DE1051326B - Circuit arrangement for electronic pulse control of electromagnets with the aid of a blocking oscillator circuit - Google Patents

Description

GERMAN

In electronic impulse technology, the task often occurs by means of a very brief and low-power impulse to make an electromagnet respond. Because such an impulse on the one hand does not have the necessary energy to operate an electromagnet and on the other hand opposite the mechanical inertia of the electromagnet is much too short-term, there is a need to to stretch this impulse once in time and to strengthen it in its performance on the other. Usually a monostable multivibrator is used for this purpose, which is switched by this pulse and in turn emits an impulse of the length required for the excitation of the electromagnet is needed. In those cases in which the pulse power output by the monostable multivibrator to excitement. is not sufficient, it is also necessary to add another toggle switch to connect a separate amplifier.

To the space required for such a switching arrangement, which is usually only an additional unit for one Electronic counting, calculating or similar devices should be kept as low as possible if flyback transformers are used, by means of a continuous return current after each tilting process into the starting position to be postponed. However, this space saving in the transformer must come with a greater energy requirement to be bought.

The invention has set itself the goal of simplifying the circuit, the effort and the Reduce the power requirement for the excitation of such electromagnets significantly. This is done according to the invention achieved in that the electromagnet to be actuated itself as a transformer for the blocking oscillator circuit is formed.

The electromagnet is thus provided with a second winding and in the blocking oscillator circuit included so that a separate blocking oscillator transformer can be omitted. Furthermore this new blocking oscillator circuit is provided with a separate storage capacitor from which the energy required for switching is taken during the switching process. In the. Switching breaks this storage capacitor is charged again via a relatively large resistance. Since the As a blocking oscillator transformer, the electromagnet always used a more or less large air gap has, a reset current to increase the flow stroke is not required.

The structure of a known arrangement is shown in FIG. 1, the simplified structure according to the invention is shown in an exemplary embodiment in FIG.

The differences in the structure and the different circuit arrangement for the electronic pulse control of electromagnets
with the help of a blocking oscillator circuit

Applicant:

Kienzle Apparate GmbH,
Villingen (Black Forest)

Günter Martens, Schliersee,
has been named as the inventor

These working methods are explained in more detail using the drawings below:

According to FIG. 1, a control pulse fed to either input 1 or input 2 'causes a monostable blocking oscillator consisting of a transistor 3 and a transformer 4 to tilt. The breakover time of the blocking oscillator is determined by the dimensioning of the blocking oscillator transformer 4 and the level of the battery voltage. After expiration. this unique. During the tilting process, the blocking oscillator returns to its rest position by the means mentioned below and, after a certain reset time has elapsed, is ready to carry out a new switching process. ges ready. This reset time is due to a continuous current which flows through a winding 4c of the transformer 4 in such a way that the magnetic flux in the transformer 4 is brought into such an initial state that the greatest possible flux change occurs in the core during the tilting process leaves. The flux change from the initial state to saturation and the applied voltage then gives the breakover time of the blocking oscillator circuit, which must be long enough to allow an electromagnet 6 to respond during this time. During this breakover time, a negative voltage is induced in a winding 4 d of the transformer 4, which voltage is fed to the base of a transistor 5 and makes it conductive. The now flowing collector current of this transistor 5 is strong enough to actuate the electromagnet 6.

The continuous current return of the transformer 4 is necessary to keep the dimensions as small as possible the transformer 4 still has a sufficiently large flux

■ 809 767-65

change, which is sufficient for the excitation of the electromagnet 6, during the tilting process to obtain.

In an example carried out, current pulses of about 0.3 A amplitude and 6 ms duration are required. The current required to reset the transformer 4 was about 10 mA. Since ten or more electromagnets are provided in such a system that have to be actuated one after the other or possibly at the same time, was for this purpose from A continuous current of at least 100 mA is required on the side of the power supply unit. He had to The power supply unit must also be dimensioned in such a way that it can withstand a possible shock load of 3 A. A such a power supply unit is necessarily quite large and expensive.

In Fig. 2, the blocking resonant circuit consists of an electromagnet 17 with the windings 17 α and 17 b, a transistor 12, the collector of which is connected via a resistor 14 to the input of the winding 17 α of the electromagnet 17, while its base is connected via -eine Resistor 15 leads to the input of the winding 17 b . At the output of the winding 17 a is a pole of a storage capacitor 18, which is connected to the same pole via a resistor 19 to the negative pole 20 of the voltage source. The output of the winding 17b and the other pole of the capacitor 18 · are at the positive pole 21 of the DC voltage source.

The emitter of the transistor 12 is connected to the negative pole of a diode 13, the positive pole of which in turn leads to the positive terminal 21 of the DC voltage source. In the idle state, the transistor 12 is in the non-conductive state. In each case flowing collector leakage current generated across the diode 13 a voltage drop of about Vio V, thus making the emitter of the transistor 12 is negative with respect to its base, so that the transistor 12 with _security: is blocked state.

If a negative control pulse is now fed to the input terminal 11, it arrives at the base of the transistor 12 via a coupling capacitor 22 and makes it conductive. As a result, a collector current begins to flow through the resistor 14 and the winding 17 a, which generates a change in flux in the electromagnet. As a result of this change in flux, a voltage is induced in the winding 17 b , which has such a winding sense that the base of the transistor 12 connected to it via the resistor 15 is supplied with a negative voltage. This negative voltage keeps the transistor 12 in the conductive state as long as the flux in the electromagnet 17 changes. As a result of the inductance formed by the winding 17 a, the collector current begins to rise from zero, roughly in a sawtooth shape, until the current strength is limited to a maximum value by the direct current resistances in the collector circuit (including the direct current resistance of the transistor itself and that of the diode 13) over which the collector current can no longer rise. As a result of the now remaining constant field strength in the electromagnet 17 also the flow does not change therein, and b induced in the winding 17 voltage stops. As a result, the transistor 12 immediately becomes non-conductive again.

As a result of the air gap contained in the electromagnet 17, the field breaks at the end of the described Tilting process immediately back together and would be in the winding 17 a for the Transistor 12 induce harmful voltage spikes if this voltage spike is not caused by one with the The beginning and the end of the winding 17 α connected and correspondingly polarized diode 16 would be destroyed. During the tipping process, the storage capacitor was 18 unloaded. The dimensioning of the capacitor 18 is such that the voltage of the Capacitor 18 by the tilting process only around

ίο about 10% reduced. During the now following In a pulse pause, the capacitor 18 is restored to its original voltage via the resistor 19 charged.

The power requirement of the arrangement according to the invention is extremely reduced compared to the previously described known arrangement. A Continuous current for a reset process is not required at all. Despite the during the Tipping process occurring with high current peak

With a maximum value of 0.6 A, the DC voltage source is practically not at all loaded, since the energy for this current surge is taken from the storage capacitor 18. Of the The tilting process takes about 2 ms.

During this time, the capacitor 18 is drawn by the current peak of 30 V, for example discharged to about 27 V. The response time of the mechanical parts of the electromagnet 17 used, which z. B. is designed as a pot magnet, is about 4 ms compared to 6 ms for the aforementioned Circuit using the same magnet. During the rest period of the electromagnet, the Capacitor 18 again to the voltage of the DC voltage source on.

The storage capacitor 18 included in the new circuit arrangement according to FIG. 2 means opposite the circuit arrangement described in Fig. 1 by no means an additional expense, since a corresponding Large storage capacitor is also provided in the power supply unit associated with the circuit according to FIG. 1 have to be. The proposed assignment of a correspondingly smaller storage capacitor 18 however, for each individual electromagnet 17-brings the advantage that with a simultaneous response of all electromagnets 17 no mutual influences are possible.

For a circuit according to FIG. 2, the following are required: a blocking oscillator transformer, which is connected to the actuating electromagnet 17 is identical, and a transistor 12. · ·.

In contrast, belong to a circuit according to Fig. 1: An electromagnet, a blocking oscillator transformer, two transistors and a special power supply.

In the example described, the storage capacitor 18 used and the associated Charging resistor 19 conditional time constant V2 seconds. With this time constant the is maximum charging current approx. 1 mA, limited to the duration of the time constant. Compared to the known Arrangement according to Fig. 1, in which a permanent quiescent current of 10 mA is required, proves this is a considerable saving in electricity. In addition, in the arrangement according to FIG. 1, the special Power supply must be able to use several electromagnets at the same time to be able to deliver the considerable current peak of 3 A. As a result of the greatly reduced Power requirement 'of the arrangement according to the invention according to FIG. 2, it is in the majority of the application

If possible, the operating voltage from the power pack of the associated electronic device remove. A special power supply unit is therefore superfluous with the new arrangement.

The use of the arrangement according to the invention in additional mechanical devices is particularly advantageous for electronic counting or calculating devices. A particularly advantageous application results for the locking solenoids in pressure or display devices.

Claims (4)

Patent claims: 1. Circuit arrangement for electronic pulse control of electromagnets with the help a blocking oscillator circuit, characterized in that the electromagnet to be actuated (17) itself is designed as a transformer for the blocking resonance circuit. 2. Arrangement according to claim 1, characterized in that that the energy necessary for the excitation of the electromagnet (17) during of the response process is taken from a storage capacitor (18), which so is switched so that it is recharged during the rest periods. 3. Arrangement according to claim 1 and 2, characterized in that the blocking oscillator circuit an electromagnet (17) with two windings and a transistor (12). 4. Arrangement according to claim 3, characterized in that in the emitter line of the transistor (12) a diode (13) for generating an emitter open circuit voltage which is negative with respect to the base is provided. 1 sheet of drawings © 80 »767/365 2.59