DE1103966B - Logical element - Google Patents

Description

GERMAN

The steadily increasing demands which are placed on the automatic systems have shown that Ordinary relays require too much space and have too limited a mechanical life and don't work fast. One must also expect that with the many relays in the system one Contact errors can occur.

To avoid the disadvantages of normal relays, one often uses non-contact circuits, usually those with transducers, electron tubes or transistors that perform the same function as a normal one Relay can meet, d. that is, they can depending on the presence or absence of an initial signal take on two different states, usually due to the presence or absence of an output signal Marked are. Circles of this kind are collectively referred to as "logical elements".

Known logic elements with transducers have the advantage that the input of the element of the output can be carried out galvanically isolated. In contrast, these logical elements mostly work not faster than ordinary elements and must also be supplied with alternating voltage, so that even very brief interruptions in the mains voltage cause the information stored in the element get lost.

Logic elements with transistors have the advantage that they have small dimensions and high operating speed and with direct voltage of A battery can be fed, so that brief interruptions in the mains voltage are of no consequence are. The previously known logic elements with transistors, however, have the disadvantage that one cannot galvanically isolate the output of the element from the input.

The invention relates to a logical element that depends on the presence or absence of an input signal has one of two states, which is caused by the presence or absence of an output signal is characterized, takes and takes all the advantages of the known, with transducers or transistors working logical elements without being burdened with their disadvantages. The logical element after the invention can thus be produced with small dimensions, has a high operating speed, can with DC voltage supplied by a battery and designed so that the output from the input is galvanically isolated, so that the output signal with selectable polarity is switched back or switched on can be. You can also have several galvanically isolated outputs and several from one another receive galvanically isolated inputs. The logic element according to the invention, its input and Output circuits galvanically isolated from each other. Logical element

Applicant:

Allmänna Svenska Elektriska

Aktiebolaget,
Västeräs (Sweden)

Representative: Dipl.-Ing. H. Missimg, patent attorney,
Giessen, Bismarckstrasse. 43

Claimed priority:
Sweden 8 July 1958

Egil Angeid and Dipl.-Ing. Friedemann Bacher,

Västeräs (Sweden),
have been named as inventors

and depending on the presence or absence of an input signal, an output signal or emits no output signal or vice versa, is characterized in that it essentially consists of consists of a known transistor oscillator, which is used as an input signal by means of a DC magnitude is throttled or excited, and that the output signal from a rectified part the alternating voltage excited by the oscillator and the input and output circuits are galvanic are separated from each other in that the input circuit and / or the output circuit with the oscillator are or is transformer-coupled.

Since the output signal consists of the rectified oscillation voltage of the oscillator, it is with Advantage taken via a transformer, thereby galvanic isolation of the output signal by the oscillator and thus also by the input signal. If this transformer with If several secondary windings are provided, one obtains several separate outputs.

According to the invention, the oscillator advantageously consists of a transistor blocking oscillator. Receives the advantages peculiar to the transistors, namely small dimensions and low power requirements. The blocking oscillator also has particular advantages in one designed according to the invention logical element. The transition from the throttled state to full amplitude oscillation as well as from oscillation to completely reduced feed

109 539/401

stand happens very quickly with a blocking oscillator, which is why the logical element is a gets great working speed. This also gives the output signal a very good curve shape. In the case of a blocking oscillator, the transistor is always either fully conductive or fully throttled state, so that variations in the data of the transistor are substantial do not affect the function of the logical element. . .

The mode of operation of the invention is described below with reference to the drawing in which FIG. 1, Figures 2 and 3 show different embodiments of the logic element according to the invention, essentially consists of a transistor blocking oscillator.

The logic element shown in Fig. 1 consists of a transistor 1, the emitter of which is connected to ground through a diode 2, while the collector is connected to a negative DC voltage through the primary winding 3 α of a feedback transformer 3, which z. B. comes from a battery. The base of the transistor 1 is connected on the one hand through a capacitor 4 and the secondary winding 3 b of the transformer 3 to the supply voltage of the transistor and on the other hand connected through a resistor 5 at the emitter. The base is also connected through a resistor 6 to one of the two input terminals 7 of the element. The feedback transformer 3 has an additional winding 3c, which is connected to the output terminals 11 of the element via a rectifier 8 and a smoothing arrangement consisting of a capacitor 9 and a resistor 10.

The transistor 1 is thus connected like a blocking oscillator. The circuit is, however, determined so that when no voltage or only a relatively small direct voltage is connected to the input terminals 7, the differential resistance of the emitter circuit, which is essentially determined by the alternating current resistance of the diode 2, is so great that the oscillator cannot vibrate. If, however, an input signal consisting of a negative direct voltage is connected to the input terminals 7, the direct current through the diode 2 increases, whereby its alternating current resistance and thus the differential resistance of the emitter circuit decreases. If the input signal is large enough, the resistance of the emitter circuit becomes so small that the blocking oscillator begins to oscillate in the manner characteristic of a blocking oscillator. This causes transistor 1 to conduct, with positive feedback to the base being obtained through feedback transformer 3 so that the collector current of the transistor increases very quickly until the collector can no longer supply a larger current. If the collector current no longer increases, the inductive reactance of the feedback transformer causes a voltage change in the collector, which is fed back to the base, so that the collector current decreases again quickly until the transistor is completely throttled. If the input signal is still present, the oscillator starts again after an interval, the length of which is determined, among other things, by the capacitor 4, and the oscillator thus continues to oscillate as long as the input signal is there. If, on the other hand, the input signal has stopped and the oscillator has throttled itself, it cannot start again, so that the oscillation stops. When the oscillator oscillates, an alternating voltage is obtained across the additional winding 3 c of the feedback transformer 3, which alternating voltage is rectified and smoothed so that a direct voltage is obtained as an output signal via the output terminals 11. Thus, when an input signal is applied to the element, the oscillator oscillates and an output signal is obtained, while when there is no input signal, no output signal is obtained either. The output signal is galvanically isolated from the oscillator and thus also from the input signal, which is why the output signal can be fed back or fed back in with the desired polarity. Furthermore, several output signals that are electrically isolated from one another can be obtained if the feedback transformer 3 is provided with several additional windings. In order to control the oscillator in FIG. 1, it is not necessary to connect the DC voltage serving as the input signal to the base of the transistor 1, but it is also possible to connect it only via the diode 2, although it is expedient to connect the base of the transistor 1 to ground and to reverse diode 2. The embodiment shown in FIG. 1 is more expedient in that the current gain of the transistor is also used for the input signal, so that it does not have to be so large. The oscillator can also be controlled with a DC voltage on the base of the transistor without the diode 2 being there, but it is necessary that a positive voltage is connected to the base in order to throttle the oscillator completely, which complicates the construction power.

If you want to control the oscillator by influencing the AC resistance of a diode located in the emitter circuit of the transistor by means of a direct voltage serving as an input signal, it is not necessary that the diode is connected directly in series with the emitter. FIG. 2 shows a logic element according to the invention, which consists of a transistor blocking oscillator of basically the same construction as in FIG. The secondary winding 3 b of the feedback transformer 3 is, however, in this case not connected between the base of the transistor 1 and the supply voltage, but between the base and earth. There is no need here for the capacitor 4, the main task of which in the embodiment shown in FIG. 1 is to isolate the supply voltage from the base. In the embodiment shown in FIG. 2, the oscillation frequency of the oscillator is essentially λόιι the inductance of the feedback transformer 3 is determined. In this case, the emitter of the transistor 1 is not connected to ground by a diode, but rather by the primary winding 12 δ of a transformer 12. Two diodes 13 and 14 are connected via the secondary winding 12 σ of the transformer. One of the input terminals 7 is connected through a resistor 15 to the center point of the secondary winding 12 α , the other to the interconnection point between the diodes 13 and 14 , are the ^ j | barren 13.14 flowed through by a direct current , "*
reduced by their alternating current resistance "i
As a result, the alternating current resistance of the primary winding 12 b of the transformer 12 and 4a ■ with the differential resistance of the emitter circuit also decreases so much that the oscillator begins to oscillate and an output signal is sent to the output

clamp 11 is obtained. In this embodiment of the invention the input is also from the oscillator galvanically separated, and because the transformer 12 is provided with additional windings, can several galvanically isolated inputs can be obtained. This embodiment of the invention also has the advantage that the diodes 13, 14 do not have the discharge current of the transistor flowing through them as is the case with diode 2 in FIG. This is an advantage as the leakage current influences the alternating current resistance of the diode 2 and thus a controlling influence on the oscillator Has.

Instead of controlling the oscillator by influencing the differential resistance of the emitter circuit of the transistor, it can be controlled by influencing the degree of feedback. Fig. 3 shows such an embodiment of the invention. The oscillator is constructed in the same way as in FIG. 1, with the exception that the emitter of transistor 1 is connected directly to ground. Furthermore, the input terminals 7 are connected to an additional winding 3 d of the feedback transformer 3 through a resistor 16. The oscillator is designed to oscillate when no input signal is received on the input terminals 7. If, on the other hand, an input signal consisting of a direct voltage of an appropriate magnitude is connected to the input terminals 7, a direct current will flow through the winding 3 d and excite the feedback transformer 3 with direct current. This reduces the degree of feedback, so that the oscillator is throttled and cannot start again until the input signal ceases. In this version, too, the input is galvanically isolated from the oscillator. and it is possible to have several galvanically isolated inputs. In this embodiment, in contrast to those described earlier, you get an output signal when there is no input signal and no output signal when the input signal is connected. The logic element consequently reverses the signal, which can be useful in certain uses. The fact that in a logic element according to the invention the input can be galvanically isolated from the output, it is possible by means of a logic element which contains a single layer transistor, for. B. to produce a bistable multivibrator or a "memory" element, ie an element that remains in the state it has assumed due to the action of the input signal, even after the input signal has ceased, which was previously not possible.

A "memory" element can e.g. B. with the embodiment of the invention shown in Fig. 1 thereby obtained that the output signal at the input with the same polarity as the input signal is switched back, whereby the oscillator continues to oscillate and provide output signals, too when the input signal has stopped. The "memory" can be restored in this way, for example be that the feedback is opened briefly, or that the oscillator by means of a short DC signal on an additional winding of the feedback transformer 3 in the is throttled in the manner shown in FIG.

Claims (8)

Patent claims. 1. Logical element whose input and output circuits are galvanically separated from each other are an output signal depending on the presence or absence of an input signal or emits no output signal or vice versa, characterized in that it essentially consists of a known transistor oscillator, which by means of an input signal serving direct current quantity is throttled or excited, and that the output signal from consists of a rectified part of the alternating voltage excited by the oscillator and the input and output circuits are galvanically separated from each other in that the input circuit and / or the output circuit is or is transformer-coupled to the oscillator. 2. Logical element according to claim 1, characterized in that the oscillator consists of a transistor blocking oscillator consists. 3. Logical element according to claim 2, characterized in that the output signal has a Rectifier arrangement from an additional winding of the feedback transformer of the Blocking oscillator is removed. 4. Logical element according to claim 2, characterized in that the feedback transformer of the oscillator carries an additional winding and on this one as an input signal Serving DC voltage is connected so that the input signal passes the feedback transformer excited with direct current and thereby influences the degree of feedback of the oscillator and thus controls the oscillator. 5. Logical element according to claim 2, characterized in that one is used as an input signal serving DC voltage is connected to the base of the transistor and thereby the oscillator controls. 6. Logical element according to claim 2, characterized in that the emitter circuit of the transistor contains a diode in the circuit of the DC voltage serving as the input signal and so the alternating current resistance and thus also the differential resistance of the emitter circuit of the transistor and thus the oscillator is controlled. 7. Logical element according to claim 6, characterized in that the diode in the circuit of the The secondary winding of a transformer has its primary winding in series with the emitter of the transistor is connected. 8. Logical element according to claim 3, characterized in that the output signal at the input is fed back with such a polarity that the oscillator is in the state it is through has taken over the influence of the input signal, even after the input signal has stopped remains. 1 sheet of drawings © 109 539/401 3.