DE3639501C2 - - Google Patents

Description

This invention relates to a gas confirmation device according to the preamble of claim 1.

Such a device is known from DE-AS 20 40 917, after being adjusted in the transmission device arranged through the servo motor the articulation point for a control rod acting on the adjusting lever on a turn axis comes to lie in such a way that adjustments on the accelerator pedal do not cause any adjustment of the adjustment lever.

However, this document gives no indication of interference with the Ver lever for the injection pump or the carburetor.

It is therefore an object of the invention to operate the gas develop device according to the preamble of claim 1, so that an adjustment of the adjustment lever has no effect has the position of the throttle control and also regardless of the just existing position of the throttle lever acts, the solution should be as simple and safe as possible.

This task is carried out with the characteristic features of the contractor spell 1 solved.

Just by using another servo motor it is possible during a circuit with appropriate control the Depending on the type of gearshift lever in full load or in move the engine stop position to adjust the speed to switching gear elements to accelerate automatically without that the driver be in his speed control on the accelerator is impaired. So conditions are created similar like a circuit in a conventional automatic Powershift transmission.

According to the features of claims 2 to 6, the invention designed in an advantageous manner.  

The transmission device consists of an over the gas Pedal rotatable shaft used to operate a rule rod connected adjusting lever carries an inclined unit that twisted with, it becomes a particularly simple transmission aims. Next is by straightening this oblique unit over a first servo motor in a very simple way of working together on the accelerator pedal and adjusting lever.

When the shaft is axially displaced by a second servomotor from a central position, on the other hand, almost all elements of the transmission device - apart from the accelerator pedal and accelerator linkage - are used again for further actuation of the adjustment lever during a shift - adjustment at full load or in engine stop -. If the servomotors are actuated by pressure medium, simple actuation and control devices result. Especially when the second servomotor is a three-position cylinder, the middle position of which is achieved by springs.

For converting a rotary motion of the rotary shaft into one Longitudinal movement over an inclined unit can do that in a simple manner slanted shear known from hydraulic axis piston machines principle or a universal joint can be used because a straight position with both principles is possible in a simple manner is.

Further details of the invention are based on one Embodiment and a drawing explained.

In the drawing: the only Figure shows a schematic representation of a gas actuating device..

The Fig. Shows the gas actuation device with a gas pedal 1 , the adjustment via a linkage 11 and a He bel 12 as a rotary movement on a shaft 21 , which is also arranged in the housing 6 , is transmitted. A fixed disk 23 or a corresponding half disk and a swashplate 22 are arranged on this shaft 21 , the latter also being able to be pivoted into a straight position 220 by means of a first servo motor 3 .

A second servo motor 5 acts on the fixed disk 23 via a sliding block 56 , which runs in a guide 25 of the disk 23 , and a piston rod 55 . This is designed as a 3-position cylinder 51 , 52 , 53 and can move the shaft axially. The left end position 51 is the full load position VL of the right end position 52 , the engine stop position MS and the middle position 53 the idle position LL of the adjusting lever 41 . Near the outside diameter of the swash plate 22 , a control rod 42 is arranged in the housing 6 , which is connected to an adjusting lever 41 of the injection pump 4 or the carburetor.

The gas actuating device described acts as follows: For the transmission of the position of the throttle lever 1 on the United lever 41 , z. B. the injection pump 4 , the Schwenkbe movement of the throttle lever 1 via a linkage 11 and a lever 12 is transmitted to the shaft 21 as a limited rotational movement. This also rotates the swash plate 22 , which - as drawn - converts the rotational movement of the shaft 21 into an axial movement of the control rod 42 in the oblique position. The adjusting lever 41 is thus in operative connection with the throttle lever 1 and can take the position engine stop MS , idling LL and full load VL but also only the positions between idling LL up to full load VL .

The piston from the first servo motor 3 is not pressurized via the Magnetven valve 7 with pressure medium, so that this is pressed by the Fe of the 33 into the left-hand end position 31 . The first servo motor 3 makes due to its articulation to the disc 23 and the swash plate 22 rotatably and axially but be pivotally limits the rotational movements of the shaft 21 , the distance 34 from this shaft both on the cylinder 36 and on the piston rod 35 approximately is equal to.

Also, the second servo motor 5 is not fourth actuated by pressure medium, but the piston 57 is held by springs 54 in the drawing center position 53 so that the shaft 21 is held axially in the position shown and can only perform rotary movements, and the Transmission device acts as a well-known throttle linkage between accelerator pedal 1 and Ver lever 41 on the injection pump or the carburetor.

Shortly before each gear shift, pressure means are supplied via a solenoid valve 7 to the first servo motor 3 via a control device (not shown ) and thus the piston moves into the right end position 32 and the swash plate 22 sets straight - position 220 -. About the spring 43 is completely un depending on the accelerator pedal position of the actuating lever 41 moved to the idle position LL .

In the further course of the circuit is then from the Steuerein direction depending on the speeds in the drive train pressure medium via the solenoid valves 8 or 9 leads to the second servo motor 5 . When the right piston chamber is acted upon by the solenoid valve 9 , the piston 57 assumes the end position 51 , in this case the piston rod 55 and the sliding block 56 , which is arranged in a guide 25 of the disk 23 , this, and thus the shaft 21 the straightened swash plate 22 and the control rod 42 of the actuating lever 41 adjusted for the duration of the pressure medium loading in the full load position VL .

However, if the second servo motor 5 is supplied with pressure medium via the solenoid valve 8 , the piston moves counter to the end position 52 , since the transmission device 2 - shaft 21 , swash plate 22 , control rod 42 - is adjusted in this direction, the adjusting lever 41 comes in the position engine stop MS . This position also remains only for the duration of the pressure medium supply via the solenoid valve 8 . After performing the circuit, the pressure medium supply is canceled in 2 of the 3 pressure valves, z. B. 7 and 8 or 7 and 9 , so that all solenoid valves are vented, and the first servo motor 3 again the left end position 31 and the second Servomo tor 5 assumes the central position 53 .

Instead of the swash plate 22 , a cardan drive (not shown) can also be used as an inclined unit for converting a rotary movement into a longitudinal movement, which can also be straightened out in a manner similar to the swash plate for the automatic motor. Instead of cylinders pressurized with pressure medium, lifting magnets or electric servomotors can also be used as servomotors, and finally the swiveling movement of the accelerator pedal can also be transmitted to the shaft 21 via a toothed rack and a toothed wheel.

Claims (5)

1. Gas operating device for motor vehicles with an accelerator pedal (1), which is connected via transmission means (2) to the adjusting lever (41) of an injection pump (4) or a carburetor with a in the transfer device (2) arranged actuated servo motor (3) , when it is actuated via transmission means, the displacement of the adjusting lever ( 41 ) acted upon by the accelerator pedal ( 1 ) is canceled and when it is adjusted there is no reaction to the accelerator pedal ( 1 ), characterized in that a second servo motor in the transmission device ( 2 ) ( 5 ) is arranged so that when it is adjusted to one end position ( 51 ) of the adjusting lever ( 41 ) at full load (VL) and in the other end position ( 52 ) to engine stop (MS) is adjusted when the first servo motor ( 3 ) is in the active position at the same time. 2. Gas confirmation device according to claim 1, characterized in that the transmission device ( 2 ) consists of a via the accelerator pedal ( 1 ) rotatable and via the second servo motor ( 5 ) displaceable shaft ( 21 ) for converting the rotary motion into a longitudinal motion with a Schrägein unit (swash plate 22 ), the adjustment of which is transmitted via a control rod ( 42 ) to the adjusting lever ( 41 ) and which can be brought into a straight position ( 220 ) via the first servo motor ( 3 ). 3. Gas actuating device according to claim 2, characterized in that the servomotors ( 3 , 5 ) are actuated with pressure medium, and the second servomotor ( 5 ) is a 3-position cylinder with a spring force (springs 54 ) achieved th central position ( 53 ). 4. Gas actuating device according to claim 3, characterized in that the inclined unit is a swash plate ( 22 ). 5. Gas actuating device according to claim 4, characterized in that for transmission of the pivoting movement in a rotary motion, the accelerator pedal ( 1 ) via a Ge rod ( 11 ) and a lever ( 12 ) with the shaft ( 21 ) that the shaft ( 21 ) has a disk ( 23 ) or half disk that is fixedly connected to it, on which the first servo motor ( 3 ) with the cylinder ( 36 ) and axially fixed, but axially fixed, is rotatable and axially fixed at a distance from the swashplate radius ( 34 ), but limited pivotable a sliding block ( 56 ) is fastened in a guide ( 25 ) of the disk ( 23 ) and the piston of the second servomotor ( 5 ) is rotatably fastened via a piston rod ( 55 ), the second servomotor ( 5 ) being axially attached to a housing ( 6 ) supports that the shaft ( 21 ) rotatably and axially, but pivotally carries the swash plate ( 22 ), which has a connection to its pivoting (piston rod 35 ) with the piston of the first servo motor ( 3 ), which thus rotates the shaft ( 2nd 1 ) and the swash plate ( 22 ) with, wherein a control rod ( 42 ) guided in the housing ( 6 ) is articulated to the adjusting lever ( 41 ) of the carburetor or the injection pump ( 4 ), which is connected via a spring ( 43 ) is pressed against the swash plate ( 22 ) and that a return spring ( 33 ) in the first servo motor ( 3 ) leads the swash plate ( 22 ) to the normal position (misalignment) when venting, and the 3-position cylinder ( 5 ) via two springs ( 54 ) assumes its central position ( 53 ) when venting.