DE1134714B - Self-excited magnetic amplifier - Google Patents

Description

The invention relates to a self-excited magnetic amplifier, the excitation of which by one in a Bias winding flowing, changeable alternating current is controlled.

The most important properties of a self-excited magnetic amplifier (transducer) with alternating current bias should be briefly recalled in the following. Fig. 1 shows one such Transducer. The working windings 1 and 2 are provided with rectifiers 3 and 4, which to to serve one's self-excitement. The load resistance 5 is different from that of the secondary winding 9 of the supply transformer 10 coming working alternating current flowed through. The windings 6 and 7 for the premagnetization are connected in series, d. H. that the in these turns by changing the Flux generated by the working windings (when rectifiers 3 and 4 are short-circuited are), induced voltages are in phase and add up. The alternating voltage of the secondary winding 8 of the supply transformer 10 is applied to the bias tracks 6 and 7. So that the Alternating bias currents flow and generate the demagnetization effect in the transducer core the voltage applied to the control windings must compensate the voltage, which is induced in these windings by the change in the flux generated by the working windings will. The change in this current can be achieved in two different ways:

1. By varying the AC voltage of the secondary winding 8 (for example by means of a variable autotransformer), or

2. by changing the series-connected resistor 11 in the bias circuit.

The great advantage of a self-excited transducer with alternating current bias is his quick response. Since an alternating voltage is used for the premagnetization, changed its current immediately becomes its value. It results from the fact that the response time of such a transductor is smaller than the period of the AC voltage. However, to control such a transducer, Until now a mechanical organ was needed which allows the resistance 11 to be changed or the To change the voltage of the secondary winding of the transformer 10. The disadvantages caused by this mechanical control organ, for example its inertia, are obvious.

Magnetic amplifiers are also known in which the excitation is carried out by a bias winding flowing current takes place, the self-excited magnetic amplifier

Applicant:

Societe Anonyme des Ateliers de Secheron, Geneva (Switzerland)

Representative: Dipl.-Ing. H. Görtz, patent attorney,
Frankfurt / M., Schneckenhofstr. 27

Claimed priority:
Switzerland of April 17, 1959 (No. 72 173)

Louis Maret and Alain Wavre, Geneva (Switzerland), have been named as inventors

is changeable. This change in the current took place in a known manner, for example mechanically variable resistances, which naturally only respond relatively slowly. this is also valid for the known magnetic amplifiers, especially for variable speed drives, in which one is used to influence the degree of amplification variable pre-magnetization designed as controllable self-magnetization is.

In the magnetic amplifier according to the invention, the disadvantages mentioned are avoided in that in the bias circuit, through which an external current flows, a full-wave rectifier bridge (Graetz circuit) is switched on with both of its AC terminals and on both of them DC terminals a polarized static resistance element, ζ. Β. a transistor, connected is, whose ohmic resistance is on the rectifier side as a function of an applied electrical Voltage or current changes.

According to the invention, the premagnetization current is fed in from an external source, which is for example has the advantage that, by means of relatively small currents, large powers are carried out without delay mechanically induced inertia can be controlled.

The drawing shows two exemplary embodiments of the amplifiers according to the invention and one embodiment an application of this device explained.

As already mentioned, Fig. 1 shows an electrical diagram to illustrate the most important properties

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shanks of a self-exciting transductor AC bias;

2 shows a diagram of a first embodiment of the amplifier according to the invention;

3 shows a diagram of a second embodiment of the amplifier according to the invention;

Fig. 4 is an explanatory diagram;

FIGS. 5, 6 and 7 show schemes which are intended to explain certain advantages of the device;

8 shows a circuit diagram of a voltage regulating device of an alternating current machine, that is to say an example of the use of the device;

Fig. 9 shows a third embodiment of the device.

The example shown in FIG. 2 differs from the known device shown in FIG with respect to the bias circuit, the other elements are the same. The shown in Fig. 1, variable resistor 11 is made up of a rectifier bridge 12 and a static resistance element 13, its apparent resistance as a function of an electrical quantity applied to it is variable. This element 13 is a transistor here. This can actually be seen as an apparent resistance be considered whose value changes by acting on the voltage-base-emitter can be. This apparent resistance changes in a rough approximation inversely proportional to Base current of the transistor. The energy required to control the base current is much less than the alternating current energy for biasing, whereby considerable gain can be obtained. Incidentally, it is clear that the use of the static elements 12 and 13 eliminates the above-mentioned disadvantage of known devices.

In the exemplary embodiment shown in FIG. 3, the general disposition is generally the same as in Fig. 2; the difference is in the bias circuit. A fixed resistor 14 is in series with the rectifier bridge in this circuit and transistor existing arrangement connected, which is connected in parallel to the bias winding is. This must have a much greater resistance than the minimum apparent resistance Resistance of the arrangement consisting of the rectifier bridge and transistor is. If those Arrangement has a minimal apparent resistance, it closes the bias winding almost entirely short, and the alternating current flowing in it is minimal. If this arrangement has a maximum resistance is the alternating current flowing in the bias coil flows, maximum. The resistance is increasing more or less away from the control AC voltage, depending on the resistance of the rectifier bridge and transistor existing arrangement is small or large.

Fig. 4 shows the static characteristics of a self-excited transducer, ie the mean voltage U _s across the load resistor 5 as a function of the alternating bias current i _c , the change in this current in one of the two known ways described above or by that shown in FIGS Arrangement is obtained.

The devices described make it possible to manufacture magnetic amplifiers with self-excitation, which have the following advantages:

1. Great reinforcement,

2. response time below the period duration,

3. Control with DC voltage or rectified AC voltage.

These devices also allow a simplified Construction and thus a reduction in cost.

In fact, the response time is less than that

ίο Period, regardless of how the resistance of the bias circuit is large. The resistance of the bias circuit has a very low value while the transducer is completely demagnetized (the current in the Work coils is then minimal). Under these conditions, the tension necessary to generate the Allow current to flow in the bias circuit, low, and the number of turns for the Control winding can be kept small in relation to the number of turns in one Transductor with direct current control would be necessary. In most cases the winding can be done with a insulated wire can be made by hand as only a few turns are required. The construction is thus simplified and the manufacturing cost is reduced. This advantage appears especially when when the static element is formed by a transistor and a rectifier bridge. Instead of a transistor could, for example, also be an electron tube or a controlled rectifier use.

The manufacturing costs are initially due to the simplicity of the construction of the control winding reduced. Then it is no longer necessary when you get a rectified working current desires to provide six rectifying elements as in the DC control. In fact it is Indispensable for direct current control, provided that the load resistance is inductive, that from transductor rectifier and load resistor existing arrangement, as shown in Fig. 5, to switch in order to "hang up" of the transducer (or at least a strong change in slope) in the lower part of the static To prevent transductor characteristics (Fig. 4). If alternating current is used for control, this effect does not occur, and it is sufficient even if the load resistance is inductive, the arrangement, consisting of transducer rectifier and load resistor, to be switched according to Fig. 6, which only requires four rectifier elements, or as shown in FIG. 7, if one uses a transformer whose secondary winding has a tapping point in the middle. This latter solution only requires two rectifier elements. Since thus the number of load rectifiers, which is very expensive can be reduced, the cost is also greatly reduced.

With reference to FIG. 8, an application example of the described devices is shown below Regarding the voltage regulation of an AC synchronous machine described.

The voltage to be regulated from the alternator 20 is applied to a transformer 21. With this voltage, after it has been rectified in a low-pass filter 22 and filtered is fed to a measuring bridge 23, which consists of linear elements and a non-linear element 24. The output size of this bridge, the one

DC voltage controls the base current of transistor 25. This base current affects how described above, the size of the apparent resistance of the transistor. This change in the apparent resistance in the bias circuit 26 of the transducer 27 allows the change the alternating control current and, as a result, the voltage applied to the load resistor of the transducer, d. H. the impedance of the induction poles 28 of the excitation machine 29. This excitation machine delivers the excitation energy for the inductors 30 of the alternator 20. The energy to operate of the regulator is taken from the AC machine or an auxiliary network by means of the transformer 31. The non-linear element 32 (for example a Zener diode) protects the transistor against overvoltages between the base and the emitter, and the temperature effect that creates the apparent Resistance of the transistor is affected, is compensated by the temperature effect, which affects the nonlinear element 24. It is sufficient, for example, if a Zener diode is used, the temperature coefficient to be chosen so that it the Compensated for the temperature effect on the collector current of the transistor. The stabilization circuit of the control circuit (consisting of the regulator, the exciter and the AC machine) is a differential appealing circle, which is formed by the elements 33, 34 and 35 that allow the Adjust the time constant of the stabilization circle and the reaction ratio.

The response time of such a regulator is shorter than the period if you consider the time constant of the low-pass filter are taken into account.

If you need to regulate the voltage of a DC machine, you use a regulator which only has the arrangement 36, the arrangement 22 is superfluous. Feeding the The control device at 31 would then of course take place from an auxiliary network with alternating current.

The device shown in Fig. 8 could also be used for the speed regulation of a rotating electrical machine, for example a motor or generator, can be used. This could be like take place as follows:

The arrangement 22 would serve to measure the speed to be regulated, and the arrangement 36 would then form the control device. Element 28 would then go through the inductors a motor or a generator or formed by the armature of a motor.

In the example shown in FIG. 9, the static element comprises a voltage generator, which is represented by the rectifier bridge 15 and a fixed resistor 16 to which the the Device controlling DC voltage is applied. The voltage supplied by the rectifier bridge 15 adds to that supplied by the rectifier bridge 12 such that im Resistor 16 in the absence of the control voltage a sufficiently large current flows to the in the resistor 5 to block flowing load current. If a DC control voltage is applied to resistor 16

voltage sets whose polarity is opposite to the voltages to be generated by the rectifiers 15 and 12 is, the current flowing in the bias circuit of the transducer is reduced, and the Load current increases. The combination of the rectifier bridge 15 with the resistor 16 to which applying the control voltage thus allows the apparent resistance of the bias circuit to change. This combination thus forms a static element 37 with an apparent resistance, which can be varied as a function of an applied electrical quantity.

Instead of the direct current generator 15, an alternating current generator could also be used.

Claims (5)

PATENT CLAIMS: 1. Self-excited magnetic amplifier, the excitation of which is controlled by a variable alternating current flowing in a bias winding, characterized in that a full-wave rectifier bridge (Graetz circuit) with its two alternating current terminals is switched on in the bias circuit through which an external current flows a polarized static resistance element, e.g. B. a transistor is connected, the ohmic resistance of which changes on the rectifier side as a function of an applied electrical voltage or a current. 2. Apparatus according to claim 1, characterized in that the AC terminals of the Rectifier bridge are connected in series with the bias winding. 3. Apparatus according to claim 1, characterized in that the control circuit of the magnetic amplifier a fixed resistor connected in series with the bias winding and the bias winding in parallel with the AC terminals of the Rectifier bridge is connected. 4. Apparatus according to claim 1, characterized in that said static element a DC or AC voltage generator in series with a fixed Resistance is connected to which the control voltage is applied. 5. Use of the device according to claim 1 for controlling a rotating electrical Machine. Considered publications:
German Auslegeschrift No. 1 046 107,
699; German patent application S 25 333 VIII a / 21a ² , 18/08 (published on October 23, 1952); Electronics magazine, August 1953, pp. 136 to 140; Book: W. A. Geyger, »Magneticamplifier Cirfio cuits ”, New York-Toronto-London, 1954, p. 165. Legacy Patents Considered:
German Patent No. 1100 701. 1 sheet of drawings