DE1026362B - Magnetic amplifier in self-draining circuit - Google Patents

Description

Magnetic amplifier in self-saturation circuit The invention relates on magnetic amplifier in self-saturation circuit with a magnetization by an auxiliary alternating voltage that has the same frequency as the alternating supply voltage having. The term self-saturation circuit is to be understood as meaning an arrangement in which a valve is connected in series with the load winding of the magnetic amplifier, so that the load current caused by the valve direction acts in the same sense Magnetization is generated like the control winding. The load winding thus supports automatically the control process, so that a particular advantage of this type of circuit shows that significantly less control energy than others not in self-saturation circuit executed magnetic amplifiers is required.

The invention has set itself the task of providing the required control energy or the time constant of a magnetic amplifier, which is related to the control energy stands to lower it even further. A magnetic amplifier according to the invention is characterized by an alternating supply voltage with a voltage pause in each half cycle, the auxiliary alternating voltage essentially taking part in this voltage pause that required for saturation, otherwise to be supplied by the alternating feed voltage Applying voltage time area, in such a way that the saturation time in the Period falls in which the alternating supply voltage is different from zero.

It is already known for magnetic amplifiers in self-saturation circuit by an auxiliary alternating voltage of the same frequency as the alternating supply voltage to reverse magnetize the iron cores in the respective blocking phase of the AC supply voltage. For this circuit the designation #, Rücklaufsteuerungcc has become known, the expresses that the reverse magnetization normally carried out by direct current is taken over by the auxiliary AC voltage.

It is also known in magnetic amplifiers to reduce the Load alternating current at the level of zero an alternating excitation of the basic excitation to overlay. In this way it is possible to control the current flowing in the load winding to be displaced, as it were, by the auxiliary current.

Finally, there has already been some suggestion for magnetic amplifiers with alternating current control the ratio of alternating excitation to self-excitation using one of the inductor current to change the same frequency control alternating current. So you can do the magnetization derive partly from the control alternating current and partly from the working alternating current, so that the working current is adjusted depending on the size of the alternating control current.

In contrast, the invention is based on the basic idea that the AC supply voltage of the magnetic amplifier has a voltage pause in each half cycle in which an auxiliary AC voltage completely covers the voltage-time area required for saturation or partially applies, while the auxiliary AC voltage itself in general has a voltage pause as long as the AC supply voltage is different from zero is. So it is not a question of magnetization with the auxiliary alternating voltage to repeal that was applied by the working current, and it should also not Displacement between auxiliary and working current can be achieved. On the contrary, it is supposed to the auxiliary AC voltage of the AC supply voltage is part of its job, the To magnetize core material to saturation, remove.

The magnetic amplifier according to the invention requires in the simplest case to control no special control winding fed with direct current; he can rather be controlled by the auxiliary AC voltage itself, either by changing the amplitude and / or the phase position of this voltage. That through the load winding applied voltage time integral is when controlled by the Auxiliary AC voltage is advantageously dimensioned in such a way that there is just no saturation occurs when the auxiliary AC voltage is zero. The auxiliary winding circuit is preferably constructed in the same way as the one on the load winding of the magnetic amplifier connected circuit. Is the load circuit of the magnetic amplifier for example executed in AC circuit, d. H. with one throttle and one valve each for each of the load current half-waves in different directions, the auxiliary circuit can also an auxiliary winding per choke coil and one connected in series with it Have valve. In the case of a direct current bridge circuit of the magnetic amplifier, the load circuit also in a DC bridge circuit educated will. However, the device according to the invention also works when the auxiliary circuit has a different design than the load circuit. The one in the auxiliary circuit lying working resistance can be of any type, e.g. B. an effective resistance. is If there is a reactance, a phase control of the Magnetic amplifier can be achieved. The magnetic amplifier according to the invention can also be equipped with a bias winding and controlled by this will.

In the drawing is a circuit example of the object of the invention shown. It shows Fig, l a magnetic amplifier in a direct current bridge circuit, FIG. 2 is a graphical representation for explanation in the case of alternating current control, FIG. Fig. 3 is an explanatory diagram in the case of DC control.

The magnetic amplifier according to Fig. 1 has two inductors 1 and 1 ', each one load winding 2 or 2 ', an auxiliary winding 3 or 3' and a bias winding 4 and 4 'respectively. The load circuit of the magnetic amplifier is more drawn out; it is connected to an alternating current network at R and S and contains the load windings 2 and 2 'a saturation throttle 12 to achieve the voltage pauses, four valves 5, 5 ', 6, 6' and the load 14. The auxiliary circuit is, for example, in the same It is structured like the load circuit and contains four auxiliary windings 3, 3 ' Valves 7, 7 ', 8, 8' and a working resistor 13. The auxiliary circuit is from the alternating current source 9 with an auxiliary voltage of the same periodicity as the load voltage fed. The voltage from a direct current source is used to control the magnetic amplifier 10, which are connected to the bias windings 4 and 4 'via a choke coil 11 are changed. The choke coils 1 and 1 'can be made of both special iron and be made of normal sheet iron. The working resistance 13 of the auxiliary circuit is relatively high resistance and dimensioned such that the in the auxiliary circuit consumed power with saturated choke is low.

The mode of operation of the circuit according to FIG. 1 with alternating current control by the auxiliary circuit will be explained with reference to FIG. For this purpose, the premagnetization circuit with the premagnetization windings 4 (FIG. 1) and 4 ', the direct voltage source 10 and the choke coil il should be thought away. The upper part of FIG. 2 shows, for an alternating current half-cycle, the voltage-time integrals which are reached at different voltages of the voltage source 9 (FIG. 1) and which act on the choke coils 1 or 1 '. The area between 0 and t1 is applied by the auxiliary winding 3 during the supply voltage break, the area from t 1 to 2 by the load winding. The time integral applied by the load winding is advantageously chosen to be so large that saturation just does not occur when the auxiliary AC voltage is equal to zero. For two different modulation states a and b, two different voltage-time integrals applied by the auxiliary windings are shown. While the left part of the illustration from 0 to 2 applies to the choke coil 1, the right part to 2T applies to the choke coil 1 '. The lower part of FIG. 2 shows the inductor current in the load winding z resulting in different levels a and b. With modulation a there is a current according to curve i ", with modulation b a current according to curve ib. According to the larger voltage time integral in case b, the choke coil has an earlier transition to saturation. This process triggers the vertical rise of the current curves and It is therefore also referred to as ignition. It takes place in curve i "at time t", in curve ib at time tb similar relationships.

Should the magnetic amplifier according to Fig. 1 instead of the auxiliary circuit and the auxiliary voltage from the current source 9 solely by a direct voltage the current source 10 can be controlled via the bias windings 4 and 4 ', so the voltage time integral applied by the auxiliary windings 3 and 3 ' permanently set and the phase position of the auxiliary voltage is advantageously dimensioned in such a way that that the voltage time integral applied by it and the load circuit, such as shown in the upper part of Fig. 3, connect to each other. The area I in the upper Part of Fig. 3 represents the voltage time integral applied by the load circuit, the area II that of the AC auxiliary circuit. The connection of the area II to the Area I can be determined, for example, by appropriately dimensioning the working resistance 13 can be achieved. To achieve that the magnetic amplifier at a control voltage Zero on the bias windings 4 and 4 'still shows no modulation and from then on a modulation that increases evenly with the size of the voltage, An additional DC bias, selected negatively in this way, can be provided that with the help of the load windings 2, 2 'and with the help of the auxiliary windings 3 and 3 'applied voltage-time integrals the magnetic amplifier is just unsaturated permit. There is now a certain control voltage on the premagnetization windings 4 and 4 'before, the saturation of the magnetic amplifier by one of the control voltage corresponding amount is reached earlier than after a half-wave has elapsed.

The middle part of FIG. 3 shows, as a function of time t, the current i through the load winding 2 for two differently large modulations a and b with the aid of the bias winding 4. With a modulation c, a current curve according to curve i "results with a greater one Modulation d - corresponding to the saturation achieved earlier - a current according to curve id. The maximum value of the current i is determined for a given load by the time line t2, which simultaneously represents the dividing line between the voltage surfaces I and II. The modulation range of the magnetic amplifier can be adjusted by moving the Time line t2 can be changed, in particular by changing the voltage on the auxiliary winding 3.

The flux changes d0 and 40d of the choke coil 1 required for the various modulations c and d can be seen in the lower part of FIG. The curve 00 represents the flux generated by the voltage areas of the auxiliary and load circuit. The levels c and d with direct current through the bias winding 3 correspond to the horizontal curves 0 "and 0, at the intersection of these curves with curve 0, at time t , or td, the choke coil 1 is ignited.

The magnetic amplifier according to the invention is required for full control in contrast to the known magnetic amplifiers in self-saturation circuit a much lower tax output. As is well known, it is aimed at saturation control power required for a magnetic amplifier in a self-saturation circuit according to the voltage time integral to be applied by the load circuit. Since this through the auxiliary winding is kept smaller than with the usual magnetic amplifiers in self-saturation circuit, the achievement of the advantage mentioned is explained just like that. Efforts will be made to achieve the output generated by the load circuit at zero output Voltage time integral in relation to the voltage time integral of the auxiliary circuit to make it as small as possible or one that takes into account other influences to give optimal '' value in order to get by with the lowest possible tax output. As already stated above, the magnetic amplifier according to the invention also offers the possibility of a control with alternating current, the control both can be done by the amount as well as by the phase position.

The magnetic amplifier according to the invention is not limited to that shown Embodiment limited. It can also be implemented in a multi-phase circuit his, also in other self-saturation circuits known per se. The auxiliary circuit can be connected to the same alternating current source in addition to a particular alternating current source be connected like the load circuit and can be one of the circuitry of the load circuit have different designs without any valves. It is further possible with the magnetic amplifier according to the invention both a control by the auxiliary winding 3, 3 'with alternating current as well as a control at the same time make the bias winding 4, 4 'with direct current and with the controls to bring various influences to effect. The auxiliary winding can also be used for Feedback can be used.

Claims (9)

PATENT CLAIMS: 1. Magnetic amplifier in self-saturation circuit with magnetization by an auxiliary alternating voltage of the same frequency as the Supply voltage, characterized by an alternating supply voltage with a voltage break in each half cycle, the auxiliary AC voltage being essentially in this voltage pause part of the saturation required, the rest of the AC supply voltage Applies to be delivered voltage-time area, in such a way that the saturation time falls in the period in which the AC supply voltage is different from zero. 2. Magnetic amplifier according to claim 1, characterized in that the load winding applied voltage time integral is dimensioned such that just no saturation occurs when the auxiliary AC voltage is zero. 3. Magnetic amplifier after Claim 1, characterized in that it has such a negative DC magnetization has that by means of the load winding and by means of a basic auxiliary voltage applied voltage-time integrals the magnetic amplifier is barely unsaturated permit. 4. Magnetic amplifier according to one of claims 1 to 3, characterized in that that for its control at the same time the auxiliary winding and the bias winding to serve. 5. Magnetic amplifier according to one of claims 1 to 4, characterized in that that the circuit of the auxiliary winding is high resistance. 6. Magnetic amplifier according to claim 1, 2 or 3, characterized in that its control by changing the amount the alternating voltage feeding the auxiliary winding takes place. 7. Magnetic amplifier after one of claims 1 to 4, characterized in that its control by changing the phase position of the alternating voltage feeding the auxiliary winding takes place. B. Magnetic amplifiers according to one of the claims up to 5, characterized in that the circuit connected to the auxiliary winding is also in self-saturation circuit, so z. B. in AC circuit or in DC bridge circuit is constructed. 9. Magnetic amplifier according to claim 7, characterized in that the working resistance of the auxiliary circuit a z. B. variable reactance is. Considered publications: German Patent Nos. 914864, 917128; U.S. Patent No. 2,465,451.