DE2009393C3 - Program control device - Google Patents

Description

The invention also relates to a program controller according to the preamble of claim 1.

In a known program control device of this type (DE-PS 10 60 962), it is a Device for driving preferably remote-controlled switches with several, on a contact bank contacts arranged next to one another and a forward or backward rotating contact arm, which the Carries out the control process itself. Devices of this type allow remote control of switches great distances. Difficulties arise insofar as when using motorized Drives because of the inertia forces of the motor of the contact arm only with difficulty exactly on the desired one Contact can be paused. To eliminate this problem, a relatively complex, mechanical? Control proposed. The known device is an arbitrary one Operation of the remote-controlled switches. Completely different problems arise with program control devices, which work in such a way that the voluntary operation

ίο time-dependent takes place here in particular for this care must be taken that each new control command is taken into account even if it overlaps in time occurs with the previously given control command. This is not the case with the known program control device possible that only allows one switch position of the switch

Also known is a device for remote setting of the tuning device of high-frequency devices (DE-PS 7 21 933), which consists of a ring with switches arranged on this and a crank arm rotating in this ring, driven by a motor and seated on the shaft of the tuning device Actuation of the switch comprises As soon as one of the switches is closed, a circuit for the motor representing the drive device is closed. This then rotates the tap changer until the movable contact hits the fixed contact that is connected to the closed switch. In this position, the circuit for the motor is interrupted, which is then stopped. Such a device is suitable for remote adjustment. However, it is not suitable for time-dependent programming in which the switches ¹ · are closed at a certain point in time, remain permanently closed for a certain time and then open again, with the periods of closing of different switches can overlap. In this case, the known device would not be functional, since with two switches closed the motor would continue to run and would never be stopped by the program control device.

The object of the invention is to create a time-dependent operating program control device at that a proper function is ensured even if a switch is closed depending on the time before the previously closed switch has dropped out, so that control commands are timed overlap. This object is achieved by the features characterized in claim 1. Appropriate

such refinements are characterized in the subclaims.

It can be seen that here the drive device of the tap changer (for example a motor) is not directly is driven by closing the switch, but via a toggle stage. The tilt stage itself is in turn not immediately caused by the closing of one of the sallets, which are breakers of any design can act, controlled, but via an OR gate. In this way it is made visible that when one of the switches is closed, a Kippsignai is placed on the flip-flop and through this Influencing the drive device the tap changer is put into operation. But as soon as the movable contact of the second tap changer

⁶ S the fixed contact connected to the closed switch has accumulated, regardless of whether another switch is closed or not, a reset signal is applied to the flip-flop and the

Drive device put out of operation again. At the same time, the tipping stage is ready for operation again If another switch is closed in this state, although the previously closed switch is still also closed, the program control device can easily respond to the new Obey the command, as closing the further switch generates a toggle signal and is placed on the tilting stage. It is only necessary to ensure that no more than two at the same time Switches are closed, otherwise the switching of the step switch at one between the previously closed and the now newly closed switch located further closed switch ended would. In principle, however, a time-dependent program control device is created which ensures reliable work that is adapted to their peculiarities. The structure of the device is included extremely simple, easy handling ensured and versatile usability in Connection achieved with any information source. It is easily possible to have one at the same time Manual operation bypassing the time-dependent, automatic program control device to achieve.

In the following description, the invention will be explained with reference to a program control device shown in the drawing explained for the tuning device, so the station selection in a radio receiver is determined. It shows

1 shows a circuit arrangement of a first exemplary embodiment a program control device for the scanner selection! in a radio receiver,

2 shows a circuit arrangement of a second Exemplary embodiment of a program control device with step-wise driving electromagnet,

F i g. 3 shows a diagram of the switching states of transistors of an astable multivibrator in FIG Arrangement according to FIG. 2,

F i g. 4 is a perspective view of one used in the circuit arrangement of FIG Plunger coil,

F i g. 5 and 6 representations of other drive modes for actuating the contacts of the two tap changers independent of the time signal,

F i g. 7 shows a circuit without a diode for changing the capacitance in a tuning device,

F i g. 8 a circuit for the program-controlled actuation of several electrical devices,

9 shows a circuit for preselecting frequencies and

Fig. 10 shows a circuit for presetting the power supply to information sources.

Fig. 1 shows a drive 1, for example a clock, which works as a function of time. A time signal generator 2 is connected to this drive 1, the switches S \ to S% of which are closed at preset times at least until movable contacts / "of step switch ^ 3 and 45 have scanned all fixed contacts a to e and generated time signals at the generator output. The step switch 3 is a switch whose fixed contacts a to e are each connected to the outputs of the switches Si, S ₂ , S ₃ , which form the time signal generator. S »or S _{5 are} connected and the movable contact / is rotated in a certain direction by a motor 39 described below, whereby the fixed contacts a to e brought into contact with the movable contact f are automatically switched over one after the other with capacitors 5 and 9, resistors 10 to 14 and 20 and diodes 15 to 19 is connected to the output of the time signal generator 2 in this way n that even if any switch of the time signal generator 2 was brought into the operating state during the operation of another, a time signal can always arise at the output of the switch activated later, so that a memory 21 can work properly in the subsequent stage. The memory 21 consists of a bistable multivibrator, also known as a flip-flop, with two transistors 22 and 23, resistors 24 to 29, capacitors 30 and 31, and diodes 32 and 33. However, it can just as well consist of mechanical switches. A capacitor 34 is connected between the movable contact f of the tap changer 3 and the cathode of the diode 33 of the memory 21, and a capacitor 35 is located between the output of the OR gate 4 and the cathode of the other diode 32 of the memory 21 Its base is connected to the collector of the transistor 23 of the memory 21 via a resistor 37 and its emitter is connected to a current source via a resistor 38. A motor 39 is connected between the collector of transistor 36 and earth and drives the movable contact / tap changer 3 as described above. Variable resistors 40 to 44 are used to set the reception frequency and determine the bias voltages applied to a diode 47 of variable capacitance, which belongs to a tuning device of a radio receiver 46. Adjustable taps of the resistors 40 to 44 are each connected to fixed terminals a, b, c, d and e of the first tap changer 45, the movable cam / as in the case of the second tap changer 3 is driven by the motor 39 and via a resistor 48 is connected to the anode of the diode 47. A tuning coil 49 together with the diode 47 forms the tuning device of the radio receiver 46 and a capacitor 50 blocks the direct current.

In the above embodiment it is assumed that the various radio programs are switched one after the other and are to be received at different times, e.g. B. Program Azure time a, program ß at time b ...

In this case, only the switches Si, S ₂ ... of the time signal generator 2 need to be set in such a way that they optionally work at the times a, b ... and the variable resistors 40, 41 ... for setting the Reception frequency, which each correspond to the switches Si, S ₂ ..., in such a way that the voltages at their respective slide terminals correspond to the programs A and B ... respectively.

It is assumed that the switch Si is the timing signal generator 2 is set such that it is moved at the time a in the switched position, while the corresponding resistor 40, due to its setting will produce a necessary for reception of the program A voltage, and that the switch St of the time signal generator 2 is switched on at time b , while the corresponding variable resistor 43 is to generate the voltage necessary for receiving the program B. The moving contacts of the step switches 3 and 45 are arranged in front of the fixed contacts c.

If, under these conditions, the time a

is reached, the switch S \ of the timing signal generator 2 is switched on and a certain current flows through the resistor 20, the diode 15 and the capacitor 5 of the OR gate 4, whereby a negative timing signal is generated at the output of the diode 15. Since the time pulse signal acts on the cathode of the diode 32 of the memory 21 via the capacitor 35, the base of the transistor 23 is negatively biased and this blocks. When the transistor 23 is switched off, its collector potential approaches a positive value and the base of the other transistor 22 is positively biased and thus the transistor 22 becomes conductive. This condition is maintained until the base of transistor 22 is biased negatively. By switching the transistors 22 and 23 on and off in this way, the base of the switching transistor 36 is simultaneously also positively biased and the latter is thereby made conductive. A strong current flows through the collector of the switching transistor 36 and the motor 39 connected to it rotates in a certain direction. The motor 39 is coupled to the movable contacts / tap changers 3 and 45 in the manner described above, so that when the motor 39 rotates, the movable contacts / are also rotated and move onto the fixed contacts a, b, c which come into contact with them , d and e toggle one after the other.

It is assumed that the movable contacts / are rotated counterclockwise or in the direction in which the fixed contacts are successively switched from a to £>, from b to c, from c to d ... by the rotation of the motor 39; the movable contacts f, which were previously in contact with the fixed contacts c , then come into contact with the fixed contacts d, ea .. one after the other. When the movable contacts / the fixed contacts touch a, the voltage corresponding to program A and set by the variable resistor 40 is applied via the first tap changer 45 and the resistor 48 to the variable capacitance diode 47, which is the tuning device of the radio receiver 46, whereby the tuner is tuned to the frequency of program A and at the same time a certain current flows through the resistor 51, the second step switch 3 and the switch S, of the time signal generator 2 and generates a negative voltage at the movable contact / the second step switch 3. Correspondingly, negative voltage is applied to the cathode of the other diode 33 of the memory 21 via the capacitor 34 and the other transistor 22 of the memory 21 is blocked. The collector potential of the transistor 22 or the base potential of the other transistor 23 thereby approaches a positive value and the blocked transistor 23 becomes conductive. The voltage acting on the base of the switching transistor 36 becomes negative, so that the transistor 36 is blocked. The rotation of the motor 39 is stopped and the movable contacts / tap changers 3 and 45 are stopped when they are in contact with the fixed contacts a. In this way, the voltage corresponding to the program A , set by the variable resistor 40 as described above, remains applied to the variable capacitance diode 47 forming the tuner of the radio receiver 46, and the program A can be received from time a.

When the movable contacts / tap changer 3 and 45 come into contact with the fixed contacts b, c, cf and e by the rotation of the motor 39, voltages are applied to the variable capacitance diode 47 through the tap changer 45 and the resistor 48, respectively correspond to the predetermined programs and are set by means of the variable resistors 41 to 44. At time a, however, all switches 52, S3, Si and S5 of the time signal generator 2 corresponding to these variable resistors 41 to 44 are open, so that no negative voltage is generated at the output of the step switch 3 and thus the operation of the memory 21 is not switched. The motor 39 continues to rotate without interruption and the programs set by the respective variable resistors 41 to 44 are not received at time a.

The following description relates to the case in which the point in time b is reached. In this case, the switch 54 of the time signal generator 2 is switched on, so that a certain current flows through the resistor 20, the diode 18 and the capacitor 8 and a negative time pulse signal is first generated at the output of the diode 18, as in the case of time a. As at time a, this time signal is applied via the capacitor 35 to the cathode of the diode 32 of the memory 21, so that the transistor 23 turns off and the transistor 22 becomes conductive. As a result, the switching transistor 36 becomes conductive and the motor 39 drives the movable contacts / the tap changer 3 and 45 in a certain direction as at time a. The movable contacts f, which were previously in contact with the fixed contacts a, are now brought into contact with the fixed contacts in the order b, c and d . When the movable contacts / fixed contacts b and c touch, the switches S2 and 53 of the timing signal generator 2 are not closed as described above. For this reason, the transistor 23 in the memory 21 remains blocked and the transistor 22 is conductive. The switching transistor 36 also remains conductive and the motor 39 continues to rotate. After the movable contacts / the fixed contacts b and c to come into contact with the fixed contacts d , current flows through the resistor 51, the step switch 3 and the switch Sa of the timing signal generator 2 as at the time a and in this way the negative voltage occurring on the side of the movable contact / tap changer 3 is applied through the capacitor 34 to the cathode of the diode 33 of the memory 21. The operation of the memory 21 is thus switched, the transistor 22 blocks and the transistor 23 conducts. As a result, the switching transistor 36, which stops the rotation of the motor 39, is turned off. The movable contacts / the step switches 3 and 45 thus remain in contact with the fixed contacts d, whereby the voltage corresponding to the program B set by means of the variable resistor 43 through the step switch 45 and the resistor 48 to the, the tuning device of the radio receiver 46 forming diode 47 variable capacity is applied.

In this embodiment, preset programs can be closed automatically one after the other predetermined times can be received by setting the operation start time with switches 5i to 5s of the Time signal generator 2 and the voltage corresponding to the desired programs with the variable Resistors 40 to 44 can be set.

As described above, the device is actuated by a signal from the timing signal generator, they but can also be put into operation independently of the time signal. Like F i g. 1 shows is after closing of a switch 56 forms the base of the switching transistor 36 positively biased by the resistor 52 and thereby the switching transistor 36 switched on. Thereupon the drive 39, z. B. the engine started and the scanned turning of the step switches 3 and 45 enables. After the movable contacts / the step switch 3 and 45 to any If you have moved contact e, switch & is opened. The drive 39 is stopped and the rotation of the Step switches 3 and 45 ends. In this way, each contact can a to e independently of the time signal to get voted. If the contacts are connected to the information sources beforehand, the Information can be switched optionally.

In the device described above is as a drive 39 a motor used. In its place, however, others can also be actuated by electromagnetic force Facilities are used as they are, for. B. in Fig. 2 and 4 are shown.

Instead of the drive according to FIG. 1, FIG. 4 shows an electromagnetically fed drive, a so-called plunger core coil. An oscillator 69, namely an astable multivibrator, is used to switch an electromagnet 67 on and off. Transistors 54 and 55 of oscillator 69 block and conduct alternately with respect to one another and the oscillations are repeated in such a way that transistor 54 conducts at one point in time and transistor 55 blocks and at the next point in time the former blocks and the latter conducts (FIG. 3). . The output signal is applied from the collector of the transistor 55 of the oscillator 65 via a resistor 64 to a transistor 65 and this is switched by this. The electromagnet 67 is switched on and off by conducting and blocking the transistor 65. The output signal of the transistor 65 is applied via terminals x ' and y' of the electromagnet 67 (FIG. 4). When current flows through the terminals x ' and y' of the electromagnet 67 with the transistor 65 conducting, an iron core 70 is magnetized and pulls an iron part 71, which is fastened to the outer end of a lever 72, downwards. A shaft 73 is then rotated clockwise according to the arrow. As a result, one of the contacts inside a switch 74 is rotated. When the transistor 65 subsequently blocks, the electromagnet 67 loses its force of attraction and the lever 72 is moved upwards by a spring 75. The shaft 73 is held in the rest position at this point in time and is not rotated counterclockwise. When transistor 75 conducts again, switch 74 is rotated clockwise again and moves a contact. Due to the structure, each time the transistor 65 is conductive, a contact is moved clockwise. When the operation of the oscillator 69 is stopped, the rotation of the switch 74 is also stopped. The switch 74 is connected to the step switches 3 and 45 in FIG. 1 coupled To stop the oscillator, the output of the memory 21 is applied to a switching transistor 53. When the transistor 53 is switched on, the oscillator 69 is actuated and when it is blocked it is switched off

If program A is to be received at time a, program β at time b , and so on, as with reference to FIG. 1, the switch Si of the time signal generator 2 is closed when the time a is reached, whereby the signal is applied to the cathode of the diode 32 of the memory 21 via the capacitor 5, the diode 15 and the capacitor 35. According to the description above, the memory 21 is then switched on, the transistor 23 blocking and the transistor 22 conducting, and the transistor 53 also becoming conductive. The oscillator 69 is now ready to start and as a result the transistor 65 and also the electromagnet 67 are switched on and off alternately. In this way, the step switches 3 and 45 are successively driven intermittently and successively switch the fixed contacts a to e. When the movable contacts f touch the fixed contacts a, the voltage set by the variable resistor 40 and corresponding to the program A is passed through the step switch 45 and the resistor 48 to the. the tuning device of the radio receiver 46 forming diode 47 of variable capacitance is applied, whereby the tuner is tuned to the frequency corresponding to the program A , and at the same time a certain current will flow through the resistor 51, the step switch 3 and the switch S \ of the time signal generator 2, so that a negative voltage occurs at the moving contact / tap changer 3. The negative voltage is thus applied to the cathode of the diode 33 of the memory 21 via the capacitor 34 and the latter is switched off; the transistor 22 blocks and the transistor 23 becomes conductive. As a result, the switching transistor 53 is blocked, the oscillator 69 stops its oscillation, the transistor 65 as well as the electromagnet 67 interrupts its on-off operation and the movable contacts / the step switches 3 and 45 stop in contact with the fixed contacts a. Consequently, according to the above description, the voltage corresponding to the program A and set by the variable resistor 40 is applied through the step switch 45 and the resistor 48 to the variable capacitance diode 47 forming the tuner of the radio receiver 46, so that from the time a on the program A. can be received. If program B is received at time b , a corresponding process is carried out

F i g. 2 also shows a possibility in which the contacts of the step switches 3 and 45 can be moved independently of the time signal. A switch Si is connected in series with the electromagnet 67. After switching the switch 57 to the terminal x, a pulse current flows through a capacitor 68 through the electromagnet 67, and this actuates the step switches 3 and 45. Since the switch 5? returns to terminal y when it is released, capacitor 68 is discharged via contact terminal y of switch 57. When the switch 57 is reconnected to the terminal χ, an impulse current again flows through the electromagnet 67, and the latter actuates the step switches 3 and 45 again. By repeating this process, the variable contacts / can be moved to any desired position of the fixed contacts a and e as a result, information can be output independently of the time signal by connecting certain information sources to the fixed contacts a to e. In addition, which is not shown in FIG. 2, a switch can be switched on between the base and collector of the transistor 53 via a resistor, and the oscillator 69 can be started or stopped by the on and off operation of the switch; thus they are

Step switches 3 and 45 can also be switched regardless of the time signal.

F i g. 5 shows a further device for adjusting the step switches 3 and 45 independently of the time signal if the drive is a motor according to FIG. 1 has. The switch 74 contains the two step switches 3 and 45. A shaft 76 couples the switch 74, a gear 77 and a manually operated setting button 79. With the gear 77 there is another gear 75! engaged. Likewise, a motor 80 and a shaft 81 are provided which couple the gear 78 and the motor 80 to one another. If the operation takes place by the time signal, the gear wheel 78 is set in rotation by the shaft 81 with the aid of the drive containing the motor 80 and thereby also the gear wheel 77. The switch 74 then receives the rotation of the gear 77 transmitted by the shaft 76 and thereby the movable contacts f to the contacts a to e of the step switches 3 and 45 are moved. In contrast, when the operation is independent of the time signal, the setting knob 79 is rotated by hand. The step switches 3 and 45 provided in the interior of the switch 74 can be rotated by the shaft 76.

The contacts of the step switches 3 and 45 are in the circuits according to FIG. 1 and 2 can also be moved in other ways independently of the time signal. 6 shows presettable switches S] ι to S15 of a preset switch arrangement 82, each with switches Su Si, Sv S * and Si of the time signal generator according to FIGS. 1 and 2 are connected in parallel.

It is assumed that the variable resistor 40 has the appropriate voltage for the reception of the program A set on it, but a program is just to be received independently of the time signal; the presettable switch 5h is set to the on position. As in the above description and similar to when the switch Si is switched to the switched-on side, a negative pulse is applied to the diodes 32 of the memory 21 via the capacitor 5, the diode 15 and the capacitor 35, the switching state of the memory 21 is changed and the switching transistor 36 made conductive, which sets the motor 39 and thus the step switches 3 and 45 in rotation. When the movable contacts f reach the fixed contacts a, a negative pulse signal is applied to the diode 33 of the memory 21 via the step switch 3 and the capacitor 34 because the preset switch S \ is closed. As a result, the memory 21 is reset and switches off the switching transistor 36 and thus the motor 36. For this reason, the movable contacts / "of the step switches 3 and 45 are stopped at the fixed contacts a and the voltage of the variable resistor 40 is applied from the contact a of the step switch 45 to the variable capacitance diode 47 in the radio receiver 46, so that the program A can be received.

In the same way, any programs can be selected independently of the time signal by moving the presettable switches Sn to S \ s, which correspond to the respective variable resistors 40 to 44, to the on position. Operation with the time signal also corresponds to the description above.

Although rotary switches are used for step switches 3 and 45 in the description above, however, other switches such as slide switches and electronic switches with transistors, Diodes, etc. can be used, provided that both switches can be coupled together and through a Drive can be driven together. Furthermore, the 5 OR gate is designed such that, if one of the Time signal generator 2 forming switches Si to 52 is switched on as long as another is still switched on, it can be prevented that the later switched on switch does not emit a time signal, whereby

ίο the switch that is switched on later does not work normally can. Consequently, the OR gate is not absolutely necessary if a value exceeds a certain value between the respective setting times Time interval is present.

Even if in the above embodiments a flip-flop formwork as a memory 21 for controlling of the switching transistor 36 and the motor 39 is used, the flip-flop circuit and the switching transistor are used 36 not always necessary. For example, a changeover switch is used as a circuit for controlling the motor 39 usable, which is operated by an electromagnet. Next, instead of the motor 39 or the Electromagnet 67 as a drive can also be used for other devices.

In the embodiments described above, the tuning device of the radio receiver 46 consists of the tuning coil 49 and the diode 47 of variable capacitance; The invention can, however, be used advantageously in radio receivers 46 which - as shown in FIG. 7 - do not have a variable capacitance diode in the tuner. In this case it is sufficient if the respective changeable capacitors 83 to 87 or changeable inductances are connected to the respective fixed contacts a to e of the tap changer 45.

In a radio receiver, it is also possible that the frequency band setting switches are connected in series to adjust to amplitude modulation or frequency modulation and the fixed contacts a to e of an additional step switch are coupled to the step switch 3, whereby the originally set frequency band can be automatically received. 9 shows a suitable circuit for this. Frequency band setting switches Sib to S20 are connected in series with the fixed contacts of a further step switch 95 coupled to step switch 3. In the same way, the power source can be turned on by setting its on-off operation beforehand.

50th or switched off.

Fig. 10 shows a circuit suitable for this. It includes a step switch 96, which is connected to the step switch 3 is coupled The setting switches S21 to 525 to switch the power source on and off are each in series with the fixed contacts a to e des Step switch 96 switched, the originally set power source being automatically switchable

The following description relates to a time signal generator. For drive 1 according to F i g. 1 and 2 devices can be used which can be actuated as a function of the time, e.g. B. a Motor and a spring. The time signal generator 2 has a time setting device for presetting certain Times, through the setting of which the respective switches Si to 5s of the time signal generator 2 be operated at the respective set times. In one embodiment, a round drum is used for this provided, the corresponding to their scope

Having contact parts; the switches are operated by making contact with the contact parts. In another embodiment, an object driven by the drive 1 and a non-driven object provided for the time setting are operated in such a way that the respective gaps are changed at the set times and the switches are thereby operated. In a further embodiment, the switches are switched on and off with the aid of a transistor circuit or a diode circuit which is actuated as a function of the frequency fed in, whereby time signals are generated, etc.
As can be seen from the description, the invention can be used not only for radio program selection, but also for television broadcasts. Like F i g. 8 shows, by separately providing a step switch 93 coupled to the step switch 45, by connecting a radio receiver 88, a tape recorder 89, an electric washing machine 90, an electric. Rice cooker 91 and a stereo recording device 92 to fixed contacts o, p, q, r and s of the tap changer 93 and connecting a movable contact t of the tap changer 93 to the power source, the electrical devices 88 to 92 switched automatically and one after the other at any time and thus operated will.

For this purpose 4 sheets of drawings

Claims (3)

Patent claims: 1. Program control device with a first step switch (45) actuated by a drive device (39), the fixed contacts (a-e) of which are connected to information sources (40-44) for program control, and with a drive connected to the first step switch (45) coupled second tap changer (3), the fixed contacts of which are connected to switches (Si-S ₅ , Sn-Si ₅ ) that can be closed at will and then a potential (-B) to the fixed contacts (a-e) of the second tap changer (3), characterized in that a bistable multivibrator (21) is provided to control the drive device (39), one input of which is at the output of an OR gate (4), the inputs of which are in turn connected to the fixed contacts (a-e ) of the second step switch (3) and that the other input of the bistable flip-flop (21) is on the movable contact (Q of the second step switch (3), so that when one of the switches (z. B. Si) is closed, an OR -Gate (4) generated the flip-flop signal is applied to the bistable flip-flop (21) and through this the drive device (39) of the step switch (45, 3) is put into operation and held until the moving contact (Q of the second step switch (3) hits the fixed Contact (e.g. B. a), which is connected to the closed switch (Si), a reset signal is applied to the bistable multivibrator (21) and thus the drive device (39) is stopped in this position of the stage switch (45, 3), and that in this position the information source (e.g. 40) corresponding to the closed switch (Si) or the fixed contact (e.g. a) of the first step switch (45) connected to it via its movable contact (Q with a to be programmed Device (46) is connected. 2. Program control device according to claim 1, characterized in that a switch (Si-Ss) at predetermined times and for one predetermined duration closing drive (1) is provided 3. Program control device according to claim 1 or 2, characterized in that the Aniriebsvorrichtung is a step switch (45, 3) step-wise driving electromagnet (67) between the and the bistable multivibrator (21) an oscillator (69), in particular an astable multivibrator, connected is, which is dependent on the control of the bistable flip-flop (21).