FR3009051A1 - ELECTROMECHANICAL CLUTCH CONTROL DEVICE FOR A MECHANICAL GEARBOX OF A MOTOR VEHICLE - Google Patents

Abstract

Electromechanical clutch control device for a motor vehicle gearbox, comprising a housing (1, 2) which supports a rotary drive motor (3), and maintains in bearings an intermediate gear (4) driven by a pinion output shaft (3a) of the motor which drives in rotation a nut (5) immobilized in translation and internally threaded so as to move by turning a threaded spindle (6) traversed axially by a pulling cable (10) of a release fork (12), characterized in that the axis of the pinion (4) passes through a portion (2) of the housing (1, 2) and has outside thereof an extension whose end (4a) is suitable receiving a manual rotational drive tool (17).

Description

The present invention relates to an electromechanical clutch control device for a mechanical gearbox of a motor vehicle. BACKGROUND OF THE INVENTION The present invention relates to an electromechanical clutch control device for a mechanical gearbox of a motor vehicle. It relates more particularly to a clutch control device for a motor vehicle gearbox, comprising a housing which supports a rotary drive motor, and maintains between intermediate bearings an intermediate gear driven by an output gear of the motor, which rotates a nut immobilized in translation and threaded internally, so as to move by turning a threaded spindle axially traversed by a pulling cable. Such a device constitutes a mechanical transmission gear type gears parallel axis and ultimately by transformation of the rotational movement into a translation movement by a screw-nut system, whose screw exerts a pull on a cable, which is connected at a fork of 20 clutch. Publication FR 2 767 168 discloses an actuating device comprising an electric motor whose toothed end of the shaft drives a pinion fixed to a threaded spindle by means of a pinion gear. The motor is arranged parallel to the threaded spindle. This is locked in translation by a bearing, and causes turning the axial displacement of a nut. The nut, partially spherical externally, is connected to a rod, bearing at its end a ball joint control rod 30 allowing misalignment between the rod and the rod. Finally, the motor is assisted by a compensation spring, for disengagement. The publication FR 2 838 170 describes another device comprising an electric motor, the toothed end of the shaft drives a motor pinion directly connected in rotation to a nut immobilized in translation. In this device, there is no intermediate gear for returning between the drive pinion and the nut. The nut is supported by two bearings implanted, one in the housing of the actuator, and the other in the cover. The nut is free to rotate, and locked in translation. It is threaded internally. By turning, it moves in translation a threaded rod, which is locked in rotation by a flange stopped in rotation by the housing. The rod is traversed from one side by an actuating cable of a release fork. The flange also has the role of transmitting to the screw the axial thrust of a compensation spring of the disengagement force. In the two devices mentioned above, the thread is reduced, and the actuator is irreversible, that is to say stable in each position. This has a significant advantage because it is possible to maintain the clutch fork in different positions, without stressing the engine, so without consuming power, especially in the waiting position at the point of licking, and in the clutch position open. However, the irreversible nature of these two devices has a major disadvantage because it blocks the clutch in position, in case of failure of the actuator 25 itself, or the global robot system. The present invention proposes to solve the problems posed by the irreversibility of the system, by opening the possibility of simply acting on the actuator by manual intervention, especially in case of failure, in order to release the clutch from control positions. inadequate. For this purpose, it provides that the axis of the intermediate gear passes through a portion of the housing, and has outside thereof an extension, the end of which is adapted to receive a manual drive tool in rotation. Preferably, the axis of the intermediate gear is supported in the housing by guide rings, and extends beyond one of them, exiting through an opening in the housing. Finally, the tool can be advantageously a key cooperating with the end of the axis of the intermediate gear. The present invention will be better understood on reading the following description of a non-limiting embodiment thereof, with reference to the accompanying drawings, in which: FIG. 1 is a sectional view of the actuator of FIG. clutch in the engaged position, FIG. 2 is the same section as the preceding one when approaching the control key, FIG. 3 is a sectional view of the actuator, in the disengaged position after intervention of the key. FIG. 4 is a sectional view of the actuator, in the extreme position of release of the cable, and FIG. 5 is a sectional view of the actuator, in the extreme position of attachment of the cable. The electromechanical actuator illustrated in the figures, is composed of a housing 1, which supports the electric motor 3 25 and the entire mechanism. A lid 2 completes the housing to support the mechanism, and protect it from the outside environment. The sealing of the contact surface of the casings is provided by the seal 2a, and that of the engine docking face by the seal 3b. The motor 3 provides the energy to move a release fork 12 through a mechanism having two reduction levels. The first level of speed reduction is provided by sprockets with external toothing: the pinion 3a on the motor shaft, the intermediate gear 4, and the toothing 5a of the nut 5. The second level of reduction is constituted by the cooperation of the threaded spindle 6 with the nut 5, which also realizes the transformation of the rotational movement of the motor into a final translational movement. The housing supports the motor 3, and maintains in bearings, the guide rings 15, and the intermediate gear 4 driven by the output gear 3a of the motor, which itself drives in rotation the threaded nut 5. The latter is immobilized in translation, and internally threaded, so as to move by rotating the threaded spindle 6, which is traversed axially by the pulling cable 10 of the release fork 12. The cable 10 has a first nozzle 10a resting against a cup 14a to one end of the pin 6 and a second end 10b, at its other end, resting against the declutching fork. The sealing of the cable exit from the casing 1 is provided by a bellows 11. The intermediate gear 4 is mounted on the guide rings 15. It does not participate in reducing the speed, but it is necessary to limit the size of the device. It is also very advantageous for the realization of the invention. The nut 5 is supported by two guide bearings 7, arranged in the housing 1 and the cover 2 with support clips 7a. It is animated by a rotation movement, but is blocked in translation. By turning, the nut 5 inflicts the screw 6 a simple translational movement, because it is locked in rotation through the sleeve 8, the angular guide protrusion 8a flows in the groove 1a of the housing 1 The screw 6 is traversed right through by a pulling cable 10 of the release fork 12. Thus, depending on the direction of rotation of the nut, the screw 6 moves in the direction of opening or closing. closing the clutch.

The disengagement force is high, it is provided a spring 9 force compensation. The spring 9 is guided by the sleeve 8, and exerts a separation force between the housing 1 and the sleeve 8. This force is transmitted by the sleeve 8 to the screw 6 and the cable 10. The spring is put in place with a certain pre-charge, and thus has a quantity of elastic potential energy determined. It relaxes in the direction of opening the clutch, and then provides mechanical energy, that the engine does not have to provide.

Conversely, when closing the clutch, it restores the potential energy provided in part by the diaphragm of the clutch. In this sense, it limits the restraining energy that must provide the engine to control the closing of the clutch.

In order to prevent wear of the diaphragm nozzles, and the squeal noise during the abrupt rise in speed, the clutch stop (not shown) must always remain in contact with the diaphragm with some force. The actuator is able to meet this requirement, thanks to the presence of a pre-load spring 13. The latter is supported, on the one hand on the cup 14a which ensures its guidance and rests on the cable end 10a, and on the other hand on the washer 14b which rests on the end of the threaded spindle 6. The axis of the intermediate gear 4 is supported by the rings 25 arranged in the casing 1 and the lid 2. It passes through the cover 2 of the housing, and has outside thereof an extension, whose end 4a is adapted to receive a rotary drive tool 17. The axis of the intermediate gear 4 extends beyond one of the rings 15 30 exiting through an opening of the housing. The seal between the shaft and the cover is achieved by the seal 16. The end 4a of the axis, has a particular shape, allowing it to cooperate with a suitable tool, such as the drive key 17, shown in the approach position in FIG. 2, and in the operating position in FIGS. 3 and 4. The intervention of the key 17 on the axis of the intermediate gear 4 makes it possible to turn the nut 5, and to modify the axial position of the screw 6 and the clutch fork 12. The key 17 cooperates with the end 4a of the axis of the intermediate gear 4. With the key 17, it is possible to manually rotate the intermediate gear 4. In a first direction of rotation, the key 17 can give the screw 6 a release movement to place the actuator in the situation of Figure 3. This movement allows to separate the gearbox of the engine, in circumstances breakdown or intervention. The key 17 makes it possible to pull manually on the cable 10, to place the clutch in the disengaged position by rotating the intermediate gear 4 in a first direction of rotation. In the opposite direction of rotation, the key 17 makes it possible to place the actuator in a particular extreme position, illustrated by FIG. 4: the clutch remains closed, the compensation spring 9 is compressed, the cable 10 remains tensioned by the action of the pre-load spring 13 which has relaxed. The pre-load spring can be compressed to the maximum extent by keeping the clutch in the engaged position, by rotating the axis of the intermediate gear 4 with the key 17 in a second direction of rotation. By exerting traction on the cable, it is able to move sufficiently the tip 10b of the cable 10, the fork to achieve decoupling the fork of the cable, as in Figure 5. This possibility is particularly interesting when the assembly of the power train at the factory, or during an intervention in the network. In summary, the extension of the axis of the intermediate gear through the lid, allows manual intervention on the state of the actuator in all circumstances, and in particular to manually open the clutch (equivalent to the opening of the driveline), or to easily couple or disconnect the control cable.

Claims (5)

REVENDICATIONS1. Electromechanical clutch control device for a motor vehicle gearbox, comprising a housing (1, 2) which supports a rotary drive motor (3), and maintains in bearings an intermediate gear (4) driven by an output gear (3a) of the motor which drives in rotation a nut (5) immobilized in translation and threaded internally so as to move by turning a threaded spindle (6) traversed axially by a pulling cable (10) of a release fork (12), characterized in that the axis of the pinion (4) passes through a portion ( 2) of the casing (1, 2) and has outside thereof an extension whose end (4a) is adapted to receive a manual rotary drive tool (17). 2. Control device according to claim 1, characterized in that the axis of the intermediate gear (4) is supported in the housing (1, 2) by guide rings (15) and extends beyond the one of them exiting through an opening of the housing. 3. Control device according to claim 1 or 2, characterized in that the tool (17) is a key cooperating with the end of the axis of the intermediate gear (4). 4. Control device according to claim 3, characterized in that the intervention of the key (17) on the axis of the intermediate gear (4) makes it possible to turn the nut (5) and to modify the axial position. the screw (6) and the clutch fork (12). 5. Control device according to claim 3 or 4, characterized in that the key (17) allows manual pulling on the cable (10) to place the clutch in the disengaged position by rotating the intermediate gear (4) in a first direction of rotation .. Control device according to claim 3, 4 or 5, characterized in that it comprises a force compensation spring (9) which expands upon opening of the clutch and compressing when closed, which can be compressed as much as possible by keeping the clutch in the engaged position, rotating the axis of the intermediate gear (4) with the key (17) in a second direction of rotation. 7. Control device according to claim 6, characterized in that the tip (10b) of the cable (10) resting on the fork (12), can be moved away from it to decouple the fork (12) , the cable (10).