DE1056711B - Magnetic amplifier formed from chokes with reset circuit for a controlling voltage time area - Google Patents

Description

GERMAN

PATENT OFFICE

kl. 21 c 67/70

INTERNATIONAL KL.

H-02j ^ G05f

REGISTRATION DAY:

B 27697 Vinb / 21 c

September 30, 1953

NOTICE THE REGISTRATION AND ISSUE OF THE

May 6, 19 5 9

In the case of magnetic amplifiers formed from chokes with a reset circuit for a controlling voltage-time area, so-called return flow or self-desaturating magnet amplifiers, is a division of the two half-cycles of the feeding AC voltage in one control and working half-cycle. It Circuits of such magnetic amplifiers are already known in which a choke is provided for each phase which contains the feeding AC voltage both in the working and in the control circuit and which in each case in one, the control half-period by a voltage-time area of the magnetic flux to a controllable Amount is demagnetized. In the following, the working half-period must then first the same The voltage-time area of the magnetic flux is used to re-magnetize the choke, before it is saturated and the supply voltage can take full effect on the load. The consequence one of which is that a controllable load current occurs only during one of the working half-cycles.

Magnetic amplifier circuits have become known in which a pair of chokes is connected upstream Valves is fed from an alternating current network and in which the obtained through the valves Self-saturation can be reduced by connecting variable resistors in parallel with the valves will. These circuits have the disadvantage that only resistors and none in the control circuit Control voltages can be used as the magnetization and demagnetization of the core in each Period caused by the same alternating voltage. In other known circuits, the and demagnetization of different power sources done in separate windings. she require a great deal of effort, especially on auxiliary valves, and are also not immediately open multi-phase operation applicable.

The invention relates to one of chokes with a reset circuit for a controlling voltage-time area formed magnetic amplifier with two anti-parallel via valve lines and on one common burden working chokes, in which a load current during both half-waves of the feeding AC voltage occurs and, according to the invention, the chokes from a common control member are controlled with valve-related decoupling of the control and working circuit.

In a multiphase throttle valve arrangement, a common control element and two valve sections bridged by this and located in the common branch of the control circuits and two throttles with the other associated valve sections for each phase are provided for all phases. A voltage gain can be achieved by reducing the ratio of chokes with reset circuit
for a controlling stress-time area
educated magnetic amplifier

Applicant:
Brown, Boveri & Cie. Aktiengesellschaft, Mannheim-Käfertal, Boveristr. 22nd

Dr. rer. nat. Max Syrbe, Mannheim-Wallstadt,
has been named as the inventor

nisses between control and working windings of the throttles can be achieved. Furthermore, the two Chokes are either in series with a feedback coil acting alternately on the other choke coil or by a common one with A feedback winding connected to a rectifier arrangement can be influenced. The two throttles can also be controlled by at least one preamplifier, for which also two in the sense of the Throttle valve arrangement according to the invention of the power amplifier switched chokes can be used. Highly permeable material is expediently used for the throttle. To reduce the dead time and the consumption of active material, the working frequency can also be increased.

For the common control element of the throttle valve arrangement according to the invention, a variable Resistor, an electron tube, a transistor or the final stage of a transistor amplifier, a photocell or a semiconductor that is generated by magnetic or electric fields, light, heat or mechanical forces are influenced in its conductivity, or an equal and or or AC voltage source, which is generated directly or with the aid of a resistor that forms a voltage drop performs the control, serve.

By the inventive throttle valve circuit of the return solenoid amplifier, which is through the Utilization of the two half-waves of the feeding alternating voltage at its output alternating current leads, the advantage is achieved that now the output voltage of the magnetic amplifier can be transformed. So are in theirs. Resistance of different consumers is the same

909 5097348

Better to adapt the power requirement to a specific magnetic amplifier. At the same time there will be an improvement of the power factor of the power consumed as well as the efficiency achieved by its The reason for this is a lower stress on the axial valve sections in the blocking direction, so that this can be equipped with a fraction of the normally required number of plates.

In the drawing, several embodiments of the invention are shown in Figs. 1 to 6.

The circuit arrangement shown in Fig. 1 of a return magnet amplifier with AC output contains two chokes 1, 2, each having only one winding, a load resistor 3, a control element 4 and valve sections 5 to 10. Here, the valve sections 5 to 10 are switched into the circuits so that the working group for the choke 1 from the line conductor R via the choke 1, the valve line 5, the load resistor 3 to the line line S ₁ the working group for the choke 2 from the line line R via the choke 2, the valve line 6, the load resistor 3 to the line line S. , the control circuit for the throttle 1 from the line conductor R via the throttle 1, the valve section 7, the control resistor 4, the valve section 9 to the line conductor 5 "and the control circuit for the throttle 2 from the line conductor R via the throttle 2, the valve line 8, the Control resistor 4, the valve section 10 leads to the line conductor vS " .

In the first half cycle of the feeding AC voltage flows through the working circuit R, 1, 5, 3, 5 of the choke 1, the positive half cycle of the working current. At the same time standing on remanence reactor 2 flows degaussing current in the control circuit R, 2, 8, 4, 10, 5 ". In this case, each turns to the position of the control resistor 4, the voltage-time area of the supply voltage to the control resistor 4 and the throttle 2. The voltage drop of the control resistor 4 lies in the blocking direction at the valve path 9.

During the second half cycle of the supply voltage, the negative half cycle of the working current flows in the working circuit R, 2, 6, 3, 6 * via the demagnetized choke 2 controlled in the first half cycle. In the control circuit R, 1, 7, 4, 9 of the choke 1 , the demagnetizing current now flows, which applies the controlling voltage-time area to the choke 1. The voltage or the voltage drop of the control element 4 is now located in the blocking direction on the valve section 10.

From the circuit arrangement described and its mode of operation it can be seen that for the load current both half-periods of the feeding AC voltage can be made usable. The inventive Return magnet amplifier therefore carries an alternating current at its output, from which the result mentioned advantages.

The return solenoid amplifier with AC output can also be implemented in multiple phases. In Fig. 2, such a multi-phase throttle valve arrangement is shown. Two throttles with a valve group are provided for each phase, of which throttles 11, 21 and valve group 51, 61, 71, 81 in phase R and throttles 12, 22 and valve group 52, in phase S. 62, 72, 82 and in phase T the chokes 13, 23 6; and the valve group 53, 63, 73, 83 are located. A common control element 4, in the present case an electron tube, which is bridged by the valve sections 9, 10 , is provided for all phases. The output circuits of the throttle valve assembly each

Phase are connected to an output transformer 30, 31, 32 , the circuit of this transformer being shown in more detail in FIG.

If the magnetic return amplifier according to the invention is used for the regulation of electrical, thermal or mechanical quantities, then in general a pure power amplification is not sufficient. In most cases it is therefore necessary to combine the power amplification with a suitable voltage amplification. Such a voltage gain can be achieved by reducing the ratio between control and working windings, since the auxiliary AC voltage in the control circuit also decreases in the same ratio and thus also the voltage time integral required for full control, ie the desired voltage gain occurs. Switching arrangements of magnetic amplifiers with a throttle valve arrangement and a voltage gain are shown in Figs. 3, 4 and 6. In the arrangement according to FIG. 3, the chokes 1, 2 are provided with taps 14 , 15 for voltage amplification, which lead to a tap 16 of the secondary winding 17 of the input transformer 18 .

The magnetic amplifier can also have a feedback arrangement which is then used if a high-quality magnetic material is not used for the chokes. Through the Introduction of such a feedback, which the remanence point apparently on the magnetization curve Relocated to the area of greater saturation, the undesirable voltage drop across the chokes can be reduced when the magnetic amplifier is activated.

The feedback arrangement shown in Fig. 3 has two feedback coils 19, 20 which are alternately in series with the chokes 1, 2 , i.e. the feedback coil 19 with the choke 2 and the feedback coil 20 with the choke 1. The switching of the valve sections 5 to 10 basically corresponds to that of Fig. 1.

In the switching arrangement according to Fig. 4, the two chokes 1, 2 are influenced by a common feedback winding 33 , which is connected on the one hand directly and on the other hand via the load resistor 3 to a rectifier arrangement 34 in a bridge circuit. The rectifier arrangement 34 is connected to the secondary winding 35 of the output transformer 36 , the primary winding 37 of which is in the working circuit of the choke 1, 2 . It is so here that the load resistor 3 is transformer-coupled to the chokes 1, 2 , the circuit of the load resistor 3 carrying direct current through the interposition of the rectifier 34 in this case.

Furthermore, the throttle amplifier arrangement according to the invention can also have an alternating current output be designed as a cascade amplifier. Two embodiments of such a cascade amplifier are shown in Figs. 5 and 6. This is also done simultaneously by a feedback circuit and a voltage amplification according to Fig. 3 is made use of.

In the case of the cascade amplifier according to FIG. 5, a known preamplifier with control coils 26, 27 and working coils 28, 29 is used. The circuit of the power amplifier corresponds to that according to Fig. 3. According to Fig. 6, a throttle-valve arrangement according to the invention, consisting of the throttles 1a, 2a and the valves 7a to IOa), is also used for the preamplifier. A tension amplification of this case

Claims (10)

Chain amplifier is achieved in that taps 14a, 15a of the chokes la, 2a of the preliminary stage are connected to a tap 16a of the input transformer and taps 14,15 of the chokes 1, 2 of the output stage with a tap 16 of the input transformer 17. P.A Γ K N'T AN'Sl'ROCHE: 1. Magnetic amplifier formed from chokes with a reset circuit for a controlling voltage-time area with two throttles connected in antiparallel via valve sections and working on a common burden, with a load current occurs during both half-waves of the feeding AC voltage, characterized in that the Throttles from a common control element with valve-related decoupling of control and Working group are controlled. 2. Magnetic amplifier with a multiphase choke arrangement according to claim 1, characterized in that that a common control unit and two bridged by this for all phases, in the common branch of the control circuits and two throttles for each phase are provided with the other associated valve sections. 3. Magnetic amplifier according to claim 1, characterized in that a voltage gain achieved by reducing the ratio between control and working windings of the throttles will. 4. Magnetic amplifier according to claim 1, characterized in that the two chokes each with a feedback coil acting alternately on the other choke coil are in series. 5. Magnetic amplifier according to claim 1, characterized in that the two chokes of one common feedback winding connected to a rectifier arrangement will. 6. Magnetic amplifier according to claim 1, characterized in that the two chokes of at least one preamplifier can be controlled. 7. Magnetic amplifier according to claim 6, characterized in that also for the preamplifier two chokes connected in the sense of the throttle valve arrangement of the power amplifier are used will. 8. Magnetic amplifier according to claim 1, characterized in that in order to reduce the Dead time and the amount of active material the work frequency is increased. 9. Magnetic amplifier according to claim 1, characterized in that a variable for the control member Resistor, an electron tube, a transistor or the final stage of a transistor amplifier, a photocell or a semiconductor that is generated by magnetic or electric fields, Light, heat or mechanical forces are influenced in its conductivity, is used. 10. Magnetic amplifier according to claim 1, characterized in that one for the control member Direct and / or alternating voltage source is used directly or with the help of a Voltage drop forming resistor performs the control. _ Considered publications:
U.S. Patent No. 2,036,708;
Elektrotechnik, 3 (1949), p. 135 ff. (Fig. 9);
Transactions AJEE (1951), pp. 1214ff., 2124ff. 1 sheet of drawings ® 90 »509048 4.59