EP3969308A1 - Clutch assembly - Google Patents

Abstract

A clutch assembly (10) for coupling an engine shaft of an internal combustion engine to a rotor of an electric machine is provided, with a dual-mass flywheel (14) for damping torsional vibrations, wherein the dual-mass flywheel (14) has a primary mass (16), which can be connected directly or indirectly to the engine shaft, and a secondary mass (24), which is rotatable to an extent which is limited by means of an energy storage element (20) which is configured, in particular, as a bow spring, wherein the secondary mass (24) has an output flange (22) which can be caused to bear tangentially against the energy storage element (20), and with a friction clutch (28) which is configured, in particular, as a plate clutch and which serves for coupling the secondary mass (24) to the rotor of the electric machine, wherein the output flange (22) forms a friction surface (26) for bearing in a frictionally locking manner against an axially movable clutch disc (34) of the friction clutch (28), which clutch disc (34) can be coupled to the rotor. By way of the integration of the output flange (22) as a friction partner into the friction clutch (28), otherwise free installation space of the dual-mass flywheel (14) can be used for the friction clutch (28), with the result that a hybrid module with a small installation space requirement is made possible.

Description

Coupling requirement

The invention relates to a clutch unit with the help of which, in particular within a hybrid module, an internal combustion engine and / or an electrical Ma machine can be coupled to a motor vehicle transmission.

From DE 10 2009 059 944 A1 a hybrid module for a drive train of a vehicle is known, with a wet multi-plate clutch of the hybrid module in the torque flow between an internal combustion engine and an electric motor coaxially arranged with the hybrid module and a further wet multi-plate clutch of the hybrid module in the torque flow between the Electric motor and a motor vehicle transmission are arranged in the drive train. A dual-mass flywheel and a centrifugal pendulum for torsional vibration damping are coupled in the direction of force flow between the multi-disc clutch.

There is a constant need to reduce the installation space of hybrid modules.

It is the object of the invention to show measures that enable a hybrid module with a small footprint.

The object is achieved according to the invention by a clutch unit with the features of claim 1. Preferred embodiments of the invention are specified in the subclaims and the following description, each of which can represent an aspect of the invention individually or in combination.

According to the invention, a clutch unit for coupling a motor shaft of an internal combustion engine with a rotor of an electrical machine is provided with a dual-mass flywheel for damping torsional vibrations, the dual-mass flywheel having a primary mass that can be directly or indirectly connected to the motor shaft and an energy designed in particular as a bow spring - Storage element has limited rotatable secondary mass, the secondary mass having a tangential stop on the energy storage element output flange, and a, in particular designed as a plate clutch, friction clutch for coupling the secondary mass to the rotor of the electrical machine, the output flange having a friction surface for frictional contact with a with the rotor can be coupled axially displaceable clutch disc of the friction clutch forms.

The friction clutch can couple a motor shaft of an internal combustion engine with an inter mediate shaft to which the rotor of the electrical machine is coupled. In particular, the intermediate shaft already represents a rotor shaft that is non-rotatably connected to the rotor. The intermediate shaft, in turn, can be coupled to at least one transmission input shaft of a motor vehicle transmission. The motor shaft can have rotational uniformities due to the type of generation of the torque in the internal combustion engine, which are to be damped by the dual mass flywheel. This makes use of the knowledge that the energy storage element for damping the rotational irregularities in the torque coming from the internal combustion engine should be operated in a frequency range in which the energy storage element must be made as long as possible and therefore, for example in the form of an arc spring, on a possible large radius should be arranged. As a result, space can be created radially within the energy storage element construction, which can be used at least partially by the friction clutch. The friction clutch can thereby be positioned axially offset to the electrical machine, so that the installation space around the intermediate shaft can be used for other components. In particular, it is possible to couple the intermediate shaft to a first transmission input shaft and / or a second transmission input shaft of a double clutch transmission via a double clutch, which has two, preferably wet, multi-plate clutches in particular, despite otherwise tight installation space conditions. As a result of the friction clutch shifted from the space required for the double clutch around the intermediate shaft, installation space can be saved in the area of the electrical machine and a double clutch which is structurally simple to implement can be provided. In addition, the friction clutch can utilize otherwise free installation space of the dual-mass flywheel, so that the axial installation space requirement can be reduced. Since the initial flange of the secondary mass forms a counterplate of the friction clutch at the same time, so that the clutch disc can be pressed against the friction surface of the output flange, a separate counterplate can be saved, whereby the axial installation space requirement is additionally reduced. By integrating the output flange as a friction partner in the friction clutch, otherwise free space of the dual mass flywheel can be used for the friction clutch, so that a hybrid module with a small footprint is possible.

In a pulling mode, the torque coming from a motor vehicle engine can be introduced into the primary mass, while in a pushing mode the torque coming from the drive train can be introduced into the secondary mass, whereby the reverse installation is also possible, in a pulling mode that of the motor vehicle engine The torque coming from the drive train can be introduced into the secondary mass, while in overrun mode the torque coming from the drive train can be introduced into the primary mass. The primary mass and the secondary mass coupled to the primary mass via the energy storage element designed in particular as an arc spring so that it can rotate to a limited extent can form a mass-spring system which, in a certain frequency range, has rotational irregularities in the speed and in the torque of the drive power generated by a motor vehicle engine can dampen. The mass moment of inertia of the primary mass and / or the secondary mass and the spring characteristic of the energy storage element can be selected in such a way that vibrations in the frequency range of the dominant engine orders of the motor vehicle engine can be dampened. The mass moment of inertia of the primary mass and / or the secondary mass can in particular be influenced by an attached additional mass. The primary mass can have a disk, to which a cover can be connected, whereby a substantially annular receiving space for the energy storage element can be limited. The primary mass can, for example, tangentially strike the energy storage element via impressions protruding into the receiving space. An output flange of the secondary mass can protrude into the receiving space, which flange can strike tangentially at the opposite end of the energy storage element. In particular, the friction surface is provided in a radius region of the output flange that is bent away from the rotor. A gap that arises between the primary mass and the output flange can thereby be minimized, as a result of which the installation space that can be used for the friction clutch, in particular radially inside the energy storage element, can be increased. As a result, the friction clutch can be nested to a greater extent in the axial direction in the Zweimas senschwungwheel, whereby the axial space requirement can be further reduced.

Preferably connected to the output flange is a clutch cover for the axial, in particular special pivotable, support of an actuating element designed in particular as a lever spring pivotable about a pivot axis running in the circumferential direction, for moving a pressure plate for axially pressing the clutch disc between the pressure plate and the output flange. The clutch cover, which is connected in particular radially inside to the energy storage element with the output flange of the secondary mass, can easily be guided past the energy storage element. The components of the friction clutch can be retained between the output flange and the clutch cover in a captive manner. In particular, the output flange and the friction clutch can be installed inexpensively and quickly as a common preassembled unit in the clutch assembly. The axial forces occurring in the friction clutch can be absorbed on the one hand by the output flange and on the other hand by the clutch cover and can be mutually supported.

Particularly preferably, the primary mass and / or the secondary mass delimit an annular receiving space for receiving the energy storage element, with a relatively rotatable sealing membrane that can be slid off the primary mass to seal the receiving space from the friction clutch with the output flange, in particular the sealing membrane and the cup treatment cover are fastened to the output flange via a common fastening means. In particular, a lubricant, for example lubricating grease, is provided in the receiving space, with the aid of which the energy storage element can be lubricated. The receiving space can be sealed off by the sealing membrane to such an extent that the lubricant cannot reach the friction clutch, which as a result, it can be operated dry and with a high coefficient of friction compared to a wet and / or lubricated friction clutch. A sudden drop in the maximum possible torque to be transmitted from the friction clutch due to lubricant accidentally getting into the friction clutch can thus be avoided.

In particular, the clutch disc has an output hub for rotationally fixed but axially displaceable coupling with the rotor of the electrical machine, the output hub having at least one assembly opening for introducing a tool for fastening the primary mass to an input shaft using a connec tion means. The axially displaceable clutch disc can be coupled to the intermediate shaft in a rotationally fixed manner via the output hub. The mounting opening can ensure that the primary mass can be attached directly or indirectly to a motor shaft, in particular a crankshaft, of the internal combustion engine when the clutch unit is mounted. The friction pairings of the Rei friction clutch can be provided radially outside of the assembly opening.

The primary mass preferably has at least one fastening opening for fastening the primary mass to an input shaft with the aid of a connecting means, with the secondary mass, in particular the output flange, being mounted radially inside the fastening opening on the primary mass directly or indirectly via a bearing, with the secondary mass has at least one through opening for introducing a tool for fastening the primary mass with an input shaft with the aid of the connecting means. As a result, the secondary mass can be mounted on the primary mass on a comparatively small radius, so that a correspondingly inexpensive mount can be used. The bearing is designed in particular as a deep groove ball bearing. The secondary mass can, in particular, be mounted on the primary mass to prevent it from tipping over. A simple assembly of the clutch assembly can be ensured through the through opening when the primary mass is to be connected to the input shaft, in particular a cure shaft of a motor vehicle engine. Particularly preferably, the primary mass has at least one fastening opening for fastening the primary mass to an input shaft using a connec tion means, the secondary mass, in particular the output flange, being mounted radially outside the fastening opening on the primary mass directly or indirectly via a bearing. By mounting the secondary mass radially outside half of the fastening opening, a through opening in the secondary mass which is aligned with the fastening opening can be saved. The bearing is designed in particular as a deep groove ball bearing. The secondary mass can, in particular, be mounted on the primary mass to prevent it from tipping over.

In particular, the bearing is designed as a plain bearing or roller bearing, in particular a deep groove ball bearing. Tilting of the secondary mass out of a radial plane of the clutch assembly can be avoided. The bearing is preferably designed to absorb both radial forces and axial forces. The bearing can thereby also specify an axial relative position of the secondary mass to the primary mass.

The friction clutch is preferably arranged radially inside to the energy storage element, in particular the friction clutch being arranged at least partially in a common axial area with the energy storage element. Viewed in the axial direction, the energy storage element and the friction clutch can at least partially overlap. The friction clutch can thereby be positioned at least partially nested in the dual mass flywheel. The axial installation space can thus be kept small.

Particularly preferably, the primary mass has at least one fastening opening for fastening the primary mass to an input shaft with the aid of a connec tion means, with a sealing element, in particular designed as a slide bearing or axial ring, in a sealing manner on the primary mass and the output flange, radially outside of the fastening opening Sealing of a limited by the primary mass and / or the secondary mass receiving space is provided for receiving the energy storage element. As a result, the receiving space can be sealed well, in particular together with the sealing membrane. A leakage of lubricant from the exception space radially inward can thereby be avoided. This can prevent lubricants from getting on the friction pair the friction clutch and influenced the friction properties of the friction clutch.

The invention is explained by way of example with reference to the accompanying drawings using preferred exemplary embodiments, the features shown below being able to represent an aspect of the invention both individually and in combination. Show it:

Fig. 1: a schematic sectional view of a first embodiment of a hitch treatment unit and

Fig. 2: a schematic sectional view of a second embodiment of a hitch treatment unit.

The clutch assembly 10 shown in Fig. 1 is provided, for example, for torsionally damped coupling of a motor shaft of a motor vehicle engine with an intermediate shaft 12 leading to a rotor of an electrical machine. The clutch assembly has a dual mass flywheel 14 for torsional vibration damping, which has a primary mass 16 that can be fastened to the motor shaft. The primary mass 16 delimits an annular receiving space 18 in which an energy storage element 20 designed as a bow spring is received. The primary mass 16 can, for example, tangentially strike one end of the energy storage element 20 via inwardly protruding impressions. At the other end of the energy storage element, an output flange 22 of a secondary mass 24 that can be rotated to a limited extent relative to the primary mass 16 can strike tangentially.

The output flange 22 forms a friction surface 26 for a friction clutch 28 in a radius region that is bent away from the intermediate shaft 12. The output flange 22 can thereby simultaneously form a counterplate of the friction clutch 28 to which an axially displaceable pressure plate 30 can be frictionally pressed via an output hub 32 on the intermediate shaft clutch disc 34 non-rotatably attached. For the axial displacement of the pressure plate 30, a feather spring 34 designed in the manner of a plate spring is provided, which is attached to a clutch cover 36 riveted to the output flange 22 about a pivot point extending in the circumferential direction by changing its co- nicity is pivotably supported. Together with the intermediate flange 22 and the clutch cover 36, a sealing membrane 38 is riveted which, via a sliding ring 40, lies sealingly against a welded-on cover 42 of the primary mass 16 with spring preload.

The primary mass 16 has a fastening opening 44 into which a connecting means 46 designed as a screw can be inserted in order to fasten the primary mass 16 to the motor shaft of the motor vehicle engine. In order to be able to apply a tool to the connecting means 46 for this purpose, the output hub 32 and, if necessary, also the lever spring 34 have assembly openings 48.

In the embodiment shown in Fig. 1, the secondary mass 24 is radially inner half to the mounting opening 44 on the primary mass 16 via a bearing 50 gela Gert and centered. The bearing 50 is designed, for example, as a deep groove ball bearing, wherein the bearing 50 can alternatively also be designed as a slide bearing, in particular as a radial and axial slide bearing. The bearing can prevent the secondary mass 24 from tilting and in particular the friction surface 26 from a radial plane of the coupling unit 10 from tilting and can support both radial forces and axial forces. In order to maintain the accessibility of the connecting means 46 for the tool, the secondary mass 24 can have a through-opening 52 which is coaxially aligned with the fastening opening 44. Optionally, the receiving space 18 is radially outside half of the fastening opening 44 via a on the primary mass 16 and the secondary mass 24 axially adjacent axial ring, not shown, sealed radially inward from.

In the embodiment of the clutch assembly 10 shown in FIG. 2, in comparison to the clutch assembly 10 shown in FIG. 1, the secondary mass 24 is mounted radially outside of the fastening opening 44 on the primary mass 16. The bearing 50 is configured, for example, as a radial and axial sliding bearing, wherein the bearing 50 can alternatively also be configured as a roller bearing, in particular as a deep groove ball bearing. To support radial forces of the bearing 50, a centering piece 54 is connected to the primary mass 16 with the aid of the connecting means 46. The bearing 50 can in particular also fulfill a sealing function, so that the receiving space 18 is sealed radially inward by the bearing 50. Reference symbol list centering piece

Intermediate shaft

Dual mass flywheel

Primary mass

Recording room

Energy storage element

Outlet flange

Secondary mass

Friction surface

Friction clutch

Pressure plate

Output hub

Lever spring

Clutch cover

Sealing membrane

Slip ring

cover

Mounting hole

Lanyard

Assembly opening

camp

Through opening

Centering piece

Claims

Claims

1 . Clutch unit for coupling a motor shaft of an internal combustion engine with a rotor of an electrical machine, with a dual mass flywheel (14) for damping torsional vibrations, the dual mass flywheel (14) having a primary mass (16) that can be directly or indirectly connected to the motor shaft and a primary mass (16), in particular As an arc spring, the energy storage element (20) has a limited rotatable secondary mass (24), the secondary mass (24) having an output flange (22) that can be tangentially abutted on the energy storage element (20), and a friction clutch (28) designed in particular as a plate clutch ) for coupling the secondary mass (24) to the rotor of the electrical machine, the output flange (22) forming a friction surface (26) for frictional contact with an axially displaceable clutch disc (34) of the friction clutch (28) that can be coupled to the rotor.

2. Clutch assembly according to claim 1, characterized in that the friction surface (26) is provided in a radius region of the output flange (22) that is bent away from the rotor.

3. Clutch assembly according to claim 1 or 2, characterized in that with the output flange (22) a clutch cover (36) for the axial, in particular pivotable, support of an actuating element, in particular as a lever spring (34) pivotable about a pivot axis running in the circumferential direction for moving a pressure plate (30) for axially pressing the clutch disc (34) between the pressure plate (30) and the output flange (22).

4. Coupling unit according to one of claims 1 to 3, characterized in that the primary mass (16) and / or the secondary mass (24) is an annular Bounding the receiving space (18) for receiving the energy storage element (20), a relatively rotatable sealing membrane (38) which can be slid off the primary mass (16) to seal off the receiving space (18) from the friction clutch (28) with the output flange (22) is connected, in particular the sealing membrane (38) and the clutch cover (36) via a common fastening means with the output flange (22) are attached.

5. Clutch assembly according to one of claims 1 to 4, characterized in that the clutch disc (34) has an output hub (32) for rotationally fixed but axially displaceable coupling to the rotor of the electrical machine, the output hub (32) having at least one mounting opening (48 ) for introducing a tool for fastening the primary mass (16) to an input shaft with the aid of a connecting means (46).

6. Clutch assembly according to one of claims 1 to 5 characterized in that the primary mass (16) has at least one fastening opening (44) for fastening the primary mass (16) to an input shaft with the aid of a connecting means (46), the secondary mass (24), in particular the output flange (22), is mounted radially inward of the fastening opening (44) on the primary mass (16) directly or indirectly via a bearing (50), the secondary mass (24) having at least one through opening (52) for introducing a tool for fastening the primary mass (16) to an input shaft with the aid of the connecting means (46).

7. Clutch assembly according to one of claims 1 to 5 characterized in that the primary mass (16) has at least one fastening opening (44) for fastening the primary mass (16) to an input shaft with the aid of a connecting means (46), the secondary mass (24), in particular the output flange (22), is mounted radially outside the fastening opening (44) on the primary mass (16) directly or indirectly via a bearing (50).

8. A clutch unit according to claim 6 or 7, characterized in that the bearing (50) is designed as a plain bearing or roller bearing, in particular a deep groove ball bearing.

9. Clutch assembly according to one of claims 1 to 8, characterized in that the friction clutch (28) is arranged radially inside to the energy storage element (20), in particular the friction clutch (28) at least partially in a common axial area with the energy storage element (20) ) is arranged.

10. Clutch assembly according to one of claims 1 to 9 characterized in that the primary mass (16) has at least one fastening opening (44) for fastening the primary mass (16) to an input shaft with the aid of a connecting means (46), being radially outside to the fastening opening (44) a sealing element, in particular designed as a plain bearing or axial ring, sealingly adjacent to the primary mass (16) and the output flange (22), for sealing off a sealing element delimited by the primary mass (16) and / or the secondary mass (24) Receiving space (18) is provided for receiving the energy storage element (20).