WO2013083328A2

WO2013083328A2 - Optimized barrel for controlling the gear ratio of an automated gearbox, and control methods

Info

Publication number: WO2013083328A2
Application number: PCT/EP2012/071047
Authority: WO
Inventors: Michel Raoul
Original assignee: Renault S.A.S.
Priority date: 2011-12-06
Filing date: 2012-10-24
Publication date: 2013-06-13
Also published as: FR2983549A1; WO2013083328A3

Abstract

The invention relates to a device for controlling a gearbox having a barrel, comprising a rotatable drum, which has, on the cylindrical wall thereof, circular grooves (6a, 6b, 6c) with sectors for diverting elements (7a, 7b, 7c) for controlling inner forks of the gearbox in order to select gear ratios, characterized in that the angle of rotation of the drum for shifting gears is differentiated according to the ratios in question.

Description

OPTIMIZED BARREL FOR CONTROL OF AUTOMATED BOX SPEEDS AND CONTROL METHODS

The present invention relates to the control of shifting on a gearbox with parallel shafts of the manual type, controlled from a selector or lever actuated directly by the driver, or of the robotic type, where a passage actuator is placed under the control of a transmission computer.

More specifically, it relates to a barrel-type gearbox control device, comprising a rotationally driven drum, which has circular grooves on its cylindrical wall with deflection sectors of internal fork control elements of the gearbox. for the engagement of the reports.

Known gearboxes, of the type indicated above, called "sequential boxes". These boxes are provided with a barrel control device comprising a drum provided with a plurality of grooves which receive generally cylindrical elements, pins or rollers, integral with the control brackets of the players of the box. The grooves have sectors of deflection of the control elements of the forks. The engagement race, is the same regardless of the report to engage, because the race to the lever or the pedal (when it comes to motorcycle) is constant.

Sequential boxes are mainly manually operated. There are, however, robotic applications of the barrel sequential control system, where the rotation of the drum is automated. It can thus be driven by an electric actuator, itself controlled by a control member. The present invention aims to take advantage of the possibilities offered by the control of an electrically driven actuator to adapt the geometry of the grooves of the drum to the different gearshifts of the box.

For this purpose, it proposes that the angle of rotation of the drum for the gearshifts, is differentiated according to the reports concerned.

It also proposes that the slopes of the grooves in the deflection zones corresponding to the shifts, are differentiated according to the report concerned.

According to the invention, the slope of the deviations of the grooves is lower for the engagement of the reports requiring more synchronizer capacity, or more effort applied to the range, than for the engagement of the reports requiring little capacity of synchronizer, or less effort applied to the range.

In particular, the slope a of the deflection sector of the first and second forward gear may be less than the slope β of the sector of the third and fourth forward gear.

For gear changes involving two forks controlled by two different grooves, the angle of rotation of the drum is reduced by anticipating the engagement of the targeted gear before the complete disengagement of the gear left.

According to a particular embodiment, one of the grooves, preferably the groove of the first and second forward gear, has an additional deviation between the neutral position and the reverse position, ensuring the synchronization of the reverse gear before the engagement of this one. The invention proposes alternatively that, to go backward, the drum rotates to the first gear from neutral to perform the synchronization of this ratio, using the brake synchronizer reversing, then a rotation in reverse to reverse.

The present invention will be better understood on reading the following description of a nonlimiting embodiment thereof, with reference to the appended drawings, in which:

FIG. 1 is a section of a gearbox control cylinder,

FIG. 2 is a view of the unrolled drum with uniform deflection slopes,

FIG. 3 is a view of the unrolled drum with differentiated deflection slopes, and

Figure 4 is a view of the unrolled drum with uniform deflection slopes and additional deflection on a control groove.

The barrel illustrated in Figure 1 consists of a drum 1 closed at one end by a gear wheel 2 belonging to a drive system wheel and worm not shown. The drum, contained in its own housing 3, is supported by a fixed axis 4. It has three grooves 6a, 6b, 6c can each receive a control element, such as a pin or a roller 7a, 7d, 7c. Each element 7a, 7b, 7c is connected to a gearshift fork (not shown) of the gearbox. In the case of a five-speed gearbox and a reverse gear ratio, the first groove 6a and the first fork control for example the first and second forward gears, the second groove 6b and the second fork control the third and fourth forward gears. The third groove 6c and the third fork control the fifth forward gear and the reverse gear (MAR).

Figures 2, 3 and 4 are representations of the drum of Figure 1, length 1 unrolled flat, on which we find the three grooves 6a, 6b, 6c of the figure. While in reality, the grooves 6a, 6b, 6c run past the pins or rollers during the rotation of the drum by moving (or not) the latter in the only longitudinal direction of the drum, the rotation of the drum is reflected in the figures 2, 3 and 4 by a displacement of the three elements 7a, 7b, 7c along the grooves, with a transverse deflection on the deflection sectors. In the three figures, the length traveled by the elements in their groove between the engaged gear positions is not the same for all the changes, which reflects on the diagrams the fact that the rotation angle of the drum for the passages is differentiated according to the reports concerned.

In FIG. 2, the displacement between two ratios involving a single fork, for example the passage from first to second 1-2, is longer than the displacement between two ratios involving two forks, for example, for example the passage of second in third 2-3.

During the passage 2-3, the engagement of the third report starts as soon as the race of "decoupling" This necessary to the release of the report of second is made. Similarly, during a 3-2 retro passage, the engagement of the second report starts as soon as the "decoupling" race Ce, necessary to disengage the report. third, is realized. The reduction of some races (here the races of the passages where intervenes two forks) makes it possible mainly to shorten the developed length of the drum, therefore its mass and its bulk. This reduction makes it possible to reduce the corresponding passage times. However, the deflection angle a is identical over all the grooves, so for all the movements of transverse deviation of the rollers. As a result, races Cl-2 and C3-4 are equal, as are races C2-3 and C2-5. Nevertheless, the rotation angle of the drum for shifting is differentiated according to the reports concerned.

In FIG. 3, the deviation angles α, β, γ, δ are differentiated. On the first groove 6a, the deviations for the first gear passages have the slope a, the lowest. The torque given on the drum is reflected by very high axial force on the connecting element with the fork. This portion occupies a significant length on the unrolled surface of the drum.

On the first and second grooves 6a, 6b, the sectors relating to the passages on the third and fourth gear, have a greater deflection angle β, which translates a given torque on the drum into a lower axial force on the first gear. connecting element with the fork. This decrease in the applied force is permissible because the need for thrust on the third and fourth synchronizers is less than on the first and second synchronizers. The advantage of this arrangement is to reduce, as much as possible, the length used for these passages on the unrolled surface of the drum. On the third groove 6c, concerning the passages on the fifth and reverse gears, the deviations have an even steeper slope δ and γ, which translates a given torque on the drum into an even lower axial force on the element. link with the fork. This force is sufficient compared to the need for force on the fifth synchronizer. It may also be sufficient for the MAR, since the reversing control systems generally provide adjustments or braking strategies of the reverse gear. Thus, the portion occupied on the unrolled length of the drum for shifting is even shorter on the third groove 6c than on the second groove 6b. Overall, the slope of the deviations of the grooves is therefore lower for the engagement of the reports requiring more synchronizer capacity, or more effort applied to the range, than for the engagement of the reports requiring little capacity of synchronizer, or less effort applied to the range. This makes it possible to unify the synchronizers and to homogenize the torque to be supplied by the motor for the same size and a similar mass of the drum. Finally, for gear changes involving two forks controlled by two different grooves, the rotation angle of the drum can be reduced by anticipating the commitment of the target report before the complete disengagement of the departed report.

FIG. 4 shows a drum whose grooves 6b and 6c have the same geometrical characteristics as those of FIG. 2. Nevertheless, the passage groove 6a has however a particular geometrical characteristic, which concerns the passage of the MAR. Between the neutral position and the position MAR engaged, the groove 6a has an additional deviation, which corresponds to a commitment of the first report. This deflection ensures the synchronization of the first gear, and the complete stop of the primary shaft (when the vehicle is stopped), before the engagement of the MAR. It improves the passage of the MAR by limiting crunches. However, it occupies a certain section on the unrolled length of the drum, thus having a significant impact on the total overall size of it.

It may therefore be preferable to differentiate the slopes from the existing deviations, in accordance with Figure 3, by adopting in this case an appropriate steering strategy, to obtain the same results on the improvement of MAR's commitment delivery. This strategy may consist in particular to achieve the rotation of the drum necessary for the synchronization of the first report (braking of the primary shaft), before performing the reverse rotation to the commitment of the MAR.

In summary, the invention allows the proposed provisions to adapt the rotation of the drum to the changes involved reports. It takes advantage of the fact that the commitment of some reports requires more synchronizer capacity, or more effort applied to the range than others. It is thus possible to play on the geometry of the grooves to optimize the size of the drum, the size, the power, or the torque developed by the control device, as well as the capacity of the associated synchronizers, in the sense of reducing their size. size or removal of a friction cone. Finally, the biasing of the actuating device can be standardized for all the gearbox gear changes.

Claims

A barrel-type gearbox control device comprising a rotatably driven drum (1) which has circular grooves (6a, 6b, 6c) on its cylindrical wall with deflection sectors of control elements (7a). , 7b, 7c) of the internal forks of the gearbox for engaging the gears, the rotation angle of the drum for the gears being differentiated according to the gears concerned,

characterized in that the slope of the deviations of the grooves (6a, 6b, 6c) is smaller for the engagement of the ratios requiring more synchronizer capacity, or more of the force applied to the range, than for the engagement of the reports requiring little synchronizer capacity, or less effort applied to the range.

2. Barrel-type gearbox control device according to claim 1, characterized in that the slopes of the grooves (6a, 6b, 6c) are differentiated according to the ratio concerned.

3. Control device according to claim 1 or 2, characterized in that the slope (a) of the deflection sector of the first and second forward gear is less than the slope (β) of the sector of the third and fourth gear walking forward.

4. Control device according to claim 3, characterized in that the slopes (δ, γ) of the deflection sector of the fifth gear ratio and the reverse gear ratio are greater than the slope (β) of the third sector. and the fourth forward gear.

5. Control device according to one of the preceding claims, characterized in that one of the grooves (6a, 6b, 6c) of the drum (1) has a further deflection.

6. Control device according to claim 5, characterized in that the control groove (6a) of the first and second forward gear has an additional deviation between the neutral position and the reverse position, ensuring the synchronization of the ratio reverse gear before engaging reverse gear.

7. A method of controlling a barrel-type gearbox by means of a drum driven in rotation with circular grooves (6a, 6b, 6c) having control element deflection sectors on its cylindrical wall ( 7a, 7b, 7c) of the internal forks of the gearbox for the engagement of the ratios, the angle of rotation of the drum for the gearshifts being differentiated according to the reports concerned,

characterized in that, when reversing, the drum rotates to the first gear from the neutral position to synchronize this gear, to use this reverse brake synchronizer, and then to rotate in the reverse direction to reverse.

8. A method of controlling a barreled gearbox, with a device according to one of claims 1 to 6, characterized in that, for gear changes involving two forks controlled by two different grooves, the angle The rotation of the drum is reduced by anticipating the commitment of the targeted report before the complete disengagement of the departed report.