and bearing outer ring 9 is at both axial ends each with seals 24 . 25 sealed against the environment.

In the gap 23 is arranged a rheological fluid. Bearing inner ring 10 and bearing outer ring 9 each have not shown means for generating an electric field in the gap 23 on, for example, electrically insulated mounted capacitor plates, between which a voltage can be applied. In this case, one pole lies on a capacitor plate embedded in the bearing inner ring, the other pole on a capacitor plate embedded in the bearing outer ring. By applying an electrical voltage between the capacitor plates an electric field is generated in the gap, wherein the viscosity of the rheological fluid located there can be changed by the electric field.

The electrical voltage can be applied by a control unit, for example via sliding contacts similar to a rotor of an electric motor, but can also be effected by a rotor / stator assembly on the primary side and secondary side within the torque transmission device by the relative rotation between the primary side and secondary side or contactless transmitted by a magnetic field.

LIST OF REFERENCE NUMBERS

1

Torque transfer device

2

primary

3

secondary side

4

Primärmasseflansch

5

bearing bush

6

hub

7

attenuator

8th

ball-bearing

9

Bearing outer ring

10

Bearing inner ring

11

shoulder

12

inner camp thorn

13

paragraph

14

outer bearing pin

15

Ball bearing inner ring

16

Ball bearing outer ring

17

flange

18

internal gearing

19

external teeth

20

radial gap

21

axial gap

22

axial gap

23

gap

24

poetry

25

poetry

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

• DE 4117582 A1 [0002]

Claims (10)

Torque transmission device (1) comprising a dual mass flywheel with a primary side (2) and a secondary side (3) which are rotatable relative to the restoring force of an energy storage relative to each other, and a damping device (7) for dissipating energy during the relative rotation between the primary side (2) and Secondary side (3), characterized in that the damping device (7) has a controllable damping. Torque transmission device according to Claim 1 , characterized in that the damping device (7) comprises primary-side surface elements (9, 18) and secondary-side surface elements (10, 19), between which at least partially a rheological fluid is arranged. Torque transmission device according to Claim 2 , characterized in that the damping device (7) comprises a bearing outer ring (9) and a bearing inner ring (10), between which the rheological fluid is arranged. Torque transmission device according to Claim 3 , characterized in that the bearing outer ring (9) has an internal toothing (18). Torque transmission device according to Claim 3 or 4 , characterized in that the bearing inner ring (10) has an outer toothing (19). Torque transmission device according to Claim 5 , characterized in that inner toothing (18) and outer toothing (19) are arranged side by side in different radial planes. Torque transfer device according to one of the preceding claims, characterized in that it comprises means capable of generating an electric and / or magnetic field in the rheological fluid. Torque transmission device according to Claim 7 , characterized in that the means for generating the electric and / or magnetic field are electrically coupled to a power supply unit. Torque transmission device according to Claim 7 , characterized in that the energy supply unit comprises a by the relative rotation between the primary side (2) and the secondary side (3) drivable generator. Drive train of a motor vehicle comprising a torque transmission device (1) according to one of the preceding claims.

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