DE1003268B - Magnetic amplifier - Google Patents

Description

Magnetic Amplifiers Magnetic amplifiers are often called valve chokes operated with saturation angle control. There is one valve and one pre-magnetizable choke connected in series, so that a half-wave current across the choke only flows in one direction. Any part becomes due to the premagnetization the voltage half-wave set, which the throttle absorb in each work act must before they reach saturation and thus from the blocking to the conductive state device and lets the current flow through the work resistor. To take advantage of the Half-waves in both directions are usually two valve throttles in each branch connected anti-parallel. Two particularly important circuits are the doubler circuit and the bridge circuit. With the doubler circuit, the working resistance is with Alternating current, supplied with pulsating direct current in the bridge circuit. from A great variety of circuits is derived from these two basic forms. So z. B. several amplifiers connected in cascade to form a larger one To achieve gain compared to a single amplifier. Common to all circuits is the inductive coupling of control and working circuits through the transformer effect between working and control windings on the chokes.

The coupling causes the occurrence of induced voltages and thus connected to the flow of equalizing currents in the connected circuits. These equalizing currents are detrimental in two ways: First, they do the amplifier sluggish, d. H. they increase the time constant of transition processes, Second, they require suppression of their undesirable. Tax effect usually Measures that the. Reduce the gain.

According to the invention, to avoid these deficiency symptoms a magnetic amplifier with self-saturation circuit, the working circuits from other control and working circuits magnetically coupled via the choke windings. decoupled by the fact that in the circuits, in which the working windings in Row with the valves, lying, counter-voltages are introduced to the voltages, which are induced from the connected circuits into these circuits and could cause equalizing currents in this.

The mode of operation of the invention is illustrated using two examples are: Fig. 1 shows the known doubler circuit with the control part I and the Working part II. The control voltage source 1 drives the control current via the series resistor 4 through the control windings 5, 6 of the chokes 7, B. The working part II contains the alternating current source 11, which the load resistor 14 in the cycle alternately over feeds the working windings 9 (10) of the throttles 7 (8) and the valves 13.1 (13.2). The point of the working resistor 14 can also be an arrangement consisting of one Rectifier and the work resistance, take when the work resistance with Direct current is to be fed.

If the control voltage has the polarity shown, the control current in the windings 5, 6 causes one of the windings caused by the working current in the windings. 9, 10 generated opposing magnetization of the chokes 7, B. If the control voltage is increased, the windings take up a larger part of the supply voltage 11, and the voltage across the resistor 14 drops (downward control). If such a reversal process is caused by a jump in the control voltage, the voltage at the working resistor 14 does not also change abruptly, but with a time curve that can be approximated by a sequence of periodic exponential functions that replace each other within a half period. Each of these e-functions is determined by a time constant T = LIR, which is the sum of the time constants of the control circuit TI and the coupled working part T2. T2 depends on the direction of reversal and the state of the work cycle. located choke (choke 7 with the drawn polarity of 11), namely whether it is in the blocking or conducting state, depending. The relationship T = L / R shows that the time constant of the working part T2 is inversely proportional to the resulting resistance of the working part. In the case of upward control, the high blocking resistance of the valves is included in resistor R, so that practically only the time constants of the control circuit determine the reversal sequence. In the downward control of the doubler circuit, the resistance R is formed only by the resistance of two valves 13.1, 2 and the resistance of the working winding 9, 10 in the conducting state of the work cycle. T, becomes very large, so that the reversal practically only takes place during the locking state in the work cycle, the work resistance 14 in the. Resistance R is included and T2 is correspondingly smaller than in the conductive state, but still remains significantly greater than in the upward control. This has the consequence that the doubler circuit behaves extremely sluggishly in the downward control.

The application of the inventive concept to this circuit is shown in FIG. 2. Only the working part 1I is shown. The control part can according to Fig. 1, I or Fig. 3, I.

There is an auxiliary voltage in each valve circuit of the working part II 12 with the direction opposite to the flow direction of the valves 13.1 and 13.2. The voltage introduced can either be pure or pure pulsating DC voltage, and z. B. be generated according to one of FIGS.

The alternating voltage at 11 is opposite to the level of the auxiliary voltage 12 the AC voltage required for the auxiliary voltage-free circuit is increased.

The auxiliary voltage is the induced voltage in the case of down control in the opposite direction and has the effect that in the event of a control voltage jump during the conductive state no equalizing current can flow through a throttle. In this state, the The circuit according to FIG. 1 practically does not allow any change in the control variable at all, the reversal is now just as fast as with the upward steering. The doubler circuit according to Fig. 2 is thus much faster than the simple circuit of Fig. 1.

In connection with a working part according to FIG. 2, a Control part according to Fig. 3, I can be used.

This control part (Fig. 3, I) provides for the control of the working part Voltage impulses on the choke in the idle cycle of such a size, that the choke is fully controlled during a half cycle of the supply voltage can be. This control part cannot work with a working part because of the equalizing currents according to Fig. 1, 1I are used. With an arrangement according to the invention according to FIG. 2, connected to a control part according to FIG. 3, I, however, can also do the otherwise so sluggish doubler circuit can be made just as quickly as the fastest magnetic circuit Amplifier circuit at all, since each reversal is controlled within a half period can be.

As another. An example of the application of the inventive concept is that Cascade connection of two amplifiers according to FIGS. 3 and 4 explained: FIG. 3 shows the Common way of connecting a follow-up amplifier (Part III) to an input amplifier (Parts I, II). The location of the control part I shown can also be a control part 1, I occupy the place of the final link III in the same way Arrangement II -I- III, d. H. one, amplifier contains n-1 parts of arrangement II.

Part I shows a control part for pulse control. 1 is pure or pulsating DC control voltage, 2 the auxiliary control voltage. The difference the two voltages form the control impulses, which alternate in time with the feed frequency from 2, controlled by the valves 3.1-4, to the control windings 5, 6 of the throttles 7, 8 of the preamplifier given. will.

For the application of the inventive idea is the type of control part irrelevant in itself. Using the described pulse control results in however, particularly favorable and clear operating conditions.

The working part of the preamplifier, consisting of the AC voltage source 11, the working windings 9, 10 and the valves 13.1-4 supplies the control variable for the follower amplifier on the control windings 15, 16 of the chokes 17, 18 over the series resistor 14.

Part II can be seen as a bridge in which. Diagonal branches the AC voltage source 11 and the control windings. 15, 16 of the repeater lie. In terms of circuitry, the positions 14, 15, 16 of FIG. 3 are analogous to the Positions 4, 5, 6 of the control part of Fig. 1, although those supplied by them Control variables are completely different: Part I of Fig. 1 delivers in the steady state a constant control direct current, part II of FIG. 3, on the other hand, voltage pulses in the form of partially controlled half-sine waves as a control variable. As a result of the transformational Coupling of parts II, III with one another can (because of the equalizing currents in part III) neither reached the smallest proper time nor (because of the equalizing currents in Part II) the greatest gain can be achieved as only part of the gain from the amplifier supplied energy is used for control magnetization, the rest on the other hand Resistor 14 and, transformed, occurs at resistor 23 of the follower amplifier. In addition, "to compensate for the inductive load" on the amplifier are often used further measures are necessary, such as B. the connection of a capacitor in series with a resistor parallel to positions 14, 15, 16 of Fig. 3, 1I, y1 as shown in dashed lines.

Simultaneously maximum gain and smallest proper time (1/2 period) are for each amplifier stage with the invention. Circuit of the middle section II according to Fig. 4 achieved: working winding of the preamplifier 9 (10) and control winding of the follower amplifier 15 (16) are in series in the same. Current path. This will causes each choke to receive only one control pulse per period. Through appropriate Polarity of the AC voltage sources. 2, 11, 21 ensures that the control pulses can only be given to the throttles that are in the idle cycle. With these measures are parts I and III implemented in a bridge circuit with regard to the transformer effects decoupled from middle part II, but not part II from parts I and III. Are namely the throttles 7 and 17 (or 8 and 18) simultaneously in the desaturated area (Locked state), the sum of the windings on windings 9 and 15 (or 10 and 16) occurring voltages, be greater than the alternating voltage connected to them at 11 and a compensating flow in the flow direction of valve 13.1 (or 13.2) drift, which would make the amplifier unable to work in this form.

This is prevented by counter voltages 12 opposite: the flow direction of the valves 13.1, 2 and opposite to the direction of the induced voltages in the windings 9; 15 or 10, 16 are introduced, the flow of equalizing currents through the windings 9, 15 and 10, 16 prevent induced voltages. the Counter voltage at 12 can be both a pure and a pulsating DC voltage.

The voltages 11 and 12 should expediently be chosen so that that during the rest cycle their sum is at least as great at every moment is like the sum of the induced voltages and that the difference of the over one Half-period voltage time sums of both voltages during the work cycle is just as large as the total voltage time required for magnetization reversal between the Saturation limits of each inductor lying in the circuit must be applied. A prerequisite for the correct operation of the amplifier is that the magnetizing current in the windings 15 (16) is greater than in the windings 9 (10).

The location of the end link according to FIG. 3, III can also be a link according to Fig. 2 take. The circuit explained using the single-phase example can also be used can be used accordingly in multi-phase systems.

Claims (7)

PATENT CLAIMS: 1. Magnetic amplifier with series-connected pre-magnetizable chokes and valves of the self-saturation type, characterized in that its working circuits are different from others via the choke windings. magnetically coupled. Control and working circuits are decoupled in that there are counter voltages in the circuits in which the working windings are in series with the valves. are introduced into the voltages that are induced into these circuits from one or more of the other circuits of the amplifier and thus could cause equalizing currents in them. 2. Amplifier according to claim 1, characterized in that in those provided with valves (13) Circuits (II) counter voltages (12) are introduced, which prevent the flow of currents prevent induced voltages, with the infiltrated counter-voltages (12) are opposite to the flow direction of the valves (13). 3. Amplifier according to claims 1 and 2, characterized in that the working part (II) of the Doubler circuit formed according to FIG. 2 and together with a control part (I) according to Fig. 1 or Fig. 3 is interconnected. 4. Amplifier after the. Claims 1 and 2, characterized in that two or more amplifiers are used as input and follower amplifiers are connected together. 5. Amplifier according to claim 4, characterized characterized in that in each case one working winding (9, 10) of the preamplifier chokes (7, 8) and a control winding (15, 16) of the downstream amplifier chokes (17, 18 - II) lie in the same current path and that there is a valve in this current path (13.1, 13.2) for the assignment of the positive or negative half-waves of the supply voltage (11) on the associated inductor windings. provided by preamp and follow-up amplifier is. 6. Amplifier according to claim 5, characterized in that in each so formed Circle a counter voltage (12) to decouple the control and work windings is infiltrated. 7. Amplifier after the. Claims 1 and 2, characterized in that that the arrangement can be a single-phase or multi-phase circuit. B. Amplifier according to claims 1 and 2, characterized in that the sum of the introduced Voltages (12) and the auxiliary alternating voltages (11) during the working current-free Half-wave (idle cycle) is at least as large as the sum of the induced voltages .. 9. Amplifier according to claims 1 and 2, characterized in that that the difference between the voltage pulses taken over a half period (voltage time sums) of introduced voltage and auxiliary alternating voltage during the working current carrying Half-wave (work cycle) is as large as the voltage pulse that causes the magnetization to be reversed between the saturation limits of each inductor in the circuits for the relevant winding is required. Publications Considered: »Electrical Engineering ", 1953, November, p. 973.