DE1064109B - Arrangement for controlling the reverse magnetization of voltage-time-area controlled magnetic main amplifiers - Google Patents

Description

GERMAN

The invention relates to an arrangement for controlling the back magnetization of voltage-time-area-controlled Magnetic main amplifier by means of flow-controlled magnetic amplifiers. The control of voltage level controlled magnetic amplifiers is known to be carried out by Influence of the back magnetization in each blocking half-wave of the feeding alternating current. as The easiest way to use the reverse magnetization voltage is to use the alternating feed voltage itself and to influence it the voltage area of the back magnetization through a resistor or through one of the blocking half-waves opposing adjustable DC voltage. If this DC voltage is zero, the Back magnetization fully develop in each blocking half-wave, and the magnetic amplifier only takes its magnetizing current, d. i.e. it is blocked. If this DC voltage is equal to the peak value of the Back magnetization alternating voltage, so no back magnetization current can flow, and the transductor remains saturated, d. i.e., it is open.

When using the voltage-time area-controlled magnetic amplifier in control loops A difficulty often arises because the system deviation is obtained as the difference between two currents will. They can easily be used as a preamplifier in a flow-controlled magnetic amplifier form an increased control deviation, as rectified alternating current or as rectified AC voltage is available. However, this DC voltage is not readily suitable as controlling counter-voltage for the reverse magnetization of operated in voltage-time area control magnetic main amplifiers, since the rectifiers do not allow any reverse magnetization current to flow. Man therefore uses couplings by means of diodes, with the back-magnetized half-wave voltage of the diodes is blocked as long as the latter are not biased with direct current control. With growing Control direct current in the reverse direction opens them and thus allows reverse magnetization.

The invention now shows a way that allows flow-controlled magnetic amplifiers with DC output to be used directly to control the half-wave reverse magnetization voltage.

This arrangement for controlling the back magnetization of voltage-time-area controlled magnetic Main amplifier by means of flooding controlled magnetic amplifier according to the invention is thereby characterized in that the rectified output voltage of the rectifier bridge circuit flow-controlled magnetic preamplifier via a circuit that is connected to the reverse magnetization circuit Arrangement for control

the reverse magnetization

time area controlled

magnetic main amplifier

Applicant:

LICENTIA Patent-Verwaltungs - G. mbH, Hamburg 36 _r Hohe Bleichen 22

Dr.-Ing. Alfred Lang, Eßlingen / Neckar,

and Dipl.-Ing. Peter Kratz,

Endersbaca (Kr. Maintenance, Württ),

have been named as inventors

Coupling member, e.g. B. an ohmic resistor is fed.

Difficulties that arise when. itself, can not completely block the magnetic pre-amplifier can be avoided by the fact that the return magnetization voltage of the main amplifier urn, the residual stress of the locked \ ^r orverstärkers is greater.

According to a further development of the inventive concept, the control process can be accelerated if the coupling member is connected in a bridge diagonal of a resistance bridge circuit shown in two opposite bridge branches inductivities and in the other bridge branches Contains ohmic resistances, and at the other bridge diagonals the output voltage of the preamplifier lies. The ohmic resistances of the inductances are expediently greater than that Resistance values of the ohmic resistances.

The invention will be explained in more detail with reference to some embodiments shown in the drawings :

In the exemplary embodiment according to FIG. 1, the load 1 is fed via the magnetic main amplifier 2. Its transductor chokes 3 and 4 are connected to the secondary winding of the transformer 5, at the terminals 6 of which the feeding AC voltage is applied. The transductor chokes are with the load to be fed and the AC voltage source via the rectifier 7 to 10 in a known manner Way connected in such a way that self-saturation of the transductor cores takes place and across the load a direct current flows. The control of the magnetization

909 609/309

Claims (4)

3 4 tion of the transductor chokes takes place in a known, known manner, the coupling resistor 24 Way through a reverse magnetization in the time lies. Intervals in which the rectifier 7 or 8 prevents an increase in the rapidity of the upward and downward flow of a working current half-wave through the excitation of the magnetic main amplifier, so that when the coupling of the preamplifier is connected to the voltage time area control. The controlling input to the coupling resistor 24 via a voltage time area is carried out according to the invention by the resistance bridge circuit, which is applied in two flow-controlled preamplifiers with self-opposing bridge branches inductance saturation 11, which is connected via terminals 12 and in the other two bridge branches ohmic and 13 to one AC voltage is applied. The transistor contains resistors, whereby the ohmic resistances duct chokes 14 and 15 are in series with those of the inductances must be greater than the resistor saturation rectifiers 16 and 17 and the full-path resistance values of the ohmic resistors themselves,
rectifier 19, so that at the terminals 20 and 21 FIGS. 3 and 4 show two exemplary embodiments, a direct voltage occurs, the magnitude of which arises from a resistance bridge circuit of this type. The change in the control flow in the control winding 15 terminals 20 and 21 of these resistance bridge soundings 22 and 23 can be adjusted. The DC voltage that occurs at the lines is connected to the output terminals of the magnetic preamplifier 11 via the coupling resistor 24 in a bridge. The terminals 34 and 35 are inserted into the diagonal of the rectifier bridge circuit consisting of the rectifiers 25 to 28, which are numbered in the same way as the terminals 34 and 35 of FIG. 1, to be connected. The resistor 24 according to FIG. 1 is located. This rectifier bridge circuit contains the transductor chokes 3 and 4 and diagonals of the rectifier bridge circuit in two of the circuits according to FIGS the ohmic output of the transformer 5 is performed. The rectifier resistors 39 and 36 and the inductive resistor in the branches of the rectifier bridge circuit, which consists of 25 stands 37 and 38. contain the transductor chokes and thus the In the steady state, in which the bridge slide back magnetization paths form, are chosen so that a DC voltage across the resistor 24 in the ohmic resistance division of 39 and 37 for each back magnetization shown polarity follows, so there is a positive at point A and a half-wave of the transductor chokes 3 and 4 as a counterpart to point B a negative voltage of such magnitude, voltage acts. The reverse magnetization direction is that, for. B. the reverse magnetization half waves are fully shown by the dashed arrows that are Aufmagneti- blocked. When the preamplifier 11 is switched on, the direction of sizing is shown by the solid arrows next to or when this Vorden transductor chokes are suddenly raised. Amplifier is due to the inductive Wirist the preamplifier 11 with the help of a negative 35 kung van 37 and 38 temporarily a substantially control current difference flow in the control winding higher counter-voltage at the resistor 24, so that the lungs 22 and 23 blocked, so is the resistor 24 reverse magnetization of the The main amplifier adopts a relatively small reverse voltage more quickly, and stops, and thus the main amplifier opens up the reverse magnetization of the transductor chokes 3 more quickly. When the preamplifier and the main amplifier are turned down, the accelerating effect in the blocking wave can take place in full in each blocking half, so that the main amplifier is in the same direction. if blocked. In order to achieve this full blocking also with the not completely blocked preamplifier indicated by the arrows in FIG - 45 or blocking the preamplifier hurt to flow, which is charged. The reverse magnetization current flows through the voltage at the resistor 24 while rotating past the rectifier 14 via the resistor, that is, the potential of point B before -24 to the transductor chokes 3 and 4 becomes positive, the reverse magnetization span-the preamplifier is fully opened a voltage is supported, and the main amplifier blocks positive flow difference in the control winding 50 as quickly as possible. With the decay of the current loses 22 and 23, its output voltage at this accelerating voltage disappears.
Resistance 24 at least equal to the peak voltage. FIG. 5 shows the course of the back magnetization half-waves supplied by the preamplifier, so that no control chip back magnetization current can flow with the aid of the resistor brackets. The transmission U _s at the coupling resistor 24 when the duct chokes 3 and 4 are opened are then 55 and blocks in each half cycle. At the moment t ₀ the pre-saturated opens and the main amplifier remains fully open, at the time t ₁ the control voltage U _{s is} on the net. Intermediate values of the output voltage of the pre-amplifier to maintain the locked state result in intermediate values of the output required value decayed. At the moment f ₂ current of the main amplifier, ie the voltage power of the preamplifier closes, whereby the control time area-controlled main amplifier can be temporarily reversed from 50 voltage and the blocking of the zero to nominal current continuously controlled. Main amplifier supported. A modified circuit with regard to the _D
Fig. 2 shows the coupling of the preamplifier.
This Fig. Are the switching elements that are already in the 1st arrangement for controlling the Rückmagneti-Fig. 1, provided with the same reference 6gization of voltage-time area-controlled magnetic characters. In this exemplary embodiment of the main amplifiers by means of flooding, the working windings 15 and 14 of the precontrolled magnetic amplifier, characterized in that the amplifier 11 is in two branches, is characterized by the fact that the rectifier bridge bridge circuit formed in a rectifier bridge circuit 30 to 33 rectifies the output chip circuit, in one of the bridge diagonals in an 7 ° opening of the flow-controlled magnetic Preamplifier via a coupling element connected to the reverse magnetization circuit, e.g. B. an ohmic resistor. 2. Arrangement according to claim 1, characterized in that the reverse magnetization voltage of the main amplifier is greater by the residual voltage of the blocked preamplifier. 3. Arrangement according to claims 1 and 2, characterized in that the coupling member is connected in a bridge diagonal of a resistance bridge circuit, which is in two each other opposite bridge branches inductances and in the other bridge branches Contains ohmic resistances, and at the other bridge diagonals the output voltage of the preamplifier. 4. Arrangement according to claim 3, characterized in that that the ohmic resistance of the inductors is greater than the resistance the ohmic resistances are. 1 sheet of drawings © 909 609/309 8.59