FR3015605A1 - TRANSMISSION ASSEMBLY EQUIPPED WITH A PENDULUM SHOCK ABSORBER EXTENDING RADIALLY OUTSIDE A CLUTCH DEVICE - Google Patents

Abstract

The invention relates to a transmission assembly for a motor vehicle, intended to ensure the coupling between a driving shaft and a driven shaft (6, 7), said assembly comprising: - a flywheel (1) intended to be fixed to the driving shaft; - a clutch device (2); and - a pendulum damper (33) comprising a support member (34) and pendulum weights (35) movably mounted on the support member (34); in which the support member (34) of the swinging damper (33) is fixed to the cover (20) of the clutch device (2) and / or to the flywheel (1) and is arranged in such a way that the Pendulum weights (35) extend radially outwardly of the clutch device (2).

Description

TECHNICAL FIELD OF THE INVENTION The invention relates to the field of transmissions for a motor vehicle. It relates in particular to a transmission assembly intended to be disposed between a heat engine and a gearbox of a motor vehicle. State of the art In the state of the art, to allow coupling between a driving shaft, such as a crankshaft of a heat engine, and a driven shaft, such as an input shaft of a gearbox, it is known transmission sets, combining a flywheel and a clutch device. The flywheel is intended to be fixed to the driving shaft. The clutch device comprises a clutch cover attached to the flywheel, a friction disk adapted to be secured in rotation to the driven shaft, a pressure plate integral in rotation with the clutch cover and a mounted annular diaphragm. hinged to the clutch cover for axially biasing the pressure plate between an engaged position in which the friction disc is clamped between the pressure plate and a region of the flywheel forming a reaction plate and a disengaged position in which the disk friction is released. Thus, in the engaged position, the motor torque is transmitted from the drive shaft to the driven shaft. Moreover, an internal combustion engine exhibits acyclisms due to successive explosions in the cylinders of the engine, the frequency of the acyclisms varying in particular as a function of the number of cylinders and the speed of rotation of the engine. In order to filter the vibrations generated by the acyclisms of the thermal engine, it is known to integrate torsion dampers with elastic members and / or pendulum dampers, also known as pendulum oscillators or pendulums, into the aforementioned transmission assemblies. In the absence of such dampers, vibrations penetrating the gearbox would cause in operation shock, noise or noise particularly undesirable. The development of new fuel-efficient engines leads to increased motor acyclisms and therefore requires an increase in vibration filtration performance. The pendulum dampers are particularly powerful and allow to obtain an effective filtration of the acyclisms over the entire operating range of the engine. However, the integration of pendulum dampers to the aforementioned transmission sets leads to an increase in their size. This is all the more detrimental as the filter performance of the acyclic of a pendulum damper increases especially with the mass of the pendulum weights used and that, therefore, in order to obtain satisfactory performance, the pendulum dampers have significant dimensions Gold , in parallel with this requirement to increase the filtration performance, the transmission assemblies are also subject to increasingly severe space constraints. This is particularly the case for hybrid applications in which the transmission assemblies further comprise an electric machine disposed between the gearbox and the engine.

OBJECT OF THE INVENTION An idea underlying the invention is to propose a transmission assembly, intended to couple a shaft leading to a driven shaft, which is both compact and equipped with means for effectively absorbing vibrations. .

According to one embodiment, the invention provides a transmission assembly for a motor vehicle, intended to ensure the coupling between a driving shaft and a driven shaft, said assembly comprising: a flywheel intended to be fixed to the driving shaft ; a clutch device comprising: a cover fixed to the flywheel; o at least one friction disc, housed inside the cover, said friction disc being provided with friction linings and being adapted to be secured in rotation to the driven shaft; o at least one pressure plate secured to rotation of the cover and mounted axially movable relative to said cover between an engaged position and a disengaged position; and - a pendulum damper comprising a support member and pendulum weights movably mounted on the support member; wherein the pendular damper support member is attached to the clutch device cover and / or the flywheel and is arranged such that the counterbalanced weights extend radially outwardly of the clutch device .

Such a transmission assembly is particularly compact because the pendulum weights extend substantially in the axial plane of the clutch device. In addition, such an arrangement makes it possible to obtain a particularly effective pendulum damper since the effectiveness of a pendulum damper increases when the center of gravity of the pendulum weights radially outwards is shifted. According to other advantageous embodiments, such an assembly may have one or more of the following features: the support member of the pendular damper is fixed between the flywheel and the cover of the clutch device. - The support member of the pendulum damper and the cover of the clutch device are fixed to the flywheel by common fasteners. - The flywheel is a double damping flywheel comprising a primary flywheel, intended to be fixed to the drive shaft, and a secondary flywheel movable in rotation relative to each other and damping means for transmitting a torque and dampen rotational acyclisms between primary and secondary flywheels. - The secondary flywheel has a radial dimension smaller than the radial dimension of the primary flywheel and pendulum weights extend radially outside the secondary flywheel. the clutch device is a multi-disc device comprising a first pressure plate and a second intermediate pressure plate, integral in rotation with the lid and movable axially with respect thereto, and a first friction disc provided with friction linings arranged between the first pressure plate and the second intermediate pressure plate and a second friction disk provided with friction linings disposed between the second intermediate pressure plate and the flywheel. The combination of a multi-disc clutch with a pendular damper radially implanted outside said multi-disc clutch provides a compact transmission assembly, for transmitting large engine torques and particularly effective for filtering vibrations . the support member of the pendular damper is fixed between the flywheel and the cover of the clutch device and comprises, at the inner periphery, a flange having axial grooves cooperating with radial projections formed at the outer periphery of the second plate; intermediate pressure so as to rotate the second intermediate pressure plate to the support member and to axially guide the second intermediate pressure plate. each of the first and second friction discs is equipped with a hub, the hub of one of the friction discs comprising, on the one hand, internal splines intended to cooperate with splines of the driven shaft, and on the other hand, external splines cooperating with internal splines of the hub of the other friction disc. - The transmission assembly further comprises: an electric machine comprising an outer stator and an inner rotor rotatable about an axis X, said rotor having a central opening; and o an intermediate shaft which is integral in rotation with the friction disc and is intended to be kinematically connected to the driven shaft; the intermediate shaft passing through the central opening of the rotor and being integral in rotation with the rotor. the number of friction disks and associated pressure plates can be between 2 and 5. According to one embodiment, the invention provides a motor vehicle equipped with a aforementioned transmission assembly. The invention will be better understood, and other objects, details, features and advantages thereof will become more clearly apparent in the following description of several particular embodiments of the invention, given solely for illustrative purposes and not limiting, with reference to the appended figures.

In these figures: Figure 1 is a sectional view of a transmission assembly intended to be disposed between a heat engine and a gearbox according to a first embodiment of the invention; FIG. 2 is a sectional view, in perspective, of the double damping flywheel, the clutch device and the pendulum damper of the transmission assembly of FIG. 1. FIG. 3 is a perspective view, partially broken away , the dual mass flywheel, the clutch device and the pendulum damper of the transmission assembly of Figure 1. Figure 4 is a perspective view of the double damping flywheel, the clutch device and the pendulum damper of the transmission assembly of Figure 1. Figures 5 and 6 are sectional views of a transmission assembly according to a second and a third embodiment. - Figure 7 is a detailed perspective view of a pendulum feeder, a sidewall is shown partially broken away. DETAILED DESCRIPTION OF EMBODIMENTS In the description and the claims, the terms "external" and "internal" as well as the "axial" and "radial" orientations will be used to designate, according to the definitions given in the description, elements of the transmission assembly. By convention, the "radial" orientation is directed orthogonally to the X axis of rotation of the transmission assembly determining the "axial" orientation and, from the inside to the outside away from said axis X, the "circumferential" orientation is directed orthogonally to the X axis of rotation of the transmission assembly and orthogonal to the radial direction. The terms "external" and "internal" are used to define the relative position of one element with respect to another, with reference to the X axis, an element close to the axis is thus described as internal as opposed to an outer member located radially peripherally. On the other hand, the terms "rear" AR and "front" AV are used to define the relative position of one element relative to another in the axial direction, an element intended to be placed close to the engine being designated by the rear and an element intended to be placed close to the gearbox being designated by before. - - - - -15 Referring to Figure 1, there is shown a transmission assembly, intended to be disposed between a heat engine and a gearbox. The transmission assembly comprises a flywheel 1, intended to be fixed to the crankshaft of the heat engine, not shown, and a clutch device 2 for coupling or uncoupling in rotation the crankshaft to an input shaft 7 of the gearbox. In the embodiment shown, the transmission assembly also comprises an electric machine 3 intended to be arranged in the transmission chain, between the crankshaft of the engine and the input shaft 7 of the gearbox. The electric machine 3 comprises a stator 4 and a rotor 5. The transmission assembly comprises an intermediate shaft 6, cooperating with the clutch device 2, and which is further secured in rotation to the rotor 5 of the electric machine 3 and intended to be connected kinematically with the input shaft 7 of the gearbox. In another embodiment, not shown, the transmission assembly has no electric machine and the input shaft 7 of the gearbox cooperates directly with the clutch device 2. The flywheel 1 is a double damping flywheel. The double damping flywheel comprises a primary flywheel 8, intended to be fixed to the crankshaft of the engine and a secondary flywheel 9 which is centered and guided on the primary flywheel by means of a bearing 10, here a bearing rolling. The primary 8 and secondary 9 flywheels are movable about the axis of rotation X and are furthermore movable in rotation relative to each other about said axis X. The primary flywheel 8 comprises a central hub 11, radially inner bearing the bearing 10, an annular portion 12 extending radially and a cylindrical portion 13 extending axially forwardly from the outer periphery of the annular portion 12. The primary flywheel 8 is here a flexible steering wheel. In other words, its annular portion 12 extending radially between the central hub 11 and the cylindrical portion 13 is at least partly formed of one or more flexible sheets. Such a primary flywheel 8 makes it possible to dampen excitations, in the axial direction, of the crankshaft. In another embodiment, the annular portion 12 and the cylindrical portion 13 are made in a single piece element. The primary flywheel 8 also comprises an annular cover 14 fixed on the cylindrical portion 13. The annular cover 14 defines with the annular portion 12 and the cylindrical portion 13, an annular chamber 15. In addition, the primary flywheel 8 carries a cylindrical rim 68 , radially external, to add additional inertia to the primary flywheel 8.

The central hub 11 has a radial annular portion in which orifices are formed. These orifices are arranged vis-à-vis orifices formed in the radially inner portion of the annular portion 12 of the primary flywheel 8. Fastening screws, not shown, engaged in the orifices allow the attachment of the primary flywheel 8 to the end of the crankshaft.

The double damping flywheel further comprises resilient damping means for transmitting the torque and damping rotation acyclisms between the primary 8 and secondary 9 flywheels in order to reduce vibrations from the engine. In the embodiment shown in Figures 1 to 4, the damping means comprise a first and a second damping stages arranged in series. The first damping stage comprises curved elastic members 16 having a circumferential effect, such as helical springs, housed in the annular chamber 15 and distributed circumferentially around the axis X. In order to limit the friction between the curved elastic members 16 and the cylindrical portion 13 of the primary flywheel 8, the annular chamber 15 is filled with a lubricating agent, preferably grease. The curved elastic members 16 extend, on the one hand, between two support seats carried by the primary flywheel 8 and, on the other hand, between two support lugs formed on an intermediate web 17. The second stage of damping comprises a plurality of groups of two elastic members, not shown, extending radially inside the curved elastic members, and providing a coupling between the intermediate web 17 and two guide washers 18, 19. The guide washers 18, 19 extend axially on either side of the intermediate web 17. The straight elastic members of each group are connected in series via a phasing member, not shown, free to rotate relative to the veil intermediate 17 and the guide washers 18, 19. The guide washers 18, 19 are integral in rotation with the secondary flywheel 9. For more details, such a dual damping flywheel is described in particular in the document WO2010079273.

The secondary flywheel 9 is intended to form the reaction plate of the clutch device 2. In the embodiment shown in Figures 1 to 4, the clutch device 2 is a multi-disk device. Such a multidisc device has the advantage of allowing the transmission of large torques while having a small radial size. The clutch device 2 comprises a cover 20, fixed on the outer periphery of the secondary flywheel 9, as shown in Figure 2. The cover 20 has an axially oriented skirt and a bottom of radial orientation. The clutch device 2 also comprises two friction discs 21, 22 equipped with friction linings 23, 24 and integral in rotation with the intermediate shaft 6 and two pressure plates 25, 26, housed inside the cover 20. Preferably, the number of friction disks and associated pressure plates can be between 2 and 5. The rear friction disk 21 extends between the secondary flywheel 9 forming the reaction plate and the intermediate pressure plate 25. The front friction disc 22 extends between the front pressure plate 26 and the intermediate pressure plate 25. The front pressure plate 26 is rotatably connected to the cover 20 by tangential elastic tongues 27, illustrated in FIGS. 4. The tangential elastic tongues 27 allow axial movement of the front pressure plate 26. The intermediate pressure plate 25 is also integral in rotation with the lid 20 and mounted axially relative thereto, as will be detailed later. Moreover, the clutch device 2 comprises an annular diaphragm 28 with a Belleville washer which is, on the one hand, bearing on the front pressure plate 26, and, on the other hand, resting against the bottom of the lid 20 The diaphragm 28 comprises fingers which are in contact with a clutch stop 29 making it possible to tilt the diaphragm 28 around its support against the bottom of the cover 20 in order to axially move the front pressure plate 26. In the engaged position, the front pressure plate 26 and the intermediate pressure plate 25 are urged by the diaphragm 28 towards the flywheel 1, the friction linings 23, 24 of the two friction discs 21, 22 being respectively clamped between the reaction plate formed by the secondary flywheel 9 of the double damping flywheel and the intermediate pressure plate 25 and between this intermediate pressure plate 25 and the front pressure plate 26, for the transmission of a torque of rotation between the crankshaft of the engine and the intermediate shaft 6. For disengagement, a thrust is exerted on the fingers of the diaphragm 28 via the clutch stop 29. Thus, the load exerted by the diaphragm 28 on the plate of front pressure 26 decreases so that the front pressure plate 26 is biased forward under the action of the tangential elastic tongues 27. The front pressure plate 26 and the intermediate pressure plate 25 are then released and the transmission of the torque between the crankshaft of the engine and the intermediate shaft 6 is interrupted.

In a variant not shown, the clutch can be of the normally open type. In this case, it is the movement of the clutch abutment 29 towards the rear which makes it possible to solicit, via the diaphragm 28, the front pressure plate 26 in the direction of the flywheel. In such a normally open clutch, the diaphragm 28 has a resilience to return its fingers to a position before rest. The rear friction disk 21 is equipped with a hub 30 comprising internal splines cooperating with splines formed at the rear end of the intermediate shaft 6 so as to rotate the rear friction disk 21 and the intermediate shaft in rotation. 6. Furthermore, the front friction disc 22 comprises a hub 31 equipped with internal splines cooperating with complementary shaped splines formed at the outer periphery of the means 30 of the front friction disc 21. Thus, the front friction disc 22 is also secured in rotation to the intermediate shaft 6 via the hub 30 of the rear friction disc 21. Such an arrangement is particularly compact and also makes it easier, during assembly, to introduce the end of the intermediate shaft 6 through the hubs 30, 31 of the friction discs 21, 22. However, in another embodiment not shown, each of the friction discs 21, 22 com carries a hub having internal splines cooperating with complementary shaped splines formed at the rear end of the intermediate shaft 6.

Furthermore, the transmission assembly is equipped with a pendular damper 33. The pendulum damper 33 comprises a support member 34 and a plurality of pendulum weights 35 circumferentially distributed over the support member 34. The support member 34 is formed of a disc secured to the rotation of the secondary flywheel 9 of the double damping flywheel and the cover 20 of the clutch device 2. As shown in Figure 2, the support member 34 is close to its inner edge , sandwiched between the secondary flywheel 9 of the double damping flywheel and the cover 20 of the clutch device 2 and fixed thereto. In order to simplify the assembly operations, the support member 34 and the cover 20 of the clutch device 1 are fixed to the secondary flywheel 9 of the double damping flywheel by common fastening members 36, screws in the illustrated embodiment. . The secondary flywheel 9 is equipped with fastening lugs 69, illustrated in FIGS. 3 and 4, protruding radially outwards and receiving the fastening members 36 of the support member 34 and the cover 20.

The support member 34 is arranged in such a way that the counterbalanced weights 35 extend partially in the plane of the clutch device 2, radially outwardly of the cover 20 of the clutch device 2 and the friction discs 21. Thus, this arrangement makes it possible to increase the efficiency of the pendulum damper 33 by shifting the center of gravity of the pendulum weights 35 radially outwards. It should further be noted that the pendulum weights 35 extend partially outside the secondary flywheel 9. In order to provide a housing space for the flyweights, the secondary flywheel 9 has a diameter smaller than the diameter of the flywheel. 8. With reference to FIGS. 3 and 4, we also note that the pendulum weights 35 are arranged circumferentially on either side of the fastening lugs 69, which makes it possible to further optimize the bulk of the pendulum damper 33 Furthermore, the support member 34 comprises, at its inner periphery, a flange 37 of axial orientation. The flange 37 has axial grooves. In these grooves, radial projections formed at the outer periphery of the intermediate pressure plate 25 penetrate axial sliding. The intermediate pressure plate 25 is thus integral in rotation with the support member 34, and therefore the cover 20 and the secondary flywheel 9, and axially movable relative thereto.

The pendulum weights 35 are able to oscillate with respect to the support member 34 in a plane orthogonal to the axis of rotation X, in response to the irregularities of rotation. As shown in detail in FIG. 7, each weight 35 comprises two flanks 38, 39 which extend axially on either side of the support member 34 and are connected axially to each other by the intermediate of two connecting struts 40. Each connecting spacer 40 passes axially through an associated opening 41 formed in the support member 34. In addition, the oscillations of the flyweights 35 are guided by guide means comprising, for each flyweight 35, two rolling elements 42 which each cooperate with each other. with a first rolling track carried by the support member 34 and with a second raceway, carried by the weight 35, and extending vis-à-vis the first raceway. The first rolling tracks are formed by the outer edge of the passage openings 41 of the spacers 40. The second raceways are carried by the spacers 40 connecting the sidewalls 38, 39 of each flyweight 35. The rolling elements 42 are, for example, example, formed by a cylindrical roller of circular section. The first and second raceways have a generally epicyclic or circular shape and are arranged such that the oscillation frequency of the weights 35 is proportional to the rotational speed of the drive shaft. The weights 35 further comprise stop elements 43 made of elastomer material for damping shocks, when the weights 35 reach the end of stroke or during engine stop. The stop elements 43 are here arranged between the two flanks 38, 39 of each weight 35 and abut against the edge of the openings 41 for the passage of the spacers 40. The electric machine 3, shown in FIG. 1, is an electric machine Reversible rotating type alternator-starter. In starter mode, the clutch device 2 is engaged and the electric machine 3 allows the engine to start. In alternator mode, the electric machine 3 can recharge a battery of the vehicle and / or power organs or equipment consuming energy when the engine is running. It is further configured to recover energy when braking the vehicle. The electric machine 3 can in particular be configured to stop the engine, for example, at a red light or in the caps, and then restart it (stop and go function in English). In one embodiment, it is capable of providing a surplus of power putting a significant acceleration of the vehicle (boost function in English). Furthermore, the electric machine 3 is able to drive the vehicle at least a short distance, the clutch device 2 is then disengaged and the engine stopped.

As shown in FIG. 1, the reversible rotary electric machine 3 comprises an external stator 4 and an internal rotor 5. The rotor 5 has a central opening for the passage of the intermediate shaft 6. The stator 4 is carried by a support member 44 which is, on the one hand, intended to be fixed on the engine block 5 and on the other hand part, intended to be fixed on the gearbox housing. The support member 44 is inserted between the transmission case and the engine block and is arranged to allow attachment of the gearbox to the engine block. In other words, the support member 44 forms a spacer element between the engine block and the transmission case. In the illustrated embodiment, the support member 44 has a rear flange 45 provided with orifices 46 for the passage of fasteners for securing the support member 45 to the engine block. The support member 44 has an outer peripheral wall 47 whose inner surface is of cylindrical shape to cooperate with the outer periphery 15 of the stator 4. The mounting of the stator 4 in the support member 44 can be made by hooping or by force clamping. The support element 44 also has an internal web 48, extending behind the stator 4 and the rotor 5 and forming a partition wall between the clutch device 2, on the one hand, and the electric machine 3, on the other hand. The support member 44 also defines a housing extending within the rotor 5 and within which at least partially extends the clutch stop 29. Such an arrangement optimizes the axial size of the assembly. The housing is defined by an axial skirt 49 and a bottom 50 of radial orientation. The bottom 50 is provided with a bore allowing the passage of the intermediate shaft 6. Furthermore, an axial flange 51 extends from the bottom of the housing, towards the front, and forms with the front face of the bottom 50 of the housing, a cylindrical bore housing a bearing 52. Thus, the bottom 50 of the housing limits, on the motor side, the bearing housing cylindrical bore 52 and defines a radial bearing rear surface of the bearing 52. The bearing 52 it cooperates, moreover, with the intermediate shaft 6, with the aid of a shoulder 53 which defines a bearing surface before the bearing 52. The bearing 52 thus allows the centering of the intermediate shaft 6 with respect to the Support member 44. The bearing 52 includes an outer ring, an inner ring, and rolling bodies extending between said outer and inner rings. The outer ring is axially coupled to the support member 44 while the inner ring is axially coupled to the intermediate shaft. Thus, the bearing 52 is axially fixed with respect to the support member 44, on the one hand, and the intermediate shaft 6, on the other hand. In addition, such a mounting of the bearing 52 makes it possible axially to maintain the intermediate shaft 6 with respect to the support element 44. In order to axially couple the inner and outer rings, they can be force-fitted or glued. Alternatively, it is also possible to use one or more locking members, such as elastic rods or circlips. The clutch abutment 29 is a fluid-controlled abutment. The abutment 39 is concentric with the axis X and traversed by the intermediate shaft 6. The abutment comprises two parts in piston cylinder relation, that is to say a fixed portion 54, delimiting an annular blind cavity orientation axial, and a piston 55 mounted axially movable relative to the fixed portion 54. The piston 55 enters the cavity to define therewith a variable volume working chamber.

The cavity communicates through a channel with a connection arrival to a fluid supply pipe 56 connected to a master cylinder. The working chamber is therefore allowed to be pressurized or depressurized. In the embodiment shown, the fixed portion 54 of the abutment comprises a guide tube 57 and an outer body 58, surrounding the guide tube 57. The guide tube 57, for example metallic, defines the annular cavity in which the piston 55 is movable and thus guides the piston 55. The guide tube 57 is assembled to the outer body 58. The guide tube 57 is traversed by the intermediate shaft 6. The outer body 58 is equipped with fastening means, not shown to the support member 44. In an embodiment not shown, the clutch abutment 29 is an abutment controlled by an electric actuator. The stop 29 is here of the self-centering type. It comprises a ball bearing 59 with a profiled rotating ring for a point contact with the inner ends of the fingers of the diaphragm 28 and a non-rotating ring coupled axially to the piston 55. A sealing bellows 60 extends between the outer body 30 58 and the non-rotating ring. Alternatively, the stop 29 is of pulled type, the stop 29 then acting by pulling the fingers of the diaphragm 28. The inner web 48 of the support member 44 comprises a recess for the passage of the fluid supply pipe 56 the stop 29.

The rotor 5 is supported by a hub 61. The hub 61 comprises an axial skirt for supporting the rotor 5. The rotor 5 comprises a bundle of sheets which is mounted by hooping on the outer surface of the axial skirt. Thus, the hot pack of sheets is mounted by fitting on the outer surface of the axial skirt.

The support hub of the rotor 5 is fixed to the intermediate shaft 6. To do this, the front end of the intermediate shaft 6 comprises a collar 62 against which abuts an internal flange formed in the support hub 61 of the rotor 5 and extending radially inwardly of the axial skirt. Fixing means, such as screws 63, make it possible to fix the internal flange of the hub 61 to the flange 62 of the intermediate shaft 6. The intermediate shaft 6 is equipped at its front end with a bore 64 comprising grooves cooperating with splines formed at the rear end of the input shaft 7 of the gearbox. Thus, the engine torque is transmitted from the intermediate shaft 6 to the input shaft 7 of the gearbox.

Figure 5 illustrates a transmission assembly according to a second embodiment. This embodiment differs from the embodiment previously described by the structure of its double damping flywheel and that of its clutch device 2. In this embodiment, the clutch device 2 is a single-disk clutch. The clutch device 2 comprises a cover 20 fixed on the secondary flywheel 9 of the double damping flywheel in which are housed a friction disc 65 and a pressure plate 66. The pressure plate 66 is rotatably connected to the cover 20 and movable axially relative thereto between a disengaged position and an engaged position in which the friction disc 65 is clamped between the secondary flywheel 9 of the double damping flywheel and the pressure plate 66. As in the previous embodiment, the displacement of the pressure plate 66 between its engaged and disengaged positions is provided by a diaphragm 28 and a clutch abutment 29. The support member 34 of the pendular damper 33 is also fixed, near its inner edge, between the secondary flywheel 9 of the double damping flywheel and the cover 20 of the clutch device 2. Thus, the pendulum weights extend, in part, radially outward of u the secondary flywheel 9 and, in part, radially outside the cover 20 of the clutch device 2. The support member 33 of the pendulous damper 35 is here formed of a flat disk, not stamped which allows to more easily ensure the accuracy of the geometry of the raceways. Furthermore, the secondary flywheel 9 is centered and guided in rotation relative to the primary flywheel 8 by means of a sliding bearing 67. The double damping flywheel is equipped with only one damping stage comprising curved elastic members 16 which extend, on the one hand, between two bearing seats carried by the primary flywheel 8 and, on the other hand, between two bearing lugs provided on the sail 17. The sail 17 is integral with rotation of the secondary flywheel 9. FIG. 6 shows a third embodiment which associates a double damping flywheel having two damping stages, as described with reference to FIGS. 1 to 4, with a single-disk clutch. As has been described in connection with several particular embodiments, it is obvious that it is in no way limited thereto and that it includes all equivalents. techniques of means s described and their combinations if they fall within the scope of the invention. The use of the verb "to include", "to understand" or "to include" and its conjugated forms does not exclude the presence of other elements or steps other than those set out in a claim.

In the claims, any reference sign in parentheses can not be interpreted as a limitation of the claim.

Claims (11)

REVENDICATIONS1. Transmission unit for a motor vehicle, intended to mate between a driving shaft and a driven shaft (6, 7), said assembly comprising: - a flywheel (1) intended to be fixed to the drive shaft; - A clutch device (2) comprising: a cover (20) fixed to the flywheel (1); at least one friction disc (21, 22, 65) housed inside the cover (20), said friction disk (21, 22, 65) being provided with friction linings (23, 24) and being intended to be secured in rotation to the driven shaft (6, 7); o at least one pressure plate (25, 26, 66) integral in rotation with the cover (20) and mounted axially movable relative to said cover (20) between an engaged position and a disengaged position; and - a pendulum damper (33) comprising a support member (34) and pendulum weights (35) movably mounted on the support member (34); in which the support member (34) of the swinging damper (33) is fixed to the cover (20) of the clutch device (2) and / or to the flywheel (1) and is arranged in such a way that the Pendulum weights (35) extend radially outwardly of the clutch device (2). 2. Transmission assembly according to claim 1, wherein the support member (34) of the pendulum damper (33) is fixed between the flywheel (1) and the cover (20) of the clutch device (2). ). 3. The assembly of claim 2, wherein the support member (34) of the pendulum damper (33) and the cover (20) of the clutch device (2) are fixed to the flywheel by means of fastening (36) common. 4. Transmission assembly according to any one of claims 1 to 3, wherein the flywheel (1) is a double damping flywheel comprising a primary flywheel (8), intended to be fixed to the drive shaft, and a secondary flywheel (9) movable in rotation relative to each other and damping means for transmitting a torque and damping rotation acyclisms between the flywheels of primary (8) and secondary (9) inertia. 5. transmission assembly according to claim 4, wherein the secondary flywheel (9) has a diameter smaller than the diameter of the primary flywheel (8) and wherein the pendulum flyweights (35) extend radially outside the secondary flywheel (9). The transmission assembly according to any one of claims 1 to 5, wherein the clutch device (2) is a multi-disc device comprising a first pressure plate (26) and a second intermediate pressure plate (25), integral in rotation with the lid (20) and movable axially with respect thereto and a first friction disc (22) provided with friction linings (24) arranged between the first pressure plate (26) and the second pressure plate intermediate (25) and a second friction disc (21) provided with friction linings (23) disposed between the second intermediate pressure plate (25) and the flywheel (1). Transmission assembly according to claim 6, wherein the support member (34) of the swinging damper (33) is fixed between the flywheel (1) and the cover (20) of the clutch device (2). ) and comprises, at the inner periphery, a flange (37) having axial grooves cooperating with radial projections formed at the outer periphery of the second intermediate pressure plate (25) so as to rotate the second intermediate pressure plate (25) in rotation; to the support member (34) and to axially guide the second intermediate pressure plate (25). Transmission assembly according to claim 6 or 7, wherein each of the first and second friction discs (21, 22) is equipped with a hub (30, 31), the hub (30) of one of the discs friction device (21) comprising, on the one hand, internal splines intended to cooperate with splines of the driven shaft (6, 7) and, on the other hand, external splines cooperating with internal splines of the hub (31 ) of the other friction disc (22). 9. transmission assembly according to any one of claims 1 to 8, further comprising: - an electric machine (3) having an outer stator (4) and an inner rotor (5) rotatable about an axis X said rotor (5) having a central opening; and- an intermediate shaft (6) which is integral on rotation with the friction disc (21, 22, 65) and is intended to be kinematically connected to the driven shaft (7); the intermediate shaft (6) passing through the central opening of the rotor (5) and being integral in rotation with the rotor (5). 10. Assembly according to one of claims 1 to 9, wherein the number of friction discs and associated pressure plates is between 2 and 5. 11. Motor vehicle equipped with a transmission assembly according to any one of claims 1 to 10.10.