SU935905A1 - Stabilized dc voltage source - Google Patents

Description

(5) STABILIZING SOURCE OF CONSTANT VOLTAGE

I

The invention relates to a technique for regulating electrical quantities and can be used, for example, in power supply devices for automation units, computer engineering, telecontrol and communication means.

A stabilizing DC voltage source is known, which contains an electronic switch with a control circuit and a power transformer, to the output circuit of which a rectifier is connected. The control circuit contains a measuring element connected by an input with an output of a stabilized constant voltage source, and an output -. one of the inputs of the subtractor, the other input of which is connected to the output of the support element and the output of the subtractor connected to the amplifier. Connected to one of the inputs of a signal conversion element. The other input signal conversion element is connected to an additional output.

the circuit of the power transformer, and the output with the control input of the specified electronic key. The input of the electronic key is connected to the output of the rectifier, and the output of the electronic key is connected through the filter to the output of a stabilized constant voltage source 1.

The disadvantage of this stabilized DC voltage source is that, in accordance with the features of its circuit, when the device is operated, it cuts off with an electronic key part of each half-period of the output pulsating rectifier voltage (the time-varying input of the rectifier is sinusoidally power supply transformer), which leads to an abrupt change in the output voltage of the electronic key when it is switched and causes the occurrence of an intense spectrum

interference to the output of the device.

Also known is a stabilizing DC voltage source containing an electronic switch with a control unit and a power transformer, to the output circuit of which a rectifier is connected. The output of the rectifier is connected to the output terminals via a serial control element. The control element is controlled by the control unit, the input of which is connected to the output terminals, and the output - to the control, input of the regulating element, while the input of the electronic key control unit is connected in parallel to the regulating element 2.

A disadvantage of this device is the high level of interference created when operating as a result of abrupt changes in the output voltage of an electronic key that cuts off part of each half period of the input sinusoidal voltage.

The closest in technical essence to the present invention is a stabilizing source of constant voltage containing an electronic KEY; a power transformer, to the secondary winding of which a rectifier with a smoothing filter is connected, a regulating element connected in series to one of its output busbars, a regulating element control unit whose input is connected to the output terminals, and an output to the controlling input of the regulating element, and a block control of the electronic key, the output of which is connected in parallel with the regulating element. The special features of the circuitry of this device make it possible to reduce the interferences generated during its operation in comparison with the interference from the operation of the devices mentioned as the first and second analogs. This is ensured by the fact that the control unit of the electronic key releases the blocking voltage to the electronic key only when going through the zero of the instantaneous value of the alternating voltage of the supply mains and this practically eliminates the occurrence of interference when the electronic key is disconnected.

of the circuit, is that when it is working, the output of a stabilizing source of direct voltage receives interference that occurs when the electronic key is closed, because this jump increases the voltage on the primary winding of the power transformer, and hence on its secondary winding. 8 in turn, an abrupt change in these voltages leads to a spectrum of interference penetrating the output of the device, and their level remains such that it limits the possibility of using this stabilized constant voltage source to power a series of electro-radio-automatic devices.

The aim of the invention is to reduce the level of interference.

The goal is achieved by introducing a logic circuit AND and an electronic switch switching synchronizer, including a bridge rectifier, voltage comparator and pulse expander, in this stabilizing source of a constant voltage, including a diagonal of the AC bridge rectifier connected in series between the input terminal and the primary winding of the power transformer, the electronic switch is connected sequentially into the diagonal of the direct current bridge rectifier connected to the input of the comparator connected to the output of the pulse expander, the AND logic circuit is connected by its inputs to the outputs of the control key of the electronic key and the pulse expander, respectively, and the output of the control key of the electronic key, the electronic key on the transistor, the control unit of the electronic key includes sequentially connected Schmitt trigger and NOT logic.

Claims (2)

An introduction to the stabilizing source of the constant voltage of the voltage comparator and its connection to the electronic key ensures continuous automatic comparison of the potentials at the input and output of the electronic key and the formation of the output pulse signals of this omparator synchronously with the moments when the difference of the indicated potentials vanishes. In particular, such a vanishing of the indicated potential difference occurs when the current value of the sinusoidal value of the supply network passes through zero, which is converted by a rectifying bridge circuit to the electronic key made on the thyristor, into a pulsating voltage of one sign, and the sinusoidal law of variation the voltage on the power transformer indicated by the connection of the rectifying bridge circuit is not violated. The thyristor, on which the electronic switch is made, is enabled (if there is an unlocking voltage on its control electrode,) to open after each locking caused by zeroing of the specified potential difference immediately after passing through zero and returning to the positive values in each pulsation, which corresponds in time to the beginning of each half-period of the supply network. The pulse expander included at the output of the electronic key switch synchronizer extends in duration the short pulses generated at the output of the voltage comparator (the leading edge of which coincides with the MOMeHfa zero crossing of the indicated network voltage) to the value Tc needed for reliable opening of the electronic key , which is usually (0.05-0.1) 1, (1) where the required pulse duration at the control input of the electronic key performed on the thyristor, T is the period of voltage pulsations applied to the thyristor. At the same time, since during the operation of this device, during the period of sinusoidal voltage of the supplying network, there are two voltage pulsations on the electronic key, then r 2. (opy - Qi), 0.1-o.q. tu- I where f is the frequency of changes in the supply voltage. The introduction of the AND logic and its inputs to the outputs of the control circuit and pulse expander, respectively, and the outputK of the control key of the electronic key, generate and issue to the control input of the electronic key the switching signals of the output signals of the topkko control circuit while simultaneously receiving the same logic key. scheme And the specified pulses synchronization switches the electronic key. The differences in the output voltage of the control circuit supplied from it to the logic circuit AND required for the indicated switching of the electronic key are formed in the Schmitt trigger control circuit during voltage drop across the control element through a predetermined threshold value. A logical element, connected in series with the Schmitt trigger, does NOT provide for inverting the output Schmitt trigger voltage during device operation. This provides the necessary matching of the polarities of the voltages arriving at the logic circuit I. Thus, all this provides for the device to perform the necessary switchings of the electronic key only when the current value of the sinusoidal voltage of the supply network is zero, which reduces the noise level at the output of the stabilized source direct current. The drawing shows a functional diagram of a proposed constant voltage stabilizing source. The DC voltage regulating source contains an electronic switch 1, a white transformer 2, a rectifier with a smoothing filter 3, a regulating element C, an adjustment key control unit 5, an electronic key control block 6 that contains Schmitt trigger 7 and a logic circuit 8 NOT , the bridge rectifier 9 comparator 10 voltages and the expander 11 pulses, as well as the logic circuit 12 I. The input of the rectifier 3 is connected to the secondary winding of the power transformer 2. Regulating element after ovatelno included in one of the output lines of the rectifier 3- The control unit 5 k regulating element connected between the output of the adjusting member and its control input. The input pins of the control unit 6 of electrogenera 9 are connected to the regulating element 4 with a reel key. The electronic key 1 is connected in series to the DC-bridge of the rectifier 9 connected to the inputs of the voltage comparator 10. The output of the comparator is 10 voltages. 11 impulses connected to the expander input; The logic circuit 12 And is connected by its inputs to the outputs, respectively, of the electronic key control unit 6 and the expander 11 pulses, and the output to the control input of the electronic key 1. Electronic key 1 is made on the thyristor. The expander 11 pulses are made according to the one-shot circuit. The device works as follows. In the absence of a residual charge on the condenser of the rectifier filter 3, initially, up to the supply to the input terminals of the alternating voltage of the supply mains, the current through the regulating element 4 does not flow. Correspondingly, the voltage drop on the regulating element k, which is fed from it to the electronic key control unit 6 on Schmitt trigger 7, is equal to zero. Since the Schmitt trigger triggering is set to more than zero by the value of the allowable voltage drop on the regulating element, the Schmitt trigger in this case does not work, and its low-level output potential is applied to the input of the logic circuit 8 NOT, the output of which is removed and applied to one of the inputs of logic circuit 12 And the potential of the high level. After supplying the supply voltage in each half-period of the alternating sinusoidal voltage of the supply mains, in the diagonal of the direct current of the bridge rectifier 9 a pulsating positive voltage is applied, varying in time according to the sinusoid modulus law (i.e., in each sinusoid period there are two positive ripple that is applied to the electronic key 1 and the voltage comparator 10. Each time the dc voltage of the bridge rectifier 9 is pulsed from the diagonal of the pulsating voltage during zero the change according to the specified law (which corresponds to the transitions of the sinusoidal voltage of the supply network through zero), under its influence, the comparator of 10 voltages in an avalanche-like transition from one stable working state to another stable state. And with the subsequent departure of the specified pulsating voltage from zero back to the range of positive values in the voltage comparator 10, the initial steady state is restored by an avalanche-like pattern. As a result of such double avalanche transitions, first from one steady state to another, and then back to the original, narrow rectangular impulses are formed at the output of the comparator 10 voltages. The leading edge of each of these pulses coincides with the moment of transition of the current value of the sinusoidal voltage of the supply network through zero, and their frequency is equal to twice the frequency of this network, i.e. each indicated zero-crossing corresponds to the output impulse of the voltage comparator 10. Each of these pulses is output from the comparator output of 10 voltages to the input of the expander 11 pulses. As a result of their launching a one-shot, according to the scheme of which the pulse expander 11 is formed, at its output coinciding front fronts are formed with the same fronts of the starting pulses, and therefore with the moments of the supply voltage going through zero, but wider in duration, square synchronizing pulses . The duration of the pulses, which are formed by the one-vibrator of the impulse spreader, is a value specified in accordance with dependence (2), i.e. sufficient for reliable opening of the thyristor of the electronic key 1. The synchronization pulses formed in this way are fed from the output of the expander 11 pulses to the corresponding input of the logic circuit 12 AND, on another input of which the high output potential of the logic circuit 8 NOT operates all this time. As a result of the logic circuit 12 I, output rectangular pulses coinciding in time with the synchronizing pulses. They are given to the control input of the electronic key 1 and open it, leaving it open for the time of each positive ripple voltage applied between its anode and the cathode. The supply voltage through the open electronic key 1 is fed to the primary winding of the power transformer 2, Thus, at the output of the rectifier with a smoothing filter 3 connected to the secondary winding of the power transformer 2, a voltage appears which, through an open regulating element, is applied to the output terminals. The rectified current, which then flows through the regulating element k, causes a voltage drop across it. This voltage drop is applied to the input terminals of the control circuit 6 to the input of Schmitt trigger 7, but when it is below the set threshold value (selected, based on the absence of an emergency overheating of the regulating element k), it does not trigger Schmitt trigger 7. At the output of Schmitt trigger 7, a low potential continues to operate, and at the output of logic circuit 8, there is no correspondingly high potential, which is still applied to one of the inputs of logic circuit 13 AND, to the other input of which synchronizing pulses are received all the time. Therefore, from the output of the logic circuit 13 AND, the unlocking pulses continue to flow to the control input of the electronic key 1. As a result, the stabilized DC voltage source continues to operate in the order indicated above. In this case, | The current acting on its output is applied all the time also to the input of control unit 5 of the regulating element C. As a result, the output of the specified control unit 3 forms a negative feedback voltage that is applied to the control input of the regulating element C. It is in the absence of changes in the output voltage of a stabilized constant voltage source maintain the constant current flowing through the regulating element 4 and through the load connected to the output terminals, while changing The x output voltage varies in proportion to it, which causes a corresponding change in the current through the regulating element k and the said load so that the original voltage value at the output terminals is restored. When the current flowing through the regulating element changes, the voltage drop across it changes, which is fed to the input of Schmitt trigger 7 in the electronic key control unit 6. in the event of an increase in the voltage drop, through the regulating element k, more than the set value, this voltage drop on the regulator. The common element k rises above the trigger threshold of the Schmitt trigger 7. Then the trigger 7 Schmitt srabaty-; As a result, for the entire time of the specified excess over the response threshold, a high potential is drawn at its output, which is fed to the input of the logic circuit 8 NOT. Accordingly, a high potential is removed from one input of logic circuit 12 I, and a low output potential of logic circuit 8 NOT is applied to it, which locks logic circuit 12 I. As a result, the next synchronizing pulse occurs when the current value of the alternating voltage of the mains supply passes through zero does not pass from the output of the expander 11 pulses through the logic circuit 12 And, i.e. From its output to the control input of the electronic key, there is no next unlocking impulse. Consequently, in this case, the electronic key 1, after locking in, when a positive voltage applied between its anode and cathode at the end of its current ripple (which corresponds to the time at which the current value of the alternating voltage of the supply network goes to zero), goes to zero an increase in the voltage between the anode and the cathode, as in the previous cycle of operation, due to the absence of a trigger pulse on its control electrode. Thus, in this case, the power supply circuit of the primary winding of the power transformer is de-energized with the 2 electronic switch 1. In this case, the locking of the electronic key 1 occurs at the moment when the current value of the mains supply voltage vanishes and therefore does not lead to voltage surges on the power transformer 2, which virtually eliminates the occurrence of interference with the locking of the electronic key 1. It cannot then unlock All this is erring, so far from the electronic key control unit 6 to one input of logic circuit 12 And the low output potential of logic circuit 8 does NOT come, since all the synchronization pulses from the output that came to this time to its other input The water of the expander 11 of the pulses does not pass to its output, and therefore, from its output to the control input of the electronic key 1, there are no unlocking pulses. 8, as a result of de-energizing the power transformer 2, the supply from it of the supply voltage to the rectifier 3 is stopped, so that its filter capacitor is not recharged and discharged by the load current connected to the output terminals. When, as a result of the action of this current, the voltage drop across the regulating element k becomes less than the threshold value, the output potential of the Schmitt triplet 7 Schmitt abruptly sets a low potential. Accordingly, as a result of its inversion from the output of the logic circuit 8 NOT to one input of the logic circuit 12, high potential is again supplied. And then, with the arrival of another synchronizing pulse on its other input from the expander 11 pulses, from the output of logic circuit 12 I, a control pulse arrives at the control input of the electronic key 1. The electronic key 1 is unlocked with the onset of rise from the zero positive pulsating voltage applied by the GO between its anode and cathode, and through it the power transformer 2 is connected to the supply mains without abrupt voltage changes on its primary and secondary windings, and for the same specified before the circuit, as before unlocking. Further, the operation of the stabilizing DC voltage source is cyclically repeated. When a positive effect is achieved, the proposed constant voltage stabilizing source could be used 512 to provide electrical power for relays of radio-electronic automation devices, the reliability of operation of which and the elimination of false alarms from the interference determines the reliability of the systems operated by them, such as remote control means, as well as for powering computing devices with communications equipment with low noise level, recording equipment and playback equipment with high sound quality, etc. Claim 1. Stabilizing source of constant voltage, containing electronic key, power transformer, to the secondary winding of which a rectifier with a smoothing filter is connected, regulating element connected in series to one of its output busbars, regulating element controlling unit whose input is connected to the output terminals, and the output to the control input of the regulating element and the control unit of the electronic key, the input of which is connected in parallel to the regulating element, characterized in that o, in order to reduce the level of interference, a logic circuit I and an electronic switch switching synchronizer were inserted in it, including a bridge rectifier, voltage comparator and pulse expander, with the diagonal of the alternating current of the bridge rectifier connected in series between the input terminal and the primary winding of the power transformer , the electronic key is connected in series, to the diagonal of the direct current of the bridge rectifier connected to the input of the voltage comparator connected to the output of the expander pulses, the logic circuit and connected by their inputs to the outputs, respectively, the control unit an electronic key and dilator pulses, and the output - to the control input of the electronic key. 2. The source of claim 1, wherein the electronic key is made on the thyristor. 3- The source of claim 1, wherein the electronic key control unit 139359 includes a Schmitt trigger connected in series and a NOT logic circuit. ; Sources of information taken into account in the examination 1. E. S. Graver. Key constant-current voltage regulators, 5 5 nn, M., T970, p. 12 fig. 1b 2. Instruments and equipment of the experiment, 197, No. 1, p. 155-156. 3- Patent of France K 1526071, cl. H 02 M, 1970.