DE19848584A1 - Automotive clutch has a flywheel with housing that advances on the clutch plate and lining via springs - Google Patents

Abstract

An automotive friction clutch has a fixed housing with a flywheel. The housing has springs that advances on the clutch plate and lining towards the flywheel. When the clutch is disengaged, the spring pressure is varied, changing the pressure with which the clutch lining is applied to the flywheel. The pressure applied is proportional to the force exerted by the springs.

Description

The invention relates to a friction clutch, especially for motor vehicles Connect with a non-rotatable to a driven flywheel cash coupling housing, one arranged in it, from one on Clutch housing supporting contact spring pressurizable contact plate for pressing on a clutch disc with friction linings on the flywheel, the pressure spring when engaging itself exerts changing contact pressure on the pressure plate.

Such a friction clutch is for example from DE 39 40 917 A1 known. To engage and disengage the clutch is one on the pressure spring acting actuator provided mechanically or is operated hydraulically. This is partly inside the clutch arranged housing, and the actuator is out of the clutch led out housing. The friction clutch transmits the torque by means of the radially outer side connected to the transmission input shaft clutch plate provided on both sides with friction linings Pressure plate is pressed onto the flywheel of an internal combustion engine. The pressure plate is kinematically coupled to the clutch housing and axially displaceable. The pressure spring is designed as a diaphragm spring and the the actuating force applied by it determines the transmissible torque. If the pressure spring is lifted off the pressure plate, the Pressure plate, and the transferable torque is possibly up reduced to zero. A structurally unavoidable runout of the Internal combustion engine causes torque fluctuations and torque peaks that have to be transmitted without the clutch slips, which would lead to increased wear. The same applies when accelerating a high-torque internal combustion engine or  when starting a vehicle in high gear. Consequently, that of the Diaphragm spring to be applied contact pressure correspondingly large, which in Basically leads to oversizing.

Since the installation space in a motor vehicle and thus the clutch friction radius is limited, a higher clutch torque over a higher Contact pressure can be achieved, which in turn leads to higher operating forces leads. To a loss of comfort for the driver due to the high Servo devices are used to avoid the necessary disengagement force built in, which support the actuating force.

To increase the transferable torque and thus reduce the The necessary contact pressure could also be used with inorganic friction linings that have a high coefficient of friction p (for example greater or equal 0.3). The use of such friction linings, however, has the problem take side effect that they are increasing in a certain area Relative speed have a falling coefficient of friction p. Such Friction linings can then cause the clutch to jerk when engaged, which means a significant loss of comfort for the vehicle occupants.

Based on this problem, the object of the invention is to improve the friction clutch described in the introduction, that the transmissible torque can be influenced, whereby the Comfort can be improved and / or the release force changed can be.

The problem is solved with a generic friction clutch tion by a device acting on the pressure plate, via the at least in the engaged state, the contact pressure of the pressure plate in is changed substantially proportional to the force of the pressure spring. By this configuration is, for example, at least during operation an additional force is applied to the pressure plate, which leads to the  Actuating force has a supporting effect. As a result, a self-reinforcing effect realized. This configuration has at the same time the advantage that through the supportive establishment of a self after position with decreasing friction lining thickness is possible. In addition, at same transferable torque the biasing force of the pressure spring are reduced, which results in smaller disengagement forces.

Another solution to the problem provides that friction linings from one inorganic material can be used in which in a range increasing sliding speed a falling coefficient of friction occurs, and further a device acting on the pressure plate is provided, via which when engaging the contact pressure of the pressure plate essentially is reduced proportionally to the force of the pressure spring. By this Ausge The transferable torque is created by the friction linings increased coefficient of friction increased. The plucking with these friction linings can be connected, is avoided by one of the Spring force counteracting force is generated. This will help with this Art-equipped coupling realizes a self-weakening effect. At the same transferable torque as conventional couplings can be reduced here the biasing force of the pressure spring, from what Smaller disengagement forces result because appropriate friction linings are used come.

According to the invention, it is also advantageous if between the Pressure plate and the clutch housing one to a predetermined Area limited relative movement is possible, and the facility is formed by at least one pivotable between the coupling Housing or flywheel and pressure plate arranged lever. By this pivotally arranged lever can with appropriate connection during train operation (starting, accelerated travel) one additional contact pressure can be applied to the contact plate. In the same arrangement is then correspondingly in overrun (the vehicle  pushes the motor) the contact force weakens. This can be used as overload protection, e.g. B. when downshifting in too low a gear.

According to the invention, the device in question can have at least one have a closed joint. This is the appropriate lever captive and the other joint can be open or likewise be closed. When using two closed joints it is possible to transmit both compressive and tensile forces.

However, it is also possible that the device has two open joints having. A power transmission is only possible in one direction, and independent guidance of the corresponding lever must be provided become.

According to the invention, there can be a relative movement between the contact pressure plate and the clutch housing or the flywheel of the levers on the Apply pressure to the pressure plate. In such a case it is possible for example, to form two open joints, which are particularly simple in terms of manufacture and assembly.

However, it is also readily possible for a relative movement between the pressure plate and the clutch housing the lever on the Pressure plate exerts a tensile force. This advantageously leverages used, which are equipped with closed joints.

When using at least one lever that swivels between Coupling housing or flywheel and pressure plate is arranged, can advantageously the relative movement of the pressure plate by a Leaf spring are checked, which is an elongated hole at a junction having. It can in the loading direction of the pressure plate, the Lever relieves the leaf spring for limiting the relative movement of the  Pressure plate can be used. The leaf spring can in addition to Generation of a ventilation force can be used.

The lever is according to the invention via an arm formed on it Pressure plate created. An embodiment of the invention provides that the device is formed by at least one of the press plate and the clutch housing connected leaf spring, the in Direction of rotation of the leaf spring in front of pulling operation the pressure plate is provided, the rear pivot point on Coupling housing and a connecting line through both articulation points in a mathematically positive angular range is provided from a plane parallel to the friction surfaces. By the appropriate Formation and connection of the leaf spring produces this during train operation or when accelerating, an additional pressure force is exerted on the pressure plate, while in overrun a weakening of this contact pressure takes place finds. At the same time, this leaf spring can be preloaded in this way be provided that it exerts a ventilation force on the pressure plate. In order to With such a construction, separate components would be omitted and the Coupling can be practically of conventional design with a low Number of individual parts and can be installed with common individual parts.

Of course, the rear articulation point can also be directly on the Flywheel can be arranged. This does not change the effect.

The positive angular range for the connecting line between the two Articulation points should be over 20 ° if possible.

The use of a leaf spring described above is preferred in such a way that a contact pressure increasing effect is achieved in train operation becomes. In overrun mode, in which the forces are usually clear are lower, this leaf spring is then subjected to compression. It is  in principle, of course, vice versa, but then the leaf spring be trained accordingly for the other stress cases.

To improve the effect of the facility described proposed according to the invention that at the investment site between Pressure plate and pressure spring provided low-friction storage becomes. This reduces the frictional force at this point, so that the pressure plate is slightly opposite the clutch housing can move. In principle, there is both a plain bearing and one Rolling bearing conceivable.

The configuration according to the invention makes it possible, for example to reduce the friction radius of the clutch and thereby the contact spring force to keep constant. With the reduction of the friction radius, the clutch can be built more compact, which means that the necessary installation space in one Vehicle is reduced. This construction follows the requirement that is placed on all components of modern vehicles, as compact as possible to be built up as a result of vehicle optimization with simultaneous Increase in the variety of equipment available space in the Engine compartment is continuously reduced.

With increasing wear of the friction linings, the angle of the Increase lever or leaf spring. So the self-reinforcing or self-weakening effect can be enlarged. This can for example, the area used for the characteristic of the pressure spring be moved so that the change of Compensate contact spring force and self-reinforcement.

The invention is then explained in more detail using exemplary embodiments explained. They show in detail:

Fig. 1 is a perspective view of the friction clutch;

Fig. 2 is the view according to the arrow II of Figure 1 in partial view.

Fig. 3 is the axial section through a friction clutch;

Figure 4a shows the section along the line IV-IV of FIG. 3.

4b shows the section along the line IV-IV of Figure 3 with both sides of an articulated lever tethered..;

Figure 4c shows the section along the line IV-IV of Figure 3 with an articulated lever tethered to the flywheel..;

FIG. 5 is a partial radial view of the friction clutch according to arrow V in FIG. 3;

Fig. 6 is a section along the line VI-VI of FIG. 5;

Fig. 7 is a partial radial view of the friction clutch similar to Fig. 5 with self-energizing leaf spring connection.

First, the clutch and its mode of operation will be explained in more detail with reference to FIGS. 1 to 3 and 5, 6. The friction clutch consists of the clutch housing 9 , which is connected radially on the outside to the flywheel 13 via the screw connection 15 . The flywheel 13 is attached to the crankshaft of an internal combustion engine and can rotate with it about the axis of rotation 14 . A pressure plate 3 is arranged within the clutch housing 9 and is connected to the clutch housing 9 in a rotationally fixed but axially displaceable manner. It is acted upon by a pressure spring 4 , in the present case a diaphragm spring, which is supported on the clutch housing and exerts an engagement force on the pressure plate in the direction of the flywheel 13 . The clamping force of the spring can be released via the radially inward-pointing diaphragm spring tongues 4 '. Between the pressure plate 3 and the flywheel 13 , a clutch disc 6 is arranged, which is fitted with a hub 8 in a rotationally fixed manner on a transmission input shaft, not shown. The clutch disc 6 is provided radially on the outside with friction linings 11 , 12 and it is connected to the hub 8 via riveting 7 . The clutch disc 6 is clamped by the force of the diaphragm spring 4 in the engaged state between the pressure plate 3 and the flywheel 13 for torque transmission. The diaphragm spring 4 is supported on the housing via spacer bolts 5 . With its radially outer area, it lies on the cutting edge 32 of the pressure plate 3 . The illustration shows a so-called pressed friction clutch, but it is also easily possible to provide a so-called drawn friction clutch. In the drawn design, the diaphragm spring 4 is supported with its outer diameter on the clutch housing 9 and over a medium diameter on the cutting edge 32 of the pressure plate 3 . In the present case of the pressed friction clutch, the torque transmission can be interrupted in that the spring tongues 4 'are pivoted to the left by a not shown Ausrückvor direction shown in FIG. 3, whereby the radially outer region of the diaphragm spring 4 no more clamping force on the cutting edge 32 of the pressure plate 3 exercises.

In the present case, the pressure plate 3 as shown in FIG. 5 on several circumferential tangential leaf springs 17 on the clutch housing 9 is guided circumferentially and the tangential leaf springs 17 can be designed so that they exert a release force on the pressure plate 3 . The pressure plate 3 and the housing 9 are connected via rivet connections 18 , 19 . A special feature is the elongated hole 20 in the tangential leaf spring 17 , which will be discussed later. In FIG. 5 a lining spring 16 can also be seen, which can be arranged between the two friction linings 11 and 12 .

On the clutch housing 9 , levers 2 are arranged at one or more points distributed around the circumference and are mounted in webs 10 , 10 a, and each have an arm 21 projecting transversely thereto. The bearing is designed to be pivotable, specifically over axially radial axes. The end of the lever 21 corresponds to a projection 31 running essentially in the axial direction on the pressure plate 3 (see FIG. 2).

The function of this device 1 formed by parts 2 , 10 , 10 a, 21 , 31 is as follows:
During the coupling process and also during the operation of the vehicle, as long as the internal combustion engine exerts an accelerating force, a "braking force" is exerted on the pressure plate 3 via the friction linings 11 , 12 and the clutch disc 6 , which is connected to the transmission in a rotationally fixed manner which is directed against the drive direction or direction of rotation D. As a result, the arm 21 of the lever 2 comes into contact with its front end on the projections 31 of the pressure plate 3 . The pressure plate 3 is thus supported in the circumferential direction. This circumferential support is made possible by being arranged in accordance with FIG. 5 in the tangential 17 slots 20, which allows slight relative movement of the pressure plate 3 opposite to the rotational direction D. In the opposite direction, this elongated hole 20 is not formed, so that in this opposite direction of rotation, the pressure plate 3 is circumferentially properly guided by the tangential leaf springs 17 . The support of the pressure plate 3 corresponding to the arrangement of Fig. 2 causes a substantially proportional to the force of the membrane spring 4 occurring reinforcement, so that a higher torque can be transmitted in this operating case. The degree of this self-reinforcement depends on the angle α, which is formed between the mounting of the lever 2 in the clutch housing (fastening arms 10 , 10 a) and the cutting edges 31 . The larger the angle α chosen in accordance with FIG. 2, the greater this self-amplification.

The effect of this self-reinforcement can be improved in that the lowest possible frictional force occurs between the diaphragm spring 4 and the pressure plate. The friction force occurring here reduces the relatively small possibility of twisting the pressure plate. For this reason, low-friction sliding or roller bearings can be provided here.

The self-reinforcing effect described above for the contact pressure of the Pressure plate is achieved as long as a train force in the drive train is produced. This is the case when starting off, when accelerating and also at high speeds. However, the driver takes the accelerator pedal back, a thrust is generated in the drivetrain by weight of the vehicle and the engine that is idling would like to drive. This drag torque for the engine causes the self-reinforcing effect is canceled and a lowering of the Contact pressure is applied (overrun operation). This effect can be beneficial be used in extreme cases, such as improper Downshift, at least briefly slipping through the clutch disc allow so that an overload of the internal combustion engine (over-revving) is avoided.

The change in contact force F _AP according to the construction described so far follows the formula below:

where F _{F represents} the force exerted by the diaphragm spring 4 , μ is the coefficient of friction between the friction linings 11 , 12 and the flywheel 13 or the pressure plate 3 , and the angle α _{i is} the angle currently occupied by the arm 21 .

In FIGS. 4a to 4c is clearly shown, may be formed as the device 1, in order to achieve different effects.

Fig. 4a corresponds to the coupling training corresponding to Figs. 1 to 3 and 5 and 6. It is not necessary to repeat the effect here.

Fig. 4b shows on the one hand the possibility that the arms 21 and 21 'of the lever 2 can be suspended both on the housing 9 and on the pressure plate 3 in two closed joints. Compared to FIG. 4a, which has only one closed joint and one open joint, this means that the diaphragm spring 17 according to FIG. 5 is freed from its torque connection to the pressure plate 3 , and may need to apply a lifting force. On the other hand, this construction means that the levers 2 can also absorb tensile forces.

In addition, an exact mounting of the lever 2 is guaranteed in all operating states. It is of course also conceivable that the levers 2 each have an open joint relative to the clutch housing 9 or the pressure plate 3 , in which case a guide must be provided which ensures that the levers cannot change their position and position in an uncontrolled manner . If it is assumed that the same direction of rotation D is present in FIG. 4b as in FIG. A, the design of the arm 21 is identical in effect to that of FIG. 4a and increases the contact pressure force in pulling operation. If, in such a case, however, the embodiment shown in dashed lines is selected with an arm 21 ', this construction acts during the train operation in the drive train with a lowering of the contact pressure. Such a constellation can advantageously be used when friction linings made of inorganic material are used, in which the coefficient of friction μ drops above the sliding speed in a certain range. In this case, the self-weakening of the contact force changes only the sign of the angle α _i in the above formula.

In Fig. 4c a structure is now illustrated, in which the lever 2 with his arm 21 is arranged on the one hand on the pressure plate 3 with a sealed joint and with its other end to the flywheel 13 also having a closed joint. For this purpose, a recess 22 is provided on the flywheel 3 . Assuming the train operation and a direction of rotation corresponding to D, the levers 2 are stressed with their arms 21 in train and exert a self-reinforcing force on the pressure plate 3 .

In FIG. 4 is a variant of the previous embodiments is shown. Here, the tangential leaf spring 17 a takes over the function of the lever 20 described above with its arms 21 . The tangential leaf spring 17 a is on the one hand firmly connected via a rivet connection 19 to the pressure plate 3 and on the other hand via a rivet connection 18 with the hitch be housing 9th This connection can also be provided directly on the flywheel 13 . From the illustration, the radially outer edge of the diaphragm spring 4 can also be seen, as well as the friction linings 11 , 12 of the clutch disc and the screw connection 15 between the clutch housing 9 and the flywheel 13 . The axis of rotation of the complete friction clutch is designated 14. For the desired case of self-reinforcement of the contact pressure in train operation, the arrangement is such that the direction of rotation is provided in accordance with D and the connecting line X between the two rivets 18 and 19 is arranged such that the angle α ₁ between the connecting line X and one Plane is arranged parallel to the friction linings 11 , 12 in the mathematically positive sense. With this construction, an increase in contact pressure is achieved in traction and a reduction in contact force in overrun. In the opposite direction of rotation or at a mathematically negative angle α ₁ , the effects are reversed accordingly.

Claims (13)

1. Friction clutch, in particular for motor vehicles, with a clutch housing ( 9 ) which can be connected in a rotationally fixed manner to a driven flywheel ( 13 ), one arranged therein, from a pressure spring ( 4 ) which is supported on the clutch housing ( 9 ), pressurized pressure plate ( 3 ) for pressing on a clutch clutch disc ( 6 ) provided with friction linings ( 11 , 12 ) on the flywheel ( 13 ), the pressure spring ( 4 ) exerting a changing contact pressure on the pressure plate ( 3 ) when engaging, characterized in that one on the pressure plate ( 3 ) acting device ( 1 ), at least in the coupled state, the contact pressure of the pressure plate ( 3 ) is changed substantially proportional to the force of the pressure spring ( 4 ). 2. Friction clutch according to claim 1, characterized in that the device ( 1 ) is designed such that the contact pressure in the train operation of the motor vehicle is increased. 3. A friction clutch, especially for motor vehicles, comprising a rotationally fixed to a driven flywheel (13) connectable to the clutch housing (9), arranged one is from a supported against the coupling casing (9) the contact spring (4) beaufschlagba ren pressure plate (3) for pressing a with friction linings ( 11 , 12 ) provided clutch disc ( 6 ) on the flywheel ( 13 ), the pressure spring ( 4 ) exerting a changing contact pressure on the pressure plate ( 3 ) when engaged, characterized by friction linings ( 11 , 12 ) made of inorganic Material with a coefficient of friction falling in a range above the sliding speed and a device ( 1 ) acting on the pressure plate ( 3 ), by means of which the pressure force of the pressure plate ( 3 ) is reduced in proportion to the force of the pressure spring ( 4 ) during pulling operation when coupling . 4. A friction clutch according to claim 2 or 3, characterized in that between the pressure plate ( 3 ) and the clutch housing ( 9 ) a relative movement limited to a predetermined range is possible and the device ( 1 ) is formed by at least one pivotable between the clutch housing ( 9 ) or flywheel ( 13 ) and pressure plate ( 3 ) arranged lever ( 2 ). 5. Friction clutch according to claim 4, characterized in that the device ( 1 ) has at least one closed joint. 6. Friction clutch according to claim 4, characterized in that the device ( 1 ) has two open joints. 7. Friction clutch according to claim 5 or 6, characterized in that with a relative movement between the pressure plate ( 3 ) and the clutch housing ( 9 ) or the flywheel ( 13 ) of the lever ( 2 ) on the pressure plate ( 3 ) exerts a compressive force. 8. Friction clutch according to claim 5, characterized in that with a relative movement between the pressure plate ( 3 ) and the clutch housing ( 9 ) of the lever ( 2 ) on the pressure plate ( 3 ) exerts a train force. 9. A friction clutch according to claim 4, characterized in that the relative movement is made possible by an elongated hole ( 20 ) provided in a leaf spring ( 17 ) connected to the pressure plate ( 3 ) and the clutch housing ( 9 ) at a connection point ( 19 ). 10. A friction clutch according to claim 4, characterized in that the lever ( 2 ) abuts on the pressure plate ( 3 ) via an arm ( 21 ) formed on it. 11. Friction clutch according to claim 2, characterized in that the device ( 1 ) is formed by at least one of the pressure plate ( 3 ) and the clutch housing ( 9 ) connected leaf spring ( 17 a), which in the direction of rotation (D) during train operation Front pivot point of the leaf spring ( 17 a) is provided on the pressure plate ( 3 ), the rear pivot point on the clutch housing ( 9 ) and a connecting line (X) through both pivot points in a mathematically positive angular range (α ₁ ) is provided, starting from a plane parallel to the friction surfaces ( 11 , 12 ). 12. A friction clutch according to claim 11, characterized in that the rear articulation point is arranged directly on the flywheel ( 13 ). 13. A friction clutch according to one or more of the preceding claims, characterized in that a low-friction bearing is provided at the contact point (cutting edge 32 ) between the pressure plate ( 3 ) and the pressure spring ( 4 ).