DE939519C - Circuit arrangement for regulating, in particular keeping a direct voltage constant - Google Patents

Description

Circuit arrangement for regulating, in particular keeping a constant DC voltage A voltage and current regulator is already under protection, in which in connection with an input and output circuit to which a load can be connected, a bridge circuit is provided in which an element is formed by an emission tube connected as a diode. To the filament a voltage is applied to this diode, which depends on the variable to be controlled, e.g. B. the Output voltage or output current, depends in a certain way. Will as a result a voltage fluctuation or a load disturbs the bridge equilibrium, this is done using suitable amplification or transmission means creates a tension that tries to restore the original state is.

The current regulator according to the older patent is for AC consumer circuits determined, but the bridge circuit itself is preferably charged with direct current and at the same time the one derived from the starting circle or from the variable to be regulated AC voltage is fed to the bridge circuit via a rectifier.

In contrast, the invention relates to a power circuit arrangement for regulating a direct current output which is derived from an alternating current input circuit is won.

By the arrangement according to the invention, the direct current output voltage kept constant within the limits of i o / o when the load or the AC input voltage, or both factors.

According to the invention, in a circuit arrangement for regulating a DC voltage that is taken from an AC voltage network via a rectifier, using a bridge circle as a control - in the A diode is connected to a bridge arm, the filament of which is connected to the DC voltage to be regulated lies. The output voltage of the bridge circuit is controlled by a tube amplifier Control means for influencing the feeding AC voltage in the control sense.

Further features of the invention emerge from the following Description with reference to the drawings, and specifically FIG. 1 shows a circuit arrangement an embodiment of the invention in which a full-wave selenium rectifier is used to convert an alternating voltage into a direct voltage, where the DC voltage, in turn, is the temperature of the tungsten filament of a diode determines what changes the inductance of a magnetic amplifier, which in turn influences the feeding AC voltage, so that changes in the DC voltage are equalized, Fig. 2, 3 and 4, joined together, a circuit arrangement of a modified embodiment of the invention, in which the control the output DC voltage through phase shift in a rectifier circuit is achieved with one or more ion tubes, while Figs. z, 3 and 5, also placed next to each other, the application of the arrangement according to the invention for keeping constant the output voltage of a radio frequency oscillator.

As can be seen from Fig. I, the bridge circuit consists of resistors io, ii and 12 and a tungsten filament diode 13. As mentioned earlier, is this diode together with the resistors io, i i and 12 the control element of the arrangement .: The input voltage to the bridge circuit becomes the secondary winding 14 of the transformer 15 taken, the primary winding 16 of which is in series with the winding 43 of an autotransformer 42 is connected to the AC input network 17 and i8. Parallel to the bridge arm that the Contains diode 13, a capacitor 77 is provided, which beats or other Prevents overlaps in the power transmission that is fed to it, to take effect in the output circuit of the bridge.

The transformer secondary winding 14 is connected to a rectifier tube 2o connected through a resistor 75 and a capacitor 76, while the DC output circuit this tube is connected to the input terminals 21 and 22 of the bridge io, 11, 12 and 13 is. To the opposite terminals 23 and 24 of the bridge circuit is the. Input circle an amplifier tube 25 is turned on. Tube 25 receives heating current from the secondary winding 26 of the transformer 27 is supplied, the primary winding 28 of which is directly connected to the network 17, 18 lies. Anode current is supplied to the tube 25 from the secondary winding 3o of the transformer 27 fed through the full wave rectifier 31, at the output circuit of which a capacitor 78 is turned on, via the lines 32; 33, 34, 35, the control winding 36 of the magnetic amplifier 37 and the line 38.

The magnetic amplifier 37 is provided with an alternating current winding 40, which is connected in series with the winding 41 of the autotransformer 42. transformer 15 is also provided with a secondary winding 44, which via the lines45 and 46 is connected to the input of a rectifier which consists of four selenium rectifiers 47, 48, 49 and 5o in a bridge circuit. The output of the rectifier is connected via lines 51 and 52 to output terminals 53 and 54, wherein the line 51 does not lead directly to the terminal 53, but via part of a Choke coil 55, which serves to filter out all harmonics that are in the output direct current could be present. The capacitor 56 is parallel to the output terminals, to increase the filter effect.

The filament of the diode 13 is via the lines 57 and 58, the variable Resistor 59, lines 6o and 61, variable resistor 62 and line 63 connected to the output 53, 54. In other words, the diode's filament 13 is parallel to the direct current output, the temperature of which is with changes in voltage in this output circuit.

The line 57 can also be at a point between the terminals of the Capacitors 56 and 81 are turned on.

From the above it follows that the basic working circle consists of the autotransformer 42 and the magnetic amplifier 37, the latter in Series with the primary winding of the autotransformer. The winding part 43 the autotransformer 42 is in series with the primary winding 16 of the transformer 15 switched. As a result, by changing the inductance of the magnetic amplifier 37 changed the voltage applied to the primary winding 41 of the autotransformer 42 lies, which also changes the voltage that the rectifier-transformer 15 is supplied. In this way, a decrease in the inductance of the Magnetic amplifier increases the input voltage of the primary winding 41 "what a Increase in the voltage at the output terminals 53, 54 result. It is reversed by an increase in the inductance of the amplifier 37, a decrease in the voltage causes at the terminals 53, 54.

To illustrate how the controller works, assume that an increase in output voltage due to a decrease in load or an input voltage increase or for both reasons. The increased The output voltage at the outputs 53, 54 has an additional heating of the filament of the diode 13, which causes a greater emission and the internal resistance the tube is reduced accordingly. Since the diode 13 has a Arm of the bridge circuit forms, this change in resistance has a change in the state of equilibrium the bridge, which is what the assumed example. the. Feeding one less = positive potential - to the control grid of the power amplifier tube 25 causes.

This grid voltage has a decrease in the anode current of the tube 25 and thus a lower saturation of the magnetic amplifier 37 result, which is in an increase in its AC resistance and a decrease in voltage affects the primary winding 16 of the transformer 15. This in turn causes a correspondingly reduced output voltage at terminals 53, 54.

A variable resistor 62 in the circuit of the diode filament serves to bring the input voltage to any point within the working range of the controller.

A potentiometer is used to compensate for changes in the input voltage. 59 provided, which is used to adjust the bias on the tube 25 and thus Compensate for changes in input voltage.

A variable resistor 49 "is in the output circuit of the rectifier provided to allow compensation for load changes. When the load increases the voltage drop across resistor 49 "also increases, and thus the current, which flows through the filament circle of the diode 13, changed accordingly while the resistance of the cathode-anode circuit of the diode then compensates for the change in load.

It is also evident that the change in resistance in the filament circle the diode 13 changes the value of the output voltage, which is necessary to a Achieve certain diode filament temperature, reducing the output voltage is regulated.

A resistor 72 is provided between the anode and the screen grid 25 of the force amplifier tube 25, the resistor serving as a compensation resistor in order to absorb current line peaks which arise in the winding 36 of the magnetic amplifier 37. This is necessary because of the very high inductance of this winding. The resistors 73 and 74 form part of a voltage divider circuit arrangement for conveying a positive potential towards the screen grid 25Q.

The arrangement shown in Fig. I has been developed to provide an output voltage of 12 volts direct current when connected to a mains with 115 volts single-phase alternating current is switched on. . This unit was operated with an input voltage which Greatest changes up to 15% and with a frequency of 5o to 6o periods worked per second. The output voltage was adjustable from -i i to 13 volts, whereby the output load was 5 to 8.5 amps. It has been found that the output voltage could be regulated to ± i% of the predetermined output direct current value. 2, 3 and 4 relate to a modified embodiment of the invention, in which the - changes in the impedance of a magnetic amplifier 37 are exploited be to balance a circuit arrangement with an input transformer to change in such a way that the phase is shifted, d. H. the ignition timing a pair of ion tubes, thereby changing the DC output voltage of the system will.

In FIGS. 2, 3 and 4, the same reference numerals have been used for the same switching elements, so that reference can be made to the description above. Additional parts have of course been given new reference numerals and these will be described below. From FIG. 2 it can be seen that the magnetic amplifier 37 is provided with an alternating current winding go, which is arranged in a circuit with the inductance 9i and 92 and the resistor 93. In parallel to the bridge circuit between the outputs 94 and 95, the primary winding 96 (FIG. 3) of a transformer 97 is connected, the secondary winding 98 of which has a center tap. The center tap of the secondary winding 98 is connected via a line ioo to the direct current output terminal ioi and also to the cathodes of the ion tubes 102 and 103.

The cathodes of the tubes 102 and 103 are supplied with heating current from the secondary winding 104 of the transformer 105 , the primary winding io6 of which is in turn connected via lines 107, 108, 17 and 18 to a 230 volt AC mains. Anode current is supplied to tubes io2 and 103 from the secondary winding iio of a transformer iii, the primary winding 112 of which is connected to lines io7 and iog.

The bridge rectifier circuit is controlled by the ignition pin Tubes 113 and 114 completed their cathodes with heating current from the secondary windings 115 and 116 of the transformer io5 are supplied.

As mentioned above, the anode current is supplied to tubes io2 and 103 by a transformer iii, the primary winding of which is connected to lines io7 and iog. Line iog leads to a terminal of a relay 140. When this relay responds, it connects line 141 to line io8 and via this to line conductor 18 and 144 lies. Line 144 is directly connected to the mains line 17, while line 143 is connected to the center tap-95 of the coil 91, -g2. This connection provides a voltage of approximately 115 volts to relay 142 when switch 145 is closed (assuming the voltage on power conductors 17, 18 is approximately 230 volts).

The arrangement of the relays described above protects the tubes 102, 103 and 113, 11q., And to the extent that it excludes anode voltages These tubes are transmitted before the filaments are heated for a certain period of time have been. In other words, by closing switch 146 (Fig. 2) the filament voltage is transmitted to the tubes while the switch is closing 145 only causes the excitation of the relay i42, which after a certain Duration of the response of the relay 140 and the application of anode voltage to the Tubing causes.

Lights 147 and 148 are provided to indicate the circuit switching states to be identified during starting.

It can be readily seen that in the circuit arrangement described above, a change in the DC output voltage at the output terminals ioi and i2o results in a temperature change in the filament of the diode 13 (FIG. 4) and thus a change in the resistance of this tube. Tube 13 is connected via conductors 121 and 122 (FIGS. 4, 3 and 2) into the bridge circuit with resistors 10, 11, 12. As with the above-described controller according to FIG Inductances 91 and 92 and the resistor 93 exists, which causes a change in the phase of the ignition times of the tubes io2 and 103 . As is generally known, such changes in the phase relationship cause correspondingly changed output direct currents of the bridge rectifier circuit, as a result of which the output voltage is regulated to a predetermined value.

Often it is desirable to have a broadcast frequency oscillator in such To operate in a manner that a constant voltage can be drawn from this. By inserting FIG. 5 in place of FIG. 4 of the circuit arrangement described above a circuit diagram is achieved which represents a solution to this problem. Included it should be noted that the circuit arrangement according to FIG. 5 is better than that according to Fig. I can be used as with that of Figs. 2 and 3 if necessary can.

In the circuit arrangement with the aid of which the output voltage of a radio frequency oscillator can be controlled, the oscillator 130 (FIG. 5) is fed with direct current from the output of the controller via the lines 131 and 132 which are connected to the output terminals ioi and 120 in Fig. 3 are switched on. Part of the output voltage of the radio frequency oscillator 130 is transmitted via the coupling coil 133, which is coupled to the coil 134, which is connected to the filament of the diode 13. In this way, the resistance of the diode is changed in accordance with the output of the radio frequency oscillator, the balance of the bridge with the resistors io, ii and 12 and the diode 13 being changed accordingly. This change is effective, as has already been described, to bring about a change in the phase relationship between the ignition times of the tubes io2, 103, whereby the output DC voltage is influenced in the opposite manner and the output circuit of the radio frequency oscillator is adjusted to its predetermined value.

Claims (6)

PATENT CLAIMS: i. Circuit arrangement for regulation, in particular Keeping a DC voltage constant, which is fed to an AC voltage network via a rectifier is taken using a bridge circle as a control, thereby characterized in that a diode (13) is connected in one branch of the bridge, whose The filament is connected to the DC voltage to be regulated, and that the output voltage of the bridge circuit via a tube amplifier control means for influencing the feeding AC voltage controls in the normal sense. 2 circuit arrangement according to claim i, characterized in that a parallel to the bridge arm containing the diode Capacitor (77) is connected. 3. Circuit arrangement according to claim i, characterized in that a magnetic amplifier (37) is provided as a control means for influencing the feeding AC voltage, the control winding of which is connected to the tube amplifier (25). 4. Circuit arrangement according to claim 3, characterized in that that the working winding (4o) of the magnetic amplifier in series with the primary winding an autotransformer (42) is connected to the feeding AC voltage. 5. Circuit arrangement according to claim i, characterized in that for rectifying the feeding alternating voltage Ion tubes are provided which are connected to the output voltage of the bridge circuit The phase of the grid voltage can be controlled with the help of a magnetic amplifier. 6. Circuit arrangement according to claim i to 5 for maintaining the output voltage an oscillator at a constant value, characterized in that the Oscillator is fed from the DC output circuit of the arrangement and that the output circuit of the oscillator via a coupling element with the filament of the Diode communicates.