DE1269513B - Automatic electrical switching device for step change gearboxes of motor vehicles - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. α .:

B60k

German KL: 63 C-20/30

Number:
File number:
Registration date:
Display day:

P 12 69 513.5-21
December 10, 1962
May 30, 1968

The invention relates to an automatic electrical switching device for step change transmissions of motor vehicles with at least three solenoids, one of which each when energized Gear turns on.

Such a switching device has become known in which a device is provided which is used in selected speeds of the transmission output shaft causes the selective excitation of the solenoids, wherein the supply circuit of the solenoids is led through a common transistor that is in his conductive state releases the current to excite the selected solenoid, in addition to the common Transistor is put into the conductive state by a device when the accelerator pedal has left its idle position, and the common transistor continues to be conductive State is set when the speed of the transmission output shaft exceeds a predetermined value. In the known switching device, the simultaneous excitation is finally achieved by means of devices prevented by two solenoids (French patent 1 243 067).

According to the known switching device, they are automatically dependent on the accelerator pedal position and Driving speed selectable solenoids the common transistor via several bistable electronic Downstream toggle switches that are arranged in branches and respond to the switching signals, so that the supply circuit can only reach one of the solenoids. In the automatic switching range thereby act the toggle switch as a safety device that the simultaneous excitation of two solenoids prevented. This backup therefore does not extend to manually selectable ones Corridors, such as B. reverse.

The object of the invention is to avoid this disadvantage and to provide a way of all Secure gear shift solenoids against simultaneous excitation.

The solution makes use of the fact that with simultaneous excitation of two solenoids the current flow in the Supply circuit is increased.

The solution to the problem is characterized according to the invention in that a resistor is connected in the emitter-collector circuit of the common transistor, and a further transistor is provided which, in its conductive state, has no influence on the common transistor, but in its blocking state puts the common transistor into the non-conductive state via further control means, the base and emitter of which are each connected to an automatic electrical switching device for
Step change transmissions of motor vehicles

Applicant:

C.A.V. Limited, London

Representative:

Dipl.-Ing. W. Cohausz and Dipl.-Ing. W. Florack, Patent Attorneys, 4000 Düsseldorf, Schumannstr. 97

End of said resistor are placed and its base voltage as a bias circuit is coordinated in such a way that thereby the bias voltage, which is then imposed by said resistor when current flows through it when a single solenoid is energized, it is overcome, whereby the further transistor remains in its conductive state, while due to the increased bias, which is then imposed by the resistance when this with simultaneous excitation of two solenoids are traversed by an increased current, the other transistor in the non-conductive State is shifted.

With this arrangement, the protective device works independently of the type of triggering device and the signals for changing gears. In the protective device can therefore easily also all gear shift solenoids are included, which are independent of the speed-controlled automatic Gear shifts are excitable, such as reverse gear.

As an embodiment of the invention is shown in the drawings

F i g. 1 is a circuit diagram of the overall arrangement including all details of automatic and manual gear selection,

F i g. 2 is a simplified block diagram.

The general effect of the circuit can be seen in FIGS. 2 must be made understandable. The solenoids 57?, 51, Sl, 53 and 54 are used to switch on the reverse gear, the first, second, third and fourth gears in the energized state, and there are also manually operated switches GR, Gl, Gl, G3> and GA provided in the respective circuit of the solenoids. However, as will be explained in more detail below, under no circumstances can one of the solenoids mentioned be energized, unless the transistor Γ1 is in

809 557/276

is in the conductive state. The state of the conductivity of the transistor T 1 is controlled by a gate circuit which can be actuated to make the transistor T 1 conductive by an acceleration switch or a speed-sensitive switching circuit.

The reverse gear, the first and the second gear can be switched on manually by closing the switches GR, G 1 or G 2.

The third gear can be switched on manually by closing the switch G 3, the provided transistor T 22 being kept in the conductive state by the switching circuit.

The second, third and fourth gear can also be switched on automatically by closing the switch GA. The gear to be engaged is controlled by the switching circuit that acts on transistors Γ12, T 21 and T 29, respectively.

The acceleration switches change the driving D 6 connected to the fixed contact of a switch A 1. The switch A 1 is one of the aforementioned acceleration switches which can be actuated by the accelerator pedal of the vehicle in a manner which will be described below. The movable contact of switch A 1 is connected to line 4. The switch A 1 is closed when the accelerator pedal is released and is opened when the accelerator pedal is depressed.

The lines 3, 4 are also bridged in series by a resistor R 14 and a variable resistor VR 1, a point between these two resistors being connected to the base of a transistor T 4. The collector of this transistor T 4 is connected to the line 5 via a resistor R 15, while its emitter is connected to a point lying between the resistor R 4 and the diode D 2. The collector of the transistor T 4 is also via a diode D 8

speeds at which the gears are changed ao and a capacitor C 8 is connected to line 4. The entire circuit and the individual are closed, with a between the diode D 8 and operations should now be made with reference to FIG. 1 point closer to the capacitor C 8 with the base, in which a first and a second of the transistor T 5 are connected. Terminal 1, 2 are provided, which are connected to a DC The base of the transistor T 2 is also via a

power source or a rectified alternating current 25 diode D 7 are connected to the collector of the transistor Γ S anquelle in such a way that they are in operation
always have a negative or positive polarity. The terminals 1, 2 are bridged by a resistor R 3 and a Zener diodeZl and

closed, which forms one transistor of a pair of transistors T 5, T 6, the emitters of which are connected to line 4 via a resistor R 20. The bases of the transistors T 5, T 6 are with the

also connected to two lines 3, 4. Furthermore, 30 line 4 via the resistors R 21 and R 22 ver

the mentioned switches GR, G 1, G 2, G 3 and GA are provided, which are connected to a lever which is designed similarly to an ordinary mechanical gear lever of a road vehicle, and arranged so that they are closed when the lever is in Corresponding positions that correspond to reverse gear, first gear, second gear, third gear and an overdrive gear in a mechanical transmission are brought. The movable contacts of these switches are connected to the collector of a main current transistor Γ1, the emitter of which is connected in series to the line 4 via the diodes D1, D 2 and a resistor R 4. The base of the transistor T 1 is connected to the line 4, while its collectors are connected to the line 5 via the resistors R 16 and R 17, respectively. Furthermore, the bases of the transistors 5 and Γ 6 are connected to the collectors of the transistors Γ 6, Γ 5 via the resistors R 19 and R 18.

The device also includes an alternator A for generating an electrical signal proportional to the speed of the transmission output shaft of the vehicle. This signal is applied to terminals 6 and 7 and then fed to a full wave rectifier consisting of diodes D 19, D 20, D 21 and D 22, which generates DC signals on negative and positive lines 8 and 9, respectively and the strength of

Via a resistor R 5 and also connected to the 45 DC output pulses proportional to the rotary emitter of a transistor Γ 2, the number of which is the transmission output shaft. The lines 8

Collector is connected to line 5 via a resistor R 6. The line 5 is with a point between
Resistance-R 3 lies,

the Zener diodeZl and the connected in such a way that their voltage is stabilized by the Zener diode. The base of the transistor T 2 is connected via a resistor R 9 to the collector of a transistor T 3, the emitter of which is connected to the emitter of the transistor Tl . The base of the transistor Γ 3 is connected to the line 4 via a resistor R 11 and also via a resistor R 10 to the fixed contact of the switch GR . This fixed contact is also connected to the line 3 via the solenoid SR , which is bridged by a diode 24. In addition, the base and the collector of the transistor TS are connected to one another via a capacitor C 1, while the collector of the transistor Γ 3 is connected to the line 5 via a resistor R 12.

The base of the transistor T 2 is also connected to the line 5 via a diode D 6 and a resistor R 13 and is also connected together via the diode and 4, and the lines 8 and 9 are bridged by four parallel circuits that form a capacitor C 7, resistors R45 and R46 in series, resistors R51 and R 50 in series, and resistors R 77 and R 76 in series. The terminal 7 is connected to the line 4 via parallel tracks, one of which contains a capacitor C 4 and a diode D 26 in series and the other the capacitor C 4 and a diode D 9 and a capacitor C 3 in series. A point lying between the diode D 9 and the capacitor C 3 is connected to the base of a transistor Tl via a resistor R 23. The base of this transistor is also connected to line 4 via a resistor R 90. The collector and the emitter of the transistor T 7 are correspondingly connected to the collector and the emitter of a further transistor T 8, and the collectors and emitters of the transistors Γ 7 and T 8 are connected to the lines 5, 4 via the resistors R 24, R 89 connected. Furthermore, the collectors of the transistors T 7, Γ 8 with the line 4 via a

Diode D 25 and a capacitor C 5 connected in series, while the base of the transistor Γ 8 is connected to the line 5 via a resistor R 25, to the line 4 via a diode D 10 and to the line 9 via a resistor R26 .

A point between the diode D 25 and the capacitor C 5 is connected to the base of a transistor T 10, which forms one of a pair of transistors T 9, Γ10, the collectors of which are connected to the line 5 via the resistors R 27 or R 28 are connected and their bases are connected to the line 4 via the resistors R 31 or JR 32 and their emitters are connected to the line 4 via a common resistor R 33. In addition, the bases of the transistors T 9, T10 are connected to the collectors of the transistors Γ10 and T 9 via the resistors R 30 and R 29, respectively. The collector of the transistor T 9 is connected in series with the base of the transistor T 2 via a diode D 5, a diode D 3 and a resistor R 8.

The collector of the transistor T 10 is connected via a diode D 11 to the base of a transistor T 11, the collector of which is connected to the line 5 via a resistor R 35. The emitter of the transistor T11 is connected to the base of the transistor T 12 and to the line 4 via a resistor R 36. The emitter of the transistor T 12 is connected to the fixed contact of the switch GA , while its collector is connected to the fixed contact of the switch G 2. The collector of the transistor T12 is also connected to the line 3 via the solenoid S 2, which is bridged by a diode D 12.

A point between the resistors R 45 and R 46 (between the lines 8 and 9) is connected to the line 4 via a diode D 13 and a resistor R 38 and is also connected to the base of a transistor T13, the base of which is also connected to the line 5 is connected via a resistor R 37. The emitter of this transistor is connected to the line 4 via a resistor R 43, while its collector is connected to the base of a transistor T 14 and also to the line 5 via a resistor R 39. The emitter of transistor T 14 is connected to line 4 via a resistor R 42 and a resistor R 43, while its collector is connected to line 5 via a resistor R 40 and to the base of a transistor T 15 via a resistor R 41 whose collector is connected to line 5 via a resistor R 44. In addition, the emitter of the transistor T 15 is connected to the emitter of the transistor T 3, while the collector of the transistor T15 is connected via a diode D 4 to a point between the diodes D 3 and D 5 .

A point between resistors R 50 and RS1 (between lines 8 and 9) is connected in series with line 5 via a variable resistor VR 2, resistor R 52 and resistor R 48, a point between resistors R 48 and .R 52 can be connected to the line 4 via the resistor R 49 and an acceleration switch A 4. One point on the variable resistor VR 2 is connected to the base of the transistor T 16, the emitter of which is connected to one point of the variable resistor FjR 3. One end of this resistor is connected to the line 4 via a resistor R 60, while the other end is connected to the emitter of a transistor T 18. The collector of the transistor T 18 is connected via a resistor R 58 to the line 5, via a resistor R 34 to the base of the transistor T11 and via a resistor R 57 to the base of a transistor Γ17, the emitter of which is connected to the collector of the transistor T. 16 is connected. The collector of the transistor T17 is connected to the base of the transistor Γ18 and via the resistor R 53 to the line 5, while the base of the transistor TVT is connected in series with the base of the transistor T15 via a resistor R 56 and the resistor R 41 is also connected to line 4 via a resistor R 59. The base of the transistor Γ17 is also connected to the line 5 via the resistors R 55, R 54.

The collector of the transistor T 18 is also connected via a resistor R61 to the base of a transistor Γ19, the emitter of which is connected to the emitter of the transistor T 3. The collector of transistor T 19 is connected to the base of a transistor T 20, the collector of which is connected to line 5 via a resistor JR 63 and its emitter to line 4 via a resistor jR 64 and also connected to the base of a transistor T 21 is. The emitter of the transistor T 21 is connected to the fixed contact of the switch GA , while its collector is connected to the line 3 via the solenoid S 3, which is bridged by a diode D 15, and also to the collector of a transistor T 22. The emitter of transistor T 22 is connected to the fixed contact of switch G 3, while its base is connected to line 4 via a resistor R 65 and also to the emitter of a transistor T 23, the collector of which is connected to line 5 via a resistor i? 66 is connected. The base of the transistor T 23 is connected to the line 4 via a resistor R 91 and is also connected via a resistor R 7 to a point between the diodes D 3, DS .

A point between the resistors R 77 and R 76 (between the lines 8 and 9) is connected in series with the line 5 via a variable resistor VR 4, a resistor R 68 and a resistor R 67. A point between the resistors R 67 and R 68 is connected to the fixed contact of the switch A 4 via a resistor R 69. The moving contact of the variable resistor Fi? 4 is connected to the base of a transistor T 24, the collector of which is connected to the emitter of a transistor T 25 and the emitter of which is connected to the movable contact of a variable resistor VR 5 . One end of the variable resistor VR S is connected to the line 4 via a resistor R 80, while its opposite end is connected to the emitter of a transistor T 26, to the base of which the collector of the transistor T 25 is connected. The collector of the transistor T 26 is also connected to the line 5 via a resistor R 78, via a resistor R 62 to the base of the transistor Γ 20 and via a resistor R 72 to the base of the transistor T 25. The base of the transistor T 25 is through a resistor R 70

and R 71 in series with the line 5, turns on an overdrive in a way that is to be described after-resistance R 74 in series with the line 4 and above standing. The respective one of a resistor R 73 and the resistor R 41 in connection of the gears is electromagnetically connected to the base of the transistor T 15 according to the series. excitation of one of the solenoids SR, Sl, S2, S3 or S 4 In addition, the collector of the transistor T 25 5 is effected.

with the line 5 through a resistor R 75 comparable The operation of the various Komponenbunden while to ten between the resistors then R 70 and R are described 71 lying point with a fixed con- hereinafter in detail in greater detail, tact of the accelerator switch A 2 is connected, _TT whose movable contact is closed on line 4 an- io main gate circuit. This fixed contact is also connected to this circuit contains the power transistor to a point between the resistors R 54 and R 55 Tl, which is connected in series with each of the switches GR, G 1 to. G 3, GA is connected in such a way that if any of these The collector of the transistor T 26 is also switch is closed, the associated solenoid SR, will only be energized through a resistor R 79 to the base of a transit 15 S 1 to S 4 can, if the sistor Γ 27 is connected, the emitter of which is conductive with the transistor T 1. The transistor T 1 is connected in the emitter of the transistor Γ 3. The conductive or non-conductive state in Ab collector of transistor Γ 27 is offset by a dependence on whether transistor T 2, which stood R 81 on line 5 and also connected to the base of a transistor as an emitter follow-up control T 28 connected, the 20 of which is conductive or non-conductive. The main gate switching collector with the line 5 via a resistor device can be switched on, ie the transistor T1 R 83 is connected. The emitter of the transistor T 28 is made conductive by a number of gate signals with the line 4 via a resistor R 82 and len, which are applied to the base of the transistor T 2 and are also connected to the base of a transistor T 29. One of these signals is given by the bond, the emitter of which is connected to the fixed contact of the 25 scMeuniger switch A 1, which is opened, switch GA . The collector of the as soon as the accelerator pedal is depressed to the transistor Γ 29 is switched on with the line 3 via the gate circuit. Solenoid 54, which is bridged by a diode D 17 to explain the operation of the circuit is connected. The following is carried out: If any gear The circuit also contains an accelerator 30 is engaged, the transistor T1 is in the movement switch A 3, its movable contact with conductive state, and a current flows through that of the line 4 and its fixed contact a resistor R 4. The voltage drop across the resistor R 86 to the base of a transistor T 30 R 4 results in the emitter voltage of the transistor T 4, which is connected. The base of the transistor Γ 30 is the base voltage of which is also determined by the resistors R 14 to the line 5 via parallel circuits 35 and VR 1. The arrangement is closed, one of which has a resistor R 85 as follows: The transistor T 6 is in the conductive state and the other is a variable resistance state and contains the transistor T 5 in the non- VR 6 and a capacitor C 6. An intermediate state. If thus accidentally two see the capacitor C 6 and the variable gears engaged, ie two of the solenoids SR, S 1 to resistor VR 6 lying point is excited via a diode 40 S 4 at the same time, the current flow D 18 to the fixed contact of the switch A3, doubled over by the resistor R 4, and the diode D 18 and a further resistor R 84 potential of the emitter of the transistor T 4 is connected to the line 5. The collector of the more negative, so that this transistor is switched off transistor T 30 via a resistor R 88 with is. Thus, when the transistor φ 4 is connected to the non-line 5 and, moreover, the base 45 is rendered conductive, a current from a transistor T 31 can be connected. The emitter of the negative terminal via the resistor R 15, the transistors Γ 30 and Γ 31 are via a common diode D 8 and the base-emitter track of the transamen resistor R 87 with a fixed contact of the sistor and the resistor R. 20 connected to the positive switch A 3. In addition, the terminal is flowing, so that the transistor Γ 5 begins to reach the collector of the transistor T 31 via a resistor 50 and the bi- R 47 and a diode D14 to a point, the intermediate stable circuit T 5 , Γ 6 is switched to the state of the resistors R 48 and R 52, and is switched, in which the transistor T 5 is conductive, via a diode D 16 to a point between When the transistor T 5 is in the conductive Zuden Resistors R 67 and R 68 is connected. stood, a path from the positive Ver-The fixed contact of the switch G1 is connected to the 55 supply terminal via the resistor R 20, the solenoid Sl with the line 3, the emitter and collector of the transistor T 5 and the solenoid Sl is bridged by a diode D 23. Diode D 7 closed to the base of transistor T 2 , “,. ,. so that the transistor Γ 2 and the transistor Tl mode of operation are switched off.

The circuit described allows the driver to 60 It is also important that the switch A 1

reverse gear, the first, second and third is not the only element that controls transistor T 2

Manual gear by moving the gear lever to controls. Of course, if switch A1 is

insert the appropriate positions and which is closed, the negative voltage supply to the

Switch Gi ?, Gl, G 2 and G 3 close in accordance with the control electrode of transistor T 2 via the switch. Alternatively, the driver can divert 65 A1 by moving so that transistor T 2 is non-conductive

movement of the gear lever to a position that is the shift. Meanwhile, even if switch A 1 is open,

ter GA closes the automatic control in such a way that a negative current goes to the base of the transistor

drive, which could automatically flow the second, third and T 2 , can also have other signals

9 10

keep the transistor T 2 in the non-conductive state. know circumstances can be excited to the two-One of these signals was just above to engage the first gear when the switch GA is rung. This signal occurs when the transistor has been closed. The transistor T 12 is switched off to T 4, a connection being switched on and off at the same time as the tran transistor T 2 to the positive supply terminal via 5 sistor T 11, which normally biases the transistor T 5. holds to it via resistors R 34 and R 58

To make the proper operation of the circuit conductive. Under certain circumstances (which is the following: Assuming that the speed is to be described below) is increased, but is below 240 rpm, the transistor T11 is switched on in the non-conductive state transistor T 13, whereby the Transistor io offset so that second gear does not have to be automatically switched off at T14. The transistor Γ15 must be able to be switched on. Otherwise the second will be switched on, and all the current that is automatically switched on by Gang when the switch flows through the resistor R 44, is closed via the collector GA and the gate circuit. Emitter track of transistor Γ15 derived. That ,_. . . _,.,.,.

The emitter potential of transistor Γ13 is determined by the 15 low speed level

Resistances R 42, R 43 determined, but changes the automatic control device for the low

whose base potential with the output voltage of the speed stage (second gear) is comprised of the alternator as a result of connection to a well-known Schmitt trigger circuit of the Trandie compound of R 45, R 46. At 240 revolutions sistoren T13, Γ14, the transistor T 13 gen per minute, the transistor T13 is switched as soon as the voltage divider R 45, R 46 is switched in such a way, and a base current flows through R 39 in order that it receives a signal that is in its size from the transistor T 14, which as a result is switched on. The speed of the gearbox output shaft is dependent. The The transistor T14 passes the base current from the transit trigger circuit is adjusted so that when the rotational speed of Getriebeaustet is their Zusistor T from 15, so that the transistor T abgeschal- 15 was changed. The current flow through the resistor R 44 »5 output shaft reaches 240 revolutions per minute, now flows through D 4, D 3 and i? 8, so that the tran- yet in its original state is only switched on to transistor Γ 2, whereby also T 1 is switched back when the speed of the gear is switched. output shaft below 145 revolutions per minute

The oil drops at 145 revolutions per minute.

sistor T13 switched on again, so that the base 30 The transistor Γ14 conducts an output signal to current to the transistor T 2 via the resistor R 44 to the transistor T 15, which is derived again via its collector. alternative gate signal to the main gate circuit

.. directs. This way it becomes the main gate circuit

Reverse gear held on regardless of the switch

When the switch GR is closed, 35 A 1 occurs, provided that the speed of the transmission output shaft does not initially change anything until the accelerator pedal down exceeds 240 revolutions, unless the is pressed. This causes switch A 1 to drop below 145 revolutions per minute, opens to switch on the gate circuit, and the motor goes into reverse below this speed. At the same time, its idle speed range, in which the second transistor T 3 is blocked, remains in 40 gear and cannot be switched on. this state as long as from the transistor Tl " _Ί1 .._. . . ,. _A _

Power over the switch? Gi? flows, and generates an automatically shifted third gear

alternative switching signal for the gate circuit. Da- The automatic control device for the third

The reverse gear is independent of the gear contains a known Schmitt trigger with the position of the switch A 1 switched on until the transistors Γ16, Γ18 are opened again by the voltage of the switch GR , whereby the divider R 50, R 51 is switched and its state transistor T 3 becomes conductive again, and the age changes when the speed of the gear output-native switching signal for the gate circuit is omitted. wave rises above 735 revolutions per minute, and

returns to the original state when

First gear _{50 this} speed below 545 revolutions per minute

The operation of the first gear is only from the fall. The exact values required can easily depend on the position of the accelerator pedal as soon as the switch has been closed by coordinating the variable resistors G1. The operation of the accelerator pedal Fi? 2 or Fi? 3 can be obtained. The operating rotation opens the switch A 1 and shifts the first gear numbers of the transmission output shaft are under. However, as soon as the accelerator pedal is taken back 55 knowing circumstances by the switches A3, A4, which is, the switch A 1 is closed, and which can be actuated by the accelerator pedal, changed, for solenoid S 1 of the first gear is de-energized. the moment, however, the effect of these

. . . , ·, Tung can be disregarded.

Manually operated second gear _{If the} trigger Γ16, T18 its status at

The actuation of the second gear, if this changes 60 735 revolutions per minute, is an off

was selected manually, corresponds to the input pulse that was previously transmitted to transistor T11

of the first gear, whereby the actuation only depends on which the resistors i? 34, i? 58 was created,

Switch A 1 is dependent as soon as switch G 2 gives, and the second gear is switched off. the

was closed. Change of the state of the trigger T16, T18

".,. ,,. 65 also makes transistor T 19.

Automatically switched second gear _{The conductive} state of transistor T 19 allows

By the transistor T12 an alternative the conductive state of the pair of transistor ^{tracks is provided, whereby the solenoid 5 1} 2 under renT20, T 21 to influence in such a way that the

Solenoid S 3 is excited via the gate circuit to engage third gear. The reverse work cycle takes place when the speed of the transmission output shaft falls below 545 revolutions per minute. The third gear is then switched off and the downshift into second gear is effected.

Manual third gear

T 18 and obtained from the collector of transistor T 14 at the low speed level when the speed of the transmission output shaft drops to 145 revolutions per minute. The first signal ensures that the switched-on state cannot be entered before the third gear step has been switched on, while the second signal ensures that, when the switched-on state has been entered, it is activated at 145 revolutions per when the switch G 3 is closed, in order to switch on third gear manually, at which point the engine is idling on-solenoid S3 is energized by transistor Γ 22, occurs and second gear cannot be switched on either. provided that the latter is through the transistor The third signal, which determines whether the switch-on

T 23 was switched on. The transistor Γ 23 is assumed or not, is only switched on under normal circumstances when received when the switch A 2 is closed. The control device described here for the low switch A 2 is open during the middle and

full throttle opening, so that third gear is only held d. H. remains switched on, when the accelerator pedal is not depressed or is only depressed to the small throttle position is.

The transistor T 25 in the control device for the automatic shifting of the fourth gear performs exactly the same function. In this case

constructed analogously to that for third gear. 25 the both, the third and the second gear, switched off-The circuit is controlled by signals from tet, unless the accelerator pedal is depressed, the voltage dividers R 76, R 77 at speeds of the
Transmission output shaft derived from 1165 and 950 revolutions per minute and fed to the base of transistor 24 when the first-mentioned 30 fourth shifts to second gear.
Speed exceeded or the second-mentioned lower

is stepped. The circuit acts as in the case of the ² · ^action S ^of switches A 3, A4

third gear, however, in this case, the purpose of switch A 3 is to increase the speed

increase the conductivity of the transistor Γ26, in which the change from second to the signal that is applied to the base of transistor T 20 takes place in third gear or from third to fourth gear to ensure that third gear takes place, so that a greater acceleration is achieved

will. The switch A 3 works in this way only when it is open, ie when the throttle valve is in the middle and fully open position. The purpose of the switch A 4 is to increase the speed at which the further gear change takes place. This

speed stage has changed its state, so that the third gear below a speed of the transmission output shaft of 145 revolutions per minute cannot be switched on.

Automatic fourth gear The control device for fourth gear is

when the speed of the transmission output shaft is between 145 and 545 revolutions per minute. In this case, the transmission is directly from the

is shifted, and to prevent the re-engagement of third gear until fourth gear has been switched off again.

Influencing the automatic shifting of third and fourth gears depending on the accelerator pedal

The movement of the throttle valve is expediently divided into three parts: small, medium and full throttle opening. As previously explained, the switch A 1 is open after the accelerator pedal is depressed and remains open in all positions of the accelerator pedal except for the relieved position. The effect of the

The switch is only activated when the throttle valve is fully open opened.

Time-dependent control
in connection with switch A 3

If switch A 3 is open while the throttle valve is in the middle position and the other switches A1 , A3 and A 4 are now in second or third gear, they are to be used. closes the withdrawal of the accelerator pedal in the small

Throttle position the switch A 3 and can cause the third or fourth gear to be engaged.

This may not be desirable when the accelerator pedal

1. Effect of switch A 2

In the control device for the automatic third

Gear stage, transistor Γ17 can act so that 55 only for a short moment as a result of one of the third gear being kept switched on, even if the speed of the transmission output shaft has been reduced below 545 for temporary hindrances in the path of the vehicle. Hence a time dependent revolutions per minute falls. If the transistor control is provided that a gear change is switched on at T 17, the circuit acts as described before the closing of the switch A 3 for the time standing. If, however, it decelerates non-conductive 60 by about 3 seconds, so that it is a sub, transistor T 18 will normally be in its state below the difference between a temporary and a longer given speed at which the trigger circuit is made continuous release of the pedal changes, switched on. The time-dependent control is controlled by the switch. Trigger T 30, Γ 31 and the associated con-

The transistor T 17 can be formed by three signals from the capacitor C 6, the arrangement being such

be switched; Two of these signals prevent is that when the switch A 3 closes the trigger

the actuation of the circuit when switched on cannot change its state until the condenser

stood and are fully charged by the collector of the transistor C 6. The duration of the

The delay can be set using the variable resistor VR 6.

Protection against engaging two gears at the same time

With certain types of transmissions it is possible that two gears are selected at the same time due to an error and therefore a protective circuit must be provided to prevent this unforeseen possibility prevented.

The current that excites one of the solenoids for the gear shift flows through the resistor R 4, the voltage drop of which is applied to the transistor T 4. The base voltage of this transistor is matched by a variable resistor VR 1 in such a way that the transistor T 4 is just conductive. Meanwhile, if two gears are selected at the same time, ie excitation current flows to two solenoids, the voltage across the resistor R 4 is doubled and the transistor T 4 is placed in the non-conductive state, the bistable circuit with the transistors TS, T 6 in the another state is set, which in turn switches off the main circuit (transistor T1) via the transistor T 2.

Protection circuit against faulty signals

The protection circuit against erroneous signals is provided to prevent the second gear from being engaged at high speeds as a result of an error. The protection circuit contains a bistable circuit T 9, T 10, which is normally in the one state and has no effect. If, however, an error occurs, it is brought into the other state in which it biases the transistor T11 in order to prevent the engagement of the second gear, so that the engine is returned to idle. A second effect of this circuit is that it biases transistor T 23 to allow third gear to be manually engaged even if a signal is generated corresponding to a speed of the transmission output shaft below 145 revolutions per minute lies.

The circuit is actuated by receiving an unadjusted signal from terminal 7 which is applied to diode pump integrator C 4, D 26, D 9 and C 3 and then passed to the base of transistor T 7. The base of the transistor T 8 is connected to the line 9, so that the transistor T 8 remains conductive until the speed of the transmission output shaft reaches 600 revolutions per minute, and is then switched to the non-conductive state. In this way, every fault switches at a speed of more than 600 revolutions per minute, which has the effect of switching off transistor Γ7; the bistable circuit T9, T10 in their operative state.

at least three solenoids (SR, 51 to 54), each of which engages a gear when energized, and with a device that causes the solenoids to be selectively energized at selected speeds of the transmission output shaft, the supply circuit of the solenoids via a common transistor ( T 1) is performed, which releases the current to excite the selected solenoid in its conductive state, furthermore, the common transistor is put into the conductive state when the accelerator pedal has left its idle position by a device (A 1, Γ 2) the common transistor is switched to the conductive state by a device (T 13, T 14, T 15, T 2) when the speed of the transmission output shaft exceeds a predetermined value, and finally the simultaneous excitation of two solenoids is prevented by devices, characterized in that a resistor (R 4) in the emitter-collector circuit of the common Tran sistor (T 1) is connected, furthermore a further transistor (T 4), which in its conducting state has no influence on the common transistor, but in its blocking state the common transistor via further control means (T 5, T 6, T 2 ) is put into the non-conductive state, the base and emitter of which are connected to one end of the resistor (Z? 4) and whose base voltage is tuned as a bias circuit in such a way that the bias voltage, which is then imposed by the resistor (R 4) when current flows through it when a single solenoid is energized, is overcome, whereby the further transistor (Γ 4) remains in its conducting state, while the increased bias voltage, which is then forced through the resistor (R 4), when this is flowed through simultaneous excitation of two solenoids of a higher power level, the second transistor (T 4) in the is placed in a non-conductive state.

Claims (1)

Claim: Automatic electrical switching device for step change gearboxes of motor vehicles with Considered publications: German Patent No. 596,927; German Auslegeschrift No. 1 058 376; French patents No. 1 243 067,
282 306; French additional patent specification No. 78 377 (addition to French patent specification No. 1 208 036); Journal "Elektroanzeiger", Verlag W. Girardet, Essen, from May 1, 1957, pp. 153 to 156; "Feinwerktechnik" magazine, December 1958, p. 430; Reprint from the magazine of the Association of German Engineers Z.-VDI, Vol. 78, No. 10 (from the year 1934), article "Basics for the automatic control of motor vehicle transmissions"; Automobiltechnische Zeitschrift ATZ, September 1947, pp. 65 to 72. 1 sheet of drawings 809 557/276 5.68 © Bundesdruckerei Berlin