FR2878487A1 - Drive shaft locking mechanism for motor vehicle, has release spring applying constant force on clamping lever to force back lever to released angular position, where lever has balance weight for soliciting lever towards angular position - Google Patents

Abstract

The mechanism has a parking lock gear (8) integrated in rotation with a drive shaft (4). A clamping lever (9) includes a locking pin received between teeth of the parking lock gear. A release spring (11) applies constant force on the clamping lever to force back the lever to a released angular position. The lever includes a balance weight (27) for soliciting the lever towards the angular position. An independent claim is also included for an automatic transmission including a locking mechanism.

Description

Mechanism for locking a transmission shaft of a vehicle

automobile 5

  The invention relates to a locking mechanism of a transmission shaft of a motor vehicle, and more particularly of the transmission shaft at the output of an automatic gearbox or gearbox.

  Conventionally, a locking mechanism of a transmission shaft of a motor vehicle comprises a wheel, said parking, toothed rotationally integral with the transmission shaft, a locking lever which carries a locking pin capable of being received in a slot of the toothed wheel, said locking lever being pivotally mounted around a tilting shaft between an armed angular position in which the locking finger engages between two teeth of the parking wheel, and an angular position released a release spring applying a constant force on the locking lever so as to push it towards said unobstructed angular position.

  On vehicles equipped with automatic gearbox or an electric motor associated with a gearbox, the driver has a lever for controlling the running of the vehicle. This control lever generally has several positions, including at least the following: forward (D), reverse (R), neutral point (N) and parking (P). The lever transmits its position to the gearbox or gearbox via a cable or linkage. The parking position corresponds to a parking state of the vehicle, in which the movement of the vehicle must be prohibited. For this, the transmission shaft of the gearbox or reducer is immobilized, which prevents the rotation of the drive wheels of the vehicle, and immobilizes it.

  Conventionally, the transmission shaft of an automatic transmission comprises a gear wheel, also called parking wheel. A locking lever pivotally mounted on the gearbox comprises a locking pin which can be inserted into a slot between two teeth of the toothed wheel when the locking lever pivots, thus achieving a rotational stop of the gear wheel and of the drive shaft. The geometry and materials of the teeth and the locking finger are chosen so that the locking lever is not wedged between the teeth when the wheel is biased by a torque, for example when the vehicle is parked in a steep slope.

  The holding of the locking finger between the teeth of the toothed wheel only results from the forces applied by a control mechanism. A release spring mounted on the axis of rotation of the locking lever tends to keep it clear of the toothed wheel. A control lever connected to an actuator interacts with the locking lever by pivoting it so that the locking finger engages in a slot of the gearwheel. The control lever is controlled by the cable or the linkage via a spring and a slide.

  The return spring is conventionally mounted around the axis of the locking lever and is dimensioned so as to provide the return torque opposing the force due to the vertical acceleration applied to the locking lever and the other components of the locking mechanism. In the documents EP-0571274 and FR-2810422, the forces applying to the components of the locking system are important. The components are dimensioned accordingly causing an increase in their mass and in particular an increase in the mass of the locking lever. The release spring must then provide a large booster torque approaching the limits of reasonable sizing.

  The present invention aims to reduce the return torque that must exert the release spring of a locking mechanism of a transmission shaft of a motor vehicle.

  For this purpose, the present invention proposes that a locking lever comprises a balancing flyweight biasing said locking lever to the unobstructed angular position.

  The locking mechanism of a transmission shaft of a motor vehicle according to the invention also has the following characteristics: the release spring is mounted on the housing and rests on a surface of the release weight and a wall; of the housing, the locking lever pivots about the disengagement shaft whose axis is located between the locking pin and the balancing weight, - a disengagement spring is mounted around the tilting shaft and bearing against the locking pin and a wall of a housing, the locking lever comprises a protrusion which cooperates with a control lever having at least one armed position which allows the locking of the drive shaft and at least one position release which releases the rotation of the transmission shaft, -expansion of the locking lever has a profile cooperating with a roller of the control lever so as to maintain said locking lever in a position angular army, and - the balancing weight comes from foundry with the locking lever.

  The present invention also applies to an automatic gearbox, characterized in that it comprises a locking mechanism, the transmission shaft being an output shaft of the gearbox.

  The invention will be better understood on reading the following description of a particular embodiment thereof which is not limiting, in conjunction with the appended drawings, in which: FIG. 1 is a general layout diagram, FIG. 2 is a view along the arrow A of the casing mentioned in FIG. 1, showing a first embodiment of the control device in the disengaged position, FIG. 3 corresponds to the same embodiment in the braking position with a view. in section of the control lever, - Figure 4 schematically illustrates the same embodiment shown in three dimensions in the braking position, and - Figure 5 illustrates a second embodiment of the invention in the open position.

  In FIG. 1, the motor 1, for example an electric motor, of a motor vehicle, is associated with a gearbox 2, which transmits the movement to the wheels 3 via the transmission shaft 4. This shaft passes through the housing 5 constituting the front wall of the gearbox 2. On the inner face of the housing 5, a recess 5 ', formed in the mass thereof, receives the end gears 6 and 7 of two shafts 4 and 4' of the mechanism reduction. The parking wheel 8 is carried by the shaft 4 inside the housing 5.

  FIG. 2, showing the control elements disposed on the outside face of the casing 5, shows, in broken lines, the implantation of the recess 5 'in the mass of the casing and the edge of the side wall 2' of the reducer 2, on which is supported the housing 5.

  As indicated above, the parking wheel 8 is integral in rotation with the transmission shaft 4. The teeth 8 ', cut on the periphery thereof, are intended to receive a locking pin of a locking lever 9 pivoting on an axis carried by the housing 5. An unlocking spring 11, wound around the axis 10 of the locking lever 9, bears against an arrangement, not shown, of the housing 5 and the lever 9 so as to ensure the withdrawal thereof when unlocking the parking wheel 8. A control lever 12 maintains in an unlocked position, illustrated by Figures 2 and 5, the locking pin set back from the parking wheel 8.

  As illustrated in detail in FIG. 3, the end 13 of the locking lever 9 is actuated by a control lever 12 to allow the engagement of the finger between two teeth 8 'of the wheel 8. This control lever 12 is connected via a metal rod 15 to a connecting rod 17 secured to a control shaft 16. The control lever 12 further comprises a slot 20 which cooperates with an outgrowth 21 of a guide 18. This guide 18 is mounted on the axis 10 of the lever 9 so as to orient the stroke of the control lever 12 when actuated.

  Two rollers 22 and 23 identical, and generally cylindrical, are mounted on the control lever 12 in a direction substantially parallel to the transmission shaft 4. These two rollers 22 and 23 are free to rotate about their respective axis 24 and 25 so that they roll on each other. The distance between the axes 24 and 25 therefore corresponds to the value of the diameter of a roller. The first roller 24 remains in contact on the one hand with the finger of the lever 9 and on the other by the second roller 23 during the locking and unlocking phases of the parking wheel 8. As for the second roller 23, there remains in contact on the one hand with the first roller 22 and on the other hand with the guide 18. The end 13 of the finger remains in effect always in contact with the second roller 23 since the return spring 11 applies a permanent force which straightens the lever 9 against the roller 23. The use of these two rollers 22 and 23 provides a rolling without sliding between the finger and the latter. There is no sliding effect between these parts when the user selects the parking position (P), which makes it possible to reduce the release effort under load.

  In addition, the control lever 12 comprises an orifice in which the metal rod 15 is engaged. This rod 15 receives at its end a stop 26 which serves on the one hand as a rail to the lever 12 while sliding on the guide 18 and on the other. on the other hand, to prevent the rod 15 from disengaging from the lever 12 in the unlocked position.

  The operation of the first embodiment of the invention will now be described with reference to FIGS. 2, 3 and 4, respectively illustrating the situation of this device when the parking brake is not locked and when it is locked, Figure 4 showing the device in three dimensions in locked position. In Figure 2, the selection lever is in the neutral position (N). The locking finger is then released from the parking wheel 8. It is the same when the selection lever is in the forward (D) or reverse (R). However, when the selection lever is in the parking position (P), according to Figures 3 and 4, the parking brake is locked by engaging the locking finger between two teeth 8 'under the action of the lever. order 12.

  The kinematic chain for engaging or disengaging the locking finger to actuate the parking brake is as follows. When the user engages a speed, for example when he selects the parking position (P), via a control selector, not shown, a rotating means, not shown, rotates the control shaft 16. The it then drives the rod 17 which transmits its movement to the rod 15. Under the action of the metal rod 15 and a spring 19 mounted on the metal rod 15 between the rod 17 and the lever 12, the latter translates along the guide 18 in the direction imposed by the protrusion 21 cooperating with the slot 20. The rollers 22 and 23 being connected to the lever 12, the roller 23 rolls on the profile of the end 13 and constrains the lever 9 which enters in a rotational movement about its axis 10. The finger then engages between two teeth 8 'of the wheel 8 to lock the drive shaft 4.

  The spring 19 exerts an arming force intended to engage the finger when the parking position (P) is selected and the finger is facing a tooth 8 'of the wheel 8. Indeed, it is possible that the finger can not to be inserted between two teeth 8 'and remains wedged against a tooth 8'. In this case, when the vehicle initiates a movement when the user selects the parking position (P), the shaft 4 pivots by driving the wheel 8. The control lever 12 is always biased by the arming effort exerted by the spring 19 which allows to engage the finger between two teeth 8 'of the wheel 8, when it arrives in front of a hollow.

  According to the invention and according to all of FIGS. 2, 3, 4 and 5, the groove finger comprises a balance weight 27 situated opposite the end 13, the weight 27 and the end 13 being located on either side of the axis 10. This balance weight 27 allows to bring the center of gravity of the assembly consisting of the finger, the control lever 12 and the guide 18 closer to the axis of rotation 10 by acting on the shape of the parking finger by adding a counterweight on it. In addition, the return torque that must exert the return spring 11 on the finger to keep it clear is less, which reduces its dimensioning.

  In a second embodiment illustrated in FIG. 5, the return spring 11 is positioned differently. Indeed, this return spring 11 which is generally a torsion spring mounted on the axis 10 of the locking lever 9, can be replaced by a compression spring supported on the one hand on the lever 9 on the side of the balancing weight 27 and secondly on a housing arrangement 5 in which is mounted the system. Similarly, this compression spring 11 is of reduced dimensions since the restoring force to be applied to the finger is mainly exerted by the balance weight 27. The spring 11 and the weight 27 cooperate together to straighten the locking finger in open position.

  Because the parking wheel is located on the drive shaft 4, the forces on the system components are important. The components are dimensioned accordingly and their mass increases. The present invention has the advantage of providing a balance weight 27 which supports the return spring 11. Such an invention improves the operational safety of the locking system of the parking wheel of a vehicle and provides greater strength the efforts to which the components are subjected.

Claims (8)

  1. Mechanism for locking a transmission shaft (4) of a motor vehicle of the type comprising: - a wheel (8), said parking wheel, toothed rotationally integral with the transmission shaft (4), - a locking lever (9) which carries a blocking catch which can be accommodated in a slot of the toothed wheel (8), said locking lever (9) being pivotally mounted around a tilting shaft (10) between a armed angular position in which the locking finger engages between two teeth (8 ') of the parking wheel (8), and an open angular position, and - a release spring (11) applying a constant force on the locking lever (9) so as to push it towards said unobstructed angular position, characterized in that the locking lever (9) comprises a balancing flyweight (27) urging said locking lever (9) towards the angular position released.   2. Locking mechanism of a transmission shaft (4) of a motor vehicle according to the preceding claim, characterized in that the release spring (11) is mounted on the housing (5) and is supported on a surface the release weight (27) and a housing wall (5).   3. Locking mechanism of a transmission shaft (4) of a motor vehicle according to one of claims 1 or 2, characterized in that the locking lever (9) pivots around the disengagement shaft (10). ) whose axis is located between the blocking finger and the balancing weight (27).   4. locking mechanism of a transmission shaft (4) of a motor vehicle according to one of the preceding claims, characterized in that a release spring (11) is mounted around the tilting shaft (10). ) and bearing against the locking lever (9) and a wall of a housing (5).   5. Locking mechanism of a transmission shaft (4) of a motor vehicle according to one of the preceding claims, characterized in that the locking lever (9) comprises a protrusion (13) which cooperates with a lever of control (12) having at least one armed position which allows the locking of the transmission shaft (4) and at least one unobstructed position which releases the rotation of the transmission shaft (4).   6. Locking mechanism of a transmission shaft (4) of a motor vehicle according to claim 5, characterized in that the protrusion (13) of the locking lever (9) has a profile cooperating with a roller (23). ) of the control lever (12) so as to maintain said locking lever (9) in an armed angular position.   7. Locking mechanism of a transmission shaft (4) of a motor vehicle according to one of the preceding claims, characterized in that the balance weight (27) is derived from casting with the locking lever (9). ).   8. Automatic gearbox, characterized in that it comprises a locking mechanism according to claim 1, the transmission shaft (4) being an output shaft of the gearbox (2).