DE965083C - Magnetic trigger circuit, especially for electric calculators - Google Patents

Description

It is known to build trigger circuits from electron tubes or gas-filled discharge tubes. A trigger is an electrical: tilting arrangement with two stable, states, which are switched from one to the other by external impulses. Such trigger circuits are often used as a counter element in electrical calculating machines.

The invention relates to a magnetic trigger circuit, which consists of series-connected Ohmic, capacitive and inductive switching elements are made from an alternating voltage source be fed. According to the invention, a changeover winding is provided on the choke coil see whose magnetic field is perpendicular to the coil field. With the help of this winding, the Switching the trigger from one stable state to the other. The advantage is one ■ effective decoupling of the two windings so that the pulse width dear switching pulses no Causes interference.

A feature of the invention is a ferroresonance trigger circuit, in which the changeover winding and the load winding are always separated, if no trigger pulses are applied.

Further features of the invention emerge from the following description and are shown in FIG the drawings illustrate the embodiments of the invention by way of example demonstrate.

709 524/285

The drawings have the following meanings: FIG. 1 shows a series connection to illustrate the mode of operation of ferroresonance; Figure 2 is a graph of the current-voltage characteristics for the circuit according to Fig. ι;

Fig. 3 is a circuit diagram of a common impedance trigger circuit, which comprises two mixed-switched ferroresonance branches;

4 a, 4b and 4c are dynamic hysteresis diagrams an inductor core exposed to trigger pulses;

Figures 5, 6 and 7 illustrate design features the throttle;

Figure 8 is a circuit diagram of a dual ferroresonance trigger.

The present invention relates to magnetic switching elements in which ferroresonance is used in the form of the series connection of a resistor R with a capacitance C and a saturable inductor L and an alternating voltage source E _AC . With an appropriate selection of the values of the various switching elements and the frequency and voltage of the source E _AC , the operating point of this circuit can be in one of two stable states. According to FIG. 2, which illustrates the current-voltage characteristic of the series circuit of FIG. 1, there are two stable states α and b for a specific voltage value E ₂ .

During the transition from state α to state b , assuming a fixed supply voltage value, either the capacitor voltage 'can be increased by direct pulse transmission to the capacitor C or the entire supply voltage can be increased by voltage pulses to the inductor L or the inductor impedance can be reduced by current pulses, which results in a The capacitor voltage is increased. If the pulse duration is equal to or less than the oscillation duration of the carrier frequency, careful synchronization with the carrier voltage E _{AC is} necessary so that the magnetic flux in the core is increased and not decreased. In general, amplitude and width are important related quantities. An improvement in the basic series connection can be obtained by using two series-connected choke coils L which are individually coupled to two series-connected Umschaltwickgo lungs which are wound in opposite directions. The synchronization difficulties are reduced in this way, since a unidirectional switching pulse applied to the opposing windings generally has the tendency to saturate one of the two choke coils.

Switching to the low current state α is best done by discharging the capacitor with switching pulses (short-circuit trigger). However, it is difficult to switch the circuit to this state by pulses on the choke coil because the switching pulses must be applied during the brief period in which the capacitor changes its charge in order to be effective. As a result of these difficulties, the series connection according to FIG. 1 is not often used as a bistable trigger element. Another disadvantage of using a trigger circuit with only one branch is the problem of high-frequency feed when several trigger circuits with a random distribution of low and high current states are used.

This difficulty can be reduced by using two ferroresonance circuits connected in parallel, in which one of the two branches connected in parallel is always in the high current state when the other is in the low current state. An example of the parallel branch trigger circuit is the so-called impedance trigger circuit shown in FIG. 3. By appropriate selection of the switching elements and the voltage E _AC , one branch can be in the high current state and the other in the low current state or vice versa, but both branches cannot assume the same state at the same time. To distinguish between the switching elements of the two branches of the additives are added to 1 and 2, the designations R, C and L for the basic switching elements of FIG. 1 and the DrosselspulenvoTspannungs- or Unischaltwicklungen T. The circuit consisting of two series ferroresonance branches connected in parallel no longer has the difficulty of switching from one state to the other, as discussed above. Through the changeover windings T ₁ and T ₂ , the branch with the low amperage is always switched to the high amperage state and held there by the switchover pulse until the capacitor C , which was originally in the high state, is discharged, whereby its associated branch changes to the state low amperage is switched. AC output signals, the magnitudes of which change when the ferroresonance branches switch from one stable state to the other, are obtained from output circuits which are coupled to the connection point of the L and C elements of the respective branches. The circuit of FIG. 3 can be operated dual by the changeover windings. T ₁ and T _{2 are connected} in series so that each switching pulse is applied to both branches at the same time.

In this type, the magnetic flux according to the phase position of the Umschaltimptilses with respect to the Carrier supply voltage can be increased or decreased. However, if the pulse duration is less than that Oscillation period of the carrier voltage and also the amplitude of the switching pulse is small that the impulse alone does not switch the magnetic trigger circuits synchronization of the pulse with the carrier voltage is necessary.

The transformative coupling of the switching pulses in ferroresonance trigger circuits according to FIG. 3, however, has disadvantages because

the reference point for the flux changes in the inductor shifted during the pulse duration is.

According to the invention, a field winding is used in each branch inductor which supplies a magnetic flux perpendicular to the normal coil magnetic field and, although it can control the inductor of the inductor L , does not couple the switching circuit with the inductor unless the ίο normal and the transverse field are applied simultaneously . Furthermore, regardless of the polarity of the normal coil field, a magnetic flux always arises when the transverse field is applied. It is therefore not necessary to provide double cores or two series-connected choke coils, as mentioned above. The polarized state of the choke coil as a result of the use of transformer-coupled switching pulses and the symmetrical dynamic hysteresis curve obtained by using switching pulses of the transverse field are illustrated in FIG. Figure 4 a of this figure shows the dynamic hysteresis loop of the inductor core without switching pulses, 4b with transformer coupling of the switching pulse and 4c when the transverse field is used.

The switching pulse of the cross-field can be direct

be passed through the core material itself or through a pipe around which a cylindrical Magnetic core element and the alternating current winding lie.

According to Fig. 5, the core material 10 is used as a conductor. It is shaped into a ribbon and extends along the central axis. It is folded again in the middle. Then one will Copper line 11 welded at the ends or -soldered to form leads. A cylindrical core design is illustrated in Fig. 6, in which the core material 10 around the conductor 11 has rolled. The conductor passing through corresponds to one winding. However, multiple conductors can be brought into the central core opening, a single turn with multiple turns or a plurality of turns as desired Form windings. The alternating current winding 12 can be applied directly to the magnetic material 10 or via an insulating cylinder 13 according to FIG. 7, which is then wound onto the core material 10 . is pushed. The direction of the power spring is shown in FIGS. 8-10. The alternating current winding is preferably made in a single layer in order to reduce leakage flux and distributed capacitance to a minimum. Very thin, highly permeable magnetic tape material is used to make a choke coil where the ratio of the reactance in the unsaturated state to the reactance is large when saturated. Even with a large air gap, ratios of 4: ι achieve.

The ferroresonance trigger circuit illustrated in FIG. 3 can be connected as a dual trigger, as FIG. 8 shows, with a single input circuit 14 and two output circuits 15 and 16. The transverse field switching windings T 1 and T 2 are connected in series with the input circuit, can be grounded on both sides, as shown. The capacitor Ci is bridged by a diode 17 and a parallel circuit of resistor 18 and capacitor 19, the capacitor C 2 by a diode 20 and a parallel circuit of resistor 21 and capacitor 22. These elements are used to smooth and rectify the lines 15 and 16 appearing output potentials. The common impedance element Z is illustrated as a capacitor 23, and one end of the resistor 24 is connected between the capacitor 23 and the connection point of the two parallel ferroresonance branches. The other end of resistor 24 is grounded and provides a path for the DC output signal appearing on lines 15 and 16. The resistor 24 can, however, be omitted if an inductance or a resistor is used as a common impedance element.

It is assumed that branch 1 is in the high current state, as described above, and branch 2 is in the low current state. A switching pulse in any direction applied to line 14 excites windings Ti and T 2 simultaneously and thus switches the trigger circuit so that a low current flows in branch 1 and a large current in branch 2. An increase in potential occurs at output 16, while a drop is detected at output 15. The branch with low current is always switched to the high current state and held there until the capacitor C of the branch originally in the high current state discharges and thereby switches the associated branch to the low current state.

By using a transverse field, the magnetic flux changes in the coil are symmetrical regardless of the phase position of the trigger pulses, and the problem of trigger pulse and carrier synchronization is eliminated, which results in reliable operation as a bistable magnetic trigger. Furthermore, the alternating current windings of the coils L and the trigger windings T are only coupled when the trigger pulses are applied, and as a result unwanted harmonics generated by the currents in the ferroresonance branches can only enter the signal circuits during the trigger pulse times.

The described dual trigger can be known in Manner are used in counter circles, position shift registers and the like, in which a chain of trigger circuits, interconnected.

Claims (5)

PATENT CLAIMS: i. Magnetic trigger circuit, consisting of ohmic, capacitive ones connected in series and inductive switching elements that are fed by an alternating voltage source, special for electric calculating machines, characterized in that on the choke coil a changeover winding is provided, the magnetic field of which is perpendicular to the coil field. 2. Arrangement according to claim i, characterized in that that two ferroresonance branches connected in parallel are connected in series with an impedance element and the voltage source are. 3. Arrangement according to claim 2, characterized in that the output circuits each to the connection point of the inductance and capacitor switching elements of the ferroresonance branches are connected. 4. Arrangement according to claim 2 or 3, characterized characterized that the saturable. Inductors each include a coil that is on an elongated core consisting of at least one folded strip of conductive There is magnetic material, and at its ends lines for the connections and switching windings are attached. 5. Arrangement according to claim 2 or 3, characterized in that the saturable inductances consist of coils., which are wound on a cylindrical core made of Strip of magnetic material is formed, and in which there is at least one reversing winding is located. Considered publications:
Electronics, 25, pp. 121-123, 1952, No. 4 (April). 1 sheet of drawings © 609 737/158 12.56 (709 524/285 5. 57)