DE102009045980B4 - friction clutch - Google Patents

Abstract

Friction clutch (1) with a pressure plate (4) which can be axially displaced relative to a clutch housing (2) by means of a diaphragm spring (6), and an additional spring (16) which provides an additional spring force parallel to the diaphragm spring (6), the Diaphragm spring (6) have diaphragm spring tongues (12) with diaphragm spring slots (32) arranged between them and the additional spring (16) have additional spring tongues (28) with additional spring slots arranged in between, at least some of the diaphragm spring slots (32) being dimensioned such that the additional spring tongues (28) in the diaphragm spring slots (32) can be introduced, characterized in that the at least some diaphragm spring slots (32) have a widening (34) at their free end, in which the additional spring tongues (28) can be received.

Description

The present invention relates to a friction clutch with a pressure plate which is axially displaceable by means of a diaphragm spring with respect to a clutch housing and an additional spring which provides an additional spring force parallel to the diaphragm spring.

Such a coupling is for example from the EP 1 832 769 A2 or the DE 10 2007 004 168 A1 known. In a friction clutch, in order to produce a frictional coupling between a clutch disk on the one hand and a flywheel and a pressure plate on the other hand, the pressure plate is acted upon by means of a diaphragm spring with an axial force. In the engaged state, the diaphragm spring presses the pressure plate against the flywheel, while in the disengaged state, the axial contact pressure of the diaphragm spring is released. For this purpose, the radially inner end of the diaphragm spring on a plurality of spring tongues, which are connected to a disengaging unit with which the spring tongues can be moved in the axial direction. The diaphragm spring is mounted on the clutch housing by means of a plurality of fastening elements, so-called spacer bolts, so that the diaphragm spring rotates with the clutch housing, but depending on the position of the disengaging unit either presses the pressure plate against the flywheel or not.

For this purpose, the spacer bolts enforce the diaphragm spring at corresponding areas in the spring. In order to axially fix the diaphragm spring in the region of the spacer bolts relative to the clutch housing, wire rings or rocker rings are placed between the diaphragm spring and the radially widened ends of the spacer bolts, which thus form an axial stop for the diaphragm spring.

The disengaging unit can be actuated mechanically, electromechanically, hydraulically or pneumatically. It must be taken into account, especially in pneumatic disengaging units, that the slopes of the force / travel characteristics of the diaphragm spring and disengaging unit form a clear equilibrium position, so that the clutch travel is clearly defined. Such an equilibrium position can be achieved, for example, by virtue of the fact that the diaphragm spring has a progressive spring characteristic over the entire operating range.

In order to influence the spring characteristic of the force acting on the pressure plate of the diaphragm spring in response to the Einrückweg in a desired manner, designed as a diaphragm spring auxiliary spring can be provided, which - like the diaphragm spring - is held by the spacer bolts in position. The additional spring rests with its radially inner end on one side of the diaphragm spring. Upon disengagement of the coupling device, the auxiliary spring generates a desired additional force parallel to the diaphragm spring, so that the spring characteristic of the coupling device in total has a desired size and shape over the coupling path.

The spring force of the additional spring acts against the actuating force, ie the diaphragm spring force rectified, so that the friction clutch has a flatter Ausrückkraftkennlinie. Since the force of the additional spring occurs only after an initial actuation of the clutch and can also be dimensioned such that the additional spring force acts only in the region of the degression of the diaphragm spring, the maximum actuation force of the clutch does not increase or only slightly. Compared to a clutch assembly without additional spring, the operating force of the clutch in the end region of the actuating path increases slightly, so that overall a flatter characteristic results at a higher level.

The auxiliary spring in this case has spring tongues, which have axially in the direction of the diaphragm spring projecting contact areas for contacting the diaphragm spring.

A disadvantage of this prior art, however, is that due to the direct contact between the diaphragm spring and auxiliary spring friction between the two occurs, which is both a mechanical load on the two springs, as well as a hysteresis between the actuation and the release of the clutch causes.

From the DE 44 07 260 A1 and from the US 5 730 267 A Furthermore, friction clutches are known with a pressure plate, wherein the pressure plate by means of a diaphragm spring against a clutch housing are axially displaceable and further wherein an additional spring which provides an additional spring force parallel to the diaphragm spring, is arranged. Here, the spring tongues of the diaphragm spring and the auxiliary spring are bent towards each other, so that they are mutually arranged in their radially inner region in a common plane.

Object of the present invention is therefore to provide a friction clutch and manufacture, in which the friction between the diaphragm spring and auxiliary spring is reduced.

This object is achieved by a friction clutch according to claim 1.

The invention is based on the idea of the known friction clutch with diaphragm spring and auxiliary spring, wherein the diaphragm spring spring tongues and interposed diaphragm spring slots and the additional spring also spring tongues with intermediate arranged additional spring slots to change in that the additional spring tongues do not contact the diaphragm spring tongues, but that at least some of the diaphragm spring slots are dimensioned such that the additional spring tongues can dive into the diaphragm spring slots. It is advantageous here that the additional spring tongues contact the disengaging unit in the radial region in which the diaphragm spring also acts on the disengaging unit.

According to the invention, some membrane spring slots at their free end to a broadening, in which the additional spring tongue is receivable. This has the advantage that the membrane spring tongues are not weakened by excessive material removal in their spring force. This also means that the diaphragm spring itself need not be made thicker in order to have sufficient rigidity or spring force representing the minimum actuating force.

This advantageously still provides an additional spring force parallel to the spring force of the diaphragm spring, but the possible friction between the diaphragm spring and auxiliary spring and thus the Hystereseausbildungsmöglichkeiten be reduced.

It is particularly preferred if this immersion occurs without friction, so the membrane slots are dimensioned such that the additional spring tongues can be received without contact in the diaphragm spring slots.

In addition, it can be provided that the diaphragm spring tongues and the additional spring tongues are spaced apart in an engaged state of the friction clutch, so that the additional spring force is provided parallel to the diaphragm spring.

In a further advantageous embodiment of the invention, the disengaging unit can also be operated automatically actuated, for example by means of electromechanical or hydraulic actuators. It must be taken into account in particular that the Ausrückkraftkennlinie the coupling device is designed so that clearly a release position can be assigned to an operating force of the disengaging. If the gradients of the Ausrückkraftkennlinie and the actuating force close to each other, this can lead to malfunction, since an operating force can not be clearly assigned to a disengaged position. It is therefore not possible to determine in which state the coupling is currently located.

According to a further advantageous embodiment, the additional spring force of the auxiliary spring is provided only after a predetermined part of the actuation path, which is given by the distance between additional spring and diaphragm spring. A further embodiment of the invention provides that an end stop position is provided for example by a mechanical stop, which limits the Ausrückweg. In this way, not only in mechanical actuation of the clutch by means of a clutch pedal, but also in an automated clutch actuation system, an end stop position of Auskuppelbewegung imparted, since the force required to operate the clutch pedal and the disengaging unit increases significantly. Alternatively, the force characteristic of the auxiliary spring can also rise sharply above a defined deflection, which likewise corresponds to an end stop position.

In particular, it is advantageous if the additional springs are immersed after covering a predetermined part of the actuation path in the diaphragm spring slots and are dimensioned such that they contact a disengaging unit and are also axially displaceable by it in the direction of the pressure plate. In this case, the disengaging unit preferably contacts the diaphragm spring tongues at the beginning of the actuation and displaces them axially in the direction of the pressure plate, as a result of which the contact pressure of the diaphragm spring is reduced and the pressure plate pivots axially in the direction of the clutch housing, so that the friction clutch is released.

According to a further advantageous embodiment, the additional spring contacted at its radially outer region, the diaphragm spring such that the diaphragm spring can be supported on the auxiliary spring. This is particularly the case when the additional spring is designed as a support ring with spring tongues arranged thereon.

Instead of the formation of the additional spring as a support ring may also be, as another advantageous embodiment shows, between the additional spring and diaphragm spring a wire ring be introduced, which assumes the support function. It is also possible that the additional spring extends only to a fastener, such as a spacer bolt, the additional spring, which axially spaced the auxiliary spring from the housing and secured to the housing, wherein the fastener is preferably adapted to bias the auxiliary spring toward the housing. In addition, the fastening element can also be designed for fastening the diaphragm spring to the housing.

Advantageously, the wire ring or the additional spring formed as a support ring form an additional spring-side pivot bearing for the diaphragm spring, on which the diaphragm spring can be supported when spring pressure acts on the pressure plate. Furthermore, a housing-side pivot bearing is advantageously present, on which the diaphragm spring can be supported when releasing the spring pressure on the pressure plate. In this case, the diaphragm spring is preferably arranged without play between the housing-side pivot bearing and the additional spring-side pivot bearing.

According to a further advantageous embodiment, the housing-side pivot bearing of the diaphragm spring is provided by a wire ring which is arranged between the housing and the diaphragm spring.

According to the number of diaphragm spring tongues and the number of additional spring tongues does not have to match, but it is sufficient if a smaller number of additional spring tongues than diaphragm spring tongues is present. In this case, however, care must be taken that the additional spring tongues correspond with the correspondingly dimensioned diaphragm spring slots. For this purpose, at least one mounting recess is advantageously provided in the auxiliary spring, which assigns the auxiliary spring a certain spatial orientation on the diaphragm spring. It is particularly advantageous if the mounting recess is designed to be centered on the fasteners and thus occupies a certain spatial positioning to the housing.

In order also to impart the corresponding orientation to the diaphragm spring, the diaphragm spring can have mounting openings, which are preferably mounted between the diaphragm spring tongues and are arranged offset over the circumference to the broadened diaphragm spring slots. Advantageously, the mounting opening are arranged either asymmetrically, so that a unique position between the diaphragm spring and housing is guaranteed or they are arranged symmetrically, so that a plurality of relative positions between the diaphragm spring and housing are possible.

At least one mounting opening and at least one mounting receptacle are provided in the diaphragm spring, the diaphragm spring and additional spring being spatially positioned by aligning the mounting opening and the mounting receptacle with one another. Due to the easy to be oriented to each other mounting hole and mounting receptacle advantageously errors in the assembly of the friction clutch can be reduced.

Further advantageous and preferred embodiments are defined in the description, the drawings and the claims.

In the following, the invention will be described by way of example, without limitation of generality, with reference to embodiments illustrated in the drawings.

Show it:

1 a schematic representation of a first embodiment of the friction clutch according to the invention in the engaged state;

2 this in 1 illustrated embodiment in disengaged state;

3 a schematic representation of a preferred embodiment of the diaphragm spring according to the invention;

4 a schematic representation of a preferred embodiment of the additional spring according to the invention;

5 a schematic view of a diaphragm spring according to the invention and an additional spring according to the invention from the housing side;

6 a schematic view of the in 5 shown component from the pressure plate side;

7 a schematic representation of a second preferred embodiment of the friction clutch according to the invention;

8th a schematic representation of a third preferred embodiment of the friction clutch according to the invention; and

9 a diagram of the release force (y-axis) over the Ausrückweg (x-axis).

In the following, the same or functionally equivalent elements are numbered with the same reference numerals.

In 1 is a friction clutch 1 shown in the engaged state, which is constructed in the usual way. A housing 2 is rotatably connected to a flywheel (not shown) of an internal combustion engine (not shown), wherein the housing 2 can rotate around a common axis of rotation. In the case 2 is a pressure plate 4 rotatably arranged axially displaceable, which can transmit torque to the flywheel.

Between the pressure plate 4 and the clutch housing 2 is a diaphragm spring 6 arranged, which around a support area 8th , or the support section 26 tiltable and here is the pressure plate 4 axially in the direction of the flywheel presses to transmit a torque. The diaphragm spring 6 is composed of a plate-like diaphragm spring section 10 , which has a substantially circular shape, and so-called diaphragm spring tongues 12 extending from the diaphragm spring section 10 extend radially inward and the diaphragm spring 6 around her swivel range 8th pivot during a coupling process. At the diaphragm spring tongues 12 picks up a release unit 14 , in particular an automated clutch actuation, which is axially displaceable.

On the pressure plate 4 facing side of the diaphragm spring 6 This is done by a trained as a support ring auxiliary spring 16 opposite the housing 2 held. The additional spring 16 has a support area 18 and an additional spring range 20 on, with the support area 18 the diaphragm spring against the housing 2 supported. The additional spring 16 in turn is made by fasteners 22 on the housing 2 supported and positioned. Here, these fasteners pass through 22 the diaphragm spring 6 in the area of the diaphragm spring tongues 12 so that also the diaphragm spring 6 from the fastener 22 is held. In addition, the fasteners 22 preferably evenly over the circumference of the diaphragm spring 6 distributed around a uniform force distribution and attachment of the diaphragm spring 6 to enable. Furthermore, the fastening element may have mounting areas 24 having a support of the auxiliary spring 16 provide on the side facing away from the housing.

The fasteners 22 are in this case designed such that the additional spring 16 on the one hand to the fasteners 22 and on the other hand with its rest section 26 on the diaphragm spring 6 can support. This will cause the diaphragm spring 6 between the support area 8th and the rest section 26 axially fixed, but can be pivoted during a coupling process to these bearings, bringing an axial movement of the pressure plate 4 accompanied.

The additional spring range 20 is as radially inwardly extending additional spring tongues 28 formed in the engaged state with its end 30 from the diaphragm spring tongues 12 the diaphragm spring 6 spaced apart by a distance Y.

The additional spring tongues 28 and the diaphragm spring tongues 12 According to the invention are designed such that at an axial displacement of the diaphragm spring tongues 12 by applying force by the disengaging unit 14 , the end area 30 the additional spring tongues 28 not on the diaphragm spring tongues 12 accumulate and contact them, but in widened slots between the diaphragm spring tongues 12 can dive. This immersion is preferably friction-free, so that a friction between the diaphragm spring 6 and the auxiliary spring 16 reduced or even negligible. This also has the consequence that the hysteresis education in the characteristics when pressing or releasing the release unit 14 is significantly reduced.

In the in the 1 illustrated engaged state is the diaphragm spring 6 in its basic position and the diaphragm spring section 10 is supported radially on the outside at its contact point on the pressure plate 4 and radially inside the support area 8th of the housing 2 off, leaving the pressure plate 4 firmly pressed against the flywheel in the axial direction. Instead of one integral with the housing 2 trained support area 8th , this may alternatively be formed by a wire ring or other intermediate element.

As already indicated above, the diaphragm spring 6 on the pressure plate 4 facing side by the additional spring 16 in the axial direction on the housing 2 held. The ring-shaped auxiliary spring 16 can from the mounting areas 24 on the fastener 22 be supported in the axial direction. It can be provided that the additional spring 16 so spring-loaded with its support section 26 on the diaphragm spring 6 abuts that the diaphragm spring 6 around the support area 26 , Is mounted rotatable or tiltable, but no clearance or no clearance is available. The bias with which the auxiliary spring 16 on the diaphragm spring 6 is applied is advantageously such that even with a change in the force with which the diaphragm spring 6 on the pressure plate 4 press, no play or no air forms.

Now the friction clutch 1 operated, so the diaphragm spring shifts 6 with their diaphragm spring tongues 12 in the direction of the pressure plate 4 and approach the additional spring tongues 28 or the end regions 30 the additional spring tongues 28 at. As the disengaging movement progresses, the additional spring tongues will dip 28 in the diaphragm spring slots of the diaphragm spring 6 one until they are also from the disengagement unit 14 be contacted.

This is in 2 showing the friction clutch in the disengaged state. With progressive disengagement, the additional spring tongues 28 the additional spring 16 and the diaphragm spring tongues 12 the diaphragm spring 6 by the pivoting movement of the disengaging unit 14 elastic in the direction of the end position of the disengaging position of the diaphragm spring 6 deflected. There is an elastic deformation of the diaphragm spring tongues 12 and the additional spring tongues 28 instead of.

With increasing deformation of the additional spring tongues 28 becomes a gradually increasing counterforce of the additional spring tongues 28 on the release unit 14 exercised. After the start of contacting and supporting the additional spring tongues 28 at the release unit 14 is provided that these additional spring tongues 28 define a maximum disengaging position. The maximum Auskuppelposition, so the end position of Auskuppelstellung, by the additional spring tongues 28 be limited so that their support force increases significantly. This can be done by reaching the maximum Auskuppelposition the spring travel of the additional spring tongues 28 is used up.

In the 3 to 6 are preferred embodiments of the diaphragm spring according to the invention 6 and the additional spring according to the invention 16 shown alone and in the assembly.

It shows 3 a plan view of a diaphragm spring according to the invention 6 , As this figure can be clearly seen, the diaphragm spring 6 Diaphragm spring fingers 12 and diaphragm spring slots 32 on. The diaphragm spring slots 32 have at their radially inner ends arranged widenings 34 on, which are designed to the additional spring tongues 28 the additional spring 16 record as frictionally free. Not all diaphragm springs have broadening 34 but only those associated with the additional spring tongues. This has the advantage that the overall stiffness of the diaphragm spring 6 not reduced by too much material removal.

4 on the other hand shows schematically a preferred embodiment of the auxiliary spring 16 , As this figure can be clearly seen, have the additional spring tongues 28 a radially inner end region 30 on, which is designed in particular short and narrow, while a radially outer region 36 wider and longer, so that the spring characteristic of the auxiliary spring 16 can be optimized. In this case, the spring characteristic of the additional spring tongues 28 by width, number and thickness of the additional spring tongues 28 to be influenced.

There, like in the 2 and 3 shown, the auxiliary spring 16 not the same number of spring tongues 28 has, as the diaphragm spring 6 Slits and also the widening 34 in the diaphragm spring 6 not on all diaphragm spring slots 32 are formed, need additional spring 16 and diaphragm spring 6 spatially aligned to a dipping of the additional spring tongues 28 in the widened diaphragm spring slots 34 to enable.

This is indicated by the additional spring 16 in their radial area mounting recesses 38 on, by means of the auxiliary spring 16 on the fasteners 22 is centered while the diaphragm spring 6 mounting holes 40 has, which at the diaphragm spring slots 32 are formed. The orientation of diaphragm spring 6 and additional spring 16 happens according to the invention by the orientation of the diaphragm spring 6 existing mounting holes 40 on the in the auxiliary spring 16 existing assembly exceptions 38 , In addition, with the help of mounting exceptions 38 the additional spring 16 and thus also the diaphragm spring 6 to the housing 2 be aligned, because the assembly exceptions 38 as described above, on the fasteners 22 be centered.

During assembly, only the auxiliary spring 16 over the mounting recesses 38 on the fasteners 22 centered and thus to the housing 2 positioned. Then, to ensure that the additional spring tongues 28 after installation in the widened slots 34 the diaphragm spring 6 are arranged, the diaphragm spring 6 arranged such that the mounting holes 40 the diaphragm spring 6 with the mounting recesses 38 the additional spring 16 correspond. The mounting holes 40 the diaphragm spring 6 can either be arranged asymmetrically, so that a unique position between diaphragm spring 6 and housing 2 is guaranteed or they are arranged with offset but symmetrical, allowing multiple relative positions between diaphragm spring 6 and housing 2 possible are. The symmetrical variant is preferred because then the diaphragm spring 6 at several positions relative to the housing 2 can be arranged so that eliminates a tedious searching for the exact right position.

Although it is conceivable, additional spring 16 and diaphragm spring 6 to design such that the same number of additional spring tongues 28 like diaphragm spring slots 32 is present, but as a result, the spring characteristics of additional spring 16 and diaphragm spring 6 be greatly influenced, especially because of the broadening 34 the spring force of the diaphragm spring 6 is reduced, this variant is advantageous only under special circumstances.

The 5 and 6 show diaphragm spring 6 and additional spring 16 in the assembled state, being 5 a view of the diaphragm spring, so from the housing side 2 shows while 6 a view of the auxiliary spring 16 , ie from pressure plate side 4 out represents.

As 5 it can be seen, dip the additional spring tongues 28 into the cultivation 34 the diaphragm spring slots 32 one, with the broadening 34 dimensioned so that as possible no direct contact and thus you no friction between the diaphragm spring 6 and the auxiliary spring 16 occurs.

5 also shows that the diaphragm spring tongues 12 and the additional spring tongues 28 have the same inner radius, so they also have the same starting diameter for the disengaging unit 14 exhibit.

As already mentioned above, the diaphragm spring 6 mounting holes 40 on, in the case shown here in the diaphragm spring slots 32 to the left of every other broadening 34 are arranged. These mounting holes 40 facilitate relative positioning between auxiliary spring 16 and diaphragm spring 6 so that installation errors can be avoided.

6 shows a schematic plan view of the diaphragm spring according to the invention and the additional spring according to the invention 16 from the pressure plate side. As this figure can be clearly seen, have the additional spring tongues 28 a radially inner region 30 on, which is designed in particular short and narrow, while the radially outer region 36 wider and longer, so that the additional spring tongues 28 frictionless as possible in the broadened diaphragm spring slots 34 can dive. Also 6 it can be seen that the mounting holes 40 in the diaphragm spring 6 the mounting exceptions 38 the additional spring 16 are assigned so that a defined spatial positioning of diaphragm spring 6 and additional spring 16 is possible.

The 7 and 8th show alternative embodiments of the friction clutch according to the invention.

This in 7 illustrated embodiment differs from the embodiment of 1 and 2 in that the auxiliary spring 16 regarding the diaphragm spring 6 no support area 26 has, but the support of the diaphragm spring 6 in the direction of the additional spring 16 via an additionally introduced wire ring 42 provided. This wire ring 42 can via the correspondingly shaped auxiliary spring 16 be guided radially.

Alternatively to the in 7 illustrated embodiment shows the embodiment in 8th that the auxiliary spring 16 not necessarily through the fastener 22 extends, but also from this radially on the outer edge of the auxiliary spring 16 can be fixed, so that the auxiliary spring 16 no support area 18 having. It is between the pressure plate side bracket 24 of the fastener 22 and the diaphragm spring 6 again a wire ring 42 arranged, which is the additional spring side bearing for the diaphragm spring 6 Are defined.

9 shows a Kraftwegdiagramm the Ausrückkraft (y-axis) on the Ausrückweg (x-axis). In this case, release force means the force that must be expended to the release unit 14 axially in the direction of the pressure plate 4 to adjust and thus the force that needs to be expended to the friction clutch 1 to solve.

When the provided by the additional spring additional spring force when you press the release unit 14 comes to fruition, is the distance Y between diaphragm spring tongues 12 and additional spring tongues 28 Are defined. This additional force leads to a change in the Ausrückkraftkennlinie, since in addition to the diaphragm spring force, the additional spring force of the additional spring acts. This change in the characteristics is shown schematically in FIG 9 shown.

In the unactuated state contacted the release unit 14 with a small, not shown preload the diaphragm spring tongues 28 so that both force and way are at their zero point. Now should the friction clutch 1 be disengaged, the release unit 14 pressed and in the direction of pressure plate 4 axially adjusted. She presses on the diaphragm spring tongues 12 which in turn exert a measurable force on the disengaging unit on the disengaging unit. This measurable force is in 9 represented by the graphs "M", "Z", and "K", wherein the graph "M" is the characteristic of the operating force in the region of the tongues of the diaphragm spring 6 only, the graph "Z" the characteristic of the auxiliary spring alone and the graph "K" the resulting characteristic of the operating force on the tongues of the diaphragm spring 6 represents.

The further the release unit in the direction of pressure plate 4 moves, the less spring force is applied to the pressure plate 4 applied. From a certain point X, the pressure plate begins to lift off the clutch disc. Up to here, the release force increases, due to the interaction force between the clutch disc and the pressure plate. From the point X, the disengagement force drops due to the characteristic of the diaphragm spring again. Preferably, the region X is at the maximum of the actuating force, so that the force for further disengagement no longer increases, but slightly drops.

To counteract this sharp drop in the characteristic "M", the diaphragm spring 6 and the additional spring 16 positioned to each other such that shortly after the point X, the additional spring tongues 16 in the diaphragm spring slots 32 submerged, also contact the trigger and apply a force in addition to the diaphragm spring force. The point in time or the position at which the disengaging unit also contacts the additional spring tongues is in the diagram at the end of the path Y. In this case, the characteristic of the additional spring can be varied by adjusting the width, number and thickness of the additional spring tongues.

Due to the now additionally acting force of the additional spring Ausrückkraftkennlinie "K" is changed, so that the Ausrückkraftkennlinie remains at a relatively uniform level by the additionally applied spring force, which gives the driver a pleasant operating feeling.

Instead of the linear characteristic of the auxiliary spring shown here, for example, a multi-stage curve can be conceivable, wherein the multi-stage curve is achieved in that the additional spring tongues do not all have the same distance to the diaphragm spring tongues, but that a part of the additional spring tongues a first distance Y1 and a second part of the additional spring tongues has a second distance Y2 to the diaphragm spring tongues. As a result, the disengaging unit first runs on the diaphragm spring tongues 12 , then on the first part of the additional spring tongues 28-1 and finally to the second part of the additional spring tongues 28-2 , whereby the characteristic is changed again.

LIST OF REFERENCE NUMBERS

1

friction clutch

2

casing

4

pressure plate

6

diaphragm spring

8th

housing-side support

10

Belleville spring section

12

Diaphragm spring fingers

14

disengaging

16

additional spring

18

support area

20

Additional spring range

22

fastener

24

holding area

26

bearing section

28

Additional spring tongues

30

radially inner end region of the additional spring tongues

32

Diaphragm slots

34

Broadening in the diaphragm spring slots

36

radially outer region of the additional spring tongue

38

Assembly exception in additional spring

40

Mounting opening in diaphragm spring

42

wire ring

Y

Distance between diaphragm spring tongues and additional spring tongue

M

Characteristic of diaphragm spring

Z

Characteristic of the additional spring

K

Combined characteristic of additional spring and diaphragm spring

Claims (14)

Friction clutch ( 1 ) with a pressure plate ( 4 ), which by means of a diaphragm spring ( 6 ) with respect to a coupling housing ( 2 ) is axially displaceable, and an additional spring ( 16 ), which has an additional spring force parallel to the diaphragm spring ( 6 ), wherein the diaphragm spring ( 6 ) Diaphragm spring tongues ( 12 ) with diaphragm spring slots ( 32 ) and the auxiliary spring ( 16 ) Additional spring tongues ( 28 ) with additional spring slots arranged therebetween, wherein at least some of the diaphragm spring slots ( 32 ) are dimensioned such that the additional spring tongues ( 28 ) into the diaphragm spring slots ( 32 ) are einbrangbar, characterized in that the at least some diaphragm spring slots ( 32 ) at its free end a broadening ( 34 ) into which the additional spring tongues ( 28 ) are receivable. Friction clutch ( 1 ) according to claim 1, wherein the additional spring tongues ( 28 ) substantially frictionless in or through the diaphragm spring slots ( 32 ) can be introduced. Friction clutch ( 1 ) according to one of the preceding claims, wherein the additional spring force is provided only after a predetermined part of a Kupplungsbetätigungswegs. Friction clutch ( 1 ) according to claim 3, wherein the additional spring tongues ( 28 ) after the predetermined part of the actuation path (Y) in the diaphragm spring slots ( 32 ) are received in such a way that they are separated by a release unit ( 14 ) are contactable. Friction clutch ( 1 ) according to claim 4, wherein the disengagement unit ( 14 ) also the diaphragm spring tongues ( 12 ) contacted. Friction clutch ( 1 ) according to any one of the preceding claims, wherein the auxiliary spring ( 16 ) via a fastening element ( 22 ), in particular via spacer bolts, to the housing ( 2 ) is biased. Friction clutch ( 1 ) according to any one of the preceding claims, wherein the auxiliary spring ( 16 ) is designed as a support ring. Friction clutch ( 1 ) according to one of the preceding claims, wherein the diaphragm spring ( 6 ) a housing-side pivot bearing ( 8th ) and an additional spring-side pivot bearing ( 26 ; 42 ) are assigned, at which the diaphragm spring ( 6 ) when operating the clutch ( 1 ) is supported. Friction clutch ( 1 ) according to claim 8, wherein the auxiliary spring ( 16 ) is formed as a support ring with spring tongues and the support ring, the additional spring-side pivot bearing ( 26 ) for the diaphragm spring ( 6 ). Friction clutch ( 1 ) according to claim 8, wherein between diaphragm spring ( 6 ) and auxiliary spring ( 16 ) a wire ring ( 42 ) is introduced, the additional spring side pivot bearing for the diaphragm spring ( 6 ) serves. Friction clutch ( 1 ) according to one of claims 8 to 10, wherein the housing-side pivot bearing ( 8th ) of the diaphragm spring ( 6 ) is provided by a wire ring disposed between the housing ( 2 ) of the friction clutch ( 1 ) and the diaphragm spring ( 6 ) is arranged. Friction clutch ( 1 ) according to any one of the preceding claims, wherein the auxiliary spring ( 16 ) Mounting recesses ( 38 ), that of the auxiliary spring ( 16 ) a certain spatial orientation on the diaphragm spring ( 6 ) to assign. Friction clutch ( 1 ) according to claim 6 and 12, wherein the mounting recesses ( 38 ) are adapted to the fasteners ( 22 ), in particular the spacer bolt to be centered. Friction clutch ( 1 ) according to one of the preceding claims, wherein the diaphragm spring ( 6 ) Mounting holes ( 40 ), the diaphragm spring ( 6 ) a certain spatial orientation to the housing ( 2 ) and / or to the additional spring ( 16 ) to assign.

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