SU213710A1 - DEVICE ELECTRICAL PROTECTION OF THE ELECTRIC POWER TRANSMISSION CURRENT LINE - Google Patents

Description

This invention relates to the field of protection of power lines of direct current and is a selective protection connected to the line through a voltage divider and containing a selective body that reacts to the duration of the derivative of voltage at the beginning of the line during transients, the actuator with sensor pulses and organ AFIiB. A distinctive feature of the invention is that in order to increase reliability, it employs an additional electoral body that responds to the duration of the established minimum voltage value in a line and containing a minimum voltage block connected in series with the minimum voltage time measuring block a digital module for suppressing the output signal, and a feedback unit connected between the input and output of the additional electoral body, which is shun After the protection has been activated, the specified organ is triggered for the time required to restore the linear voltage above the level of the additional organ actuation. The automatic reclosing device of the device contains an integrator and an execution unit, which produces a signal of permanent disconnection after accumulating a certain number of pulses in the integrator. FIG. 1 is a functional block diagram of a DC transmission system with a patented relay protection device, and FIG. 2 - basic electrical relay protection circuit. A transmission line connects rectifier / and inverter 2 stations. A voltage divider 4 is connected to line 3, the low voltage from which has been supplied: to an electoral protection body comprising blocks 5, 6 to 7. Block 5 is an element of the minimum voltage that, when the voltage removed from the divider decreases 4, below a predetermined level, generates a signal, for example, in the form of a constant voltage at the input of unit 6, which measures time and has the properties of a capacitor. The voltage on this capacitor will thus characterize the duration of the signal coming from block 5. The output signal of block 6 is measured by block 7, which, when the input signal reaches a predetermined level, creates a signal, for example, in the form of a short pulse, and delivers it to the pulse sensor (generator) 8, which converts this signal into a pulse of a certain duration. Further, this impulse is served on

the control electrode of the thyristor 9 connected between the earth and the control circuit of the rectifying station /. When the thyristor is opened, the rest of the pulse from the generator 8 passes through the main circuit of the thyristor and the diode 10.

In this scheme, an additional voltage source // and a resistor 12 are used, the resistance value of which is sufficiently large so that the voltage of source 11 could not keep thyristor 9 in a conducting state after the end of the generator pulse 8. At the rectifier station will receive a blocking signal of the same duration as the pulse of the generator 8. After the end of this pulse, the control system of the rectifying station will be able to transfer it to the normal voltage mode, provided that there is a short to ground connection Neno for a period of blocking.

In order to prevent the protection system from tripping after the blocking period expires for the time required to increase the voltage on the line above the protection system response level, the latter should be blocked for some time after the blocking pulse from the output of the generator 5. For A feedback block 13, 14 is provided for this purpose in the protection system. An extended pulse coming from the feedback block 14 is fed to the input of block 5, simulating a normal level of voltage in the line . Upon completion of the extended pulse in block 5, the actual level of the linear voltage can be measured. If there is still a ground fault, a new trip signal appears along the circuit of blocks 6, 7 and generator 3. With a permanent fault: The protection system will issue a series of blocking pulses to the rectifying station on the ground.

If after passing a series of such pulses the closure “and the ground is not eliminated, then the emergency station and the whole transmission system must be permanently blocked, for which the protection system contains a block of automatic reclosing, which, for example, after two or three shutdowns, Lro permanently blocks the transmission system. Said counting unit contains two elements 15 and 16, of which 15 is an integrator, for example, in the form of capacitance, the voltage on which is proportional to the number of pulses of the generator 8. The voltage on this capacitance is measured by element 16, which at a certain value of this generates a pulse to thyristor 1 (7, putting it into conductive state. The parameters of elements 15 and 16 are chosen so that the control pulse goes to thyristor .17 when the latter is in the conducting state. Source til with a resistor IS, and that the thyristors 9 and 17 form

the closed circuit, and the resistance of the resistor 18 is so large that the specified circuit retains its conductivity, and a constant blocking voltage is applied to the control system of the rectifier station /. After detecting and fixing a fault in the line, the blocking pulse coming from the protection system must be removed with the help of contactor 19 connected in parallel with thyristor 17. When this thyristor is short-circuited with the indicated contactor, it will be de-energized, and with subsequent break of contact the thyristor circuit 9 will be 12 will be broken. After that, when voltage is applied to the line, the protection system is in the working state.

FIG. 2 shows as an example the scheme of the device of selective protection. Connection with divider 4 is supplied to: terminals,

shown on the left in the diagram. The unit 5, which is sensitive to the voltage level, contains transistors 20 and 21. The base of transistor 21 is connected to a voltage divider on resistors 22 and 23. The divider is connected in parallel

The input terminals of the protection device are in series with the source 24. The polarity of this source is such that its voltage is summed with the voltage removed from the divider.

The following circuit includes a source 25 with the same voltage as the source 24. In the normal line voltage, the total voltage removed from divider 4, together with the source voltage 24

exceeds the voltage of the source 25 in the control circuit of the transistor 21. Under these conditions, the transistor 21 in series with the resistors 26 bridges the capacitor 27, and the current from the source of the source flows through the transistor,

connected through a resistor 28 with variable resistance. When the line voltage drops to a certain level, the value of which can be set using a resistor 22, the voltage

source 25 will exceed the voltage removed from the divider on the resistors 22, 23 b as a result of What the transistor 21 will be in the locked. This will start. charging a capacitor 27 to a source through a resistor 28. With multiple voltage drops due to transients, transistor 21 can unlock and cause a discharge of capacitor 27 through resistor 26 and transistor 21. Thus, the voltage on capacitor 27 will be

contain information about the time during which the transistor 21 was in the locked state, i.e., about the time during which the voltage in the line was below the set level. To ensure fast discharge of capacitor 27 after the cessation of abrupt voltage drops in the line, the resistance value of the resistor 26 must be significantly less than the resistance of the resistor 28. | ESLR1

is charged, and when the voltage value on it exceeds the set value determined by the controlled diode and the positive battery source, the capacitor 27 will be discharged through the controlled diode. The circuit will work as a time meter and C resistor 29 will generate a voltage pulse if the “april in the lily will be stable. The tripping time of the protection system is set by the setting value of the variable resistor 28.

In the generator circuit 8 isnolzovan a sweepsformer and a transistor 30 connected in connection with the primary winding 31 of the specified transistor. KpOiMe additionally, the transformer has a magnetic bias winding 32. An impulse arising on the resistor 29 enters the base of the transistor 30, as a result of which a current flows in the main winding of the transformer. This current causes an increase in the voltage in the secondary winding 33 of the transformer, the voltage from which is supplied to the base of the transistor, its transfer to the open state during the time of the specified voltage, i.e. the current in the winding 31 will not reach the level saturation. When this state is reached, the transistor 30 will be locked, the current in the Main Winding will stop and the transformer will be demagnetized by means of a Thagging 32. In the secondary winding 34 one inductive current period will be induced through the middle and two Extreme Winding leads connected to the diodes, After the thyristor has been opened, the remaining part of the rectified pulse from the winding 34 will pass through diode 10 and then through the main circuit of the thyristor 9. To obtain a constant value of p voltage induced in the winding 34 during the magnetization reversal transformer in series with the bottom of circuit switched diode Zener diode. During the conductive state of the thyristor 9, due to the operation of the generator 5, the voltage source // will be powered by a positive blocking voltage control system of the rectifying station. The Resistance value of resistor 12 is selected to be High enough that source 11 cannot ensure the continuation of the conducting state of the thyristor after the end of the blocking pulse. The control system of the DMR station may increase the line voltage to the nominal level.

In order to prevent the protection system from operating and blocking the forwarding station before the voltage in the line reaches its normal value, feedback blocks 13 and 14 are provided in the SYSTEM. The first consists of a transistor 13, the base of which is supplied The voltage from the winding 35 of the generator 5. During the time of the pulse of the generator 8 in the base circuit of the transistor 13, the latter will be in the open state and the capacitor 36 of the unit 14 will be charged from the source 37. When the voltage on the capacitor exceeds living source 37, significantly less than the voltage of source 38, from the capacitor 36 to the INPUT of the cascade connection of the transistors 21 and 39 will be fed a control voltage, i.e. a positive voltage will be applied to the base of the transistor 21

transistor 39, and during the time when this transistor 1 is opened by the voltage removed from capacitor 36, unit 5, which is sensitive to the voltage level, will behave in the same way as: pr, and to the normal voltage B line. Due to the presence of voltage on the capacitor 36, the protection system will also be blocked For the time after the end of the pulse of the blocking generator 8. Selection of the capacitor capacitor 36 and the value

Resistance of resistor 40 is set. The charge time for which the protection system will be blocked.

iB If the fault persists, the protection system will disconnect once

After the voltage on the capacitor 36 becomes less than the voltage of source 38, it will issue a new blocking impulse to the rectifying station Through a resistor 12. To set the specified number of Disconnected and switched on during a long Fault in the line to the winding 41 of the blocking generator 8 connected counting unit. Element 15 (counter integrator) includes a capacitor in Seb connected in parallel with a large

discharge resistance. The voltage across this capacitor rises gradually with each pulse coming from the blocking generator. When this voltage reaches a certain level,

the discharge of a capacitor through a controlled diode 42 and its voltage divider, as a result of which the control pulse arrives at the thyristor 17, connected along with the source //, M 9 and the resistor 18,

at the same time, the blocking voltage goes through the resistor 12 to the rectifying station.

For certain malfunctions, such as a low-resistance ground fault or a short-circuit close to a rectifying station, usually in most cases there is no need for a time delay carried out by blocks .5, 6, and 7, and therefore blocks 43, 44 should be used (Fig. 1 ) for quick shutdown. The control units of the derivative 43, 44 are connected in parallel to the blocks 5, 6 and 7, between the input of these circuits and the generator 8, I include a pulse transformer 45, the primary current of which is connected in series with the variable capacitor 46 and parallel to the resistor 47 with variable resistance. At large negative values of the derivative of the voltage in the line, the voltage

the torus 4-5 is charged to the controlled diode 48 through the diode 49. The capacitor 50, charged to a lower voltage, will be discharged through the diode 5 /, the controlled diode 48 and the resistor 52, resulting in the blocking of the base transistor 30 Oscillator 6 will be given a short pulse that triggers without lag in time. Using the capacitor 46 and the resistor 47 set the value of the derivative, providing a disconnect.

If the transmission of direct current occurs in more than one single line, for example, in a two-wire system, then each of the lines must be provided with earth-fault protection, as described in this invention. However, in this case, the instantaneous disconnection from the emergency line cannot be ensured due to the mutual influence of one wire and the other.

If a ground fault occurs in the direct current line 3, for example, at the second pole of a two-pole direct current line, the voltage induced by line 3 causes the blocks 43, 44 to operate. The induced voltage has a short duration surge compared to the duration of the process at the closure of the line 3. to the ground, and the circuit, sensitive to the voltage level, will be able to determine whether it is caused by a induced voltage or a direct closure. With a single-pole, single-wire, transmission system, the movable contact of the switch 53 is set to the upper position, and with the double-pole one, to the bottom.

The signal c, blocks 43, 44 starts a pulse generator 54, which wa for a short time turns on voltage measurement circuits 55, 56. The pulse generator is made according to a circuit with two stable states at transistors 57, 58 and is powered from

source 59. Under normal conditions, i.e. in the absence of a signal from blocks 43, 44, transistor 57 conducts current simultaneously along the base and collector circuits under the action of source voltage 59. The potential at point 60 of the circuit will be positive and will interact with the potential on the terminals of the voltage divider 4, as a result of which the transistor b of the circuit 55 will be open. Schemes 55, 5-6, 62 are completely identical to blocks 5, 6, 7.

Subject invention

Line Selective Protection Device

DC power transmission connected to the line through a voltage divider and containing a selective authority that responds to. the duration of the derivative of the voltage at the beginning of the lion at

transitional processes, an executive body with a pulse sensor and an automatic reclosing body, characterized in that, in order to increase reliability, an additional selective body is used, which reacts to the duration of the established minimum line voltage and contains a minimum voltage block connected in series with the measuring unit the time of existence of the minimum voltage with a discharge circuit to suppress the high voltage signal, and a feedback unit connected between the output and the input electoral authority that shunts the indicated authority after the protection has been activated for the time required to restore the linear voltage above the triggering level of an additional authority, and the reclosure authority contains an integrator and an execution unit that generates a permanent shutdown signal after accumulating a certain number of pulses integrator.

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