DE1216975B - Circuit arrangement for keeping a direct voltage or a direct current constant - Google Patents

Description

Circuit arrangement for keeping a direct voltage constant or of a direct current The invention relates to a circuit arrangement for keeping constant using a direct voltage or a direct current with high accuracy a bridge circuit with a variable resistor in a bridge branch, an auxiliary AC voltage applied to a bridge diagonal and an actuator, which with the help of the control voltage obtained from the second bridge diagonal in its acting on the voltage to be regulated or the current to be regulated Value is changed.

Highly constant direct voltages or direct currents are known z. B. for electronic tuning in frequency-selective members using corresponding controllable elements (capacitance diodes) are required.

The generally used circuit arrangements for keeping constant Direct voltages or direct currents can almost all be based on what is described below Return the circuit diagram: into the line that carries the voltage to be regulated is an actuator switched on; part of the output power of this actuator is fed to a discriminator, which is also given a comparison variable will. From the comparison of these two supplied voltages or currents, the Controlled variable derived; this is then applied to the actuator. Both known arrangements, the comparison variable z. B. taken from a comparison battery. However, glow stabilizers can also be used. The discriminator can in the known circuits z. B. only in a counter-switching of two voltages be seen.

These known arrangements, however, have the major disadvantage that at best they allow regulation to an accuracy of U = 104, where (3-U represents the ratio of the nominal voltage U to the maximum deviation d U. This is the main reason why greater accuracy cannot be achieved , because no more precise comparison values (with long-term constancy) can be generated, but the constancy obtained with these known arrangements is not sufficient for many purposes, for example for the problem of electronic voting described above.

It should also be mentioned that a voltage stabilizing arrangement is known in which the regulated DC voltage is converted into an auxiliary AC voltage will. However, this auxiliary AC voltage is of constant frequency and its amplitude depends on the regulated DC voltage. This auxiliary alternating voltage is this stepped up in such a way that it has a constant DC voltage by one exceeds a small amount. From the comparison (formation of the difference) of the half-waves This auxiliary alternating voltage and the constant direct voltage then become current pulses obtained, these are converted into an alternating voltage and this becomes after rectification the control voltage gained. Here too, the regulated DC voltage is converted despite the conversion in an alternating voltage, a constant direct voltage is used for comparison. The disadvantages mentioned thus also occur here.

Another circuit arrangement is used to avoid these disadvantages for keeping a DC voltage constant, at which the desired Can achieve accuracy. This circuit arrangement also has an actuator intended. Part of its output power is used to tune an oscillator used. In addition, there is another highly constant oscillator (crystal oscillator) intended. The frequencies of these two oscillators are used in a discriminator compared and the voltage obtained by this comparison is used for the control of the actuator used.

This circuit arrangement is advantageous from an electrical point of view but still the disadvantage of a relatively large effort.

It is also a voltage or current regulator for DC or AC voltage became known in which a bridge circuit is used in whose branches are ohmic resistances. One of these resistors is controllable and is formed by the voltage to be regulated or the to regulating Electricity changed in size. An auxiliary AC voltage is applied to one of the bridge diagonals coupled. The control voltage and its frequency are on the other bridge diagonal is equal to the frequency of the auxiliary AC voltage, decoupled. This tension will to influence an actuator that acts on the voltage to be regulated, used.

The invention is based on this known control circuit. According to However, the invention is used to improve the long-term constancy of the circuit Increasing the accuracy of the control or to increase the control speed proposed to design the bridge circuit as an AC bridge in which a branch by the constant DC voltage to be kept -bzw. the constant to be kept direct current switched on in its electrical size controllable element is. To decouple the control voltage from the second bridge diagonal, a Decoupling member provided; this (if necessary with the interposition of a Amplifier) as well as the arrangement for generating the auxiliary AC voltage are with a circuit arrangement for comparing the phases of the two applied alternating voltages tied together. A control DC voltage is used in the last-mentioned circuit arrangement generated, the size of which depends on the amplitude and phase of the output voltage of the bridge is dependent. This voltage is fed to the actuator.

An exemplary embodiment of the circuit arrangement according to the invention is shown in FIG. 1 of the drawing. The DC voltage to be kept constant is between input terminals 1a and 1b. The regulated DC voltage is picked up between terminals 2 a and 2 b. With 3 the actuator is designated. Part of the output power of the actuator 3 is decoupled via the adjustable potentiometer 4 and used to control a capacitance diode 5. This capacitance diode, together with the capacitor 6, forms a branch of the alternating current bridge 7. In the example given, the other bridge branches are also formed by capacitors 6a, 6b and 6c. The auxiliary AC voltage that is generated in the oscillator 7a is also applied to points 8 and 9, that is to say to the one bridge diagonal. The primary side of a transformer 12, the secondary side of which is connected to an alternating current amplifier 13, is connected between points 10 and 11, ie in the other bridge diagonal. In the element 14, the output voltage of the amplifier 13 is compared in phase with the output voltage of the oscillator 7a. In addition, a direct voltage is generated in this element 14, the amount of which depends on the amplitude of the output voltage of the amplifier 13. The polarity of this direct voltage is determined by the phase comparison of the two supplied alternating voltages of the same frequency. The voltage is used to adjust the actuator 3 in a known manner.

The mode of operation of the circuit arrangement is as follows: If the input voltage between terminals 1 a and 1 b, and thus the output voltage between terminals 2 a and 2 b, is of the desired size, then with the appropriate dimensioning of the bridge elements and the appropriate setting of the potentiometer 4, the AC bridge 7 just balanced. So there is no voltage at the output of the amplifier 13; likewise, there is no voltage at the output of member 14 and the actuator remains in. previous state. If, on the other hand, the input voltage between terminals 1 a and 1 b deviates from the nominal value, the AC bridge 7 is detuned. When detuning, the magnitude of the current between points 10 and 11, that is to say in the primary winding of the transformer 12, depends on the magnitude of the deviation of the actual voltage from the nominal value. The direction of the 'current in the primary winding depends on whether the actual value exceeds or falls below the setpoint. When the actual voltage is exceeded, the direct voltage at the output of the element 14, the amount of which, as already stated, depends on the amplitude of the output voltage of the transformer 12, receives a certain polarity. If, on the other hand, the input voltage between terminals 1 a and 1 b is less than the nominal value, then the polarity is reversed at the output of element 14. The actuator is thus determined by the DC voltage at the output of the element 14 by that for keeping constant. Amount regulated in the correct actuating direction.

The element 14 can for example be constructed in the following way: Both the sum and the difference are formed from the two voltages supplied (from the amplifier 13 and the oscillator 7a). The resulting voltages are rectified and switched against each other. That this results in the desired DC voltage can be seen from the vector diagram of FIG. 2 shown. There are in FIG. 2 shows two cases which differ only in that on the one hand the input voltage is too low by a certain amount and on the other hand it is too high by the same amount. In FIG. 2a, the vector 15 represents the output voltage of the amplifier 13, while the vector 16 symbolizes the output voltage of the auxiliary oscillator 7a (at the same point in time). The sum of the two voltages is formed once, resulting in the voltage represented by the vector 17. In addition, as already stated, the difference between the vectors 15 and 16 is formed (vector 15 a and 16 a), the voltage being obtained with the vector 17 a. After rectification, a direct voltage with the amount 18 is obtained on the one hand (from the sum voltage) and on the other hand an amount 18a (from the differential voltage). By connecting these two DC voltages against one another, a residual voltage 19 remains with a specific polarity.

If, on the other hand, the bridge is detuned in the opposite direction, then the one in FIG. 2 b with 15 b (output voltage of the transformer) and 16b (oscillator output voltage) designated voltage vectors. In the formation of the sum, a voltage remains which is symbolized by the vector 17 b, while in the formation of the difference a voltage with the vector 17 c results. After rectifying (amounts 18 b and 18 c) of the two voltages 17 b and 17 c and connecting them against each other, a voltage 19a is obtained, which has the same amount as voltage 19, but (caused by the opposing connection) now has the opposite polarity. It should also be mentioned that instead of the circuit arrangement described above for the element 14, a so-called ring modulator can also be used.

Is used as an actuator z. B. a transistor, so you can rectified auxiliary oscillator voltage also for setting the transistor operating point use. The bridge voltage, which is amplified and is smaller than that of the auxiliary oscillator voltage only needs to be added to the auxiliary alternating voltage by means of a transformer and the sum to be rectified; a phase comparison takes place automatically instead of. Depending on the mutual phase position of the two alternating voltages the transistor bias becomes larger or smaller. Simplified in this embodiment thus the element for generating the steep DC voltage compared to the ones described above Arrangements.

It can be seen that the circuit arrangement according to the invention is opposite the circuit arrangement listed above for keeping a direct voltage constant far less effort is required using a crystal oscillator. The auxiliary oscillator 7a does not need to be constant in frequency since there are frequency deviations can not have an adverse effect. The bridge itself is simple in its construction. Of course, it can also consist of inductors with a corresponding current-controlled Inductance can be formed in a branch. Other known bridge circuits can also be used Find use. As stated above, the link 14 is by no means a complicated one Circuit arrangement. Nevertheless, accuracies of about (-gu = 105 (and still better accuracies) can be achieved with the circuit arrangement according to the invention. In terms of accuracy, the circuit arrangement according to the invention is absolutely sufficient comparable to the just mentioned, known circuit arrangement with a quartz oscillator.

Claims (6)

Claims: 1. Circuit arrangement for keeping a constant DC voltage or a direct current with high accuracy using a Bridge circuit with a variable resistor in a bridge branch, one Auxiliary AC voltage applied to a bridge diagonal and an actuator, which with the help of the control voltage obtained from the second bridge diagonal in its acting on the voltage to be regulated or the current to be regulated The value is changed so that the bridge circuit is not shown is designed as an alternating current bridge, in one branch of which a constant through the DC voltage to be kept or the DC current to be kept constant in its electrical variable controllable component is switched on, and that for decoupling the control voltage from the second bridge diagonal is provided a decoupling element is, which optionally with the interposition of an amplifier together with the arrangement for generating the auxiliary AC voltage with a circuit arrangement to compare the phases of the two applied AC voltages and to generate them one in size on the amplitude and phase of the output voltage of the bridge dependent DC voltage, which is fed to the actuator, is connected. 2. Circuit arrangement according to Claim 1, characterized in that the branches of the AC bridges are formed from capacitors and that the controllable component, which at least partially forms one branch of the bridge, as a capacitance diode is trained. 3. Circuit arrangement according to claim 1, characterized in that that three branches of the AC bridge contain common inductors and that the fourth branch contains a current controlled inductor. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the circuit arrangement to generate the DC control voltage from elements to form the sum and the Difference between the two AC voltages supplied and those connected to them Rectifiers and a link for connecting the two rectified against each other Stress is formed. 5. Circuit arrangement according to one of claims 1 to 3, characterized in that the circuit arrangement for generating the control voltage is designed as a ring modulator. 6. Circuit arrangement according to one of the claims 1 to 3, in which the actuator as a reinforcing element, e.g. B. as a transistor is, characterized in that the circuit arrangement for generating the DC control voltage consists of a summing element and a connected rectifier, the resulting high-speed DC voltage is used as transistor bias. Into consideration printed publications: German Patent No. 1053 631; German interpretative publications No. 1128 529, 1128 530; Austrian Patent No. 196 510; U.S. Patent No. 2,562,744; H a g u e: "Alternating Current Bridge Methods" (1945), p. 439; magazine for technical physics, 18 (1937), p. 467; ETZ-B (1953), p. 321; Print separately "Neue Zürcher Zeitung", No. 2689, from December 15, 1948, titled "Precise Voltage Reguheration", Fig. 2.