DE102012219546A1 - Multi-disk clutch, particularly axially disposed double clutch, has outer disk carrier that has hub component, disk carrier pot and disk hinging component, where hub component is provided with drive side or output side of multi-disk clutch - Google Patents

Abstract

The multi-disk clutch has an outer disk and an inner disk, which are brought into frictional engagement with each other for transmission of torque. The outer disk carrier has a hub component, a disk carrier pot and a disk hinging component. The hub component is provided with a drive side or an output side of the multi-disk clutch for connecting the multi-disk clutch. The disk hinging component and the disk carrier pot are adjusted to rotationally connect with each other in the frame of the mounting of the multi-disk clutch.

Description

The present invention relates to a multi-plate clutch with an outer disk carrier for at least one outer disk and an inner disk carrier for at least one inner disk, wherein outer disk and inner disk for transmitting torque in frictional engagement can be brought together.

The present invention also relates to a dual clutch with axially one behind the other arranged single clutches for a dual clutch transmission in a drive train of a vehicle, with a drive side arranged single clutch, a transmission side arranged single clutch, a driven clutch housing or with radially nested single clutches, wherein a first of the individual clutches with the clutch housing a first transmission input shaft and a second of the single clutch, the clutch housing connects to a second transmission input shaft switchable.

In particular, the present invention relates to a built outer disk carrier for wet double clutches to reduce the required radial space, the mass moment of inertia and weight as well as enabling the use of identical lining plates on the single clutch K1 and K2 of the dual clutch.

Double clutch with axially successively arranged and hydraulically actuated (operable) individual clutches for a dual clutch transmission in a drive train of a vehicle, with a drive side arranged single clutch, a transmission side arranged single clutch, a driven clutch housing and two piston-cylinder units, wherein a first of the individual clutches the clutch housing with a first transmission input shaft and a second of the individual clutches the clutch housing connects switchable with a second transmission input shaft.

From the DE 38 19 702 A1 is a Doppelnasskupplung with axially successively arranged individual clutches known, wherein the hydraulic actuators are arranged axially before or axially after the individual clutches and on a same diameter as the individual clutches. The axial space requirement for this double wet clutch is comparatively large.

In the case of dual clutches, the torque of the respective partial clutches (also referred to as "single clutches" in the context of the present invention) is transmitted frictionally via their steel and lining disks. The torque is added or removed via plate carrier to the steel or lining plates. Such wet double clutches are eg from the DE 10 2006 048 340 A1 or the DE 10 2011 009 419 A1 known. As a rule, a toothing on the slats and disc carriers is present here. In the case of the disk carriers, a distinction is made between outer and inner disk carriers (abbreviated to "ALT" for output disk carrier and "ILT" for inner disk carrier in the following), depending on their radial arrangement with respect to the disks. Depending on the clutch arrangement, the torque supply can take place both via the "ILT" and the "ALT". The removal then takes place through the respective counterpart. From the DE 10 2011 009 419 A1 is a wet dual clutch known, the moment is introduced here in each case via ILT's in the partial clutches K1 and K2 partial clutch. The output of the K1 takes place via the ALT of the K1 and the output K2 via the ALT of the K2. ALT of the K1 and ALT of the K2 are nested for reasons of mountability. The lining discs of K1 and K2 differ here, despite the same pad diameter, in the outer diameter (toothing).

The disadvantages of this arrangement are the large radial space requirement due to nesting ALT K1 and ALT K2 and the large moment of inertia and the large weight, in particular the ALT of K1 due to its large diameter and projecting length. Since the ALT of the K1 is connected to the transmission input shaft, this leads to high moments in the synchronization of the transmission, which leads to comfort and dynamic disadvantages in circuits. Another disadvantage is the large moment of inertia and the large weight of the lining plates due to the large support plates (steel parts), resulting in more comfort and dynamic disadvantages. Furthermore, different lining plates must be used in the part coupling K1 and K2, which increased costs.

It is therefore an object of the present invention to provide a multi-plate clutch and preferably also an axially arranged double clutch with reduced radial space, which further preferably also has a reduced moment of inertia and weight and more preferably also allows the use of identical lining plates on the individual clutch K1 and K2 of the double clutch ,

This object is achieved by a multi-plate clutch with the features of the corresponding independent claims 1, 2, 4 and 5 and a dual clutch with the features of the corresponding independent claim 10. Preferred embodiments are the subject of the respective dependent claims.

The present invention will be explained in more detail below with reference to preferred embodiments in conjunction with the accompanying figures. In these show:

1 a basic arrangement of the double clutch according to the invention,

2 A first embodiment with actuating direction of both individual clutches in the direction of transmission,

3 a further embodiment with actuating direction of both single clutches in opposite directions,

4 a further embodiment of an axially constructed double wet clutch with a first embodiment of a built outer disk carrier, which is present at the same time the output disk carrier of the clutch K1,

5 a first connection variant between ALT pot and plate carrier component with retaining ring in a machined groove,

6 Another connection variant between ALT pot and plate carrier component with retaining ring in a tool-falling "groove",

7 Another connection variant between ALT pot and plate carrier component with claws in the ALT pot, which are caulked radially inwards,

8th Another connection variant between ALT pot and plate carrier component with claws in the ALT pot, which are caulked radially inwards,

9 Another connection variant between ALT pot and plate carrier component with tabs on claws in the ALT pot, which are caulked radially inwards,

10 Another connection variant between ALT pot and plate carrier component with tabs on claws in the ALT pot, which are caulked radially inwards,

It is 1 schematically a drive train of a vehicle with a drive 1 , a dual-clutch transmission 2 and one between drive 1 and dual clutch transmission 2 arranged dual clutch device 3 refer to. That from the drive 1 Torque (preferably an internal combustion engine or an electric drive or a combination of internal combustion engine and electric drive) is generated via the clutch housing 4 around the dual clutch assembly 3 routed around and to a clutch hub 5 transfer. The clutch hub 5 is with an input disk carrier 6 the first single clutch K1 and an input disc carrier 7 a second single clutch K2 connected. The individual clutches K1 and K2 comprise disc packs (in 1 not shown in detail), which each consist of at least one input side friction plate and an output side friction plate. The output side friction plates are equipped with an output plate carrier 8th for the single clutches K1 and an output plate carrier 9 connected for the single clutch K2. About the controls 10 and 11 the input-side and output-side friction plates can be brought into frictional contact with each other, wherein the respective actuating force and the direction of the actuating force on the force vector arrow F _K1 and F _K2 for the individual clutches K1 and K2 1 are removable. The output disk carrier 8th and 9 are with the two transmission input shafts 12 and 13 connected to the dual clutch transmission. In 1 is the major axis of the dual clutch assembly 3 with the reference A shown.

Furthermore, in 1 the subarea 4a the coupling housing symbolically highlighted to show that in the present wet-running dual clutch with axially arranged partial clutches (single clutches), the actuating force of the partial clutch K1 is supported via a component which simultaneously introduces the drive torque in the clutch system. The clutch housing thus fulfills a double function in the present case.

About the also symbolically highlighted area 14 should also be clarified that a support of the operating force of the clutch K2 on the additional component 14 takes place, which is essentially independent of the support 4a on the clutch housing 4 is. This prevents the partial clutches K1 and K2 from influencing each other during operation (crosstalk behavior).

The partial clutches could thereby be actuated in the direction of the drive or in the direction of the transmission (although this is not shown in the figures).

It would also be conceivable to have an arrangement in which the partial clutches K1 and K2 are actuated from the inside to the outside, as described below 3 explained. In this case, then the actuators of the partial clutches are located axially between the disk packs. When actuated in opposite directions, it is also possible to form the pressure chambers of the actuators by a common seal carrier, which carries the piston seal for both partial couplings.

It is already the schematic representation of 1 removable, that the coupling housing 4 can be designed as a coupling pot with integrally formed support for supporting the axial actuating force.

In addition, the schematic representation of the 1 removable, that the inner input disk carrier are connected to the clutch hub.

Furthermore, the schematic representation of the 1 removable, that also the additional support element 14 can be connected to the clutch hub.

In 2 a detailed construction is shown in which the actuating forces the in 1 represented force vectors F _K1 and F _K2 correspond. It shows 2 a half-section corresponding to the main coupling axis A. The coupling housing 4 is here in two parts from a clutch pot with the bottom area 4a and the cylindrical wall portion 4b and a driving plate 4c illustrated, wherein the driving plate 4c and the cylindrical wall area 4b positively connected with each other rotatably and axially via a locking ring 15 are secured. The floor area 4a , which also serves to support the axial operating force of the clutch K1, is provided with an output member 16 firmly connected, via which a pump for conveying the hydraulic medium can be driven. The component 16 has a corresponding toothing 16a for transmitting torque to a hydraulic pump. The component 16 further comprises a radially inner axial toothing, for connection to a clutch hub 17 , The between the component 16 and clutch hub 17 provided axial splines could also be replaced by a feather key or another torque-transmitting connection. This axial spline or more similar connection is in the present case via a retaining ring or a similar securing device, for example a shaft nut 18 secured.

2 also shows the input disc carrier 6 the partial clutch K1, wherein the input disk carrier 6 in the present case with the component 16 is connected, so that a torque transmission directly through this component 16 he follows. Alternatively, the input disk carrier could 6 also on the clutch hub 17 be arranged.

2 also shows the input disc carrier 7 Partial coupling K2, directly on the clutch hub 17 is connected. Between the input disk carrier 7 the partial clutch K2 and a shoulder on the clutch hub 17 is the additional support component 14 arranged. It is sufficient that the additional component 14 against rotation and against displacement in the direction of the transmission with respect to the clutch hub 17 is supported. An additional axial fixation in the direction of the drive is not mandatory in the present case. support component 14 and input disk carrier 7 could also be integrally formed.

According to a particularly preferred embodiment, the drive disk carrier designed as an inner disk carrier are in each case rotationally fixed to the rotor (= clutch hub 17 ) connected. The respective support sections 14 and 4a are also with the rotor 17 connected, but have no positive and positive connection with the inner disk carriers. The support section of the K2 (gutter 14 ) is radially centered on the rotor and supports the axial forces occurring during clutch actuation on a shoulder of the rotor. Since no torques have to be transmitted here, there is no need for the gutter 14 rotatably connected to the rotor, which is why this has been omitted. The support section 4a the K1 is removed from the drive pot 4 educated. The drive pot 4 conducts over the impeller 16 the motor torque in the rotor 17 one. When actuating the K1 transmits the drive pot 4 Torque and axial force. For this reason, the drive pot 4 radially on the impeller 16 centered, axially supported on the impeller shoulder and is rotationally fixed with the impeller 16 connected.

When operating the partial clutches K1 or K2 only the support sections 4a respectively. 14 the partial clutches K1 and K2 axially deformed. The respective drive plate carrier 6 respectively. 7 are thus axially unloaded and undeformed. Thus, the function of the torque transfer is given to the steel plates with simultaneous axial displacement of the slats in all operating conditions.

This would no longer be the case if the radially extending support section and the inner drive plate carrier were firmly connected. Torques in the direction of rotation as well as moments transverse to the direction of rotation would then be transmitted via the connection. Upon actuation of the coupling, the support portion would then deform plate-shaped due to the introduced axial force and its finite rigidity. In a solid connection between the support portion and inner disk carrier, then the inner disk carrier would be charged by the introduced axial force and deformed. The resulting, conical deformation in the direction of rotation would then lead to the head play between the suspended in the inner disc carrier steel plates and the inner disc carrier is zero. As a result, the steel plates would then jam on the inner plate carrier and would not be more force-free axially displaceable. As a result, this would lead to a loss of torque capacity, because a portion of the axially initiated operating force in the form of axial displacement forces of the steel plates "lost" would go.

At the clutch hub 17 are also sealing sheets 19 and 20 arranged, which act as a seal carrier for the two hydraulic piston-cylinder units for actuating the partial clutches K1 and K2. Between the sealing sheets 19 and 20 and actuating piston 21 and 22 the partial clutch K1 and K2 and corresponding portions of the lateral surfaces of the clutch hub 17 become the pressure chambers 23 and 24 educated. These pressure chambers 23 and 24 be via the clutch hub 17 and an internal Ölzuführ- and support member 25 supplied with hydraulic medium. Between this inner support member 25 and the clutch hub 17 are at least two radial bearings 26 and 27 and arranged a plurality of sealing elements.

In the present case, the actuating piston 21 and 22 via spring elements 28 and 29 in the direction of "clutch open" biased (although, however, a preload in the direction "clutch closed" at least one of the clutches is conceivable, resulting in energy benefits). The present case designed as coil springs spring elements 28 and 29 are each on a support member 30 and 31 supported. This component 30 and 31 turn is at the corresponding input disk carrier 6 respectively. 7 axially supported. In the present embodiment, these support plates 30 and 31 identical (identical parts).

The actuating piston (hereinafter also referred to as "pressure pots"), which introduce the respective engagement force of the clutches K1 and K2 in the disk pack, could be made in two parts, such as already from the US 2006/0086586 A1 known. The radially inner part of this two-part actuating piston in each case represents the actual "piston" and has on the outer and inner diameter (piston) seals. Furthermore, these pistons have a collar region which provides a seal running surface. The seal required in this case is located in each case as an insert in a groove cut into the rotor. The radially outer part of these two-part actuating piston initiates the engagement force in the disk set and could be referred to as a "pressure piece". At the pressure pieces each seals are arranged for the Fliehölausgleich.

• – Aufgrund der einteiligen Ausführung des Drucktopfes verkürzt sich die Toleranzkette über den Drucktopf um mindestens eine Toleranz (Bauraumvorteil);
• – Identische Drucktöpfe (Gleichteile) für beide Teilkupplungen; für eine Serienfertigung des Blechteils wird nur ein Werkzeugsatz benötigt; Auch für die Anvulkanisation der Dichtungen wird nur ein Werkzeug benötigt;
• – Die Kolbendichtungen befinden sich an den Drucktöpfen; dadurch besteht keine Notwendigkeit in umgebende Bauteile zusätzliche Dichtungsnuten einzustechen; die Montage der Drucktöpfe ist einfacher; eine Falschmontage ist ausgeschlossen;

Like the one already 2 and 3 can be removed, in contrast to the present case described immediately above, it is preferred to form the pressure pots from a component. The above-described functions of pressure piece and piston are thus combined in one component. The seal for the centrifugal oil compensation and the radially inner piston seal are vulcanised onto the (integral) pressure pot. Become like that 2 and 3 removable, identical positions of the pressure oil supply provided for both partial clutches, so for K1 and K2 each of the same pressure pot can be used (see 2 and 3 ). In the embodiment described above, the following advantages result:

• - Due to the one-piece design of the pressure pot, the tolerance chain on the pressure pot is shortened by at least one tolerance (space advantage);
• - identical pressure pots (identical parts) for both partial couplings; for series production of the sheet metal part only one set of tools is needed; Even for the vulcanization of the seals only one tool is needed;
• - The piston seals are located on the pressure pots; there is no need to pierce additional sealing grooves in surrounding components; the assembly of the pressure pots is easier; a wrong assembly is excluded;

In the present case, the pressure pots are designed in such a way that the flow cross section of the associated cooling oil supply lines is not impaired even at maximum travel distances of the pressure pots of both partial couplings. If the pressure pot partially moved over the bore of the cooling oil supply during actuation, the flow cross-section would decrease and influence the flow behavior of the clutch.

The in the 2 and 3 shown support components 30 and 31 for the springs 28 and 29 fulfill even more functions: the cooling oil guide and the centrifugal oil guide. Thus, in the present embodiment, the cooling oil supply is identical in both partial clutches. The flow behavior is therefore identical. In addition, the overflow edge of the oil deflector is located directly above the respective cooling oil supply and thus assumes the function of a flow divider. Part of the cooling oil is fed directly into the centrifugal oil chamber, so that there is an ideal filling of the centrifugal oil chamber in each operating state of the coupling. The other part of the cooling oil is fed directly to the coupling between the oil guide plate and the inner plate carrier.

The torque which can be transmitted via the disk packs of the partial clutches K1 and K2 when a corresponding actuating force is applied is transmitted via the output disk carrier 32 and 32 to the in 2 not shown in detail transmitted transmission input shafts, wherein in this case the transmission input shafts as a solid shaft and hollow shaft are formed and arranged concentrically with each other.

At the in 2 In the embodiment shown, the individual clutches are acted upon by an actuating force, ie, in both cases in the direction of the transmission, the actuating force of the gear-side sub-clutch K1 on the clutch pot and the actuating force of the drive-side sub-clutch K2 on a separate support element, wherein the support element 14 does not form part of the piston-cylinder unit of the associated single clutch and possibly with the input disk carrier 7 could be formed integrally.

In the axial direction is the in 2 Coupling shown via axial bearings between driving plate 4c and output plate carrier 32 and between the output disk carrier 32 and output plate carrier 33 and between the output disk carrier 33 and end face of the clutch hub 17 in conjunction with the fuse element 18 braced. Furthermore, the internal component 25 supported either via one of the transmission input shafts or via a connection to the clutch bell.

In 3 a further embodiment of the present double clutch is shown, wherein below essentially only the differences from the above dictated embodiments will be described. The same components are designated by the same reference numerals.

The double clutch according to the embodiment according to 3 in turn, includes a clutch housing 4 ' However, although the driving plate on the transmission side and the coupling pot were arranged on the drive side, so in this case a "reflection" of the clutch housing consisting of driving plate and clutch pot is provided. In this mirrored arrangement, the support area of the actuating force of the transmission side arranged partial clutch K1 is then no longer in the bottom area 4a but on the driving plate 4c educated.

According to the embodiment according to 3 In addition, the input disk carrier is modified by having only one disk receiving area 6a ' includes, which with the driving plate 4c ' connected so that the driving plate 4c ' at the same time the lamellar receiving area 6a ' on the clutch hub 17 ' supported. As an alternative to this example of an integral design of driving plate and input disk carrier and an input disk carrier according to the embodiment according to could 2 be used, in which case the input disk carrier and driving plate has an independent radially extending portion for connection to the clutch hub 17 , possibly with the interposition of a Pumpenabtriebsbereiches comparable to the component 16 in 2 would include.

At the clutch hub 17 is also a support plate 14 ' arranged, which in this case at the same time the support region of the input disk carrier 7 the partial clutch K2 forms. In the present case, therefore, once again only one lamella holding area 7a ' necessary, which with the support plate 14 ' connected is. Again, alternatively, an input disk carrier according to the embodiment according to 2 separately to the support plate 14 ' be provided.

The actuating force is via the actuating piston 21 and 22 transferred to the disk sets of the partial clutches K1 and K2, wherein the actuating piston 21 and 22 with a common seal carrier 34 (The present two separate gaskets 21 and 22 according to 2 replaced) together with portions of the lateral surface of the clutch hub 17 ' the pressure chambers 23 and 24 form.

The actuating pistons 21 and 22 are according to the embodiment according to 3 arranged axially between the individual clutches K1 and K2 and act in opposite directions, so that according to the embodiment according to 3 the actuating force of the transmission-side partial clutch K1 acts in the direction of the transmission and the actuation force of the drive-side arranged partial clutch K1 acts in the direction of the drive. The common seal carrier 34 is here as a separate and with the clutch hub 17 ' formed connected component, wherein a sealing element is provided to the pressure chambers 23 and 24 to deny each other. The remaining features of this embodiment 3 correspond with the related 1 and related to 2 shown.

This in 2 shown embodiment thus shows the operation of both partial clutches in the direction of the transmission, wherein alternatively, an operation of both partial clutches in the direction of the engine is possible. When actuated in the direction of the gearbox, the support of the axial actuating force of the transmission-side part clutch via the bottom portion of the coupling pot. Upon actuation of both partial clutches in the direction of such support would not take place on the clutch pot but on another support element or possibly also directly on one of the output disk carrier.

According to the embodiment according to 3 the actuation of the two partial clutches takes place in the opposite direction, wherein the actuating piston axially between the two Part clutches are located. The two actuating pressure chambers can be formed by a common seal carrier.

The embodiments of the 1 to 3 is therefore common that the drive of the dual clutch device and the support of the actuating forces or one of the partial clutches on the drive pot and that the actuation force of the corresponding other partial clutch via a separate component, whereby crosstalk of the two partial clutches is prevented. The actuation can take place in the direction of the transmission and / or in the direction of the engine. Accordingly, there is the possibility of the partial clutches "from the inside to the outside", ie according to the structure according to 3 to operate, wherein the partial clutch K1 is actuated in the direction of the transmission and the partial clutch K2 in the direction of the engine and wherein the actuating piston are arranged axially between the two partial clutches. In this operation of the partial clutches from "inside out" the operating pressure chambers of the partial clutches can be formed by a common seal carrier, whereby a further integration of the components is made possible.

In 4 is a further embodiment of an axially constructed double wet clutch shown with a first embodiment of a built outer disk carrier 100 , Which is present at the same time the output disk carrier of the clutch K1. Otherwise, the embodiment corresponds to 4 according to the embodiment 1 and 2 , Insofar as these same features in the drawing according to 4 are shown, the same reference numerals have been used. For reasons of clarity, but a part of the matching components of the double clutch from the drawing after 4 hidden.

As a result, the drawing is after 4 on the built outer plate carrier (ALT) 100 the K1 concentrated, consisting of a welded into the ALT pot hub 101 , the ALT pot 102 and the plate carrier component 103 shown. The plate carrier component 103 and the ALT pot 102 can be releasably or permanently connected to each other in the context of assembly of the overall unit. The ALT pot 102 has for this purpose axially in the direction of gear extended claws 108 which are in radially extended claws 111 on the plate carrier component 103 engage, so that when mounting a positive connection results in the transmission of torque. The diameters and toothings of the plate carrier component 103 the K1 and the plate carrier 33 The K2 are identical ("small"), which leads to a lower weight and moment of inertia and allows the use of identical lining blades. Furthermore, outside of the disk carrier K1 additional free space, which can be used to represent a catching ring.

This compound can be as follows in the 5 to 10 shown axially secured, so that there is a non-detachable connection.

Instead of the aforementioned jaw connection, another type of at least torque-transmitting connection can also be selected. Thus, the claw connection can be replaced for example by a spline, a welded joint, a riveted joint, a blind rivet, a direct caulking, screw o. Ä.

In the 5 and 6 There are two possible variations shown to the ALT pot 102 and the plate carrier component 103 over the claw connection 108 . 111 releasably connect with each other. This is basically both a releasable connection with retaining ring 104 as well as a permanent connection by caulking (as explained later) of the dog teeth possible. Here are in 5 a first connection variant between ALT pot 102 and plate carrier component 103 with a locking ring 104 in a chipped groove 105 and in 6 Another connection variant between ALT pot 102 and plate carrier component 103 with a locking ring 106 in a tool-falling "groove" 107 shown.

In the 7 and 8th is another connection variant between ALT pot 102 and plate carrier component 103 shown with claws 108 in the ALT pot 102 , which are caulked radially inward. It can also "only" a part of the claws 108 to be bent inwards and part of the claws 109 can be used "only" for torque transmission, as in 8th shown.

In the 9 and 10 is another connection variant between ALT pot 102 and plate carrier component 103 shown with tabs 110 on claws 109 ' in the ALT pot 102 , which are caulked radially inward.

• • ein gebauter ALT der K1, bestehend aus geschweißter Nabe, gezogenem ALT K1-Topf und damit lösbar oder unlösbar verbundenem Lamellenträgerbauteil K1.
• • Die Verzahnung des Lamellenträgerbauteils der K1 ist identisch zur Verzahnung des ALT der K2 und somit auf kleinem Durchmesser.
• • Die Belaglamellen der K1 und K2 sind identisch.
• • Ein Fangring ist bauraumneutral darstellbar.
• • Die Verbindung zwischen dem Lamellenträgerbauteil und dem ALT-Topf der K1 kann lösbar mit beispielsweise einem Sicherungsring ausgebildet werden,
• • Die Verbindung zwischen dem Lamellenträgerbauteil und dem ALT-Topf der K1 kann aber auch unlösbar beispielsweise durch Verstemmen ausgebildet werden,
• • Unterschiedliche Blechstärken der Einzelkomponenten sind möglich (Gewichts- und Massenträgheitsmoment-Reduktion), so dass eine verbesserte Anpassung der einzelnen Bauteile (Nabe, Topf und Lamellenträgerbauteil) an die jeweilige Belastung möglich ist.

From the above description, inter alia, objects and teachings result:

• • a built ALT of K1, consisting of welded hub, drawn ALT K1 pot and detachably or permanently connected plate carrier component K1.
• • The toothing of the plate carrier component of the K1 is identical to the toothing of the ALT of the K2 and thus on a small diameter.
• • The lining blades of K1 and K2 are identical.
• • A catching ring can be displayed in a space-neutral manner.
• • The connection between the plate carrier component and the ALT pot of the K1 can be released with be formed for example a circlip,
• • The connection between the plate carrier component and the ALT pot of K1 can also be formed insoluble, for example by caulking,
• • Different sheet thicknesses of the individual components are possible (weight and mass moment of inertia reduction), so that an improved adaptation of the individual components (hub, pot and plate carrier component) to the respective load is possible.

In particular, the present description is a double clutch with axially arranged couplings removed, with output via the outer disk carrier, wherein ALT K1 and ALT K2, for reasons of mountability, are nested. This would lead to different lining disks of the partial clutches K1 and K2, even with the same lining diameter (different carrier plates necessary) and in total to disadvantages with respect to space and inertia of the partial clutch K1. It is therefore proposed to use identical lining disks on partial coupling K1 and K2 as well as identical multi-disk toothing on the smallest possible diameter, which leads to lower weight and lower mass inertias. This is achieved via the above-described embodiment of the outer disk carrier of the K1. It also valuable space in the outer region of the clutch K1 is free, which allows the use of a snap ring and / or the connection between the drive pot and clutch cover.

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 3819702 A1 [0005]
• DE 102006048340 A1 [0006]
• DE 102011009419 A1 [0006, 0006]
• US 2006/0086586 A1 [0037]

Claims (9)

Multi-plate clutch having an outer disk carrier for at least one outer disk and an inner disk carrier for at least one inner disk, said outer disk and inner disk for transmitting torque are frictionally engagable with each other, characterized in that the outer disk carrier comprises a hub member, a disk carrier cup and a Lamelleneinhängbauteil, wherein the hub member to Connection of the multi-plate clutch is provided with a drive side or an output side of the multi-plate clutch, wherein the Lamelleneinhängbauteil has a form-fitting region which serves to rotatably connect the Lamelleneinhängbauteil with the associated fins, hub member and disc carrier pot are firmly connected to each other, and wherein Lamelleneinhängbauteil and slat carrier cup adapted are to be at least rotationally connected to each other in the assembly of the multi-plate clutch. Multi-plate clutch with an outer disk carrier for at least one outer disk and an inner disk carrier for at least one inner disk, wherein outer disk and inner disk for transmitting torque in frictional engagement can be brought together, characterized in that the inner disc carrier comprises a hub member, a disc carrier cup, and a disc retainer component, wherein the hub member is provided for connecting the multi-plate clutch with a drive side or an output side of the multi-plate clutch, the lamellar suspension component having a form-locking region which serves to connect the lamellar suspension component in a rotationally fixed manner to the associated lamellae, wherein the hub component and plate carrier cup are firmly connected to each other, and wherein Lamelleneinhängbauteil and Lamellenträgertopf are adapted to be at least rotationally connected to each other in the assembly of the multi-plate clutch. Multi-disc clutch according to claim 1 or 2, characterized in that the hub member is welded into the disc carrier pot. Multi-plate clutch with an outer disk carrier for at least one outer disk and an inner disk carrier for at least one inner disk, wherein outer disk and inner disk for transmitting torque in frictional engagement can be brought together, characterized in that the outer disc carrier comprises a disc carrier cup and a lamellar suspension member, wherein the disc carrier cup is formed integrally with a hub member provided for connecting the multi-plate clutch to a drive side or a driven side of the multi-plate clutch, the lamellar suspension component having a form-locking region which serves to connect the lamellar suspension component in a rotationally fixed manner to the associated lamellae, wherein the hub component and plate carrier cup are firmly connected to each other, and wherein Lamelleneinhängbauteil and Lamellenträgertopf are adapted to be at least rotationally connected to each other in the assembly of the multi-plate clutch. Multi-plate clutch with an outer disk carrier for at least one outer disk and an inner disk carrier for at least one inner disk, wherein outer disk and inner disk for transmitting torque in frictional engagement can be brought together, characterized in that the inner disc carrier comprises a disc carrier cup and a lamellar suspension component, wherein the disc carrier cup is formed integrally with a hub member provided for connecting the multi-plate clutch to a drive side or a driven side of the multi-plate clutch, the lamellar suspension component having a form-locking region which serves to connect the lamellar suspension component in a rotationally fixed manner to the associated lamellae, wherein the hub component and plate carrier cup are firmly connected to each other, and wherein Lamelleneinhängbauteil and Lamellenträgertopf are adapted to be at least rotationally connected to each other in the assembly of the multi-plate clutch. Multi-plate clutch according to one of claims 1 to 5, characterized in that the multi-plate clutch is designed as a wet-running clutch. Multi-disc clutch according to one of claims 1 to 6, characterized in that the disc carrier cup and the Lamelleneinhängbauteil via a positive connection, such as dog teeth, are interconnected. Multi-disc clutch according to claim 7, wherein the positive connection is secured against (axial) release via a releasable connection, such as a circlip, or via a non-releasable connection, such as caulking. Multi-disc clutch according to one of claims 1 to 8, characterized in that the Lamellenträgertopf and / or the Lamelleneinhängbauteil is designed as a deep-drawing component or are.

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