SU1718204A2 - Substation control dc circuit power pack - Google Patents

Abstract

The invention relates to secondary sources of power supply for relay protection equipment. The aim of the invention is to increase the efficiency of operation by eliminating the increase in output voltage when operating several power supply devices in parallel. At time intervals when the voltage at pin 53 is higher than at pin 58. the difference between these

Description

The invention relates to the field of electrical engineering, in particular, to devices for powering relay protection, automation, and signaling equipment according to the main author, St. No. 1654800.

The aim of the invention is to increase the efficiency of operation by eliminating the increase in output voltage during the parallel operation of several power devices.

FIG. 1 shows a diagram of the device; Figures 2-4 are diagrams of thyristor control, overvoltage protection and asymmetrical signaling control units, respectively.

The device contains an output transformer 1, the primary windings of which are intended to be connected to an AC network, six thyristors 2-7, the first thyristor control unit 8, containing sawtooth voltage-forming units 9, comparators 10, the thyristor turn-on drivers 11, output voltage divider filter, a low-frequency filter 13, a first voltage source 14 and a differential amplifier 15, three diodes 16-18, a second thyristor control unit 19, an output voltage protection protection unit 20 and Lock 21 signaling unsymmetrical modes, three resistors 22-24 and diode 25.

The second thyristor control unit 19 contains three separation diodes 26-28 and a node 29 consisting of three diodes 30-32, resistors 33 and 34, a zener diode 35g of the button 36 with a closing contact, a capacitor 37, a key element 38. the output pitch contains the first 39 and second 40 relays, the first 41 and second 42 closing contacts of the relay 3.8, the opening contact 43, the first 44, the second 45 and the third 46 closing contacts of the relay 40, the second source 47 of the reference voltage and the first indicator 48. Block 21 alarm asymmetric modes contains p shiny-pass filter 49, a threshold element 50, the element 51 with a delay time and a second operation indicator 52.

The third output output 53, additional diodes 54

and 55, an additional resistor 56, an additional key element 57, and the second thyristor control unit 19 is provided with a blocking input. The output pins of the device58 and 59.

The device works as follows.

The output voltage is stabilized by the first thyristor control unit 8, which carries out independent phase-pulse control of thyristors 5–7 of the cathode group of the rectifying bridge. Linear-varying voltages, in-phase with sorting interphase input voltages, from the outputs of the sawtooth voltage-forming units 9 are fed to the working inputs of the respective comparators 10. The output voltage of the device

with divider 12 after matching with.

the low-pass filter 13 is fed to the second input of the differential amplifier 15, the first input of which receives the reference voltage from the source 14. From the output of the amplifier 15, the error signal between the output voltage of the block and the reference voltage is applied to the brake inputs of the comparators 10.

At the moments when the working signal of the brake signal is exceeded, the comparators 10 operate, and the start up blocks 11 of forming the impulses switch on the corresponding thyristors 5-7. At the nominal value of the input voltage by adjusting the output

Block 15 sets the thyristor switching angle 5-7, at which the output voltage is equal to the nominal value.

In the event of an input voltage deviation from the nominal value, a corresponding change in the error signal occurs, the biasing moment of the comparators 10 triggering and the phase of the switching on of the thyristors 5-7, thus

that the output voltage of the device remains unchanged. Resistors 22-24 are selected so that thyristors 2-4 are turned on with a small positive anode potential relative to the cathode, i.e. work in the mode close to the diode operation mode.

In normal mode, the second thyristor control unit 19 operates in parallel with the first block 8. At the time of the first key element 38 tripping, the precharged capacitor 37 is discharged through it and the separation diodes 26-28 to the thyristor control electrodes 5-7 open them; on the anodes of which the voltage to this moment was positive with respect to the cathodes. This process is repeated with pepVh-od, determined by the values of the capacitance of the capacitor 37 and the resistance of the resistor - 33 and 34.

The constant charge time of the capacitor 37 is selected in this way, with the nominal input voltage and the first control unit 8 deactivated, the output voltage of the device is approximately 0.95 from the nominal, - This is necessary in order to stabilize the output voltage wages in: specified limits not only with decreasing but also with increasing input voltage

by 10-15%. ,; v О --....

When the device is connected to the mains, the stress on its trick is set at a 0.95 р of the nominal, mainly due to the high-speed second control unit 19. for no more than half the supply voltage period,. what follows from the principle of this block. In this case, the control pulses from the output of the first control unit 8 may come somewhat later due to the inertia of the power supply of the electronic elements, the unit 8 and the low-frequency filter 13.

After the end of the transient process in block 8, the control of thyristors 5-7 passes to it, since the pulses generated by it are somewhat ahead of the pulses in time from block 29, as a result of which the output voltage of the device is set to nominal. U in the event of damage to the first control unit 8, leading to the cessation of generation of control pulses, the normal output voltage is maintained by the second control unit 19.

Damage to block 8 is detected by test control using the button: 36 in block 19, the closing contact of which bypasses the capacitor 37, blocking operation. the second control block 19. In this case, the level of the output voltage of the device is determined only by the operation of the first; 6 control unit 8, which makes it possible to judge its serviceability. When damaged in the first control unit 8, leading to a shift of the phase of the switching pulses in the direction of advance and an increase in the output voltage above the permissible value, the first relay 39 is triggered in the protection increase unit 20 against the output voltage.

The response voltage of the first 39 and 5 of the second 40 relay is assumed to be the highest short-term allowable value of the output voltage, while the return of both relays occurs at a voltage lower than the rated voltage. When the relay is triggered 39; its first closing contact 41 energizes the winding of the second relay 40 and the first indicator 48, and the second closing contact 42 via the opening contact 43 of the second relay 40 connects the output of the second source 47 of the reference voltage to the first output of the block 20 and further to the brake the inputs of the comparators 10 of the first control unit 8, prohibiting the formation of thyristor control impulses in the generator 11. The thyristors 5-7 are controlled in this case from the second control unit 19.

If, as a result, the voltage on

5, the output of the device without deceleration will be reduced to nominal, then the second relay 39 will not operate. If a boost; the voltage at the output of the device is due to the loss of locking properties in the forward direction of one of the thyristors 5-7, then after the first relay 39 trips in block 20 and the first control unit 8 stops operating, the output voltage of the device will not reach its nominal value, how the two other healthy thyristors will be turned on regardless of the output voltage level by the second control unit 19. This will trigger the second relay 40 in the block.

0 20, which, by its opening contact 43, removes the signal that blocks the operation of the first control unit 8, and the locking contacts 44-46 ensures that the thyristors 2-4 are turned off by shunting

5 of their control electrodes.

The output voltage of the device is now formed by a fully open damaged thyristor (e.g., 5).

0 controlled thyristors 6 and 7 and the zero output of the secondary winding of transformer 1 through diode 25. In this case, the highest possible voltage at the output of the device (with fully open thyri5 storages 6 and 7) will not exceed 1.17 nominal. In fact, the thyristors 6 and 7 will be controlled with an angle determined by the first control unit 8, so that the output voltage is set at a level close to the nominal.

The fact of damage to the device circuit, which led to an increase in the output voltage, is signaled by the first indicator 48 connected in parallel to the winding of the second relay 40. If one of the thyristor control channels 5-7 fails or one of them fails by an open control circuit and hpn breakage of one of the phases of the power supply network, the average value of the output voltage of the device does not change as a result of the action of the first control unit 8, however, the harmonic composition will change in the output voltage Due to the appearance of a component with a doubled frequency of the network (second harmonic).

In block 21, the asymmetry signal of the second harmonic is separated from the output voltage of the device by a band-pass filter 49. From the output of the filter 49, the voltage goes to the input of the threshold element 50, which is triggered if the voltage at its input is above the set threshold. The high level signal from output 50 goes to the 5V time element. If the asymmetry duration exceeds the delay time of the signal in the element 51. then at the output of the last clock a high level signal, which will trigger the second indicator 52.

When several proposed devices are connected in parallel with the first and the third output terminals or when operating in parallel with other types of constant voltage sources on the third output terminal, the instantaneous voltage values may periodically exceed the instantaneous voltage values at the second output terminal. This may be due to a phase shift of the voltages supplying other devices, a higher level of their output voltage, a rectifying circuit, etc. At intervals — the time when the voltage on the third output 53 of the device is higher than on the first, the difference of these voltages is is allocated to the resistor 56. In this case, the diode 54 is closed by reverse voltage. From resistor 56, the voltage goes to the control inputs of the key element 57 through the diode 55 and causes it to trip.

When the key element 57 is triggered, the matching between its output and input, connected respectively to the blocking input and the power output of the second control unit 19, decreases to zero, the capacitor 37 is short-circuited. This leads to the output of the second unit

19 control at specified time intervals, as a result of which the voltage at the third output terminal of the device is set to the nominal due to the stabilizing effect of the first unit

8 thyristor control.

The device is intended for use at reducing substations of 10–220 kV and distribution points of 6–35 kV for supplying relay protection and automation equipment, as well as signaling circuits and switching devices. The economic effectiveness of the invention is to improve the quality of the output voltage at a parallel

work.

Claims (2)

1.Device for supplying constant operating current circuits of substations according to auth. St. Ms 1654800, which is due to the fact that, in order to increase the efficiency of operation by eliminating the increase in output voltage during the parallel operation of several devices two additional diodes, an additional resistor, an additional key element with two control inputs, a third output terminal for connecting the positive poles of parallel-connected power devices, and a second control unit equipped with a blocking input, and the first output water the first pin of the additional resistor, the anode of the first additional diode, the input and the first control input of the additional key element, and the third output pin - the second pin of the additional tion resistor, the cathode of the first additional the diode and the anode of the second additional diode, the cathode of which is connected to the second control input of the additional key element, the output of which is connected to the blocking input of the second control unit. . 2. The device according to claim 1, characterized in that the input of the key element of the second control unit is used as its blocking input. Shz