RU2435267C1 - Method to build and adjust relay protection with high-frequency exchange blocking signal along line wires - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: according to the method, from the ends of the line with a leaking power from the ends of each phase, as zero current value is exceeded in each phase, there is a high-frequency locking signal transmitted continuously along the line wires to sets of relay protections at all ends, preventing their operation in working, asynchronous and non-complete-phase modes. In case of external short circuits, by availability of a blocking signal at each end of the line good condition of a high-frequency channel is continuously monitored, in case of external short circuits and its fault, alarm is provided, as well as line switches disconnection is blocked. In case of internal short circuits on the line, due to power leak-in at the ends of the line at least in one of phases the high-frequency blocking signal along the line wires to the sets of relay protections disappears at all ends, and the latter disconnect the switches each at their end.

EFFECT: improved sensitivity.

2 dwg

Description

The invention relates to relay protection with high-frequency exchange of information between sets and can be used to build relay protection of lines of electrical networks.

A known method of constructing and configuring directional high-frequency relay protection of the line, selected as a prototype, for example, lines 110-330 kV [1. Cabinet of directional high-frequency line protection of type ШЭ2607 031: Operation manual // Firm ECRA 656453.023RE, 2000. - 77 l.].

The known method consists in comparing the directions of electric capacities at the ends of the line relative to substation buses at these ends. In the event of a short circuit (short circuit) on the power direction line at all ends, it is unambiguous - from the tires to the line, and with external short circuit at the end of the line closest to the short circuit point, the power direction is opposite. This difference is used as a reliable sign of short circuit on the line or out. This is accomplished by sending one of the phases of a line of a high-frequency blocking signal through the wires to all ends of the line from the end with the opposite direction of power. Due to this, the operation of relay protection kits at all ends of the line is blocked. In case of internal short circuit, due to the unambiguous directions of power at all ends from the buses to the line, the sending of a high-frequency blocking signal is stopped and thereby the protection sets are allowed to work at each end of the line. Protection kits automatically turn off the switches at the ends of the line where they are located. Thereby, short circuit on the line is disconnected and eliminated. To enhance the detuning from interference, the high-frequency transmitters included in the relay protection kits at the ends of the line start immediately upon the fact that the electrical values of the short circuit are superior to the values of the operating modes, which ensures reliable blocking of all sets with external short-circuit by continuously switching the high-frequency blocking signals of all transmitters to high-frequency blocking signal of one transmitter as part of a relay protection kit at the end of the line closest to the fault location. An additional detuning from interference in order to increase the selectivity of disconnecting the internal short circuit on the line, the disconnecting signal at the ends of the line is formed by significantly exceeding the short circuit thresholds used to start the blocking high-frequency transmitters with electrical values. Since blocking high-frequency signals provide the main property of relay protection - its selectivity - an automatic periodic monitoring of the high-frequency channel is applied through the phase wires of the line, implemented, for example, by turning on the relay of the relay protection kit at one end of the line and monitoring at the other ends of the high-frequency signal In the absence of superiority, the parameters of the threshold line modes for triggering a blocking signal

The disadvantages of the existing method is the limited sensitivity, also the limited time for monitoring the health of the high-frequency exchange channel on a working line. Therefore, short-circuiting is possible if the latter is not ready, which can lead to improper operation of the relay protection. Indeed, the possibility of detecting faults occurs only after activation of the high-frequency channel, which occurs if there is a superiority of the electrical values of faults over the blocking thresholds of action detuned from the operating modes. The guarantee of short-circuit shutdown is realized only if the short-circuit electric values exceed the shutdown action thresholds, which in turn significantly exceed the blocking thresholds. But the electrical values of the short circuit may not exceed the breaking thresholds, for example, due to transient resistances. So, a well-defined short-circuit range will not be detected by the existing method of high-frequency relay protection due to limited sensitivity. As for the unavailability of the high-frequency exchange channel along the line wires, short-circuiting can be detected not only with insufficient, but with any other electrical quantities. The control of the high-frequency channel along the line wires of the method under discussion is carried out periodically in the operating modes of the line. The likelihood of an inoperative state of the high-frequency channel by wire is proportional to the time of lack of control of the serviceability of the high-frequency channel of the line. The disadvantage of this method is also filter control of electrical quantities in the form of different symmetrical components, which leads to a noticeable increase in interference on the protected line during non-phase modes on the network links shunting the protected line, and during non-phase conditions on the protected line there is a large increase in interference, which causes either the impossibility or inferiority of the practical implementation of the existing method.

The objective of the invention is to increase the sensitivity to short circuit and increase the time for monitoring the health of the high-frequency channel during the entire period of working, asynchronous and non-phase modes of the line, external short circuit relative to the line.

The solution to this problem is achieved by the fact that in the method of constructing and configuring relay protection with a high-frequency exchange blocking signal, the blocking signal is transmitted through the wires of the line during a short circuit, and the direction of electric power is monitored at each end of the line, upon the expiration of power at the end of the line in case of an external short circuit, the transmission of a high-frequency blocking signal is continued, in case of a short circuit on the line upon the fact of power leakage at each supply end e lines stop the transmission of the blocking signal and, if the selected response parameter exceeds the specified threshold, the circuit breakers at each end of the line are turned off, and in the operating modes of the line, the high-frequency channel is in good condition.

According to the invention, a high-frequency blocking signal is continuously transmitted through the wires of the selected phase of the line from the ends of the line with leaking power from any phase to a current of zero, preventing the sets of relay protections at all ends of the line in operating, asynchronous and non-phase modes, with external short circuits ; by the presence of a high-frequency blocking signal at the ends of the line, the healthy state of the high-frequency channel is continuously monitored in operating, asynchronous and non-phase modes, with external short circuits and with its malfunction, detected by the absence of a high-frequency blocking signal, they provide signaling and blocking of the circuit breakers tripping.

The proposed method provides an increase in sensitivity to the level of the threshold of action, detuned from interference operating modes. This is possible because the blocking function in the claimed method does not start to operate when a short circuit occurs, as in the prototype, but works continuously, starting from a value close to the zero value of the current of each phase of the line, which can be less than the capacitive open circuit current of the line included in network from one of its ends. Blocking and disconnecting thresholds of electrical quantities in the prototype were introduced to eliminate the incorrect identification of the damaged state of the line in operating modes and external short-circuit if the blocking high-frequency signal transmitted from the ends of the line with leaking power was accidentally eliminated and to eliminate correspondingly false in the first case and unnecessary in the second case disconnecting the line. Formally, the blocking and disconnecting thresholds of the prototype correspond to practically zero and detuned from the operating modes values of the phase current of the line of the claimed method. However, if in the prototype the effect of reliable reliable isolation of the protected line is achieved by roughening the blocking and disconnecting thresholds, then in the claimed method this effect arises due to the continuous monitoring of the operability of the exchange channel through the phase wires of the line and the instant blocking of the line protection action in case of accidental disappearance of the blocking high-frequency signal in this channel. As a result, there is a set of operations of the proposed method, providing greater sensitivity of protection compared with protection of the prototype.

During a pause of the periodic procedure for monitoring the health of the high-frequency exchange channel in the prototype, a blocking high-frequency signal may accidentally disappear, therefore, if the controlled electrical values exceed the cut-off thresholds during external short circuit, the line will be unnecessarily disconnected. In the proposed method, the serviceability of the high-frequency exchange channel is continuously performed, starting with a value close to the zero current value, which is less than the capacitive open circuit current of the line connected to the network from one of its ends.

The malfunction of the high-frequency channel of the exchange of wire lines in the inventive method is detected by the absence of a high-frequency signal at the receivers of sets of RE. Since the disconnection of the line switches also occurs on the basis of the absence of a high-frequency signal at the receivers, in case of a short circuit on the line, along with the disconnection of the line switches from the network, a malfunction of the high-frequency exchange channel will also pass. In order to exclude this, it is necessary, even with insignificant operating currents at the ends of the line, to provide an alarm of the fact of the presence of a high-frequency signal along the wires of the line and, accordingly, the working condition of the high-frequency channel. Due to this, the operation of the RE sets at the ends of the line and the disconnection of the line switches will be blocked. Signaling the presence of a high-frequency signal along the wires of the line and, accordingly, the working condition of the high-frequency channel with insignificant operating currents does not mean that this alarm should also be present at zero currents at the ends of the line. If this is so, then it will not be possible to disconnect the line even with a short circuit on it, because the presence of a high-frequency signal on the line wires will block the operation of protection kits at all ends of the line.

Due to the control of the total phase capacities and currents in the claimed method, there is a complete opportunity to automatically determine each damaged phase of the line.

Figure 1 presents a line diagram for one of its ends and a relay protection kit at one of the phases of the line at this end. Figure 2 shows a vector diagram of currents and voltages for the phase at the end of the line where the protection kit is located.

The circuit of the line for one of its ends contains phase 1, which is connected to the busbars 5 of the substation connected to the power and current source through the high-frequency signal trap 2 (3G), switch 3 (V), current sensor 4 (DT) at the considered end of the line 6. The high-frequency data exchange channel formed in the phase shown includes a communication capacitor 7, an attachment filter 8 (FP), a transmitter 9 (PE), a receiver 10 (PR), normally closed 11 and normally open 12 controlled keys. A current measuring body 13 (PT1), an additional current measuring body 14 (PT2), one of the inputs of the power relay 15 (PM) are connected to the current sensor, and the other input of the latter through the voltage sensor 16 (DN) is connected to the line phase. The composition of the circuit also includes a combinational logic multiplication circuit 17 (I), an indication circuit 18 (CIGN), a remote control circuit breaker 19 (REMOTE). Phase 1 through the coupling capacitor 7 and the connection filter 8 (FP) is connected to the input of the receiver 10 (PR), also through the normally closed 11 and normally open 12 controlled keys connected to the output of the transmitter 9 (PE). The output of the additional current measuring body 14 (PT2) is connected to the control input of the normally open controlled key 12. The output of the power relay 15 (PM) is connected to the control input of the normally closed controlled key 11. The output of the receiver 10 (PR) is connected to the display circuit 18 (SIGN) and the inverting input of the combinational logic multiplication circuit 17 (I), the other input of which is connected to the output of the current measuring body 13 (PT1). The output of the combinational logic multiplication circuit 17 (I) through the remote control circuit of switch 19 (REMOTE) is connected to switch 3 (B).

As current sensor 4 (DT) and voltage sensor 16 (DN) can be used, respectively, current transformers and voltage transformers with ferromagnetic cores. Current measuring organs 13 (РТ1) and 14 (РТ2), power relay 15 (РМ), combinational circuit 17 (И), controlled keys 11, 12, indication circuit 18 (СIGN), remote control circuit breaker 19 (DIST), transmitter 9 (ПУ), receiver 10 (PR), and connection filter 8 (FP) can be implemented on the basis of Analog Device components, on the basis of КР-1554 or ATMEL series electronic logic elements. The primary equipment of the trap 2 (ЗГ) and the coupling capacitor 7, as well as high-frequency posts containing a transmitter 9 (ПУ), a receiver 10 (PR), an attachment filter 8 (FP), are typical devices and systems manufactured by Russian enterprises.

The vector diagram of figure 2 presents for one of the ends, for example a two-terminal line, the characteristic of zero sensitivity of the power relay of one of the phases of the line, with a hatching in the direction of the relay action area, as well as the voltage and current vectors at the most probable actual boundaries of the range of angles in the working under conditions of I _p and in case of short circuit I _kz in the field of operation of the relay (power flows from the tires into the line, solid vectors) and outside the field of operation (the reverse direction or flow of power from the corresponding end of the line, dashed lines), additionally capacitive current I _c at idle line with the opposite end of the line disconnected, when the current flows out of the line at the considered end (solid small vector), similar to the capacitive open circuit current with respect to voltage U at the opposite end when the switch is disconnected at the initial end of the line when this current in the opposite direction (dotted small vector). The main angular ranges of currents in the field of action (solid vectors) and in the field of inactivity (dotted vectors) are combined by solid and dashed curly brackets, respectively. The angles of phase currents in non-phase and asynchronous modes will be basically in the same range as the operating currents, i.e. in non-phase modes it is close to the corners of the operating modes, and in asynchronous modes it is close to the corners of currents during short-circuit.

In operating the operating modes line idle its course and external faults on the phase line including the input circuits of the sensor current 4 (DT) flowing the operating current I _p, the capacitive current transverse conduction I _c, short-circuit current I _sc that at one end of the two-terminal line flow in the forward direction relative to the voltage of this end U (solid lines of current vectors I _p and I _kz ), and at the opposite end of the line relative to the voltage of the other end in the opposite direction (dashed lines). Transverse capacitive currents of transverse conductivity I _s in sufficiently loaded operating modes and during short-circuit are summed with longitudinal load and short-circuited components, forming at the ends of the line the total working I _p and short-circuited I _cz vectors shown in the diagram of figure 2. Transverse capacitive currents in their pure form flow along the line at one end, when the opposite end of the line is disconnected from the network and there is no current at this end. The vectors of these currents (solid and dotted) at their ends, where they exist, with respect to the voltages at these ends, are always outside the scope of the sets of REs at these ends. Therefore, when the end of the double-ended line is disconnected, the capacitive current of transverse conductivity I _c at the opposite end will always block the action of the protection sets at all ends of the line. In the case of a multi-terminal line, when disconnecting all ends of the line, except for one, the same situation occurs as when disconnecting one end of a double-end line. When a part of the ends is disconnected in the multi-terminal line and the other two or more ends are in operation, the expiration of power from some working end will provide additional blocking of the protection kits at all ends.

The technical implementation of the control of the scope and scope of action, as a rule, provides for the absence of input signals the output state of the monitoring device coinciding with one of the specified areas of action or inaction. Most often, the specified output state is taken to coincide with the area of inactivity. Therefore, when an internal short circuit when the fault vector _kz current I is within the scope on the supply end of the line, it is necessary to eliminate the blocking action of protection at this end. However, there is no current at the dead end or disconnected end, so the device that controls the direction of the current at this end will record the area of inactivity at the output and, as a result, block the action of the protection kits at all ends of the line. Therefore, measures should be provided to prevent blocking of RE sets from the side of the disconnected end of the line, namely, to ensure blocking of RE sets at the ends of the line, for example, only at currents exceeding the zero level, i.e. exclude blocking of the RE line from the RE set of the disconnected end.

The current through the current sensor 4 (DT) at the output is converted into a proportional sinusoidal signal with the same angles with respect to the voltage of its ends. This signal is fed to the current measuring body 13 (PT1), an additional current measuring body 14 (PT2) and the first input of the power relay 15 (PM), the phase voltage at each end of the line is supplied to the other input of the latter through the sensor 16 (DN). The output signals of the current measuring body 13 (PT1), the additional current measuring body 14 (PT2) and the power relay 15 (PM) act respectively on the combination circuit of the logical multiplication 17 (I), the controlled key 12 and the controlled key 11.

The key 12 at all ends of the line is closed almost constantly, as soon as the current through the sensor 4 (DT) exceeds the insignificant setting of the additional current measuring body 14 (PT2) at each end of the phase of the line, close to the zero value of the disconnected end of the line. In this case, the output of this body will be a logical unit signal acting on the key 12. The key 11 at all ends of the line is normally closed until the input signals or voltage angles of the power relay 15 (PM) are supplied or the current angles relative to voltage U are in the region inaction (dotted current vectors I _p and I _kz , solid vector I _c ). Then the output zero logic signal of the power relay, applied to the control input of the key 11, leaves it normally closed. The logical signal at the output of the current measuring body 13 (PT1) also remains zero until the current through the current sensor 4 (DT) exceeds the maximum operating line values with a margin. The logical zero signal from the output of the current measuring body 13 (PT1) is fed to one of the inputs of the combinational logic multiplication circuit 17 (I), and to the other inverting input, the signal of the logical unit from the output of the receiver 10 (PR) is received when it receives a high-frequency signal, which it comes either from the transmitter 9 (PE) of the kit through the managed keys 11 and 12 of the protection at the end of the line in question, or from the transmitter 9 (PE) through the managed keys 11 and 12, the connection filter 8 (FP), the coupling capacitor 7 of the opposite end of the line, phase 1 whether nii, also the coupling capacitor 7 and the connection filter 8 (FP) of the considered end. The presence of a high-frequency signal at the input and, accordingly, a logical unit at the output of the receiver 10 (PR) of the considered end of the line indicates the serviceability of the high-frequency communication channel through the phase 1 wire, because this signal is always in the operating modes of power transmission to the opposite end or external short-circuit after the last comes from the transmitter 9 (PE) of the opposite end through the phase 1 wire. Indeed, power relay 15 (PM) at the considered end (solid current vectors I _p and I _KZ ) breaks the key 11 and the transmitter 9 (ПЕ) of this end turns off, and at the opposite end the power relay 15 (РМ) picks up the dashed current vectors I _p and I _кз and generates zero control action on the key 11, so it turns out to be closed. The transmitter 9 (ПУ) of the opposite end transmits a high-frequency signal through the closed keys 11 and 12 to the input of its receiver 10 (PR), and through the connection filter 8 (FP) and the coupling capacitor 7 of the same end of the line, phase 1, also a capacitor 7, the connection filter 8 (FP) is fed to the input of the receiver 10 (PR) of the initial (considered) end of the line. Due to this, the receivers 10 (PR) at all ends of the line in operating, asynchronous and non-phase modes, external faults generate a unit logical signal at each end of the line, which is fed to the display circuit of high-frequency signal 18 (SIGN), signaling the health of the high-frequency communication channel at all ends lines. At the same time, at all ends, the logic signal of the unit is fed to the inverting input of the combinational logic multiplication circuit 17 (I), as a result of which the output logic signal of this circuit remains zero, which is also transmitted through the remote control circuit of switch 19 (REMOTE). Therefore, switch 3 (B) remains on.

When the line is idling, there is no current at the disconnected end, so the key 12 is open and the high-frequency signal from the transmitter 9 (ПУ) of this end does not directly go to the input of the receiver 10 (PR), however, at the supply end, the capacitive current of the line I _c (solid vector in Fig. .2) is outside the scope of the power relay 15 (PM), which consequently is inactive and there is a zero logic signal at its output, which is then transmitted to the control input of the key 11 and it remains closed. At the same time, key 12 is also closed at the supply end of the line, since the open circuit current through an additional current measuring element 14 (PT2) is sufficient for its operation. Therefore, at its output, a logical unit is generated that provides a logical unit at the control input of key 12 and its closed state. Due to the closed state of the keys 11 and 12, the blocking signal is sent directly to the receiver 10 (PR) of the considered supply end, and through the high-frequency channel of the connection filter 8 (FP) and the coupling capacitor 7 of the same end of the line, also wire 1, capacitor 7, connection filter 8 (FP) is fed to the input of receivers 10 (PR) of all the other ends of the line. This ensures the blocking of the protection during idle line. When short-circuiting line being idle, the current I through the protection _kOe set at the feeding end with respect to the voltage of this end will be located in a power relay action. At the disconnected end of the line, additional current measuring organs 14 (PT2), due to the lack of current in the line at the output, give a zero logic signal that holds the key 12 broken. Due to this, the RE set at the disconnected end of the line will not interfere with the action of the RE set at the supply end with a short to line to be successfully disconnected.

The signal of the logical unit from the output of the combinational circuit 17 (I) takes place in the absence of a high-frequency signal at the inputs of the receivers 10 (PR), in the presence of a zero logic at the output of the receivers 10 (PR) and when the currents exceed the settings of the current measuring organs 13 (PT1) at the current and opposite ends. This will be with short circuit on the line, in which there is a direction of currents from the tires to the line at all active ends of the line. As a result, the ends of the line will short-circuit current I _sc (solid vectors) which will exceed the set point and trigger a current measuring elements 13 (PT1), which will provide a logic one signal to one of the inputs of the combinational circuit 17 (I). A power relay 15 (PM) of the damaged phase at all ends of the line will fix the current angle I _kz (solid vector) in the field of operation and therefore will work. Then the key 11 will be disconnected at all ends. Due to this, the transmitters 9 (ПЕ) will be disconnected at all ends, which will ensure the disappearance of the high-frequency signal at the inputs of receivers 10 (PR) of all ends of the line. Then at the outputs of the receivers there will be a zero logical signal, which through an inverting input is converted to a logical unit. The combination circuit 17 (I) at the same time at its output will generate a logical signal of the unit, which through the remote control circuit 19 (REMOTE) will trip the switches 3 (B) at all ends of the line.

At the dead end of the line, in this case, due to a zero short-circuit current, the power relay 15 (PM) will be in a disabled state and will output a logic signal of zero. As a result, the managed key 11 will remain in a normally closed state. In this case, the additional current measuring body 14 (PT2) at its output will produce a zero logic signal, which will be at the control input of the key 12. It will open, and thus with the closed controlled key 11 at the dead end, the circuit will be open from the output of the transmitter 9 (ПЕ ) a blocking signal to the inputs of receivers 10 (PR) of all ends of the line. In the absence of a controlled key 12 at the dead ends of the line during short-circuit, high-frequency signals of transmitters 9 (ПУ) will be transmitted through a closed key 11 directly to their receivers 10 (PR), and through a connection filter 8 (FP) and a coupling capacitor 7 of the dead ends, phase 1 , the coupling capacitor 7 and the connection filter 8 (FP) of the other (starting) ends will also arrive at the inputs of the receivers 10 (PR) of all the other ends. This would lead to blocking the operation of relay protection kits at all ends, and the short circuit on the line could not be disconnected due to the dead end (disconnected) end of the line.

The best functioning of the protection according to the proposed method will be if the current settings of the current measuring body 13 (PT1), additional current measuring body 14 (PT2), current channels of the power relay 15 (PM) are selected as the lowest of the selectivity recommended by the conditions of the margin of reserve. The first should be detuned from the maximum operating mode, so as not to have false actions in load conditions, but an increase in the reserve can lead to the passage of short-circuit through transition resistance; the second should exceed the zero value of the currents of the disconnected ends of the line, but an increase in the margin will lead to a decrease in the sensitivity and, therefore, reliability of monitoring the working condition of the high-frequency channel, and the power relay on the current channel should exceed the phase noise, however, an increase in the margin will reduce the sensitivity of the line protection kits.

A distinctive feature of the methods for constructing high-frequency protections with a blocking exchange signal over the line wires, including those constructed according to the claimed method, is the absolute detuning from asynchronous modes, swings. High-frequency signals for blocking with external short-circuit are transmitted only through undamaged wires of the line, and with internal short-circuit the RF signal through the short-circuit location is not needed at all. The latter contributes to a better and more reliable detection of damage on the line. Thanks to the proposed method, the sensitivity of short circuit detection, the sensitivity and reliability of monitoring the health of RF exchange by wire are increased. The advantage of the proposed method is the response of the measuring organs directly to the full phase electrical quantities, which allows you to absolutely detune from the out-of-phase mode and carry out a three-system construction of channels of protection sets at all ends of the line, which is advisable for the use of single-phase automatic restart.

Claims (1)

A method of constructing and configuring relay protection with a high-frequency exchange blocking signal over the line wires, which consists in the fact that during a short circuit they transmit a blocking signal over the wires of the selected phase of the line and control the direction of electric power at each end of the line, after the power has expired at the end of the line with an external a short circuit continues to transmit the high-frequency blocking signal, with a short circuit on the line upon the fact of power leakage at each supply end of the line, the gears are stopped in case of exceeding the selected threshold by the selected response parameter, the switches of each end of the line are turned off, and in the operating modes of the line, the health of the high-frequency channel is monitored, characterized in that the high-frequency is continuously transmitted to it from the ends of the line with leaky power from any phase when the current exceeds zero blocking signal over the wires of the selected phase of the line, preventing the operation of sets of relay protection at all ends of the line in working, asynchronous and in-phase mode x, when external short circuits; by the presence of a high-frequency blocking signal at the ends of the line, the healthy state of the high-frequency channel is continuously monitored in operating, asynchronous and non-phase modes, with external short circuits and with its malfunction, detected by the absence of a high-frequency blocking signal, they provide signaling and blocking of the circuit breakers tripping.

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