RU2223424C2 - Friction clutch - Google Patents

Abstract

FIELD: transport engineering. SUBSTANCE: invention relates to friction clutches with wear compensators and it is designed for use in drives of heavy trucks. Proposed friction clutch contains pressure disk installed with no possibility of rotation relative to cover plate but with possibility of limited axial shifting. At least on plate spring is installed between cover plate and pressure disk to load pressure disk in axial direction relative to cover plate, and adjusting device to provide at least approximately constant tension of plate spring during entire service life of friction clutch used in drive. Novelty is that friction clutch contains spring releases which provide axial displacement of pressure disk relative to cover plate when friction clutch is disengaged with disengagement of pressure disk and progressive distribution of load at least at this way of disengagement. EFFECT: simplified design, optimization of functional parameters, stabilization of load distribution at release of clutch, prevention of intolerable overload. 31 cl, 16 dwg

Description

 The invention relates to friction clutches, in particular to those which have a compensating wear of at least friction clutch linings, a regulating device, in particular to those described or mentioned in German applications 4239291, 4306505, 4239289, 4322677, 4418026, 4431641 and 19510095. Such friction clutches are intended, inter alia, for use in the drive circuit of a lorry and in most cases comprise mounted rotatably mounted relative to the housing, but with limited axial displacement of the pressure disk, and between the casing and the pressure disk is located at least one disk spring, which loads the pressure disk in the axial direction from the casing. The control device provided in the friction clutch provides at least approximately constant tension state of the disk spring during the service life of the friction clutch installed in the drive circuit.

 The present invention is based on the task of creating friction couplings of the kind described above, which, like their components, would be simple and economical to manufacture, and these components should also have the ability to be as simple as possible to calculate, in order to ensure optimal functioning of the friction clutch. Another task is to create friction clutches that would have as low and / or as constant load distribution as possible during shutdown, on the way to turn off the tongues of the spring disk and taking into account possible manufacturing tolerances or scatter, as well as during the service life of the friction clutch at least after releasing the clutch disc. It is also necessary to prevent an unacceptable or undesirable increase in force, which could disrupt the functioning of the control device, at the maximum possible path of switching off and during the service life of the friction clutch.

 For a friction clutch of the kind described above, in which the rotary support mounted on the casing supports the disk spring with the possibility of rotation, the disk spring loads combined with the casing without the possibility of rotation relative to it, however, the pressure disk installed with the possibility of limited axial displacement, and the adjusting device depending on wear occurring at least on the friction linings of the clutch disc biases the cup spring in the axial direction relative to the casing, the problems underlying the present invention are solved, inter alia, due to the fact that in the friction clutch there are spring-loaded exhaust means which, when the friction clutch is turned off, axially displace the pressure disk relative to the casing in accordance with the way that the pressure disk is turned off and at least One segment of this shutdown path has a progressive load distribution. This means, therefore, that the axial force exerted by the diverting means on the pressure plate when the friction clutch is switched off in at least one section of the switching movement increases. This also means that when the friction clutch engages, the axial force exerted by the diverting means on the pressure plate in at least one part of the engagement movement decreases.

 By installing such spring-loaded exhaust means in friction clutches with adjusting devices acting between the casing and the disk spring, it is possible to increase the protection against overrun when the friction clutch is turned off, namely, starting from the point or area of regulation at which the wear of the linings is compensated by the regulating device , increases the total force, which loads the Belleville spring to the rotary support from the side of the cover. This total force is created in the friction clutches of the kind described above in most cases by the liner shock absorber between the friction linings, the elements in the form of leaf springs between the casing and the pressure disk and at least one energy accumulator axially supporting the disk spring, which can be performed in aperture view. When releasing the clutch disc with the pressure plate, the pad shock absorber stops acting on the pressure plate. At this lowering point or within the path of switching off adjacent to the lowering point, the wear of the linings is compensated by the activation of the control device. This is described in more detail in the above prior art, therefore, regarding the operation and possible implementation of the control devices used in connection with the present invention, the disclosed content of these publications should be strongly referred to, so that a detailed description thereof is not required in this application.

 Through the use of spring-loaded exhaust means according to the invention, which, at least on the shut-off path remaining after releasing the clutch disc by the pressure plate, have a progressive load distribution pattern, it is ensured that the total force increases at least on this remaining shut-off path which axially supports the cup spring, i.e. loads to the rotary support from the side of the lid, due to which, accordingly, the switching force acting on the tip of the tongues of the disk spring can increase, namely, in particular, at the end of the switching path without undesired regulation, i.e. regulation not caused by wear.

 According to one use of the diverting means according to the invention, the axial supporting force acting on the disk spring which loads the disk spring to the pivot bearing on the cover side and axially supports it when the friction clutch is turned off so that it can rotate in the diameter zone of the pivot bearing can be applied exclusively by spring diverting means. It may be advisable, however, if, in addition to spring-loaded diverting means having progressive, i.e. increasing load distribution, other elastic means are used, in particular means in the form of leaf springs, which also exert axial force on the pressure plate. Additional means in the form of leaf springs can be installed between the casing and the pressure plate in such a way that on the way to turn off the friction clutch, i.e. during the displacement of the pressure plate in the off direction, they have a degressive, i.e. decreasing load distribution. The elastic characteristics of the spring exhaust means and additional spring means acting parallel to them can be coordinated with each other in such a way that the resulting resultant force acting on the pressure plate, remains almost constant along the entire possible displacement path of the pressure disk relative to the casing. Such matching is preferable when using an additional energy accumulator, which creates a predominant fraction of the force required to rotate hold the disc spring on the casing.

 According to the invention, it can be particularly advantageous if the elements in the form of leaf springs have a predetermined undulation and are connected to the casing on one side and on the pressure disk in such a way that at least with the friction mounted clutch elements in the form of leaf springs are tensioned in the axial direction of the clutch. Based on the connection of elements in the form of flat springs with a casing and a pressure plate, as well as a predetermined undulation, an additional tension of these elements is created in the form of leaf springs in the longitudinal direction. This tension of the elements in the form of leaf springs can be calculated in such a way that in the mounted state of the friction clutch there is a crimp in the longitudinal direction of these elements in the form of leaf springs. Due to the corresponding calculation of this crimp, it is possible to influence the elastic characteristic of the outlet means integrated in the friction clutch according to the invention.

 To ensure the smooth functioning of the friction clutch with the adjusting device that compensates for the wear of the pads, it may be especially advantageous if the progressive load distribution of the exhaust means, which is considered in the direction of easing, has at least approximately the entire covering path for turning off the pressure plate and the wear path for the working range of the mounted friction clutch. A predominantly progressive load distribution should continue on both sides of this operating range for at least a short distance.

 For the friction clutch design according to the invention, it can be especially advantageous if the elements in the form of flat springs extend at least approximately tangentially or at least approximately in the direction of the periphery relative to the casing or pressure plate. For mounting a friction clutch, it may be preferable if the spring-loaded outlet means are formed by leaf springs that have one middle and two end zones, and, on the one hand, the middle zone is connected to the casing or pressure plate, and, on the other hand, the end zones are connected to pressure plate or casing. At least two sets of leaf springs can also be used, the individual leaf springs being firmly connected at one end to the housing and the other to the pressure plate, the flat springs of both sets being located between the housing and the pressure disk with opposite action in the peripheral direction. Thus, one set of flat springs acts between the casing and the pressure plate in the direction of shear, and the other in the direction of tension. This means, therefore, that in accordance with the trend, one set of flat springs is tensile and the other is subjected to a bending load.

 The diverting means acting on the pressure disk according to the invention can be used advantageously in combination with friction clutches comprising a wear compensation device acting between the casing and the spring disk. Such a regulating device causes, depending on the wear and tear, in particular, on the friction linings of the clutch disc, the axial displacement of the disk spring relative to the casing. For the execution and functioning of the regulating device, it may be especially appropriate if the disk spring is axially supported by spring means with the possibility of its rotation around an annular rotary support located on the casing or supported on it. For some applications, it may be preferable if the disk spring is rotatably rotated onto the clutch casing between two bearings, of which the support supporting the disk spring when the clutch is disengaged is axially spring loaded in the direction of the disk spring or clutch casing. With this embodiment, it may be preferable if the spring-loaded support is mounted with the possibility of axial displacement. An annular rolling support provided directly axially between the clutch housing and the disk spring and the support bearing provided on the other side of the disk spring may have a contact diameter of at least approximately the same as the disk spring. It may also be advantageous if both of these supports have a contact diameter different from the cup spring. Preferably, the support leg has a smaller contact diameter than the rolling support on the lid side.

 The spring-loaded outlet means acting on the pressure disk according to the invention and the force exerted on the spring-loaded support support can advantageously act in parallel.

 For the regulation function of the regulating device provided between the Belleville spring and the clutch housing, it can be especially appropriate if, when the linings are worn, the load distribution necessary to turn off the friction clutch increases, due to which it is possible to create a force at least on a small portion of the curve of the response characteristic causing a slight axial displacement of the spring-loaded support leg. This slight axial displacement allows the regulator to compensate for the wear and tear that occurs. The Belleville spring may preferably have a characteristic that, during the displacement of the spring-loaded support leg, reduces the force required to rotate the Belleville spring. Owing to this embodiment of the disk spring, it is possible to ensure the equilibrium between the forces acting on both sides axially on the disk spring when there is wear on the linings. Preferably, the cup spring, at least on a part of the switch-off path, in particular on the segment within which the regulation takes place, can have a steep force-path characteristic.

 The axial force exerted on the supporting support can advantageously be provided by an energy accumulator, which generates a substantially constant or increasing force in the control range of the adjusting device required during the life of the friction clutch. The axially malleable or movable supporting support can be simply formed or at least loaded with a disk spring part.

 For some friction clutches, it may be preferable if spring means in the form of leaf springs are provided between the casing and the pressure plate, which load the pressure disk in the direction of disengagement of the friction clutch, act parallel to the spring exhaust means and, at least, on the way to turn off the pressure disk have a degressive characteristic of effort. With such a friction clutch, the spring-loaded supporting support described above may not be necessary. Spring means in the form of leaf springs can advantageously be firmly or rigidly connected to the casing and the pressure plate. The arrangement of the spring means in the form of leaf springs may be such that at least a part of the torque transmitted between the casing and the pressure disk is transmitted by them. It is advisable that the spring means in the form of leaf springs transmit almost the entire torque, so that in this case the spring discharge means do not experience additional load. For the functioning of the regulating device, it can be especially preferable if, due to the axial displacement of the pressure plate during the friction clutch service life relative to the casing, the return force exerted by springing means in the form of leaf springs on the pressure disk increases.

 For friction clutches in which the Belleville spring is only axially supported during spring-up by means of spring means provided between the housing and the pressure plate, it is especially advisable if the resulting force generated by these spring means is at least approximately constant, at least along the axial path the displacement of the pressure plate due to wear, in particular on the friction linings of the clutch disc during the life of the friction clutch. The resulting force generated by the application of spring force exhaust means and additional spring means in the form of leaf springs and loading the pressure plate in the direction of withdrawal or shutdown should therefore be at least approximately constant. For some applications, it may be appropriate if this resulting force increases at least slightly along the axial path of the displacement of the pressure plate relative to the casing. This increase can be about 5-25% of the initial value.

 A particularly simple and economical implementation of the friction clutch can be achieved due to the fact that it contains a disk spring, which, in the switched-on state of the friction clutch, is supported by an annular swivel bearing located on the casing or supported by it, and the pressure plate loading axially in the direction of this swivel bearing directly or indirectly spring elements, and these are at least spring means in the form of leaf springs for transmitting cr torque, the spring-loaded diverting means provided between the casing and the pressure plate, and the pad shock absorber provided, if necessary, between the friction linings of the clutch disc, create a resulting supporting force that counteracts the disengaging force acting on the disk spring when the friction clutch disengages and which, at least when released or with at least approximately complete unloading of the friction linings with a pressure plate, at least approximately Corresponds to the resulting resulting force acting in the direction of shutdown on the cup spring. Friction clutch can be made in such a way that, at least after releasing the friction linings of the clutch disc by the pressure plate and / or, at least in the fully friction clutch state, only spring return means and spring means in the form of leaf springs are applied to the pressure spring the disk is a force that axially counteracts at least the turning-off force acting in this case and is predominantly slightly higher than it, or is at least in equilibrium with it.

 The spring-loaded outlet means according to the invention with progressive load balancing when the friction clutch is switched off can also be used advantageously in combination with self-regulating friction clutches known, for example, from the German Federal Patent Application 19524827. With this combination, a disk spring loaded with a pressure plate can be mounted without turning relative to the casing clutch, and due to the principle of operation of the discharge means acting on the pressure disk according to the invention, nevertheless the load distribution of the switch-off, which is almost constant throughout the wear, is less ensured, i.e. friction clutch life. The rotation of the cup spring relative to the casing, for example, due to high angular accelerations of the engine, can be prevented with this form of execution. With regard to structural and functional features, reference should be made to the application of Germany 19524827, so that its content should be considered as integrated into the present application.

The invention is explained in more detail using the drawings, depicting:
figure 1 - friction clutch according to the invention;
figure 2 is a section along the line II-II of figure 1;
figure 3 is an enlarged view of the arrow III in figure 1;
FIG. 4 - provided between the casing and the pressure plate of the friction clutch spring spring outlet means when viewed from above;
5 is a view along arrow V of FIG. 4;
FIG. 6 - provided between the casing and the pressure plate of the friction clutch spring element in the form of a leaf spring;
7-9 are diagrams with the operating characteristics of the friction clutch and its parts;
FIG. 10 - friction clutch;
11 is a view along arrow XI of FIG. 10;
12-14 are diagrams with friction clutch performance characteristics of FIGS. 10 and 11 and its details;
FIG. 15 is a sectional view of another friction clutch made in accordance with the invention;
FIG. 16 - Belleville spring for use in the friction clutch of Fig.15.

 Depicted in FIG. 1 and 2, the friction clutch 1 comprises a casing 2 and a pressure plate 3 connected to it without rotation, but with the possibility of limited axial displacement. Axially between the pressure disk 3 and the cover 2, a pressure disk spring 4 is tensioned, which is mounted to rotate around an annular rotary support 5 located on the casing 2 and loads the pressure disk 3 in the direction of the back pressure disk 6, for example, flywheel, which is firmly connected to the casing 2, due to which friction pads 7 of the clutch disc 8 are clamped between the friction surfaces of the pressure plate 3 and the back pressure disk 6.

 The pressure disk 3 is connected without rotation with the casing 2 by means of leaf springs 9 located in the direction of the periphery or tangentially. In the depicted exemplary embodiment, the clutch disc 8 contains the so-called spring-loaded lining segments 10, which, when the friction clutch 1 is turned on, provide a progressive increase in torque due to the fact that, during the limited axial displacement of both friction linings 7, they provide a progressive increase in the effective on friction linings 7 axial forces. However, a clutch disc can also be used, in which the friction linings 7 are axially almost rigidly fixed to the carrier disc.

 In the depicted exemplary embodiment, the disk spring 4 comprises an annular base 4a that generates a pressing force, from which the actuating tabs 4b radially outwardly extend. The disk spring 4 is thus installed in such a way that it loads the pressure plate 3 by lying radially farther outward and has the possibility of tipping around the pivot bearing 5 lying radially farther inward.

 As can be seen, in particular, from figure 3, in the depicted exemplary embodiment, in addition to spring means 9 in the form of leaf springs, means 11 in the form of leaf springs act between the casing 2 and the pressure plate 3. Additional springing means 11 made in the form of leaf springs are tensioned between the casing 2 and the pressure plate 3 so that in the on state of the friction clutch 1 they exert an axial force on the pressure disk 3, which forces the pressure disk 3 in the direction of the casing 2. For this, in the form of leaf springs, spring means 11 are firmly connected with their end zones 12 to the casing 2, and the intermediate zone 13 lying between these end zones 12 with the pressure disk 3. End zones 12 in the illustrated embodiment riveted to the housing 2 by the expansion fingers 14. The intermediate zone 13 in the illustrated embodiment, together with the segment 15, the elements 9 in the form of leaf springs is firmly connected by means of a rivet or pin 16 with a radial projection or cam 17, the pressure plate 3.

 As can be seen from FIG. 3, several stacked elements 9 and 11 in the form of leaf springs can be used. So, for example, two stacked elements 9 and three stacked elements 11 in the form of leaf springs can be used, moreover, the connection shown in Fig. 3 between the casing 2 and the pressure plate 3, mainly when viewed around the periphery of the friction clutch 1, made in three places, namely mainly at an equal angular distance.

 Elements 11 in the form of leaf springs are made and tensioned in such a way that when the friction clutch 1 is turned off, they axially displace the pressure disk 3 in the direction of the casing 2 in accordance with the way the pressure disk 3 is turned off and, at least along this switching path, have a progressive load distribution . The latter means that, if you look at the shutdown path or the exhaust path of the pressure plate 3, the axial force exerted by the elements 11 in the form of leaf springs increases at least in one segment, mainly over the entire range of the shutdown path or the path of removal of the pressure disk 3.

 Elements 9 in the form of leaf springs are also installed with an axial tension between the casing 2 and the pressure plate 3. The tension of the elements 9 in the form of leaf springs is such that, if you look at the path to turn off the pressure disk 3, the axial force exerted by the elements 9 in the form of leaf springs on the pressure plate 3, is in the direction of turning off the pressure disk 3 degressive, that is, decreases. The forces exerted by the elements 9, 11 in the form of leaf springs on the pressure plate 3, therefore, act in the same axial direction and are thereby summed.

 As can be seen from figures 4 and 5, the elements 11 in the form of leaf springs consist of a relatively thin sheet material, which can have a thickness of the order of 0.2-0.6 mm, and if necessary, a thicker material can also be used. Mostly the elements 11 in the form of leaf springs are stamped from tape or plate-shaped spring steel, and in the stamp they can simultaneously acquire the desired shape. Elements 11 in the form of leaf springs are oblong, and in the end zones 12 they have a broadening made in the form of a head, and the middle zone 13 is also broadened. In the broadened zones 12, 13, openings 12a, 13a are made, which serve to provide a suitable connection, in particular riveting. From figure 5 it is seen that in an unstressed state, elements in the form of leaf springs are made between the end zones 12 convex. In this case, the shape is selected with the possibility of providing the desired force-path characteristic curve in the state built into the friction clutch 1.

 As can be seen from the comparison of FIGS. 3 and 5, the elements 11 in the form of leaf springs in the state integrated in the friction clutch and at least when the friction clutch 1 is engaged are deformed in the axial direction of the clutch and are also crimped in their longitudinal direction. Due to this, forces or stresses introduced into the elements 11 in the form of leaf springs create, at least in the switched-on state of the friction clutch 1, axial convexity on both sides of the middle fixing zone 13. Due to the appropriate choice of the distance between the attachment points, which in the illustrated embodiment are formed by spacer fingers 14, it is possible to determine the stresses introduced into the elements 11 in the form of leaf springs or to influence their deformations. In the integrated state, the elements 11 in the form of leaf springs, therefore, are tensioned both in the axial direction of the friction clutch and in the direction of the periphery or in the longitudinal direction.

 As can be seen from figure 3 and 6, the elements 9 in the form of leaf springs have a U-shaped cut 18, which covers the tongue-shaped section 19 or forms it. On both sides of the tongue-shaped portion 19, the cutout 18 is bounded by jumpers 20. Both jumpers 20 and the tongue-shaped portion 19 are connected by segments 21. At their other end, the jumpers 20 are connected by a portion 22, and this portion 22 passes into the longitudinally extending depicted element 9 in the form of a leaf spring, a tongue or extension 23. In the free end zone 24 of extension 23, an opening 25 is made by which a connection, for example a rivet connection, is formed with the clutch cover 2 or the pressure plate 3. The tongue-shaped section 19 also has an opening 27 adjacent to the free end zone 24 for forming a rivet connection with the clutch casing 2 or the pressure plate 3. As can be seen from Fig. 3, in the illustrated embodiment, the section 19 is riveted with the pressure disk 3, and the end section 24 with a casing 2. From figure 3 it is further seen that the elements 11 and 9 in the form of leaf springs are firmly connected to the corresponding part 2 and 3 by the same rivet elements 14, 16. The tongue-shaped sections 19 are rotated or axially displaced relative to the others astck elements 9 in the form of leaf springs, at least in the state integrated in the clutch, namely in such a way that the elements 9 in the form of leaf springs are elastically tensioned when viewed in the axial direction of the friction clutch 1, namely in such a way that the force provided by the elements 9 in the form of leaf springs on the pressure plate 3, displace it in the direction of the casing 2.

 The illustrated embodiment according to the invention of the elements 9 in the form of leaf springs allows for a relatively short structural length to realize a relatively long bending path between both fixing points 25, 27.

 The diagram in Fig.7 shows the force-path curves of the elements 9, 11 in the form of leaf springs and the resulting characteristic. In this case, a spring stroke is applied on the abscissa axis, and a force is applied on the ordinate axis.

 Curve 28 represents the elastic characteristic of the elements 9 in the form of leaf springs used in connection with the friction clutch 1. In the illustrated embodiment, the elements 9 in the form of leaf springs create a proportionally increasing, i.e. direct characteristic force-path. Due to the corresponding design and shape of the elements 9 in the form of leaf springs, however, it is possible to create another characteristic, which, at least on one segment, can be curved.

 Curve 29 corresponds to the elastic characteristic of the elements 11 in the form of leaf springs intended for use with friction clutch 1. From curve 29 it is seen that, based on the weakened position, the elements 11 in the form of leaf springs first have a practically linear increase in force in accordance with section 30. First, what happens depending on the deformation path, the increase in force gradually decreases after section 30, and starting from a certain deformation path, the force y created by elements 11 in the form of leaf springs enshaetsya increasing deformation path, namely in accordance with the segment 31, which in the illustrated embodiment extends straight. Due to the corresponding implementation of the elements 11 in the form of leaf springs, the segment 31 may decrease more or less steeply as the deformation path increases. When calculated according to the diagram in Fig. 7, sections or segments 30, 31 of curve 29 are straight lines. These sections 30, 31 can pass, however, due to the corresponding execution of the elements 11 in the form of leaf springs, at least on one segment curved. Both curves 28, 29 are coordinated with each other in such a way that the resulting curve 32 has a region 33 within which the axial force exerted by the leaf springs 9, 11 acting on the pressure plate 3 is at least approximately constant. This also, which is explained in more detail below, provides at least an approximately constant friction clutch operating point of FIG. 1-3 in its on state. This also provides at least an approximately constant operating range for the cup spring 4.

 To deactivate the friction clutch 1, the ends of the disc spring tongues lying radially inside 4c through the switch-off bearing exert a force in the direction of arrow A. As a result, the disc spring 4 rotates around the rotary support 5 in the form of a two-shouldered lever, as a result of which the pressure plate 3 is gradually unloaded and under the action of the elements 9, 11 in the form of leaf springs, following the outer edge of the cup spring 4, is shifted in the direction of the casing 2. Moreover, after exceeding a certain range of the common path of switching off, dit release the friction linings 7 of the clutch disc 8. Until this release, the liner absorber provided between the friction linings 7 contributes to the shutdown process. After complete unloading or releasing of the friction linings 7 by the pressure disk 3, it is pressed against the disk spring 4 only by elements 9, 11 in the form of leaf springs. The abutment between the cup spring 4 and the pressure plate 3 occurs through the cams 3a of the pressure disk 3.

 Swivel bearing 5, at a radial height of which the Belleville spring 4, when actuating the friction clutch 1 is rotated like a two-arm lever, includes only the support ring 34, sandwiched between the casing 2 and the Belleville spring 4, at least in the on state of the friction clutch 1 The ring 34, forming one rotary support for the disk spring 4, is supported on the casing 2 through the adjusting device 35. This adjusting device 35 prevents the formation of a gap between the ring 34 and the disc spring 4 p and axial displacement of the diaphragm spring 4 in the direction of the disk 6 back pressure due to wear of the friction linings 7. This axial displacement of the diaphragm spring 4 described in more detail below.

 The annular part 34, which carries or forms simultaneously a rolling support for the Belleville spring 4, has axially increasing ramps 36 extending in the direction of the periphery and distributed along the periphery of the rampart 34. The ramps 36 are based on the reciprocal ramps 37 minted in the lid.

 Slopes 36, 37 are made in the direction of the periphery with respect to their length and straightening angle with the possibility of providing at least one angle of rotation of the ring 34 relative to the casing 2, which during the service life of the friction clutch 1 provides control of the wear that occurs on the friction surfaces of the pressure plate 3 and disc 6 back pressure, as well as on the friction lining 7. In relation to the execution and design of such slopes should refer to the application of Germany 4322677, the contents of which should be considered as integrat included in this application.

 The ring 34 is spring-loaded in the direction of the periphery, namely, in the direction which, due to the incline of the slopes 36 on the response slopes 37, causes the axial displacement of the ring 34 in the direction of the pressure plate 3, i.e. axially from the casing 2. As can be seen from figure 1, the spring of the adjusting ring 34 is provided by helical springs 38, which extend in the direction of the periphery of the cover 2 and are tensioned between the adjusting ring 34 and the casing 2. The springs 38 exert a cup spring 4 through slopes 36, 37 axial force directed in the same direction as the shut-off force, i.e. arrow A.

 In connection with the characteristics shown in the diagrams of FIG. 7-9, the principle of operation of the friction clutch 1 described above should be explained in more detail.

 Curve 40 in FIG. 8 represents the force exerted by the Belleville spring 4 when it is axially deformed between two bearings, the radial distance between which corresponds to the radial distance between the rotary bearing 5 and the radially external bearing diameter 3a. Curve 41 represents a characteristic of the force that must be applied to the pressure plate 3 against arrow A in order to conically deform the disk spring 4 in the friction clutch 1. The force difference between the curves 40, 41 corresponds to the force exerted by the elements 9, 11 in the form of leaf springs. This force counteracts the force exerted by the disk spring 4 on the pressure disk 3. Point 42 represents the integrated position of the disk spring 4 when the friction clutch 1 is engaged, i.e. the position in which the cup spring 4 exerts maximum pressure on the pressure plate 3 for the corresponding integrated position. Point 42 may move up or down along curve 41 when the conical integrated position of the cup spring 4 changes.

 Curve 43 represents mainly the axial spacer force applied by the spring segments 10 of the linings, which acts between the two friction linings 7. This characteristic further contains all spring effects acting in the same way as the liner shock absorber, for example, the elasticity of the cover, the elasticity of the friction linings, etc. . This axial spacer force counteracts the axial force exerted by the cup spring 4 on the pressure plate 3. When the friction clutch 1 is turned off, the spring segments 10 are loosened, namely, on the path 44. On this path 44, which corresponds to the corresponding axial displacement of the pressure disk 3, the clutch disengages 1 is supported by said spacer force. Due to this, the applied maximum turn-off force is less than the force that would correspond to the point of incorporation 42 in the absence of spring segments 10 of the pads. When the point 45 is exceeded, the friction linings 7 are released by the pressure disk 3, and due to the degressive region of the characteristic of the spring disk 4, the then applied switching force is significantly reduced compared to the force that would correspond to point 42. The force of the disk spring 4 overcome to deactivate the friction clutch 1 decreases when exceeding point 45 until a minimum is reached in accordance with point 46. If you exceed point 46 in the off direction, the necessary response friction clutch 1, the shut-off force increases again. However, means can be provided, for example an additional spring, which at least reduce a similar increase in the shut-off force. Such funds are described in the application of Germany 19510905.

 Figure 9 shows a characteristic 47 of the shutdown force, which should be applied to turn off the friction clutch 1 in the zone of the tips 4c of the reeds. The turn-off path required in the region of the ends of the tongues 4c is correspondingly increased in comparison with the axial travel of the Belleville spring in the region of the support diameter 3a or the stroke of the pressure plate 3 by the gear ratio of the lever of the Belleville spring 4 and by the amount of deflection of the tongues 4b. This gear ratio of the disk spring or lever approximately corresponds to the ratio of the radial distance between the pivot bearing 5 or 34 and the actuating diameter in the region of the ends of the tongues 4c to the radial distance between the pivot bearing 5 or 34 and the supporting diameter 3a. This gear ratio is in most cases about 3: 1-5: 1. The characteristic of the magnitude of the shutdown force with respect to the actuating diameter in the region of the ends of the tongues 4c is reduced in accordance with this gear ratio compared with the force characteristic in the corresponding region of the spring characteristic 41 in FIG. 8.

 FIG. 8 further shows the release path 48 of the pressure plate 3. The end point of the release path 48 or the entire shutdown path 50 with respect to the pressure disk 3 is indicated on characteristic 41. 49. The release path 48 or the shutdown path 50 is usually designed such that even when the full shutdown path is reached, the shutdown force corresponding to the end point 49 is less than the shutdown force corresponding to the point 45.

 The points 28a, 29a, 32a of the corresponding curves 28, 29, 32 represent the forces and the sum of the forces exerted or exerted by the elements 9, 11 in the form of leaf springs on the pressure plate 3 in the on state of the new friction clutch 1. The points 28b, 29b, 32b represent the corresponding forces exerted in the off state of the new friction clutch 1 and with the new clutch disc 8 by elements 9, 11 in the form of leaf springs on the pressure plate 3. Points 28c, 29c, 32c of curves 28, 29, 32 correspond to the applied elements 9, 11 in the form leaf springs and the sum of these efforts exerted or exerted on the pressure plate 3 with a completely worn clutch disk 8. The almost horizontally extending region 33 of the resultant force characteristic 32 shows that during the entire service life of the friction clutch 1, a practically constant axial supporting force is exerted on the pressure plate 3 and thereby also on the disk spring 4.

 Elements 9, 11 in the form of leaf springs serve the clutch structure in FIG. 1-6 as a force sensor or sensor, which, in cooperation with the adjusting device 35, compensates for wear that occurs at least on the friction linings 7.

 In order to deactivate the friction clutch 1, the ends of the reeds 4c through the deactivation bearing or the deactivation system exert an actuating force along arrow A in FIG. 2. The characteristic force required to turn off the friction clutch 1 in the region of the ends 4c of the reeds is shown, as already mentioned, in FIG. 9 of curve 47. From FIG. 9, it can be seen further that in the first region 51 of the reed ends 4c of the predetermined common switch-off path 52 considered in the region of the tongue ends 4c, the force required to rotate the cup spring 4 increases in accordance with the curve segment 47a. In area 51, the resulting axial force acts on the pressure disk 3, which is directed axially in the direction of the casing 2 and is formed by the sum of the axial forces created by the spring segments 10 of the plates and elements 9, 11 in the form of leaf springs. The curve segment 53 passing in region 51 represents the tension force between the pressure plate 3 and the disk spring 4. Point 54 represents the state of the activated friction clutch 1, in which the pressure disk 3 at least substantially completely unloads the friction linings 7 of the clutch disk 8 . If the point 54 is exceeded in the deactivation direction, the deenergizing force necessary for actuating the friction clutch 1 changes in accordance with the segment 47b of curve 47. When the point 54 is exceeded, the axial force exerted by the spring segments 10 of the overlays on the pressure plate 3 disappears, so that only the resulting axial the force created by the leaf springs 9, 11 loads the pressure plate 3 to the cup spring 4. This is the resulting axial force in accordance with the region 33 of the curve in FIG. 7 is present in at least the characteristic region 55 in FIG. 9. From Fig. 9 it is seen that when the point 54 is exceeded due to the then steeply falling region of the characteristic of the Belleville spring 4, the axial force over a certain section of the path, namely, to the point 56, is less than the supporting force acting on the Belleville spring 4 in accordance with the region 55 of the characteristic. This ensures that the cup spring 4 continues axially adjacent to the rolling support 34 and is thereby axially supported by the cover 2. Point 54 in FIG. 9 corresponds to point 45 in FIG. 8. Point 57 in FIG. 9 corresponds to point 49 in FIG.

 As can be seen from Fig. 9, the friction clutch 1 is designed in such a way that the point 57 corresponding to the common switch-off path 52 is removed from the intersection point 56 of the characteristic characteristic areas 47b, 55, so that even if the predetermined common switch-off path 52 is exceeded by a certain amount, unintentional regulation due to the unloading of the ring 34 by a Belleville spring 4. The switching system interacting with the friction clutch 1 must therefore be designed in such a way that the point 56 is never exceeded. In order to avoid exceeding point 56 when the friction clutch 1 is activated, an emphasis can be provided that limits the response path or the angle of rotation of the disk spring 4. In FIG. 2, this emphasis can be formed, for example, by an annular section 58. Due to the corresponding extension of the tongues 4b of the disk spring then when the friction clutch 1 is turned off, the ends 4c of the reeds can abut against this stop 28 almost before reaching point 56. With regard to the functioning and location of such a stop 58, as well as for others For embodiments that prevent the friction clutch overrun during disengagement, refer to the German application 4322677. This publication also describes measures to limit the maximum applied shut-off force acting on the disc spring tongues 4b.

 The above considerations corresponded to the perfectly defined axial integrated position of the cup spring 4, and so far the wear of the friction linings 7 has not been taken into account.

 With axial wear, in particular of friction linings 7, the position of the pressure disk 3 is shifted in the direction of the back pressure disk 6, as a result of which the taper changes and thereby also the pressure exerted by the disk spring in the on state of the friction clutch 1, namely in the sense of increase. This change causes point 42 to move in the direction of point 42 'and point 45 in the direction of point 45'. As a result of this change, the balance of axial forces that existed initially when the clutch 1 was turned off in the state of the activated clutch at point 45 is violated. The increase in the pressing force of the disk spring to the pressure disk 3 caused by the wear of the pads also causes a shift in the characteristic of the switching off force in the sense of increasing. Due to this increase in the characteristic of the disengagement force, in the process of disengaging the friction clutch 1, the resulting axial force exerted by the springing means 9, 11 in the form of leaf springs on the disk spring 4 is overcome, so that the disk spring 4 is shifted or rotated by the axial value in the radial zone of the rotary bearing 5 the course of the movement, mainly corresponding to the wear of the friction linings 7. During this phase of rotation or deflection of the disk spring 4, the latter can rest on the load section 3a of the pressure plate ska 3, so that the disk spring 4 changes its taper and thereby also the energy stored in it or the torque stored in it and, as a result, also the force exerted by the disk spring 4 on the pressure plate 3. This change occurs, as seen in connection with FIG. 8, in the sense of reducing the force exerted by the spring disk 4. This change occurs until the axial force exerted mainly by the disk spring 4 and the springs 38 in the region of the support 3a on the pressure plate 3 is in balance with the response force created by the spring means 9, 11 in the form of leaf springs. This means that in the diagram of Fig. 8, the points 42 'and 45' will again shift in the direction of points 42 and 45. After this balance is restored again, the disk spring 4 can be rotated at the radial height of the rotary support 5 and thereby can again retract the pressure plate 3 from the friction linings 7. During this phase of the wear control during the friction clutch disengagement 1, the adjusting ring 34 of the adjusting device 35 is rotated by tensioned springs 38. At the end of the adjustment process, the force characteristic is turned off At least basically again corresponds to curve 47 in FIG. 9.

 In practice, the described regulation takes place continuously or in very small steps, so that large displacements of the points shown in the diagrams for a better understanding of the invention usually do not occur.

 The friction clutch 101 shown in FIGS. 10 and 12 comprises a casing 102 and a pressure plate 103 connected to it without rotation, but with limited axial displacement. Axially between the pressure disk 103 and the cover 102, a pressure disk spring 104 is tensioned, which is mounted to rotate around an annular swivel support 105 located on the casing 102 and loads the pressure disk 103 in the direction of the back pressure disk 106, such as the flywheel, which is firmly connected to the casing 102, thereby the friction linings of the clutch disc are clamped between the friction surfaces of the pressure plate 103 and the back pressure disk. Such a device is shown in figure 2.

 The pressure disk 103 is rotatably connected to the casing 102 by means of flat springs 109 located in the direction of the periphery and tangentially. The leaf springs 109 transmit torque between the pressure plate 103 and the casing 102. The leaf springs 109 may have a certain tension. In this case, leaf springs 109 can be installed in such a way that, in the integrated state of the friction clutch 101, this tension displaces the pressure plate 103, at least in the section of the switching path, axially in the direction of the casing 102. For some applications, however, it may be advisable if the leaf springs 109, at least in a portion of the shutdown path of the pressure plate 103 exert a force on it, counteracting the axial displacement of the pressure plate 103 in the direction of shutdown.

 The spring disk 104 comprises a ring-shaped base 104a which generates a pressure force, from which the actuating tongues 104b radially inwardly extend. In this case, the spring disk 104 is installed in such a way that it loads the pressure disk 103 by lying radially farther outward and has the possibility of tipping around the pivot bearing 105 lying radially further inward.

 11 shows that in addition to the spring means 109 in the form of leaf springs between the casing 102 and the pressure disk 103, spring means 111 in the form of leaf springs are provided. Spring means 111 in the form of leaf springs are arranged, formed and operate in the same way as described in connection with spring means 11 in the form of leaf springs in FIGS. 1-5.

 The function of the axial support for the cup spring 4, carried out by the elements 9 in the form of leaf springs in FIGS. 1-3 and 6, is carried out in the embodiment of FIGS. 10 and 11 by the energy accumulator 159 in the form of a cup spring or diaphragm. The disk spring energy accumulator 159 comprises a spring base 159a having radially inside portions of tongues or protrusions 159b that abut against the disk spring 104 or its tongues 104b, with which the disk spring 104 is axially supported. Radially outwardly, the energy accumulator 159 in the form of a disk spring has sections 159c formed, for example, by radially spaced tongues or protrusions. With these outside sections 159c, the energy accumulator 159 in the form of a disk spring is axially supported by the casing 102. For this, the casing 102 has corresponding sections 160 formed in the illustrated embodiment by the heads riveted with the casing 102 of the spacer fingers 161. The fingers 161 are located on a certain diameter of the casing 102 and axially pass through holes made in the spring disk 104. With fingers 161, the energy accumulator 159 in the form of a disk spring is held centered relative to the case 102. The disk spring 104 is also centered relative to the case 102 with the fingers 161. Advantageously, the fingers 161 are evenly distributed around the periphery, and their number can be about 3-18.

 The support ring 134, forming an annular swivel support for the disk spring 104, is located and acts between the casing 102 and the disk spring 104 in the same way as was described in connection with the reference ring 34 of the friction clutch in accordance with figure 1-3.

 The elastic characteristics of the individual spring parts 104, 109, 111, 138, 159 are coordinated with each other in such a way that, at least approximately when released, i.e. with almost complete unloading of the friction linings of the clutch disc, which interacts with the friction clutch 101 installed in the car, the sum of the switching off force acting on the ends of the tongues 104c in the direction of arrow A and the axial force exerted by the springs 138 through the ring 134 to the belleville spring 104 is in equilibrium or slightly less than the sum of the axial force exerted by the elements 109, 111 in the form of leaf springs on the disk spring 104, and the axial force exerted by the energy accumulator 159 in the form of a disk spring also on that coil spring 104. This is an equilibrium or quasi-equilibrium state between the forces acting on both sides of the friction clutch 101 on the cup spring 104, therefore, is comparable to or corresponds to point 45 of curve 41 in FIG. When the friction linings of the clutch disc interacting with the friction clutch 101 are worn, this equilibrium is violated in the same way as described in connection with Figs. 8 and 9, as a result of which the corresponding regulation also occurs. This regulation causes a minor axial displacement of the disk spring 104 in the direction of arrow A. Due to this displacement, the adjusting ring 134 supported by the slopes on the cover 102 is unloaded, so that it is rotated by the springs 138 and, due to the action of the slopes, continues to follow the disk spring 104, continuing to adhere to it. Due to the axial displacement of the disk spring 104 in accordance with the occurring wear, in particular on the friction linings of the corresponding clutch disc, the tension state of the energy accumulator 159 in the form of a disk spring also changes.

 As can be seen from FIG. 10, due to the radial displacement of the energy accumulator 159 for the Belleville spring 104 between the rotary support for the Belleville spring 104 formed by the ring 134 and the ring-shaped support portion 159c when the friction clutch 101 is actuated, the energy accumulator 159 is elastically deformed, namely way that he changes his taper. This deformation of the energy accumulator 159 in the form of a Belleville spring can be used to increase the protection against overrun when the friction clutch 101 is actuated. This occurs in the illustrated embodiment due to the fact that, as the shutdown path increases in the area of the ends of the tongues 104c, i.e. as the elastic deformation of the energy accumulator 159 increases, this energy accumulator 159 creates an increasing force axially acting on the spring disk 104.

 The diagram of Fig. 12 shows the resulting force-path characteristic of the elements 109, 111 in the form of leaf springs. If you do not use elements 109 in the form of leaf springs, then the elastic characteristics of the elements 111 in the form of leaf springs must be adjusted accordingly so as to at least approximately obtain a curve 129. In the absence of elements 109 in the form of leaf springs, the transmission of torque between the pressure disk 103 and the casing 102 may occur, for example, by means of a geometric closure. In the depicted exemplary embodiment, this transmission of torque can occur through the fingers 116, based on the corresponding sections of the casing 102.

 The sinusoidal shape of curve 129 is achieved mainly or exclusively by an elastic characteristic created by elements 111 in the form of leaf springs. As can be seen from figure 2, the sinusoidal curve 129 has a segment 131, within which, as the strain path increases, the force decreases. The segment 131 may extend at least approximately linearly or slightly curvilinearly.

 With the mounted friction clutch 101 and a new clutch disc, the elements 109, 111 in the form of leaf springs are in the tension state corresponding to the point 129a of the curve 129. The point 129a of the curve 129 corresponds to the tension state of the elements 109, 111 in the form of leaf springs when the new friction clutch with the new clutch disc.

 Due to the wear that occurs during the life of the friction clutch 101, in particular on the friction linings of the clutch disc interacting with this friction clutch 101, the pressure plate 103 and thereby also the cup spring 104 are shifted to the right (FIG. 10), t. e. away from the casing 102. Due to this displacement of the parts 103, 104 relative to the casing 102, the tension state of the elements 109, 111 in the form of leaf springs and the energy accumulator 159 in the form of a disk spring also changes. This means that (in FIG. 12) points 129a, 129b are shifted along the degressive segment 131 in the direction of the minimum. The point 129c corresponds to the tension state of the elements 109, 111 in the form of leaf springs with the friction clutch engaged and the maximum allowable wear on the friction linings of the corresponding clutch disc.

 In the diagram of FIG. 13 shows a force-path characteristic 128 of an energy accumulator 159 in the form of a disk spring. Curve 128 has a segment 162 extending almost linearly or slightly curvilinearly. The point 128a corresponds to the tension state of the energy accumulator 159 with a new friction clutch 101 mounted on the counter-pressure disk with a corresponding new clutch disk. Point 128b corresponds to the tense state of the energy accumulator 159 when the new friction clutch with the new clutch disc is off. The point 129b corresponds in this case to the actuation state of the friction clutch 1, at which the ends 104c of the reeds are axially displaced by the predetermined switch-off path in the direction of arrow A. If this predetermined switch-off path deviates, the point 129b shifts accordingly. If the predetermined shutdown path is exceeded, point 129b shifts in the direction of point 128c. Due to wear occurring during the life of the friction clutch 101, in particular on the friction linings of the corresponding clutch disc, points 128a, 128b are displaced along line 126 in the direction of point 128c. The point 128c corresponds to the off state of the friction clutch 101 at the maximum allowable wear on the friction linings of the corresponding clutch disc.

 As can be seen from curves 128, 129 in FIGS. 13, 12, in the process of disengaging the friction clutch 101, the corresponding axial force exerted by the elastically tensioned parts 109, 111 on the disk spring 104 increases. In the process of disengaging the friction clutch 101, the resulting force therefore becomes larger acting on the disk spring 104 axially in the direction of the cover 102. This resulting force forces the disk spring 104 to be axially displaced to the annular pivot bearing 134 so that the disk spring 104 can change be taper around this annular pivot bearing 134. Due to this, the disk spring 104 can swing around the annular pivot bearing 134 like a two-arm lever 134.

 In order to achieve an almost constant characteristic of the shut-off force during the service life of the friction clutch 101, the characteristics or elastic characteristics of the energy storage batteries loading the disk spring 104 to the run-in support 134, and in the embodiment of FIGS. 10 and 11, these are elements 111 in the form of leaf springs provided in if necessary, the elements 109 in the form of leaf springs and the energy accumulator 159 must be coordinated among themselves so that when releasing or almost completely unloading the loaded the total disc force generated by these energy accumulators was at least approximately in equilibrium with the total force acting on the other side of the disk spring, formed according to the exemplary embodiment shown, the shut-off force and axial force created by the springs 138 through slopes between the rolling support 134 and the casing 102. Thanks to this embodiment, it is ensured that due to wear of the axial displacement of the plates chatoy spring 104 and pressure plate 103 in a direction away from the housing 102 in the off state of the friction clutch 101 on the disc spring 104 always operates the same or at least approximately the same axial supporting force. The mentioned equilibrium between the resulting forces or the total forces acting on the disk spring 104 from both sides is violated by wear, in particular, on the friction linings of the clutch disc interacting with the friction clutch 101, namely, until this balance is again established and turned off during shutdown appropriate compensation will occur for any wear and tear that has occurred before. This principle has already been described in more detail in connection with the embodiment of FIGS. 1-9. In this regard, reference should already be made to the prior art already described, which describes this regulation principle in detail. Due to the aforementioned coordination between the individual energy accumulators acting on the disk spring 104 and supporting it, at least during shutdown, on the one hand, therefore, it is ensured that during unloading or at least approximate unloading of the friction linings of the clutch disc during the entire service life of the friction clutch, the disk spring 104 has a practically constant or supporting force lying in a predetermined range, and, on the other hand, that, at least e, when this release point is exceeded or the release range is relatively narrow, the support force acting on the cup spring becomes higher as the switch-off path increases, so that, as described in more detail in connection with FIG. 14, the overrun protection is substantially increased or can be increased. when actuating the friction clutch.

 The diagram in FIG. 14 is comparable to the diagram in FIG. 9. FIG. 14 also shows a characteristic 147 of the turning off force, which must be applied to turn off the friction clutch 101 in the region of the ends of the reeds 104c. In the first segment 151 of the shut-off path, the resulting axial support force acts on the cup spring 104 in accordance with curve 153.

 In the first segment 151 of the recesses of the predetermined common switch-off path 152 considered in the region of the tongue ends 104c, the switch-off force necessary for actuating the friction clutch 101 has a characteristic in accordance with the section 147a. In this segment 151, the resulting axial force acting on the pressure plate 103 in the axial direction of the casing 2 has a characteristic in accordance with section 153. The force characteristic in accordance with section 153 corresponds to the resultant force produced by the shock absorber provided between the friction linings interacting with the friction clutch 101 the clutch disc, elements 109, 111 in the form of leaf springs and an energy accumulator 159 in the form of a disk spring. Upon reaching point 154, the shock absorber between the friction linings of the corresponding clutch disc is completely or almost completely weakened. When the point 154 or narrow region 154 is exceeded, the disk spring 104 is supported only by the resulting axial force created by the elements 109, 111 in the form of leaf springs and an energy accumulator 159.

 The resulting axial force exerted by the spring elements 109, 111, 159 on the Belleville spring 104, has, after exceeding the point 154, a characteristic in accordance with section 155. It is seen that after exceeding the point 154, the axial supporting force acting on the Belleville spring 104, which allows the Belleville to rotate the spring for disengaging the friction clutch 101 increases, as has already been described in connection with the diagrams in FIGS. 12 and 13. The resultant force characteristic created in the first segment 151 by spring-loaded parts Alami 109, 111, 159, is indicated by a dot-dash line 153a. In the depicted exemplary embodiment, the created characteristic of the resulting force in accordance with the segments 153a, 155 is linear. In at least one portion of segments 153a, 155, the force characteristic may have, however, at least slightly curvilinear, for example, progressive shape. The desired force characteristic can be created by appropriately calculating the spring parts 109, 111, 159. To achieve the desired force characteristic, the action of additional energy accumulators or spring parts can also be applied.

 When the point 154 is exceeded in the direction of switching off, the switching-off force required to actuate the friction clutch 101 passes in accordance with section 147b. From Fig.14 it is seen that when the point 154 is exceeded, the required shut-off force on a certain segment of the path, namely, to the point 156, is less than the supporting force acting on the disk spring 104 in the area of the point 154.

 In the designs of self-adjusting friction clutches proposed so far with the wear compensation device acting between the casing and the disk spring, the axially supporting disk spring 104 energy accumulators are made or coordinated in such a way that the resulting axial supporting force created by them on the shutdown path remains almost constant or even falls so that these friction clutches have overrun protection when shutting down at most to point 156. Due to According to the invention, and due to the support force characteristic provided in accordance with region 155, it is achieved that the overrun protection is substantially increased, namely, to point 163. Due to this increased overrun protection when the friction clutch 101 is actuated, it is ensured that even with large variation in tolerances in the production of switch-off systems and friction clutches, there is no undesired regulation that disrupts the functioning of friction clutches.

 In addition, the increased overrun protection provided by the invention makes it possible to more freely select the characteristic of the spring disk 104.

 The invention is not limited to the forms of execution of spring discharge means with a progressive force characteristic on the shutdown path described in connection with the figures. This progressive characteristic of the force can also be created by springing means, for example, elements in the form of a disk and / or leaf spring and / or disk spring, which, for example, as shown in FIG. 11 are laid around the fingers 116 and accordingly elastically tensioned, for example, between the head 116a of the fingers 116 and the casing 102 with the possibility of elastic deformation. 11 schematically depicts a similar spring element 163. This spring element 163 may be formed by an annular spring element in the form of a Belleville spring, and the casing 102 then must be adapted accordingly. The spring-loaded outlet means 111 can also be formed by individual elements in the form of leaf springs, which are connected at one end to the casing 102 and at the other end to the pressure disk 103. These elements in the form of leaf springs can be located when viewed in the direction of the periphery of the friction clutch, with the opposite action, and this means, therefore, that the elements in the form of leaf springs are divided into at least two groups, and one group of elements in the form of leaf springs acts between the casing 102 and the pressure plate 103 in direction of tension, and another group of elements in the form of leaf springs in the direction of shear. Due to the corresponding coordination of the lengths of the individual elements in the form of leaf springs, they can also be crimped in their longitudinal direction, namely, in the same way as described in connection with the spring exhaust means 111 or 11. With the transfer in figure 11, this would mean that provided on both sides of the finger 116, the segments of the springy exhaust means 111 are formed by at least one leaf spring. In the design of FIG. 11, the leaf springs would thus have one common fixing location on the pressure plate 103, namely by means of the pin 116. In the area of this fixing location, the individual leaf springs would lie adjacent to each other. It may, however, be preferable if the leaf springs of both groups have different attachment points in the region of the pressure disk 103, so that they can then be spaced apart from each other in the direction of the periphery.

 According to one embodiment of the invention, friction clutches with a wear compensation device provided between the casing and the disk spring can be particularly suitable if spring means are provided between the casing 102 and the pressure disk 103, which load the pressure disk 103 in the off direction, and these spring means as, at least on the path of removal of the pressure disk 103 of the new friction clutch, and on the axial path of displacement of this pressure disk 103 due to wear have the disk 103, at least an approximately constant retraction force. This would mean that, in FIG. 7, the curve segment 31 extends horizontally. Such an implementation is advisable, in particular, in combination with friction clutches, in which, similarly to what has been described in connection with FIGS. 10 and 11, there is an additional energy accumulator 159, which, however, acts on the disk spring 104 at a radial height formed by ring 134 of the ring-shaped run-in support, so that this energy accumulator is practically not deformed when the friction clutch is actuated, in contrast to the energy accumulator 159 shown. Such an energy accumulator, supported by a disk spring 104 at a radial height formed by an annular rolling support ring 134, can then be configured to create a practically constant force in the spring path necessary to compensate for the wear that occurs.

 The friction clutch 201 shown in FIG. 15 comprises a casing 202 made here from sheet steel and a pressure plate 203 connected to it rotatably, but with limited axial displacement. Axially between the pressure disk 203 and the cover 202, a pressure disk spring 204 is tensioned, which is mounted to swing like a two shoulders lever at a radial height of the ring-shaped support portion 205 formed on the side of the lid. the disk 203 is rigidly connected to the casing 202 by means of leaf springs 209 located in the direction of the periphery and tangentially. Friction clutch 201 is mounted in use, as shown in FIG. 2, on the back pressure disk 6. The annular support portion 205 provided on the side facing the lid 202 is formed by an annular rotary support, which in the illustrated embodiment is formed by a sheet steel ring 234. This ring 234 is a component of an automatic adjusting device 235 that compensates for wear that occurs at least on the friction linings by axially adjusting the cup spring 204.

 The support ring 234 is sandwiched between the housing 202 and the cup spring 204, at least in the engaged state of the friction clutch 1. The ring 234 forming the rotary support for the cup spring is supported on the housing 202 by means of a slope device. This sloping device ensures that there is no gap between the ring 234 and the cup spring 204 when the cup spring 204 is axially displaced in the direction of the back pressure disk due to wear on the friction linings.

 An automatic control device 235 operates between the casing 202 and the cup spring 204 similarly to the control device 35 described in connection with FIGS. 1 and 2. This means, therefore, that the ring 234 performs the same function as the ring 34, and this can be seen from the fact that the adjusting ring 234 is loaded similarly to the ring 34 by energy accumulators 238 in the direction of regulation of the corresponding slopes. In this regard, reference should be made to the corresponding description of FIGS. 2 and 3.

 The Belleville spring 204 is fixed from turning relative to the cover 202 by means of flat rivets 260 or rivet elements 260, which axially pass through the correspondingly made slots of the Belleville spring 204.

 A significant difference between the embodiment of the clutch in FIG. 15 and those described above is that the axial supporting function for the clutch disk spring carried out by the elements in the form of leaf springs in FIGS. 1-6 or by the battery 159 in the form of a disk spring in FIG. 10 in the embodiment of FIG. 15, axially pliable spring means 261 are integral with the Belleville spring 204. These tongue-shaped spring means axially rest on portions 265 of the housing 202. Due to this, the Belle supper 204 or its base 211 is axially loaded or attracted towards the casing 202, as a result of which the annular adjustment element 234 is axially clamped between the slopes of the adjusting device provided on the cover and the disk spring.

 As can be seen, in particular, from FIG. 16, the cup spring 204 contains a ring-shaped base 211 serving as an energy accumulator, from the inner edge of which the tongues 268 directed radially inward depart, serving as actuating means for friction clutch. To turn off the friction clutch 201, the corresponding actuating force is exerted on the ends 269 of the reeds by the shutdown bearing. The springing means 261 that are axially malleable and elastically stretched to the cover 202 are formed by elongated tabs or tongues made in a loop-like or hairpin shape. Spring means 261 in the form of paws are made in the radially inner edge zone of the ring-shaped base 211 of the Belleville spring. Starting from the base 211, the spring means 261 extend in an elongated portion 262, first radially inward. Section 262 passes into the rotation zone 263, which, in turn, ends with the elongated section 264 extending backward radially outward. Thanks to such tabs, tabs 261 provide a relatively long section of bending or torsion between the junction of sections 262 with the base 211 and support 267 with side of the cover. In the depicted exemplary embodiment, the free end 266 of the loop-like spring means 261 is widened, due to which it is possible to reduce the specific load that occurs on the sections of the cover interacting with these sections 266. The free end 266 of the tongues 261 rests with tension on the side 267 of the cover 202 facing away from the pressure disk 203 or the spring base 211. The shape of the spring means 261 and the distance between the support 265 from the side of the cover for these spring means 261 and the supporting section or section 205 the springs 204 are matched so that the spring means 261 in the form of paws are in tension. Advantageously, the free ends 266 and / or the lid portions interacting with them can have a curvature or barrel-shaped shape, thereby optimizing the driving conditions that arise when the disk spring 204 is rotated between the ends 266 and opposite portions of the lid. When shaping the respective surfaces, the kinematics or relative movement between the individual parts that are present when the cup spring 204 is rotated should be considered.

 Preferably, the tabs or spring means 261 in the form of paws can have a stiffness characteristic in accordance with a section 162 of the curve shown in FIG. 13. Flat spring elements 209 may advantageously have a stiffness characteristic described in conjunction with FIG. 12.

 The claims filed with the application provide the applicant with the right to achieve further patent protection. The applicant reserves the right to claim the protection of additional features disclosed so far only in the description and / or drawings.

 The references used in the dependent points indicate further improvement of the object of the independent point through the signs of the corresponding dependent point; they should not be regarded as a refusal to achieve independent subject protection for signs of subordinate dependent items.

 The objects of these dependent clauses characterize, however, also independent inventions, which are technical solutions independent of the objects of the previous dependent clauses.

 The invention is not limited to the example (s) of the description. On the contrary, in the framework of the invention, numerous varieties and modifications are possible, in particular such variants, elements and combinations and / or materials, which, for example, due to the combination or modification of individual features or elements or technological operations described in combination with the general description and the execution forms, as well as the claims and depicted in the drawings, have an inventive step and, due to the combined features, lead to a new facility or new technological operations or subsequent technological operations, as well as in relation to manufacturing methods, control and technological processes.

Claims (31)

1. Friction clutch for use in a drive chain, comprising a pressure disk mounted without the possibility of rotation relative to the casing, but with limited axial displacement, wherein at least one disk spring is located between the casing and the pressure disk for axially loading the pressure disk casing; and a regulating device for providing at least approximately constant tension of the disk spring during the service life of the friction clutch installed in the drive chain, characterized in that it contains spring exhaust means, which, when the friction clutch is turned off, provide axial displacement of the pressure disk relative to the casing in according to the way of turning off the pressure plate and the progressive distribution of the load, at least in this way off. 2. The clutch according to claim 1, characterized in that during the service life of the friction clutch there is an axial displacement of the pressure plate relative to the casing by a certain amount, as a result of which the tension state of the spring-loaded outlet means changes. 3. The clutch according to claim 2, characterized in that the spring-loaded outlet means have a degressive load distribution throughout the displacement. 4. Clutch according to one of claims 1 to 3, characterized in that it is configured to be mounted on a counter-pressure disk, such as a flywheel, through a clutch disk. 5. Clutch according to one of claims 1 to 4, characterized in that the discharge means are formed by elements in the form of leaf springs. 6. The clutch according to claim 5, characterized in that the elements in the form of leaf springs have a predetermined undulation and are connected on one side to the casing and on the other hand to the pressure plate so that, at least when the friction clutch is mounted, the elements are in the form of leaf springs are tensioned in the axial direction of the clutch, and on the basis of the connection of elements in the form of leaf springs with a casing and a pressure plate, as well as a predetermined undulation, an additional tension of these elements in the form of leaf springs in the longitudinal direction is created. 7. The clutch according to claim 5 or 6, characterized in that, at least in the mounted state of the friction clutch, the elements in the form of leaf springs are crimped in the longitudinal direction. 8. Clutch according to one of claims 1 to 7, characterized in that the progressive load distribution curve of these discharge means, which is considered in the direction of weakening, is provided, at least approximately over the entire working range of the mounted friction clutch covering the path of turning off the pressure plate and the wear path. 9. Clutch according to one of claims 5 to 8, characterized in that the leaf springs extend at least approximately tangentially or at least approximately in the direction of the periphery towards the pressure plate. 10. Clutch according to one of claims 1 to 9, characterized in that the spring-loaded outlet means are formed by leaf springs, which have one middle and two end zones, and on the one hand the middle zone is connected to the casing or pressure plate, and on the other hand, end the zones are connected to the pressure plate or casing. 11. Clutch according to one of claims 1 to 10, characterized in that the adjusting device acts between the casing and the cup spring. 12. Clutch according to one of claims 1 to 11, characterized in that the cup spring is axially supported by spring means and is held pivotally relative to the casing. 13. Clutch according to one of claims 1 to 12, characterized in that the disk spring is supported on the clutch housing with the possibility of rotation between two supports, of which the support supporting the disk spring when the clutch is turned off is spring-loaded in the direction of the disk spring. 14. The clutch according to item 13, wherein the spring-loaded support is installed with the possibility of axial displacement. 15. Clutch according to one of paragraphs 12-14, characterized in that the force exerted by spring-loaded exhaust means and the force exerted by the spring-loaded support are directed in parallel. 16. The clutch according to one of claims 1 to 15, characterized in that when the linings are worn, the distribution curve of the load necessary for engaging the friction clutch increases, and at least in a small portion of the switch-off load distribution curve there is a force value causing a small axial displacement spring loaded support. 17. The clutch according to one of paragraphs.13-16, characterized in that during the displacement of the spring-loaded bearings, the force required to rotate the cup spring decreases. 18. Clutch according to one of paragraphs.13-17, characterized in that during regulation due to the displacement of the spring-loaded bearings, equilibrium is established between the forces acting on both sides of the disk spring. 19. Clutch according to one of claims 1 to 18, characterized in that the disk spring, at least on a part of the switch-off path, has a steeply falling load distribution curve. 20. Clutch according to one of paragraphs.13-19, characterized in that the force exerted on the spring-loaded support is generated by an energy accumulator, which has an essentially constant force in the adjustment range required during the service life of the friction clutch. 21. Clutch according to one of claims 12 to 20, characterized in that an axially pliable or movable bearing is formed or at least loaded with a disk spring part. 22. Clutch according to one of claims 1 to 21, characterized in that the pivot bearing supporting the cup spring with the clutch engaged is biased by an automatic adjusting device to compensate for the wear of at least the friction linings of the clutch disc. 23. Clutch according to one of claims 1 to 22, characterized in that spring means in the form of leaf springs are provided between the casing and the pressure plate, which load the pressure disk in the direction of disengagement of the friction clutch, act parallel to the spring exhaust means and, at least on the way to turn off the pressure plate have a degressive load distribution curve. 24. The clutch according to item 22, wherein the spring means in the form of leaf springs can be firmly connected to both the casing and the pressure plate. 25. The clutch according to item 22 or 23, characterized in that the spring means in the form of leaf springs transmit at least a portion of the torque transmitted between the casing and the pressure plate. 26. Clutch according to one of paragraphs.23-25, characterized in that due to the axial displacement of the pressure plate relative to the casing during the life of the friction clutch, the return force exerted by the springing means in the form of leaf springs on the pressure disk increases. 27. Clutch according to one of claims 1 to 26, characterized in that, at least on the axial path of the displacement of the pressure plate relative to the casing, occurring during the service life of the friction clutch, the resulting force created by the application of the efforts of the spring exhaust means and spring means in the form of leaf springs and acting on the pressure plate in the direction of shutdown is at least approximately constant. 28. The clutch according to item 27, wherein the resulting force increases slightly with the axial displacement of the pressure plate relative to the casing. 29. The clutch according to item 27 or 28, characterized in that the resulting force with the axial displacement of the pressure plate relative to the casing increases by an amount of about 5-25%. 30. Clutch according to one of claims 1 to 29, characterized in that, when the friction clutch rests on the ring-shaped rotary support of the disk spring placed on the casing, the disk spring is loaded directly or indirectly by spring elements axially in the direction of this rotary support, and this, at least spring means provided between the casing and the pressure plate in the form of leaf springs for transmitting torque, spring taps provided between the casing and the pressure disk the means and the pad shock absorber provided, if necessary, between the friction linings of the clutch disc, create a resulting supporting force that counteracts the disengaging force acting on the disk spring when the friction clutch disengages and which, at least when releasing or at least approximately completely unload the friction at least approximately corresponds to the resulting resulting force acting in the off direction Disc spring. 31. Clutch according to one of claims 1 to 30, characterized in that, at least after releasing the friction linings of the clutch disc by the pressure plate and / or, at least in the fully frictional clutch state, only spring discharging means and spring means in the form of leaf springs exert a force on the pressure plate that counteracts at least the shut-off force present at that moment.

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