SU746297A1 - Apparatus for monitoring value and shape of voltage across high-voltage converting bridge phases - Google Patents

Description

varying the output voltages of the bridges; the input circuits of the bridges are also connected via intermediate transformers and resistors to a three-phase voltage transformer, and output circuits are loaded to resistors connected in phases to the low-voltage measuring circuit in series with the secondary windings of the transformers. FIG. I shows the structural electrical circuit of the device controlling the magnitude and shape of voltages applied to the phases of the high-voltage converter bridge; in fig. 2 is an electrical diagram of the bridges included in the voltage corrector. The device contains a converter bridge 1 fed from a group of power transformers 2 consisting of three single-phase power transformers with a transformer ratio that is adjustable under load. The regulation of the transformation ratio of power transformers 2 is carried out with the help of adjustment windings, which are part of the network (primary) windings of these transformers. In addition, the device contains a three-phase voltage transformer 3 connected to a high-voltage AC network, a high-voltage current transformer 4-6 included in the phases of the converter bridge, a three-phase low-voltage measuring circuit consisting of their low voltage reactors 7 to 9 transformers 10-12 current with high-voltage transformers 4-6 current, and transformers 13-15, connected to a three-phase transformer, terminal 3, and voltage corrector 16, made in the form of three equal-shoulder bridges 17-19 s Positioners discretely varying the output voltages of bridges, whose input circuits through intermediate transformers 20-22 and resistors 23-25 are connected to a three-phase voltage transformer 3, and the output circuits are loaded on resistors 26-28, connected to the phases of the low-voltage measuring circuit. Consistently with the secondary windings of transformers 13-15, as well as an auxiliary load 29. Three equal-shoulder bridges 17-19 are made on active elements (FIG. 2). The two towers of each of the bridges are adjustable, and the two arms are unregulated. The resistances of the 1x jiuie4 are changed discretely and in such a way that their sum always remains constant and equal to the sum of the resistances of the unregulated arms. FIG. Figure 2 shows the electrical: aI circuit of bridges, corresponding to power transformers 2 with nine steps of adjusting the transformation ratio. In this beam, the bridges 17-19 consist of ten resistors 30-32, constituting adjustable shoulders, two resistors 33 and 34, constituting unregulated arms, and nine contacts 35-135-9 of the position sensor, each of which closes in according to the number of the installed step of adjusting the transformation ratio of the power transformers 2. Resistors 30-32 have resistances equal to R, where R is the step for varying the resistances of the adjustable arms, and each of the resistors 33 and 34 has a resistance equal to 5R. In this case, the total resistances of the adjustable and unregulated shoulders of the bridges are 10 R. With a large number of steps for adjusting the transformation ratio, the number of resistors that make up the adjustable shoulders, as well as the number of sensor contacts used, increases proportionally. By using bridges 17-19, the information about the number of the included control stage, obtained from the position sensors, is converted into a voltage of the corresponding value and polarity. Bridges 17 to 19 have input ramps 36 41 and output buses 42 to 47. At stage I of regulation, when contact 35-1 is closed in bridge schemes 17 to 19, the resistance of the left adjustable tube is equal to R, and the right one is 9 R, which corresponds to the Maximum misalignment of the adjustable shoulders and the maximum sprint in the output chains of the bridges (ladies 42 - 47), equal to + 4Di, where Di -, the degree of change in the output Bridge voltage 17-19. At 2, 3 If 4 steps of adjustment, when contacts 35-2, 35-3 and 35-4 close in the bridge circuits 17-19, respectively, the resistance of the left adjustable arm increases and the right one decreases. This leads to a reduction in the misalignment of the adjustable shoulders, and consequently, to a decrease in the voltage in the output bridge circuits, respectively, of f3AU, + 2AU and + Di. . At stage 5 of regulation, when in contacts of bridges 17–19, contact 35–5 is closed, the resistances of the left and right adjustable arms become equal to 5 R each, leading to, the bridges are balanced and the voltages in their output circuits disappear. On b - 9 adjustment steps, when contacts 35-6-35-9, respectively, are closed in the bridge circuits 17-19, the misalignment of the adjustable arms begins to increase again, and consequently, the voltage in the output chains of the bridges also increases. At the same time, the output voltages of bridges at 6 to 9 stages of regulation are equal in magnitude to the output voltages of bridges, respectively, at 4 to 1 stages of regulation, but have a reverse polarity (-Di, -2Di, -DI, 4Di). This is explained by the fact that at 6 to 9 and 4 to 1 steps of adjustment the bridges have the same j degree of misalignment of the adjustable shoulders, but at 6 to 9 steps of adjustment the resistance of the left adjustable shoulder of bridges is always more than that of the right, as a result of which the tires 46 , 42 and 44 are lower than the potentials of needles 47, 43, and 45, and by 4-1 steps of adjustment, the resistance of the left-hand adjustable arm of bridges, on the contrary, is always less than the resistance of the right, therefore the potentials of buses 46, 42 and 44 are higher than the potentials of tires 43 and 45.

The basis for designing bridges 17-19 was a scheme for converting position sensor information from a numerical type to a voltage of a corresponding value, which consists of resistors connected in series and position sensor contacts, when switched on, the resistors are divided into two groups.

The resistance of the resistors of the first group 25 increases in proportion to the number of the control stage turned on, the resistance of the resistors of the second group decreases, and the total resistance of all resistors remains constant.30

The supply voltage is applied to all series-connected resistors and removed from one of the groups. In this case, the voltage applied to this group of resistors varies in proportion to the number of the included-35 step of adjusting the transformation ratio.

The device works as follows.

The primary windings of transformers up to 13–15 and the input of the voltage corrector 16, i.e., the primary windings of transformers 20–22, through a voltage transformer 3, are supplied with a three-phase high-voltage network.45

In the voltage corrector, the phase voltages of the high-voltage network are converted into three voltages, the magnitude and polarity of which are determined by the number of the set trans-JQ coefficient adjustment stage.

formations of power transformers 2. The voltages formed in the equalizer 16 are applied to the resistors 26-28 and through them are connected in series with the phase voltages of the secondary windings of the transferors-55 maters 13-15,

In those cases when the transformation ratio of the power transformers 2 is less than the rated voltage and the voltage on their circuit windings

respectively, greater than the nominal (1–4 adjustment steps), the voltages applied to the resistors 26 to 28 on the side of the equalizer 16 are in phase with the voltages on the secondary windings of the transformers 13 to 15 and are therefore added to them.

If the transformation ratio of power transformers 2 is more than nominal and the voltage, their circuit windings are less than nominal (6–9 adjustment steps), the voltages applied to resistors 26–28 from the equalizer 16 side are out of phase with the voltages on the secondary windings the 13-15 transformers are therefore subtracted from them.

As a result, voltages applied to tires 46; 42 and 44. increase and decrease in accordance with the increase and decrease in the voltage of the circuit windings of the power transformers 2, due to the change in their transformation ratio.

The voltages applied to buses 46, 42 and 44 are further summarized with the voltage drops at reactors 7-9 created by the phase currents of the converter bridge 1 generated by flow through them. Since the inductances of these reactors at a given scale model the inductances of the windings of power transformers - 2, through which the indicated currents flow, the voltage drops generated at the reactors simulate the voltage drops on the windings of power transformers.

Since the inductance of the scattering of two-winding power transformers feeding the converter bridges practically does not change (due to their design features), the inductance correction of the reactors 7-9 is not foreseen when the transformation ratio changes.

As a result of the summation of the voltages of the secondary windings of transformers 1315 with voltages on resistors 26-28 and reactors 7-9 on buses 48, 49 and 50, voltages are produced that reproduce the instantaneous values at a given scale of voltage applied to the phases converter bridge 1 on the AC side and variable in size in accordance with the change in the transformation ratio of the power transformers 2.

In order to eliminate the error caused by connecting measuring devices to buses 46, 42, 44, 48, 49 and 50, a three-phase adjustable auxiliary load 29 is introduced into the device, the current of which is selected so that it is combined with the current consumed by measuring devices on resistors 26 to 28, the voltage drops equal to one or several steps of varying the voltage Di in the equalizer 16, and the parameters of the bridges 17 to 19 are chosen so that the values of their output voltages that occur when turned on vuyuschih contact position sensor for otnoscheniya shifted to the initial output voltage zhenyym the same number of steps Di stress variations.

 The sum of the resistances of the adjustable and unregulated shoulders of the bridges 17–19 increases by 2nR, where n is the maximum-altitude number of steps

changes in voltage required by shifting the output voltages of the bridges with respect to their initial output voltages;

R is the step for varying the resistances of the adjustable arms.

The resistances of resistors 33 and 34, which form unregulated shoulders, increase in this case by nR, and in adjustable arms, the resistances of resistors 30 and 32 increase by nR.

In the bridge circuit (Fig. 2), the output voltages can be shifted by 1, 2, 3, or 4 stages, since in the sense of p aBHOBeckfl, this bridge has 4 states.

For p 4, the resistances of the adjustable and unregulated arms of this bridge should be increased by 8 R (up to 18 R) by increasing the resistances of resistors 33 and 34 to 9 R (instead of 5 R) and the resistances of resistors 30 and 32 to 5 R (instead of R) .

If the voltage drops across the resistors 26 - 28 generated by the current consumption of the measuring devices and the auxiliary load 29 are, for example, 2D, this will require shifting the output bridge and {{17-19) bridges by two steps, which can be reduced by by 2 R the resistance of the resistor 30 (up to 3 I) and increasing by 2 R the resistance of the resistor 32 (to 7 R), Then at 1 step of adjustment, when in the bridge circuits 17–19, the factor is 5 1, the voltage at the output; chains of bridges will be equal to + 6Di; by 5 tables of regulation when contact 35-5 closes - f2AU; There are 7 stages of adjustment when the contact 35-7 - O is closed, and 9 of the stage of regulation when contact 35 - 9 is closed (-2Di). . In this case, the voltage drop across the resistors 26-28 produced by the current consumption of the measuring devices and the auxiliary load 29 is -2AU, in the case of a circuit 74

which are powered by two-winding power transformers with an adjustable transformation ratio, will allow you to stop using high-voltage voltage dividers for the purpose of measuring and oscillographing voltages at various points in the converter circuit.

This, in turn, will improve the accuracy of measurements, simplify operation

measuring equipment, to increase the permissible output current and, in addition, create conditions under which it will be possible to reduce the number of high-voltage voltage dividers installed at substations, and

consequently, a significant economic effect.

Invention Formula

A device controlling the magnitude and shape of aa0 | przheshshsh applied to the phases of a high voltage voltaic educational bridge, containing a three-phase voltage transformer connected to a high voltage AC network, high-voltage current transformers included in the phases of the converter bridge, and a three-phase low-voltage measuring circuit consisting of reactors connected through low-voltage current transformers with high-voltage current transformers and transformers connected to a three-phase transformer, for example and, in order to improve reproduction accuracy with instantaneous values on a given scale of voltages, a voltage corrector is introduced into it, implemented in the form of three equal-shoulder bridges with position sensors that discretely change the output voltages of the bridges, and the input circuits bridges are also inserted through intermediate transformers and resistors connected to a three-phase voltage transformer, and output circuits load 1 resistors connected to the phases of the low-voltage measuring circuit in series with the second chnymi transformer windings.

Sources of information taken into account in the examination

. USSR author's certificate If 274214, cl. H 02 M 13/16, 18.03.66. 8 cans of contacts 35-1 to 35-6 will be subtracted from the output voltages of the bridge, and in the case of contact closures 35-7 to 35-9, add to them. As a result, the error created by the current measuring devices load will be almost eliminated. The implementation of the proposed device on the sub-power supply voltage of direct current juice voltage, converter bridges

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Claims (1)

A device for monitoring the magnitude and shape of the voltages applied to the phases of a high-voltage converter bridge, containing a three-phase voltage transformer connected to a high-voltage AC network, high-voltage current transformers included in the phases of the converter bridge, and a three-phase low-voltage measuring circuit consisting of reactors connected through low-voltage transformers current, with high-voltage current transformers, and transformers connected to a three-phase voltage transformer, about characterized by the fact that, in order to increase the accuracy of reproduction by instantaneous values at a given voltage scale, a voltage corrector is introduced into it, made in the form of three equal-arm bridges with position sensors that discretely change the output voltages of the bridges, and the input bridge circuits through the intermediate transformers and resistors are connected to a three-phase voltage transformer, and the output circuits are loaded on resistors included in the phases of the low-voltage measuring circuit in series with the secondary windings of transformers.