FR2895770A1 - Motor vehicle clutch, has torsion damper placed in annular space formed between disc fixed to drive shaft end and reaction plate and mounted in series with another torsion damper supported by friction disc of clutch and with pre-damper - Google Patents

Abstract

The clutch has a torsion damper (50) placed in an annular space formed between a disc (12) fixed to an end of a drive shaft (10) and a reaction plate (16). The damper is mounted in series with a torsion damper (30) supported by a friction disc (24) of the clutch and with a pre-damper connected to an input shaft of a driveline. The damper (50) has coaxial springs (52, 54) mounted inside each other in windows of guiding washers (56) extended in direction of a rotation axis and an annular wing (58) mounted between the washers. The damper is found at the level of friction sleeves (26).

Description

TORSION DAMPER FOR CLUTCH, ESPECIALLY VEHICLE

  The invention relates to a torsion damper for a clutch, in particular a motor vehicle. A conventional clutch for a motor vehicle comprises, in general, a reaction plate fixed at the end of the crankshaft of the internal combustion engine of the vehicle, a pressure plate integral in rotation with the reaction plate and axially displaceable relative thereto, and a friction disc whose outer periphery carries friction linings intended to be clamped between the reaction and pressure plates for the transmission of a rotational torque, by an annular spring bearing against the cover of the clutch. A torsion damper connects the friction disk to an input shaft of a transmission, such as, for example, the input shaft of a gearbox, to dampen the vibrations and jolts generated by the motor. internal combustion engine, this torsion damper is generally associated with a pre-damper for filtering vibrations and noise when the transmission is in the neutral position.

  In recent vehicles equipped with a powerful engine and in particular a diesel engine of the common rail type, damping dual flywheels are used in which a torsion damper is mounted between two flywheels, one of which is fixed. at the end of the crankshaft and the other forms the reaction plate of the clutch whose friction disc is connected directly to the input shaft of the transmission. These dual damping flywheels are more efficient in damping vibrations and jerks generated by the engine than the torsion dampers of traditional clutches, but they are also more complex and much more expensive.

  The object of the invention is to combine the advantages of torsional dampers of traditional clutches and those of double damping wheels while avoiding their respective drawbacks.

  It proposes for this purpose a clutch, in particular for a motor vehicle, comprising a reaction plate integral with a drive shaft, a pressure plate integral in rotation with the reaction plate and axially movable relative thereto, a disc of friction bearing friction linings, mounted between the reaction and pressure plates, spring-pressing means on the pressure plate for clamping the friction linings between the plates, and at least one torsion damper connecting the disk friction device to an input shaft of a transmission, characterized in that the torsion damper is housed in an annular space formed between the reaction plate and a disk fixed at the end of the drive shaft and is mounted in series. with another torsion damper and with a pre-damper. The clutch according to the invention has a number of advantages over a conventional clutch and a double damping flywheel: it has a footprint equal to or slightly less than that of a double damping flywheel, while having performance similar in terms of damping vibrations and jolts generated by the engine of the vehicle, thanks to the series of assemblies of two torsion dampers and a pre-damper, - it is much less expensive than a double damping flywheel - unlike the double damping flywheel, it has no resonant frequency for a rotational speed lower than the engine idling speed, which avoids equipping it with a torque limiter, - it uses a traditional technology, highly tested and well controlled. In a first embodiment of the invention, the torsion damper housed in the annular space is connected on the one hand to the friction disc by the other torsional damper and on the other hand to the shaft of the torsion damper. input of the transmission by the pre-damper.

  In this case, the torsion damper housed in the aforementioned annular space comprises an input element formed by a guide washer fixedly connected to the guide washers of the other torsion damper, and an output element formed by a annular sail which constitutes the input element of the pre-damper. The torsion damper housed in the aforementioned annular space is radially outwardly of the other torsion damper connected to the torsion disk and the pre-damper is in the same radial plane as the torsion damper housed in the torsion damper. annular space.

  Furthermore, the torsion damper connected to the fritcion disc can be centered, by means of a bearing, on a splined hub which forms the connecting member of the pre-damper to the input shaft of the transmission. In a second embodiment of the invention, the torsion damper housed in the aforementioned annular space comprises an input member fixed on the friction disk and an output element which is connected to an input element of the invention. the other torsion damper, whose output element is connected by the pre-damper to the input shaft of the transmission. In this case, the input element of the torsion damper housed by the aforementioned annular space is a guide washer whose radially inner annular portion is fixed on the friction disc. The output member of this torsion damper is an annular web whose radially inner portion forms the input member of the other torsion damper. This other torsion damper is located radially between the torsion damper housed in the aforementioned annular space and the pre-damper and can be centered by means of a bearing on the splined hub which connects the pre-damper to the shaft input of the transmission. As for the torsion damper housed in the aforementioned annular space, it can be centered by means of a bearing on a guide ring of the pre-damper.

  Advantageously, the disc fixed on the motor shaft and which delimits with the reaction plate the space in which is housed at least one torsion damper, is an axially flexible disk. This characteristic contributes to the damping of the axial vibrations generated by the motor. According to yet another characteristic of the invention, the reaction plate is connected to the disk fixed on the drive shaft by a peripheral annular rim which has ventilation air passages. This makes it possible to cool the reaction plate of the clutch, which may be subjected to relatively high heating due to the friction of the friction linings when opening and closing the clutch. The invention will be better understood and other characteristics, details and advantages thereof will appear more clearly on reading the description which follows, given by way of example with reference to the accompanying drawings, in which: FIG. schematic half-view in axial section of a clutch according to the invention, Figure 2 shows a detail of embodiment of a torsion damper; Figure 3 is another schematic half-view in axial section showing another embodiment of the invention; Figure 4 is a partial schematic view in axial section of the reaction plate; Figure 5 is a schematic half-view in axial section illustrating an alternative embodiment of the invention; Figures 6, 7 and 8 are partial schematic views in axial section illustrating details of embodiment of the invention; Figures 9 and 10 are partial front views illustrating details of the alternative embodiment of Figure 8; Figures 11, 12, 13 and 14 are diagrams illustrating the operation of the torsion dampers of a clutch according to the invention. In FIG. 1, the reference numeral 10 denotes the end of a motor shaft such as the crankshaft of an internal combustion engine of a motor vehicle, on which a disk 12, rigid or axially flexible, is fixed by means of screws. 14. A reaction plate 16 having a peripheral rim 18 is fixed on the outer periphery of the disk 12 by means of screws 20 passing axially through the rim 18 of the plate 16.

  A pressure plate 22 is associated with the cover 44 by elastically deformable tongues (not shown) which solidarize in rotation the two plates 16 and 22 while allowing axial displacement of the pressure plate 22 relative to the reaction plate 16. A disk friction ring 24 carrying friction linings 26 at its outer periphery is mounted between the two plates and is fixed at its inner periphery to the annular web 28 of a torsion damper 30 comprising coaxial springs 32, 34 mounted one inside the other in windows of the annular web 28 and two guide rings 35 disposed on either side of the annular web 28 and which are fixed together on a hub 36 by rivets 38 at their periphery radially. internal. The pressure plate 22 is biased towards the reaction plate 16 for clamping the friction linings 26 between the two plates, by an annular spring 40 which bears at its outer periphery on a rod 42 carried by a cover 44 fixed on the reaction plate 16, the annular spring 40 comprising radial fingers 46 oriented towards the axis of rotation and cooperating with a clutch abutment 48. The torsion damper 30 which is mounted on the friction disk 24 is associated with a another torsional damper 50 and a pre-damper 52 which are housed in the annular space between the disc 12 fixed at the end of the drive shaft 10 and the reaction plate 16.

  The torsion damper 50 is of the same type as the torsion damper 30 and comprises circumferentially disposed coaxial springs 52, 54 mounted one inside the other in windows of two guide washers 56 and an annular web 58 mounted between the guide washers 56. The torsion damper 50 is located radially at the level of the friction liners 26 and its guide washer 56 located on the side of the reaction plate 16 is extended in the direction of the axis of rotation by an annular portion 60 which comprises at its inner periphery a cylindrical rim 62 for supporting the hub 36 of the torsion damper 30. In the embodiment shown, the inner periphery of the hub 36 has teeth which are engaged in notches 62 of the flange to fasten in rotation the hub 36 and the guide ring 56, 60 of the torsion damper 50. The radially inner periphery of the torsion damper 30 formed by the hub 36 and the guide washers 35, is carried by the annular portion 60 of the guide washer 56 and is locked axially by a circlip or split ring 64. The two guide washers 56 of the shock absorber torsion 50 are fixed to each other at their outer periphery, as shown in the drawing. The radially inner annular portion of the annular web 58 forms the annular web of the pre-damper 52 which includes small springs 68 mounted in windows of this annular web and two guide washers 70 which are extended beyond the annular web in the direction of the annular web. of the axis of rotation to be fixed by their inner periphery, by means of rivets 72, on a radial flange of a splined hub 74 mounted on the correspondingly splined end of an input shaft 76 of the transmission of the vehicle, such as the input shaft of a gearbox. As shown in FIG. 1, this input shaft 76 may comprise an axial extension 78 extending on the side of the drive shaft 10 and guided in a bearing 80 mounted in the central orifice of the disc 12. The pre-damper 52 is substantially in the same radial plane as the torsion damper 50 and is located substantially at the same distance from the axis of rotation as the torsion damper 30 carried by the friction disk 24 and which is itself around the hub 74 connecting to the input shaft 76 of the transmission. Advantageously, the torsion damper 50, which has a diameter greater than that of the torsion damper 30, comprises groups of springs 52, 54 which are connected in series two by two by means of phase washers 66 which are mounted between the guide washers 56 and on either side of the annular web 58 as shown in FIG. 2. These phasing washers are fixedly connected to each other for example by means of rivets and comprise windows in which are two pairs of two springs 52, 54 are mounted, the windows of the phasing washers being offset by one pitch from those of the guide washers and the annular web 58 in which the springs are also mounted by two pairs of two springs. This particular arrangement makes it possible to make the pairs of two springs work in series, to obtain the same angular deflection as with longer springs, but without the disadvantages (sensitivity to centrifugal forces and risk of jamming of the turns in support on an outer peripheral surface). The phasing washers are advantageously clamped between the guide washers 56 and the annular web 58 and thus form friction washers participating in the vibration damping and rotation jolts. The torsion damper 50 of FIG. 2 may for example comprise 4, 5, 6 or 8 pairs of springs 52, 54. In the embodiment of the invention shown in FIG. 3, the torsion damper 50 which is at the level of the friction liners 26 in the annular space formed between the disc 12 and the reaction plate 16, is connected to the friction disc 24 by the annular portion 60 of its guide ring 56, which is fixed on the friction disc 24 by means such as screws 82, for example. The annular web 58 of the torsion damper 50 forms the annular web of another torsion damper 84 comprising circumferentially disposed coaxial springs 86, 88 which are mounted one inside the other in windows of the radially internal portion of the annular web 58 and guide washers 90, one of which on the side of the friction disc 24 forms a guide ring of a pre-damper 92 mounted on a splined hub 94 for connection to the shaft 96 input of the transmission. In this embodiment, the torsion damper 84 is located radially inside the torsion damper 50 and is slightly axially offset towards the friction disc 24. The pre-damper 92 is radially located at the inside the torsion damper 84 and is axially offset relative thereto towards the friction disc 24. In the usual manner, the output member of the pre-damper 92 is an annular web which meshes with play in an external toothing of the splined hub 94. Circlips provide axial retention of the pre-damper and the inner periphery of the guide ring 90 of the torsion damper 84 on the splined hub 94. As schematically shown in FIG. 4, the outer peripheral rim of the reaction plate 16 has through holes 98 for ventilation air passage, for cooling the friction surfaces formed on the reaction plate. 16. The embodiment variant shown in FIG. 5 substantially corresponds to the embodiment of FIG. 3, and differs therefrom in the arrangement of bearings for centering and guiding in rotation between the torsion damper 84 and the hub. grooved 94 on the one hand and between the annular portion 60 of the guide ring 56 of the torsion damper 50 and the pre-damper 92 on the other hand.

  Specifically, the inner periphery of the guide ring 90 of the torsion damper 84 which is located on the side of the drive shaft is guided and centered in a bearing 100 mounted on the hub 94 and retained axially by a circlip.

  The inner periphery of the annular portion 60 of the guide washer 56 of the torsion damper 50 is centered and guided by a bearing 102 carried by a guide ring 104 of the pre-damper 92, itself centered and guided by a Bearing 106 on the splined hub 94. FIG. 6 schematically shows means for centering and guiding the hub 36 of the torsional damper 30 of the clutch of FIG. 1 and of the annular portion 60 of the washer of rotation. guiding the torsion damper 50 on the hub 74 connecting to the input shaft of the transmission, these centering and rotational guiding means here being constituted by a sleeve 110 made of a material with a low coefficient of friction, mounted on the outer cylindrical surface of the hub 74. In the variant embodiment of FIG. 7, the friction disc 24 is centered on a cylindrical rim 112 of the annular portion 60 of the guide washer 56 of the shock absorber. 50 of Figure 2 and is fixed by means of a nut 114 screwed onto the threaded outer surface of the flange 112. The annular portion 60 on which the friction disc 24 bears has stamped nipples 116 which are engaged in corresponding orifices of the friction disc 24, for securing it in rotation with the annular portion 60 of the guide washer 56 of the torsion damper 50. FIGS. 8, 9 and 10 show schematically other details of embodiment of the clutch of Figure 1, wherein the radially inner portion of the guide ring 70 of the torsion damper 50 comprises a cylindrical rim 118 formed with an external toothing which meshes with clearance with a corresponding toothing of the inner periphery the annular web 58 of the torsion damper 52.

  Similarly, the cylindrical flange 62 of the inner periphery of the guide washer 56 of the torsion damper 50 has an external toothing which meshes without play with a corresponding toothing of the hub 36 of the torsion damper 30 carried by the disk. friction 24.

  The operation of the clutch according to the invention is illustrated in FIGS. 11 to 14. FIG. 11 represents an example of angular displacement of the torsion damper 50 of the clutch of FIG. 3, as a function of the rotational torque. transmitted, this angular displacement being about 25 on either side of a rest position. FIG. 12 represents the angular displacement of the torsion damper 84 of the clutch of FIG. 3, as a function of the transmitted torque, this angular displacement being approximately 20 on either side of a rest position.

  The angular displacement of the pre-damper 92 as a function of the transmitted torque is shown schematically in FIG. 13 and in this example is 8 in the retro direction and 17 in the forward direction for a transmitted torque of 10 Nm, with a change of slope for an angular deflection of 10 in the forward direction.

  The series assembly of the two torsion dampers 50 and 84 and the pre-damper 92 provides the angular displacement shown schematically in Figure 14, which is 53 in the retro direction for a torque of 342Nm and 62 in the direction direct for a torque of 342Nm also.

  The curve of FIG. 14 shows that the damping performances of the vibrations and jolts of the torsion dampers of the clutch according to the invention are at least equivalent to those of a double damping flywheel, for a price much lower.

Claims (15)

  Clutch, in particular for a motor vehicle, comprising a reaction plate (16) integral with a motor shaft (10), a pressure plate (22) rotatably integral with the reaction plate and axially displaceable with respect to this ci, a friction disk (24) carrying friction linings (26), mounted between the reaction and pressure plates, spring means (40) bearing on the pressure plate for clamping the friction linings between the plates and at least one torsional damper (50) connecting the friction disc to an input shaft (76) of a transmission, characterized in that the torsion damper (50) is housed in an annular space formed between the reaction plate (16) and a disc (12) fixed at the end of the drive shaft and is connected in series with another torsion damper (30) and with a pre-damper (52).   2. Clutch according to claim 1, characterized in that the torsion damper (50) housed in the annular space is connected on the one hand to the friction disc (24) by the other torsion damper (30) and on the other hand to the input shaft (76) of the transmission by the pre-damper (52).   Clutch according to claim 1 or 2, characterized in that the torsion damper (50) housed in the annular space comprises an inlet element formed by a guide washer (56) fixedly connected to the guide washers of the other torsional damper (30), and an outlet member formed by an annular web (58) which constitutes the input member of the pre-damper (52).   4. Clutch according to one of the preceding claims, characterized in that the torsion damper (50) housed in the annular space is radially outwardly of the other torsion damper (30) connected to the friction disk (24).   5. Clutch according to one of the preceding claims, characterized in that the pre-damper (52) is substantially in the same radial plane as the torsion damper (50) housed in the aforementioned annular space.   6. Clutch according to one of the preceding claims, characterized in that the pre-damper (52) is connected to the input shaft of the transmission by a splined hub (74) on which is mounted a bearing (110) centering the other torsional damper (30).   Clutch according to Claim 1, characterized in that the torsion damper (50) accommodated in the annular space comprises an inlet element (56, 60) fixed on the friction disk (24) and a an output connected to an input element of the other torsion damper (84), the output element (90) of which is connected by the pre-damper (92) to the input shaft of the transmission.   8. Clutch according to claim 7, characterized in that the input element of the torsion damper (50) housed in the annular space is a guide washer (56) whose radially inner annular portion (60) is fixed on the friction disc (24).   9. Clutch according to claim 7 or 8, characterized in that the output element of the torsion damper (50) housed in the aforementioned annular space is an annular web (58) whose radially inner portion forms the input element of the other torsional damper (84).   10. Clutch according to one of claims 7 to 9, characterized in that the other torsion damper (84) is located radially and axially between the torsion damper (50) housed in the aforementioned annular space and the meadow shock absorber (92).   11. Clutch according to one of claims 7 to 10, characterized in that the pre-damper (92) is connected to the input shaft of the transmission by a splined hub (94) which supports a bearing (100) centering said other torsional damper (84).   12. Clutch according to one of claims 7 to 11, characterized in that the torsion damper (50) housed in said annular space iscentré by means of a bearing (102) on a guide ring (104) of the pre-damper (92).   Clutch according to one of the preceding claims, characterized in that the larger-diameter torsion damper (50) comprises series-connected pairs of springs (52, 54) mounted in windows of the guide washers ( 56) and the annular web (58) and in windows offset by a phasing washer pitch (66).   14. Clutch according to one of the preceding claims, characterized in that the disc (12) fixed on the motor shaft (10) is axially flexible.   Clutch according to one of the preceding claims, characterized in that the reaction plate (16) is connected to the disk (12) fixed on the drive shaft (10) by a peripheral annular flange (18) having orifices ( 98) of ventilation air passage.