SU1343397A1 - Device for stabilizing electric consumer supply voltage - Google Patents

Abstract

The invention relates to the field of electrical engineering and is intended to stabilize the supply voltage of electrical consumers, in particular televisions. The purpose of the invention is to increase the CTC. The goal is achieved by the auxiliary switch 9 disconnecting the input of the autotransformer 1 from the first output 8, which connects directly to the network through the switch 5 when the network voltage is within the allowable range of 190-230 V. The auxiliary switch 9 is turned on using the control winding 2 through rectifier 3. To control the network voltage when the autotransformer is turned off, the input of the switch control unit is connected to the inputs 7 and 13. When the network voltage is low, the switches 6 operate and 17 together with the switch 9, and with increased - switch 4 together with the switch 9. 2 Cp. f-ly. 2 Il. (L from 00 00 to 9 (a.1

Description

The invention relates to electrical engineering and the regulation of electrical quantities and is intended to stabilize the supply voltage at the terminals of electrical consumers, in particular television sets.

The purpose of the invention is to increase the efficiency of the device.

FIG. 1 is a functional block diagram of the device; in fig. 2 is the electrical circuit diagram of the control unit.

The power consumption voltage stabilization device contains a power transformer 1 with taps and a control winding 2 connected to the input of the rectifier 3, main switches 4-6, the input connected to the first input terminal 7, the output of the switch 5 connected to the first output branch 8, the outputs switches 4 and 6 - with the corresponding tapes of the autotransformer 1, auxiliary switch 9, the input connected to the corresponding tap 10 of the autotransformer 1, unit 11 controlling the main switches. The last terminal 12 of the autotransformer through the switch 4 is connected to the first input terminal 7, the second input terminal 13 to the second output terminal 14.

The output of the auxiliary switch 9 is connected to the first output of house 8, its control input is connected to the output of rectifier 3, the other extreme terminal 15 of autotransformer 1 is connected to the second output terminal 14, and the input of control unit 11 is connected to the input terminals. Between the additional tap 16 of the transformer and the first input output, an additional main switch 17 is turned on.

The control unit is made on a transformer connected to the input of the unit and a voltage master that is made on threshold elements 18 and 19 and semiconductor switches 20 and 21. The inputs 22 and 23 of the keys and the first inputs 24 and 25 of the threshold elements are connected to the output of the parametric stabilizer 26 whose input is shunted by filter 27 and through the first rectifier 28 is connected to the output of the first secondary winding 29 of the transformer.

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The second inputs 30 and 31 of the threshold elements are connected to the output of the parametric stabilizer; 1, and the outputs of the threshold elements and the first semiconductor key are connected via thyristors 32-34 to the outputs to connect the control inputs of the main switches 2, 5, 6 and 17, and the outputs of the threshold elements In addition, through diodes 35 and 36 are connected to the input of the first semiconductor key, while the input of the second semiconductor key is connected to the output of the second secondary winding 38 of the transformer via the second rectifier 37, and the output of the second A semiconductor switch is connected through chains on series-connected diodes 39-42 and resistors 43-46 to the corresponding thyristor control transitions.

The additional main switch 17 is controlled by the corresponding similar elements of the control unit — the third threshold element 47, the outputs of which through diodes 48 and 49 are connected to the first input of the second threshold element and the input of the first semiconductor key. The thyristor control switch 50 through the diode 39 and the resistor 43 is connected to the output of the second semiconductor switch.

Switches can be made on triacs, optocouplers or counter-connected thyristors. When executing switches on thyristors, their control circuits must be galvanically isolated, since other variants of execution of circuits with thyristors are not possible due to the influence of sections of the windings of the autotransformer.

The device works as follows.

In the initial state, the network voltage is zero. Switches 4-6 and 17 are closed, the voltage selector is off, and autotransformer 1 is de-energized, so the output voltage is zero. The threshold elements 18 and 19, the keys 20 and 21 and the thyristors 32-34 are closed.

When the grid voltage is turned on from the output of the transformer, voltage appears from the windings 38 and 29. The voltage from the output of the winding 29 is rectified by the rectifier 28, smoothes out

filter 27 is stabilized by a parametric stabilizer 26 and is fed to the inputs of the voltage setting device. The voltage from the output of the winding 38 is rectified by the rectifier 37 and fed to the input 23 of the transistor 21. When there is a network voltage, the transistor 21 is closed and when the network voltage is zero The transistor opens briefly.

With a network voltage of 200-230 V, the voltage at the input 24 of the threshold element 18 is greater than the voltage at the input

30, therefore, the right side of the back-up part 20, which is closed, works. The thyristor 34 is also closed.

When the network voltage is equal to zero, the switch 5 is closed, the transistor 21 opens, the thyristor 32 is controlled through the diode 2Q through the diode 42 and the control current flows through the resistor 46. Thyristor 32 opens. On the control transition of the switch 4 flows the control current, therefore when

Horn element 18. In the threshold element 19, the left part operates, since the voltage at input 25 is less than the voltage at input 31. The input of switch 20 does not receive a blocking signal from the output of threshold elements 18 and 19, therefore, transistor 20 opens.

If the network voltage is equal to zero, the transistor 21 opens and, through

a diode 41, a resistor 45, controlling the voltage of the network, other than zero.

the thyristor 34 flows through the control current. This control current is not sufficient to open the switch 5. At the same time, the thyristor 3 is opened and the control current flows through the control transition of the switch 5 through the transistor 20 and the thyristor 34. Switch 5 is unlocked, and autotransformer 1 and load are connected to the network.

When the network voltage is greater than zero, the transistor 21 is closed, but the thyristor 34 remains in the on state due to the current through its power junction. When changing the polarity of the mains voltage, the switch 5 conducts current in a different direction. Autotransformer 1 and load work. The network voltage is fed to the autotransformer 1 and the load at the very beginning of the supply voltage, so there are no radio interference and no complex filters are required. In this case, the switches enough to shunt RC-chains. The autotransformer 1 in this case does not affect the load voltage, therefore the device is characterized by the absence of a loss of transformer idling, i.e. high efficiency.

In order to eliminate the losses of idling at the voltage of the network of 200-230 V, the autotransformer 1 must be disconnected from the network. For this purpose, use

There is a switch 9, a control autotransformer. Since autotransformer 1 is disconnected from the network, the voltage across its winding 2 is zero and switch 9 is closed. The consumer receives power from the network. With a voltage of 230-253 V, the voltage at input 30 becomes higher than the voltage at input 2A of threshold element 18, therefore the left side of threshold element 18 is opened and the right is closed. Through diode 35, the voltage goes to the input transis0

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the switch 4 is opened and the network voltage is applied to the input of the autotransformer 1. Simultaneously with this voltage, the output of the winding 2 opens the switch 9 and the load is connected to the output of the autotransformer 1. The voltage across the load is 198-231 V.

When the network voltage is restored, the left part of the threshold element 18 and the thyristor 32 are closed, the right part opens, since the voltage at input 24 is higher than the voltage at input 30. Transistor 20 and thyristor 34, as well as switch 5, open. The load is powered by the network. The autotransformer 1 is disconnected, the switches 4 and 9 are closed.

With a voltage of 170 200 V, the voltage at input 25 becomes higher than the voltage at input 31, so part of the threshold element 19 is open and the left side is closed. When the network voltage is zero, the control transition of the thyristor 33 through the resistor 44 and the diode 40, as well as the transistor 21, receives a control current. The thyristor 33 and the switch 6 are opened, so the autotransformer 1 is connected to the network, and the load through the switch 9 to the output of the autotransformer 1. The switch 5 is closed, the transistor 20 is also closed

due to the arrival at its input bias through the diode 36. The voltage across the load is 198 - 231 V.

When the network voltage is restored, the switches 6 and 9, the thyristor 33 are closed, the autotransformer 1 is disconnected from the network, the transistor 20 is opened, the thyristor is FOR and the switch 5. The load is connected directly to the network.

To expand the range of monitored mains voltage from 150 to 170 V, a threshold element 47, a thyristor 50 and a switch 17 are used. the transistor 20 and the threshold element 19. The autotransformer 1 in this mode is connected to the network via the switch 17, and the load through the switch 9 is connected to the output of the autotransformer 1. The switch 17 is open. The input voltage of the load is 198 - 230 V at the mains voltage of 150-170 V.

With a voltage of 170-200 V, the switch 17 closes and the switch 6 opens. With a network voltage of 200-230 V, switches 6 and 9 are closed, and switch 5 is open.

To increase the accuracy of voltage stabilization at the load and the range of the monitored voltage of the network, the number of autotransformer sections and switches increases, while the shift from the threshold elements other than the transistor 20 must go to the lower threshold element when the network voltage increases from 250 to 270 V and higher. This means that when the network voltage drops below 170, 150 rf 130 V. In addition, to increase the reliability, the threshold elements can be mutually blocked with each other (it increases the cost of the device).

Claims (2)

1. Power supply voltage stabilizer. five 0 five 0 five 0 five 0 55 containing a power autotransformer with tap-offs and a control winding connected to the rectifier input, main switches, an input connected to the first input terminal, an output of one switch connected to the first output switch, the other switch outputs with the corresponding tapes of the autotransformer and one extreme terminal, auxiliary switch, the input is connected to the corresponding tap of the autotransformer, the control unit of the main switches, and the second input pin is connected to the second output The output is characterized in that, in order to increase the efficiency, the output of the auxiliary switch is connected to the first output, its control input is connected to the output of the rectifier, the other extreme end of the autotransformer is connected to the second output, and the input of the control unit is connected to the input terminals. 2. The device according to claim 1, characterized in that the control unit is made on a transformer connected to the input of the unit and the voltage setting device, wherein the voltage setting device is made on the threshold elements and semiconductor switches, the key inputs and the first inputs of the threshold elements are connected with the output of a parametric stabilizer, whose input is shunted by a filter and connected through the first rectifier to the output of the first secondary winding of the transformer, the second inputs of the threshold elements are connected to the output of the parametric stabilizer, and the outputs of the threshold elements and the first semiconductor key are connected to the terminals for connecting the control inputs of the main switches through the thyristors, and the outputs of the threshold elements are additionally connected via diodes to the input of the first semiconductor key, and the second rectifier is connected to the output of the second secondary winding transformer, and the output of the second semiconductor key through the chain on a series of diodes and resistors connected to the corresponding control thyristors. 3, The device according to claim 1, about the tl and - the fact that, in order to extend the functionality, an additional main switch is inserted into it, connected between the first input terminal and 13A33978 with a power tap of the power autotransformer, with the control input of the additional main switch connected to the corresponding output of the control unit. JU J