FR3071889B1 - CLUTCH SYSTEM COMPRISING A REACTION TRAY SUPPORTED BY AN ENTRY DEVICE - Google Patents

Abstract

A clutch system (10) includes an input member (26), at least a first clutch mechanism (18) and at least one first clutch actuator (52). The first clutch mechanism (52) comprises a reaction plate (32) free in rotation with respect to the input member (26), a clutch disc (34) facing the reaction plate (32) , the clutch disc (34) being rotatably connected and free in axial translation relative to the input member (26), and a clutch cover (36) integral with the reaction plate (32). The first clutch actuator (52) comprises a body (56) and a movable member (58) movable axially in translation relative to the body (56). The first clutch mechanism (18) comprises a guide bearing (30) of the reaction plate (32) for rotating guide and axially linking the reaction plate (32) with respect to the input member (26). a rotating guide stop (64) being interposed between the clutch cover (36) and the body (56) of the first actuator (52).

Description

CLUTCH SYSTEM COMPRISING A REACTION TRAY SUPPORTED BY AN ENTRY DEVICE

TECHNICAL FIELD OF THE INVENTION

The invention relates to a clutch system, in particular for a motor vehicle, and preferably, although not exclusively, to a clutch system comprising two clutch mechanisms in series.

STATE OF THE PRIOR ART

In FR2797230A1 is described a clutch system comprising an input shaft connected to an internal combustion engine, a first clutch mechanism and a second clutch mechanism arranged in series between the body of the clutch. an input and a gearbox input shaft, a first actuator for operating the first clutch mechanism and a second actuator for operating the second clutch mechanism, all housed in a clutch housing. The first clutch mechanism and the second clutch mechanism have a common reaction plate, which forms a rotating subassembly with a cover of the second clutch mechanism and with a disc also having a support function of a clutch rotor. electric motor with which it forms a cover of the first clutch mechanism. The first actuator is positioned between the combustion engine and the first clutch and attached to the crankcase. The rotational guidance of the rotating subassembly is obtained by a single bearing with two rows of balls between the support of the electric motor rotor and the body of the first actuator. The axial forces exerted by the first actuator on the first clutch mechanism are transmitted to the bearing, which must therefore be suitable for the recovery of axial forces. Furthermore, the rotating subassembly is equipped with an auxiliary drive pulley, which is positioned around the second actuator, away from the rolling bearing. Such an arrangement generates at the rolling bearing a bending moment likely to cause premature wear of the bearing.

SUMMARY OF THE INVENTION

The invention aims to overcome the disadvantages of the state of the art and to provide a clutch system that avoids axially biasing the rolling bearing.

To do this is proposed, according to a first aspect of the invention, a clutch system comprising an input member, at least a first clutch mechanism and at least a first clutch actuator, the first clutch mechanism comprising a reaction plate free in rotation with respect to the input member, a clutch disc facing the reaction plate, the clutch disk being linked in rotation and free in axial translation relative to to the input member, and a clutch cover integral with the reaction plate, the first clutch actuator comprising a body adapted to be stopped in rotation with respect to an element of a casing of a propulsion unit comprising the clutch system, and a movable member movable axially in translation relative to the body for opening and / or closing the first clutch mechanism. Remarkably, the first clutch mechanism comprises a guide bearing of the reaction plate to guide in rotation and axially link the reaction plate relative to the input member. The clutch system comprises a rotary stop of interposed guide between the body of the first actuator and clutch cover to guide the body of the first actuator in rotation and to take up the axial forces exerted by the body of the first actuator. The rotating guide stop may in particular be an angular contact bearing or a deep groove bearing adapted to take up the axial forces exerted within the first actuator.

The positioning of the guide bearing of the reaction plate can be chosen independently of the positioning of the body of the actuator. The forces applied by the movable member of the actuator on the mechanism and the reaction exerted by the body of the actuator on the cover compensate each other so that they do not generate any effort at the guide bearing of the reaction tray.

In practice, the first clutch mechanism preferably comprises a pressure plate mounted free in translation and integral in rotation with respect to the reaction plate, the clutch disk being positioned between the pressure plate and the plate of pressure. reaction, a clutch diaphragm positioned between the clutch cover and the friction plate. The movable member of the first clutch actuator is preferably connected to the clutch diaphragm by a clutch abutment. Here and throughout the text, clutch diaphragm means any type of elastically deformable intermediate element allowing a connection between the clutch abutment or the movable member of the first actuator and the pressure plate. It may in particular be a Belleville washer. The first clutch mechanism may be normally open or normally closed.

According to one embodiment, the input member comprises a shaft, the first actuator being annular and positioned around the shaft. Thus, the first actuator is positioned, when the clutch system is mounted in a drive assembly of a motor vehicle, between the engine and the first clutch mechanism. Preferably, the shaft comprises a splined portion of connection with the clutch disc. According to one embodiment, an end portion of the shaft constitutes a link interface with a motor assembly. Alternatively, it can be provided that the shaft forms a single piece with a damping flywheel mounted at the end of the crankshaft. It is also possible to provide a double damping flywheel between the crankshaft and the clutch system.

According to one embodiment, the clutch disc is connected to the input member by a splined connection.

According to one embodiment, the clutch disc is integral in rotation with the input member. This arrangement will be particularly advantageous when there is a second clutch mechanism or a damper of torque fluctuations between the first clutch mechanism and the output member of the clutch system.

In another embodiment, the clutch disk comprises a torque fluctuation damper. This arrangement will be particularly useful when the first clutch mechanism is the only clutch mechanism between the input member and the output member of the clutch system.

According to a particularly advantageous embodiment, the clutch system comprises an actuator support interposed between the clutch cover and the rotary guide stop, the latter being interposed between the actuator support and the body. of the first actuator.

According to one embodiment, a rotulant connecting member is interposed between the actuator support and the clutch cover. Alternatively, the actuator support can be fixed relative to the clutch cover.

According to one embodiment, the clutch system further comprises a second clutch mechanism, and a second clutch actuator, the second clutch mechanism comprising: a clutch disk facing the plate of clutch; reaction and a clutch cover secured to the reaction plate, the second clutch actuator comprising a body adapted to be stopped in rotation with respect to a crankcase element of a propulsion assembly comprising the clutch system, and a movable member, movable axially in translation relative to the body of the second actuator to change the axial position of the clutch disk of the second clutch mechanism relative to the reaction plate The second clutch mechanism can comprise in particular a pressure plate mounted free in translation and fixed in rotation relative to the reaction plate, the clutch plate of the second mechanism the clutch mechanism being positioned between the pressure plate of the second clutch mechanism and the reaction plate, and a clutch diaphragm positioned between the clutch cover of the second clutch mechanism and the friction plate of the second mechanism. clutch. The movable member of the second actuator is preferably connected to the clutch diaphragm of the second clutch mechanism by a second clutch abutment. The second clutch mechanism may be normally open or normally closed. Preferably, a rotating guide stop is interposed between the body of the second actuator and the cover of the second clutch mechanism to guide in rotation and axially maintain the body of the second actuator. The rotating guide stop may in particular be an angular contact bearing or a deep groove bearing adapted to take up the axial forces exerted within the second actuator.

According to a particularly advantageous embodiment, the clutch system further comprises an auxiliary auxiliary drive annular interface of a rotating subassembly comprising the reaction plate, the cover of the first clutch mechanism and, if necessary, the cover of the second clutch mechanism. In practice, this annular interface may for example be a belt drive pulley, notched or not, or a ring gear, in particular with straight or conical teeth, intended to mesh with a pinion of an auxiliary device.

In one embodiment in which the second clutch mechanism is not present, this interface may more particularly be used for driving an auxiliary load, for example an air conditioning device, or a auxiliary drive device, for example a start assist. In one embodiment in which the second clutch mechanism is present, this interface may be more particularly intended for a drive device that it is desired to be able, depending on the needs and operating conditions, to couple to the output member and gearbox in parallel with the main motor (both clutch mechanisms being closed) or mate with the engine without transmission to the gearbox (the first clutch mechanism being closed and the second open) , or again to couple to the gearbox, the engine being decoupled (the first clutch mechanism being open and the second closed), is finally decoupled from the engine itself decoupled from the gearbox (the two mechanisms clutch being open).

Preferably, the auxiliary drive annular interface has an outer diameter which is smaller than an outer diameter of the clutch disk of the first clutch mechanism. It is then possible to have an advantageous transmission ratio between the auxiliary drive annular interface and the auxiliary device to which it is connected. In particular, it will be possible and preferably to provide that the annular interface is disposed axially superimposed with the first clutch actuator or the second clutch actuator, and preferably between the guide bearing of the input member and the guide bearing of the reaction plate, for a good recovery efforts.

Preferably, the auxiliary drive annular interface is a drive pulley or a toothed wheel formed or reported on the actuator support.

According to another aspect of the invention, it relates to a propulsion assembly comprising a clutch system as described above and a fixed housing, the body of the first clutch actuator being stopped in rotation by relative to a fixed housing element. According to one embodiment, the fixed housing comprises a guide bearing of the input member.

Preferably, provision can be made for a positioning of the guide bearing of the input member such that one or more of the following conditions are realized: the body of the first actuator is disposed axially between the guide bearing of the input member and the clutch disk.

The body of the first actuator is disposed axially between the guide bearing of the input member and the guide bearing of the reaction plate.

The clutch disc is disposed axially between the guide bearing of the input member and the guide bearing of the reaction plate.

BRIEF DESCRIPTION OF THE FIGURES

Other features and advantages of the invention will become apparent from reading the description which follows, with reference to the accompanying figures, which illustrate: Figure 1, a sectional view of a clutch system according to a first embodiment of the invention; Figure 2 is a sectional view of a clutch system according to a second embodiment of the invention; Figure 3 is a sectional view of a clutch system according to a third embodiment of the invention; Figure 4 is a sectional view of a clutch system according to a fourth embodiment of the invention; Figure 5 is a sectional view of a clutch system according to a fifth embodiment of the invention.

For clarity, identical or similar elements are identified by identical reference signs throughout the figures.

DETAILED DESCRIPTION OF EMBODIMENTS

In FIG. 1 is illustrated a propulsion unit 1 comprising a clutch system 10 intended to be interposed between a main drive device 12, for example a heat engine, an auxiliary device 14, for example an electric motor, and a gearbox 16.

The clutch system 10 comprises a first clutch mechanism 18 and a second clutch mechanism 20 disposed inside a housing 22 of the propulsion system 1 and operatively in series between an output member 12.1. the main driving device (for example a crankshaft of a heat engine or a single flywheel or a double damping flywheel connected to such a crankshaft) and an input shaft 16.1 of the gearbox, which are aligned and revolve around a common geometric axis 100 which is also an axis of revolution for the first clutch mechanism 18 and the second clutch mechanism 20. The clutch system 10 further comprises an auxiliary drive annular interface 24 for connecting a sub intermediate rotating assembly 25 between the first clutch mechanism 18 and the second clutch mechanism 20 and the auxiliary drive device 14, which turns around an axis of revolution 200 which is not necessarily coaxial with the axis of revolution 100 of the first clutch mechanism 18 and the second clutch mechanism 20.

The clutch system 10 comprises an input member 26, in this case an input shaft guided in rotation by a guide bearing 29 fretted in an opening of the housing 22. The input shaft 26 has two opposite end portions, one protruding outside the housing to form an interface 26.1 for attachment to a flywheel 28 and an end face of the output member 12.1 of the drive device. main 12, the other constituting a shrinking seat 26.2 of a guide bearing 30, here a rolling bearing one or preferably two rows of rolling bodies.

The guide bearing 30 serves to guide in rotation relative to the input shaft 26, about the axis of revolution 100, a reaction plate 32 common to the first clutch mechanism 18 and the second mechanism 20. The guide bearing 30 of the reaction plate 32 takes up the axial forces and axially links the reaction plate 32 to the input member 26 and rotates the reaction plate 32 relative to the member. 26.

The first clutch mechanism 18 comprises a clutch disc 34 disposed opposite the reaction plate 32 and engaged with the input shaft 26 by a splined link 26.3 which provides an axial translation freedom and a link in rotation with respect to the input member 26.

The first clutch mechanism 18 further comprises, in known manner, a clutch cover 36 integral with the reaction plate 32, a pressure plate 38 mounted free in translation and integral in rotation with respect to the reaction plate. 32, and a clutch diaphragm 40 positioned between the clutch cover 36 and the pressure plate 38. The clutch disk 34 is positioned between the pressure plate 38 and the reaction plate 32. The clutch disk 34, the reaction plate 32 and the diaphragm 40 are arranged axially between the guide bearing 29 of the input shaft 26 and the reaction plate 32. Where appropriate, the clutch disk 34 may be equipped with a shock absorber of torque fluctuations.

The second clutch mechanism 20 comprises meanwhile a clutch plate 42 disposed opposite the reaction plate 32 and connected to the input shaft 16.1 of the gearbox 16 via a torque fluctuation damper 44 which constitutes the output member of the clutch system 10. The torque fluctuation damper 44, of known structure, is engaged on a fluted portion 16.2 of the input shaft 16.1 of the gearbox, which ensures a rotational connection and freedom of translation with respect to this input shaft 16.1. The second clutch mechanism 20 further comprises, in known manner, a clutch cover 46 integral with the reaction plate 32, a pressure plate 48 mounted free in translation and fixed in rotation with respect to the reaction plate 32, and a clutch diaphragm 50 positioned between the clutch cover 46 and the pressure plate 48. The clutch disc 44 is positioned between the pressure plate 48 and the reaction plate 32. The clutch disc 42, the reaction plate 32 and the diaphragm 50 of the second clutch mechanism are arranged facing a face of the reaction plate 32 opposite the face of the reaction plate 32 facing the clutch plate 34, the pressure plate 38 and the diaphragm 36 of the first clutch mechanism 18.

The reaction plate 32 forms with the cover 36 of the first clutch mechanism 18 and the cover 46 of the second clutch mechanism 20 the rotating subassembly 25, guided by the guide bearing 30 of the reaction plate 32 and to which the auxiliary drive annular interface 24 is attached. More specifically, the auxiliary drive annular interface 24 is here a pulley which is positioned in this embodiment in a transverse plane containing the guide bearing 30 of the reaction plate 32.

The clutch system 10 further comprises a first clutch actuator 52 for actuating the first clutch mechanism 18 and a second clutch actuator 54 for actuating the second clutch mechanism 20.

The first clutch actuator 52 comprises a body 56 and a movable member 58, which is able to move axially in translation relative to the body 56, and abuts against the clutch diaphragm 40 via a clutch abutment 59. Remarkably, the body 56 of the first clutch actuator 52 is supported by the clutch cover 36, through an annular actuator support member 60 attached to the clutch cover 36, and a rotary guide stop 64, preferably an oblique contact, of which an outer ring is engaged in the actuator support 60 and an inner ring is engaged on the body 56 of the first actuator clutch 52. so as to guide in rotation the body 56 of the first clutch actuator 52 with respect to the clutch cover 36 and to take up the axial forces between these two members. The body 56 is provided with a tab 56.1 having a slot in which a pin 62, fixed to the casing 22, is inserted, so as to stop the body 56 in rotation with respect to the casing 22 of the clutch system 10. The first Clutch actuator 52 is annular and positioned around an intermediate portion of the input shaft 26, axially between the guide bearing 29 of the input shaft 26 and the guide bearing 30 of the reaction plate 32. .

The second clutch actuator 54 has been illustrated only schematically, and can be of any known type.

The clutch system 10 illustrated in Figure 2 differs from that of Figure 1 only by the structure of the attachment interface 26.1 of the input member 26, which is constituted by a shaft end grooved, on which is s'ammancher an intermediate annular piece 66 for attachment to the flywheel 28 and the end of the crankshaft 12.1.

The clutch system 10 illustrated in Figure 3 differs from that of Figure 2 by the positioning of the auxiliary drive annular interface 24 which is here a shrink pulley on the actuator support 60, axially between the guide bearing 29 of the input shaft 26 and the guide bearing 30 of the reaction plate 32. This considerably reduces the diameter of the pulley 24, which is smaller than the outside diameter of the reaction plate 32, and preferably less than the outside diameter of contact between the friction disc 34 and the reaction plate 32.

The clutch system 10 illustrated in Figure 4 differs from that of Figure 2 by the interposition of a swivel connection 68 between the clutch cover 36 of the first clutch mechanism 18 and the support of actuator 60. More specifically, and as disclosed in FR 3030656, the swivel link 68 comprises an annular ring 72 disposed between the actuator support 60 and the clutch cover 36. This swivel link 68 offers the advantage of decoupling the first clutch actuator 52 from the clutch cover 36, so that the potential deformations of the clutch cover 36 do not off-set the body 56 of the first clutch actuator 52.

Finally, the clutch system shown in Figure 5 differs from that of Figure 2 by the structure of the second clutch actuator 54, which has been specified here and which is similar to the structure of the first actuator. clutch 52. More specifically, the second clutch actuator 54 comprises a body 74 and a movable member 76, which is able to move axially in translation relative to the body 74 and abuts against the clutch diaphragm 50 by In a remarkable manner, the body 74 of the second clutch actuator 54 is supported by the clutch cover 46 of the second clutch mechanism 20 via a workpiece. actuator support ring 80 attached to the clutch cover 46, and a guide rotary stop 82, an outer ring of which is engaged in the actuator holder 80 and an inner ring is hooped onto the body 74 of the second clutch actuator 54. The body 74 is provided with a lug 74.1 having a slot in which a pin (not shown), fixed to the casing 22, is inserted, so as to stop the body 74 in rotation relative to the housing 22 of the clutch system 10. The second clutch actuator 54 is annular and positioned around a portion of the input shaft 16.1 of the gearbox 16. As shown in FIG. the rotating guide stop 82 is an angular contact bearing capable of taking up the axial forces exerted within the second clutch actuator 54.

Of course, the examples shown in the figures and discussed above are given for illustrative and not limiting. The annular auxiliary drive interface 24 may be a gearwheel. The clutch actuators 52, 54 can be hydraulically controlled, electromechanical, or electrical or mechanical.

In the absence of housing 22 specific to the clutch system 10, one can stop the body 56 of the first clutch actuator 52 and the body 74 of the second clutch actuator 54 in rotation relative to other crankcase elements of the propulsion assembly including the clutch system 10, for example with respect to a crankcase main driving device 12 or the gearbox 16.

It is explicitly provided that one can combine the different embodiments illustrated to propose others.

It is emphasized that all the features, as they are apparent to a person skilled in the art from the present description, the drawings and the attached claims, even if concretely they have been described only in relation to other specified characteristics, both individually and in any combination, may be combined with other characteristics or groups of features disclosed herein, provided that this has not been expressly excluded or that technical circumstances make such combinations impossible or meaningless.

Claims (10)

A clutch system (10) having an input member (26), at least a first clutch mechanism (18) and at least a first clutch actuator (52), the first clutch mechanism ( 18) comprising a reaction plate (32) free in rotation with respect to the input member (26), a clutch disc (34) opposite the reaction plate (32), the clutch plate ( 34) being rotatably connected and free in axial translation with respect to the input member (26), and a clutch cover (36) integral with the reaction plate (32), the first clutch actuator (52) ) having a body (56) adapted to be stopped in rotation with respect to an element of a housing (22) of a propulsion assembly (1) comprising the clutch system (10), and a movable member (58) ), movable axially in translation relative to the body (56) to open and / or close the first clutch mechanism (18), characterized in that the first clutch mechanism (18) comprises a guide bearing (30) of the reaction plate (32) for rotating guide and axially linking the reaction plate (32) with respect to the input member (26), and in that the clutch system includes a rotatable guide stop (64) for rotatably guiding the body (56) of the first actuator (52) relative to the clutch cover (36). 2. clutch system according to claim 1, characterized in that the input member (26) comprises a shaft, the first actuator (56) being annular and positioned around the shaft (26). Clutch system according to one of the preceding claims, characterized in that the clutch system comprises an actuator support (60) interposed between the clutch cover (36) and the rotary guide stop ( 64), the rotating guide stop (64) being interposed between the actuator support (60) and the body (56) of the first actuator (52). Clutch system according to claim 3, characterized in that a swivel connecting member (68) is interposed between the actuator support (60) and the clutch cover (36). Clutch system according to one of the preceding claims, characterized in that the clutch system (10) further comprises a second clutch mechanism (20) and a second clutch actuator (54). , the second clutch mechanism (20) comprising: a clutch disc (44) facing the reaction plate (32) and a clutch cover (46) integral with the reaction plate (32), the second actuator clutch assembly (54) having a body (74) adapted to be stopped in rotation with respect to an element of a housing (22) of a propulsion assembly comprising the clutch system (10), and a movable member (76), movable axially in translation relative to the body (74) of the second actuator (54) to change the axial position of the clutch plate (44) of the second clutch mechanism (20) relative to the reaction plate ( 32), the clutch system preferably having a rotatable stop guiding ante (82) interposed between the cover (46) of the second clutch mechanism (20) and the body (74) of the second actuator (54) for rotating the body (74) of the second actuator (54). 6. clutch system according to any one of the preceding claims, characterized in that it further comprises an auxiliary drive annular interface (24) integral with a rotating subassembly (25) comprising the reaction plate (32), the cover (36) of the first clutch mechanism (18) and, if appropriate, the cover (46) of the second clutch mechanism (20). Clutch system according to claim 6, characterized in that the auxiliary drive annular interface (24) has an outer diameter which is smaller than an outer diameter of the clutch disk (34) of the first gear mechanism. clutch (18). 8. Clutch system according to any one of claims 6 to 7, in combination with claim 3, characterized in that the auxiliary drive annular interface (24) is a drive pulley or a gear wheel formed or reported on the actuator support (60). 9. A propulsion assembly (1) comprising a clutch system and a fixed housing (22), characterized in that the clutch system (10) is according to any one of the preceding claims, the body (56) of the first clutch actuator (52) being stopped in rotation with respect to an element of the fixed housing (22). 10. propulsion assembly (1) according to claim 9, characterized in that the fixed housing (22) comprises a guide bearing (29) of the input member (26), the body (56) of the first actuator (52) preferably being disposed axially between the guide bearing (29) of the input member (26) and the clutch disc (34).