SE529592C2 - Actuator for operating a semi-automatic transmission of a vehicle and the arrangement of a vehicle comprising such actuator - Google Patents

Abstract

The invention relates to a control device for operating a semiautomatic gearbox of a vehicle, which control device comprises a control means (12; 50) which can be moved step by step by rotary or linear movement between at least two fixed setting positions in order to set various gear change modes, whereby said fixed setting positions comprise a first fixed setting position (D) for setting a first gear change mode, and a second fixed setting position (N) for setting a second gear change mode. The control means (12; 50) can be moved from a first fixed setting position (D) to a springback setting position (H) for setting a further gear change mode, whereby the control means (12; 50) is arranged to spring back to the first fixed setting position (D) when it has been moved to the springback setting position (H) from the first fixed setting position. The invention also relates to an arrangement comprising such a control device.

Description

The driver by means of a control lever which in some applications can be pulled stepwise towards the driver, the braking effect increasing the closer the control lever is pulled towards the driver.

Through the patent document SE 514 131 C2, different types of actuators are previously known, with the aid of which a vehicle driver can control both a semi-automatic gearbox and an auxiliary brake in the form of a so-called retarder. The majority of the actuators described in SE 514 131 C2 are provided with a rotatable or displaceable actuator which is stepwise operable between three fixed setting positions for setting different shift modes, said setting positions in turn comprising a setting position for setting a shift mode for driving ("Drive"), a setting mode for setting the neutral position ("Neutral") of the gearbox and a setting mode for setting a shift mode for reversing ("Reverse").

OBJECT OF THE INVENTION The object of the present invention is to provide a further development of an actuator of the above-mentioned type in order to facilitate a driver's actuation thereof.

SUMMARY OF THE INVENTION According to the invention, said object is achieved by means of an actuator having the features stated in claim 1.

The actuator according to the invention is intended for operating a semi-automatic gearbox of a vehicle and comprises a rotatable or displaceable actuator which is stepwise operable between at least two fixed setting positions for setting different gear modes, said fixed setting positions comprising a first fixed setting position for setting a first shift mode and a second fixed setting mode for setting a second shift mode. With the inventive solution, the actuator is operable from the first fixed setting position to a resilient setting position for setting an additional shift mode, the actuator being arranged to spring back to the first fixed setting position when it has been actuated to the resilient setting. 20 25 30 35 529 592 from the first fixed setting mode. It should be considerably easier for the vehicle driver to associate the said additional shift mode, which may, for example, constitute a shift mode for driving uphill (“Hill”), with a spring-back function than with a certain direction of rotation or displacement. In the event that the actuator is in the first fixed setting position, which preferably constitutes a setting position for setting a shift mode for driving under normal conditions ("Drive"), and the driver, for example, intends to set the shift mode associated with the second fixed setting position. , which gear mode preferably constitutes the gear mode for neutral position ("Neutral"), the driver will sense the resilience between the first fixed setting position and the resilient setting position in the event that he turns or displaces the actuator in the wrong direction.

Thanks to the current re-suspension function between the first fixed adjustment position and the re-alignment adjustment position, the driver thus directly receives an indication of whether he has turned or shifted the control in the right or wrong direction from the first fixed adjustment position when changing shift mode from the shift mode. associated with the first fixed setting position of a desired shift mode associated with an adjacent setting position of the actuator.

According to a preferred embodiment of the invention, the actuator is also operable from the second fixed setting position to a third fixed setting position, which constitutes a setting position for setting a reverse mode for reversing ("Reverse"), the second fixed setting position constituting a setting position for setting of a gear mode for neutral position ("Neutral") of the gearbox.

According to another preferred embodiment of the invention, the actuator is operable from the first fixed setting position to the resilient setting position for setting a shift mode for driving in the opposite direction ("Hill"), the first fixed setting position being a setting position for setting a shift mode for driving under normal conditions ("Drive").

According to another preferred embodiment of the invention, the actuator is operable from the first fixed setting position to the resilient setting position for setting a shift mode among a plurality of additional shift modes only, the shift mode being adjusted thereby depends on the number of repeated operations from the first fixed setting position to the resilient setting position. This makes it possible in a simple manner to use the operating means for setting an arbitrary number of shift modes.

According to another preferred embodiment of the invention, the actuator is also designed for actuating an auxiliary brake. This makes it possible for the driver to regulate both the gearbox and the auxiliary brake with one and the same actuator, which facilitates the driver's work. Using one and the same actuator for both shifting and braking is also space-saving compared to a conventional solution with two different actuators for these functions.

Further preferred embodiments of the actuator according to the invention appear from the dependent claims and the following description.

The invention also relates to a device having the features stated in claim 16 and a device having the features stated in claim 17.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below with the aid of exemplary embodiments, with reference to the accompanying drawings. It is shown in: Fig. 1 a schematic perspective view of a part of a driver's cab in a heavier motor vehicle with an actuator according to a first embodiment of the invention mounted at the steering column of the vehicle, with the outer part of the actuator shown in detail, Fig. 2 a schematic Fig. 3 is a schematic perspective view of a part of an actuator according to a second embodiment of the invention, Fig. 3 is a schematic perspective view of a part of an actuator according to a third embodiment of the invention, Fig. 4 is a schematic perspective view of a part of a actuator according to a fourth embodiment of the invention, Fig. 5 a schematic perspective view of a part of an actuator according to a fifth embodiment of the invention, Fig. 6 a schematic illustration of the setting possibilities for the rotatable actuator of the actuators according to Figs. 1-4, Fig. 7 a schematic illustration of the setting possibilities for the displaceable actuator of the actuator according to Fig. 5, and Fig. 8 is a diagram block diagram illustrating a device according to the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS The actuator 10 according to the invention is designed for operating a semi-automatic gearbox 1 (schematically indicated in Fig. 8) of a vehicle, such as for example a truck, a tractor for semi-trailers or a bus.

The semi-automatic gearbox is in principle a manual gearbox which is provided with a number of servos, which as a function of control signals from a control unit 2 connected to the gearbox effect the loading and unloading of gears. The control unit 2 can, with the aid of various sensors, be provided with information about the current driving conditions and, on the basis thereof, in a manner known per se, calculate which gear should be used. A sensor can provide information about the current motor load. Via additional sensors, the Control Unit 2 can receive information, for example, about which gear is engaged and about the current speed or current vehicle speed. Of course, other parameters can also be detected with the help of suitable sensors. The actuator 10 is connected to the control unit 2 and the driver of the vehicle can, with the aid of the actuator, cause the control unit 2 to regulate the gearbox in the desired manner. To enable this, the actuator 10 is provided with suitable sensors which sense how the actuator is actuated by the driver and, depending on this, emit control signals to the control unit 2. In the control unit 2 there is a shift mode for different types of driving conditions pre-programmed and the control unit 2 is adjustable by means of the actuator 10 to control the gearbox 1 in accordance with the desired gear mode. Said gear mode includes, among other things, a gear mode for driving under normal conditions, which gear mode is hereinafter referred to as "Drive", a gear mode for neutral position of the gearbox, which gear mode is hereinafter referred to as "Neutral", and a gear mode for hacking, which mode of exchange is hereinafter referred to as “Reverse”. Said shift mode may also comprise one or more additional shift modes for other types of driving conditions, such as, for example, a shift mode for driving in the opposite direction, which shift mode is hereinafter referred to as "Hill". With the aid of the control unit 10, the driver can also switch between shift modes for manual upshift and downshift, which shift mode is hereinafter referred to as "Manual", and automatic upshift and downshift, which shift mode is hereinafter referred to as "Automatic". When the control unit 2 is set to Manual, the upshift and downshift, ie the selection of gear, is controlled by the driver via the control unit 10 and when the control unit 2 is set to Automatic, the upshift and downshift (gear selection) is controlled automatically by the control unit.

The actuator 10 according to the invention is preferably also designed for actuating an auxiliary brake 3 (schematically indicated in Fig. 8) in the form of a retarder of the vehicle in question, the auxiliary brake being operable by means of the actuator for regulating the braking effect thereof.

The actuator 10 is in this case suitably connected to the auxiliary brake 3 via a control unit 4, whereby the driver of the vehicle can by means of the actuator cause the control unit 4 to regulate the auxiliary brake in order to obtain the desired braking effect. To enable this, the actuator 10 is provided with suitable sensors which sense how the actuator is actuated by the driver and, depending on this, emit control signals to the control unit 4.

As will be exemplified in more detail below, the actuator 10 comprises a rotatable or displaceable actuator 12, 50 which is stepwise operable between at least three successive setting positions for setting different shift modes, said setting positions comprising a first fixed setting position for setting a first shift mode, a second fixed setting mode for setting a second shift mode and a resilient setting mode for setting one or more additional shift modes. From the first fixed setting position the actuator is either operable in one direction to the other fixed setting position or in the opposite direction to the resilient setting position, the operating means being arranged to spring back to the first fixed setting position when it has been operated to the resilient setting from the first resilient position. fixed setting mode. The said three setting positions are unlocked and thus no locking function needs to be canceled for operation between these setting positions.

Fig. 1 illustrates a part of the driver's seat in the cab of a heavier motor vehicle, such as a truck or a semi-trailer for semi-trailers. Fig. 1 shows, among other things, the vehicle's steering wheel 5 and instrument panel 6. The steering wheel 5 is mounted on a guide column 7. An actuator 10 according to the present invention is also mounted on the steering column. The actuator 10 comprises a lever 11 which is suitably located in the area near the steering wheel 5 of the vehicle in such a way that the lever 11 can be operated by the driver of the vehicle without having to change his driving position and preferably without having to release the steering wheel. Other locations of the actuator 10 are also conceivable, such as for example on the motor tunnel or the instrument panel. In the embodiment illustrated in Fig. 1, the lever 11 of the actuator is mounted in the control column 7, and in this example the actuator comprises an actuator 12 which is rotatably mounted at the outer part of the lever for setting different shift modes of a to a semi-automatic gearbox connected control unit of the type described above. The actuator 12 is in this case stepwise operable by turning in the directions marked with the arrow P1, preferably around the center axis of the lever, forwards and backwards between four different and successive setting positions. These setting modes consist in turn of a resetting setting mode H for setting Hill, for example, a first fixed setting mode D for setting the Drive, a second fixed setting mode N for setting the Neutral and a third fixed setting mode R for setting the Reverse. From the setting position D the actuator 12 is rotatable forwards one step to the setting position H and backwards one step to the setting position N, the actuator 12 being arranged to spring back to the setting position D under the action of a spring mechanism when it has been rotated from the setting position D to the setting position H. setting position N, the control means 12 is rotatably forwards one step to setting position D and backwards one step to setting position R. Setting position R is locked while the other setting positions N, D, H are unlocked. This means that a locking function must be lifted to turn the actuator 12 from the setting position N to the setting position R, while no locking function needs to be lifted for operation between the other setting positions N, D, H. Said locking function is designed, for example, in its axial direction, preferably inwards, before it can be rotated from the setting position N to the setting position R.

Switching between the reverse modes Reverse, Neutral and Drive takes place simply by the driver turning the actuator 12 to one of the fixed setting positions R, N and D representing the desired shift mode, whereby the actuator 12 remains in this setting position. Shifting from the shift mode Drive to the shift mode Hill takes place by the driver turning the actuator 12 from the setting position D to the setting position H, the actuator springing back to the setting position D and remaining there.

Shifting from the Hill shift mode to the Drive shift mode takes place by the driver turning the actuator 12 from the setting position D to the setting position H, the actuator again fi returning to the setting position D and remaining there. Shifting from the shift mode Hill to the Neutral shift mode takes place by the driver turning the actuator 12 from the setting position D to the setting position N, the actuator remaining in the setting position N.

In addition, the control unit 2 is suitably arranged to shift from the Neutral shift mode to the Drive shift mode when the actuator 12 is turned from the setting position N to the setting position H, while passing the setting position D. In the latter case, the actuator will spring back from the setting position H to the setting position D and remain there. Fig. 6 schematically illustrates how actuator 12 is rotatable between the three fixed setting positions R, N, D and the resilient setting position H.

The selectable shift modes may be marked with letters on the actuator 12 and an adjacent non-rotatable part 11a of the lever 11 is suitably provided with a mark in the form of, for example, a line or a dot which stands in the middle of the letter corresponding to the selected shift mode. alternatively, said letters may be arranged on the non-rotatable part 11a of the lever and said marking arranged on the actuator 12. The letter indicating the selected shift mode is suitably shown on a display on the instrument panel 6 together with an - 10 15 20 25 30 35 529 592'an information concerning the gear, such as, for example, engaged gear, upcoming gear, etc.

Advantageously, the actuator 12 from the first fixed setting position D is operable to the resilient setting position H for setting a shift mode among a plurality of adjustable shift modes, the shift mode being set depending on the number of repeated operations from the first fixed setting position D to the resilient position. setting mode H.

The determination of the number of repeated operations of the actuator from the first fixed setting position D to the resetting setting position H must of course be associated with some predetermined condition, such as for example that the repeated operations must take place with a certain maximum time interval between two consecutive operations or the repeated maneuvers shall take place within a predetermined period of time from the initial maneuver.

Suitably, the lever 11 or a part thereof can be resiliently tilted back from a neutral position in two substantially opposite directions for upshifting and downshifting, respectively. In the embodiment illustrated in Fig. 1, upshift and downshift take place by the driver moving the end part 13 of the lever upwards towards the steering wheel in the direction marked with the arrow P2 and downwards away from the steering wheel in the direction marked with the arrow P3. The upshift and downshift function is resilient so that the end part 13 of the lever always returns to its original neutral position after shifting. The shift can be done regardless of which shift mode is selected.

The lever 11 is suitably also provided with an actuator 14, preferably in the form of a pushbutton as illustrated in Fig. 1, for setting manual upshift and downshift (Manual) or automatic upshift and downshift (Automatic). In the embodiment illustrated in Fig. 1, switching between Manual and Automatic takes place by pressing the pushbutton 14, as indicated by the arrow P4.

The actuator 10 is preferably also designed for actuating an auxiliary brake in the form of a retarder. Adjustment of the desired braking effect of the auxiliary brake is suitably effected by displacing the lever 11 of the actuator or a part thereof. In the embodiment illustrated in Fig. 1, the lever 11, or alternatively the outer part 13 thereof, is displaceable substantially along the steering wheel rim 8 between different displacement positions for setting the desired braking effect of the auxiliary brake. . The displacement is suitably arranged to take place stepwise between a number of fixed positions. Suitably the braking effect gradually increases the longer the lever ll, or the outer part 13 thereof, is moved in a clockwise direction (indicated by the arrow P5) along the steering wheel rim 8, the braking effect gradually decreasing as the lever ll, or the outer part 13 thereof , is moved in the counterclockwise direction (indicated by the arrow P6) along the steering wheel ring 8. The zero position of the auxiliary brake is in this case furthest counterclockwise with respect to the displaceability along the steering wheel ring. The auxiliary brake is switched off when the lever 11, or the outer part 13 thereof, is at the top in the zero position. Of course, lever movements other than those described above are also conceivable for the operation of the auxiliary brake.

Figs. 2-4 show various alternative embodiments of an actuator 10 according to the present invention, which, like the actuator according to Fig. 1, comprise a lever 11 and an actuator 12 rotatably arranged on the lever for setting different gear modes, for example Hill, Drive, Neutral and Reverse. In these embodiments, this actuator 12 is stepwise operable by turning in the manner described above with reference to the corresponding actuator 12 of the embodiment according to Fig. 1. In the embodiments according to Figs. 2-4, in addition, the lever 11, or the outer part of this, displaceable between different displacement positions for setting the desired braking effect of the auxiliary brake in the manner described above with reference to the corresponding lever of the embodiment according to Fig. 1, i.e. in the directions marked with arrows P5 and P6.

The actuator 10 according to Fig. 2 comprises a further actuator 20 which is rotatably arranged at the outer end of the lever 11. In this embodiment, upshifting and downshifting is performed by rotating the actuator 20, which can either be resiliently rotatable from a neutral position in two opposite directions, indicated by the arrow P7, or be rotatable between fixed setting positions for upshifting and downshifting. Shifting is done by turning the actuator 20 in one direction, preferably backwards towards the driver, and downshifting is done by turning the actuator 20 in the opposite direction. Each rotation of the actuator 20 involves changing the gear one step. The actuator 10 according to Fig. 3 comprises an actuator 30 in the form of a resilient rocker which is arranged on the lever 11. The rocker 30 is resiliently rotatable from a neutral position in two opposite directions, indicated by the arrow P8 . In this embodiment, upshifting takes place by moving the rocker 30 in one direction, preferably backwards towards the driver, and downshifting takes place by moving the rocker 30 in the opposite direction. As in the embodiment according to Fig. 1, the lever 11 is here provided with an operating member 14 in the form of a push button at the outer end of the lever for setting manual upshift and downshift (Manual) or automatic upshift and downshift (Automatic).

In the embodiment illustrated in Fig. 3, switching between Manual and Automatic takes place by pressing the pushbutton 14, as indicated by the arrow P4.

The actuator 10 according to Fig. 4 comprises two resilient pushbuttons 41, 42 which are arranged on the lever 11 on opposite sides thereof. In this embodiment, shifting takes place by pressing one pushbutton, for example by pressing the pushbutton 41 in the direction marked with the arrow P9, and downshifting takes place by pressing the other pushbutton, for example by pressing the pushbutton 42 in the direction marked with the arrow P10 the direction. The lever 11 is in this case angled, preferably in such a way that its outer end protrudes outside the steering wheel ring, which facilitates the driver's access to the lever.

Fig. 5 shows an alternative embodiment of an actuator 10 according to the present invention, which, like the actuator according to Fig. 1, comprises a lever 11 and an actuator 50 arranged on the lever for setting different shift modes, for example Hill, Drive , Neutral and Reverse.

In this embodiment, the operating member 50 is slidably mounted on the lever 11 and consists of a slider. This actuator 50 is stepwise operable by displacement in the directions marked with the arrow P11 for setting the desired shift mode. Fig. 7 schematically illustrates how this actuator 50 is displaceable between three fixed setting positions R, N, D and a resilient setting position H in a manner corresponding to that described above with reference to the rotatable actuator 12 of the embodiment according to Fig. 1. In the embodiment according to Figs. 5, the lever is resiliently displaceable from a neutral position in opposite directions, indicated by the arrows P12 and P13, substantially perpendicular to the steering wheel of the vehicle, ie upwards towards the steering wheel in the direction marked by the arrow P12 and downwards away from the steering wheel in the direction marked with the arrow P13. Gear-up takes place by moving the lever 11 in one of these directions, preferably upwards towards the steering wheel of the vehicle in the direction marked with the arrow P12, and downshifting takes place by moving the lever in the opposite direction. In addition, in the embodiment according to Fig. 5, the lever 11, or the outer part thereof, is displaceable between different displacement positions for setting the desired braking power of the auxiliary brake in the manner described above with reference to the corresponding lever of the embodiment according to Figs. 1, ie in the directions marked with the arrows P5 and P6.

Of course, the actuators 10 according to Figs. 2, 4 and 5 are also suitably provided with an actuator for setting manual upshift and downshift or automatic upshift and downshift, even if no such actuator is shown in these figures.

The actuator 10 according to the invention could advantageously be provided with an actuator, for example in the form of a switch or a pushbutton, in order to set a position in a manner known per se for automatic engagement of the auxiliary brake and so-called constant speed braking when activating the brake pedal.

According to an alternative embodiment, the actuator comprises a lever 11 which is displaceable in two opposite directions for setting different shift modes, for example Hill, Drive, Neutral and Reverse. In this case, the actuator 12 described above thus constitutes the lever of the actuator, this lever thus being able to be displaceable between three fixed setting positions R, N, D and a resilient setting position H in the manner illustrated in Fig. 7 and corresponding to that described above with reference to the actuators 12, 50 of the embodiments according to Figs. 1-5.

The invention is of course not in any way limited to the preferred embodiments described above, but a number of possibilities for modifications thereof should be obvious to a person skilled in the art, without this departing from the basic idea of the invention as defined in the appended claims. For example, the number of setting positions of the actuators 12, 50 and the order between them can be varied as required.

Claims (1)

1. 0 15 20 25 30 35 529 592 13 PATENT CLAIMS Actuators for operating a semi-automatic gearbox of a vehicle, which actuators comprise a rotatable or displaceable actuator (12; 50) which is stepwise operable between at least two fixed setting positions for setting different shift modes, said fixed setting positions comprising a first fixed setting position (D) for setting a first shift mode and a second fixed setting position (N) for setting a second shift mode, such that the actuator (12; 50) from the first the fixed setting position (D) is operable to a resilient setting position (H) for setting an additional shift mode, the actuator (12; 50) being arranged to spring back to the first fixed setting position (D) when it has been actuated to the resilient position. setting mode (H) from the first fixed setting mode. Actuator according to claim 1, characterized in that said second fixed setting position (N) constitutes a setting position for setting a gear mode for neutral position of the gearbox. Actuator according to claim 2, characterized in that the actuator (12; 50) is also operable from the second fixed setting position (N) to a third fixed setting position (R), which constitutes a setting position for setting a shift mode for chopping. Actuator according to any one of claims 1-3, characterized in that said first fixed setting position (D) constitutes a setting position for setting a shift mode for driving under normal conditions. Actuator according to Claim 4, characterized in that the actuator (12; 50) can be actuated from the first fixed setting position (D) to the resilient setting position (H) for setting an gear node for driving in the opposite direction. Actuator according to one of Claims 1 to 5, characterized in that the actuator (12; 50) can be actuated from the first fixed setting position (D) to the resetting setting position (H) for setting a 10 15 20 25 30 35 10. ll. 12. 13. 529 592 14 shift mode among a plurality of adjustable additional shift modes, the shift mode being set depending on the number of repeated operations from the first fixed setting position (D) to the resilient setting position (H). Actuator according to any one of claims 1-6, in that the actuator (10) comprises a lever (11), and that the actuator (12, 50) is movably mounted on said lever (11). Actuator according to claim 7, characterized in that the actuator (12) is rotatably mounted on the lever (11), the actuator (12) being stepwise rotatable between said setting positions, preferably around the center axis of the lever. Actuator according to claim 7, characterized in that the actuator (50) is slidably mounted on the lever (11), the actuator (50) being stepwise displaceable between said setting positions, preferably in the longitudinal direction of the lever. Actuator according to one of Claims 7 to 9, characterized in that the lever (11) or a part (13; 30) thereof can be resiliently tilted backwards from a neutral position in two substantially opposite directions for upshifting and downshifting, respectively. Actuator according to one of Claims 7 to 10, in that the lever (11) is provided with an actuator (14), preferably in the form of a pushbutton, for setting manual upshift and downshift or automatic upshift and downshift. . Actuator according to one of Claims 7 to 11, characterized in that the lever (II) is located in the area close to the steering wheel of the vehicle so that the lever (1 1) can be actuated by the driver of the vehicle without the need to change his driving position and preferably without that he needs to let go of the steering wheel. Actuator according to one of Claims 1 to 12, characterized in that the actuator (10) is also designed for actuating an auxiliary brake. Actuator according to claim 13 in combination with any one of claims 7-12, characterized in that the lever (1 1) or a part thereof is movable for actuating the auxiliary brake. Actuator according to claim 14, characterized in that the lever (11) or a part thereof is displaceable substantially along the steering wheel rim of the vehicle steering wheel between different displacement positions for setting the desired braking effect of the auxiliary brake. device of a vehicle, which device comprises a semi-automatic gearbox (1) and a control unit (2) connected thereto, the gearbox being controllable by means of control unit in accordance with different gear modes, characterized in that the device further comprises one to the control unit (2) connected actuator (10) according to any one of claims 1-15, wherein the control unit (2) is adjustable by means of the actuator (10) to control the gearbox in accordance with the desired gear mode. Device of a vehicle, which device comprises a semi-automatic gearbox (1), a control unit (2) connected to the gearbox and an auxiliary brake (3), the gearbox being controllable by means of a control unit according to different gear modes, characterized in that the device further comprises an actuator (10) connected to the control unit (2) and to the auxiliary brake according to any one of claims 13-15, wherein the control unit (2) is adjustable by means of the actuator (10) to control the gearbox in accordance with the desired gear mode and the auxiliary brake (3) by means of the actuator (10) is operable to regulate the braking effect thereof.