JPH06327140A - Ground distance relay - Google Patents

Abstract

PURPOSE:To provide a digital ground distance relay in which the hardware can be simplified without sacrifice of the operational accuracy. CONSTITUTION:The ground distance relay 1 delivers a sampling sync signal for operating a ground distance relay 2 synchronously. The ground distance relays 1, 2 deliver zero-phase current values of their own lines from analog input sections 3, 4 based on the sampling sync signal and conduct zero-phase current correction based on the zero-phase current values of adjacent lines received by the counterpart analog input sections 3, 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ground fault distance relay, and more particularly to a digital ground fault distance relay used for protection of a digital current differential relay for protecting a transmission line of a power system.

[0002]

2. Description of the Related Art As a parallel two-line transmission line of a general electric power system, its entire configuration is shown in FIG. 3, and the connection part of a ground fault distance relay is shown in FIG. In FIG. 3, 17 is a generator, 18 and 19 are electric stations, 22 and 23 are lines 1 and 2 which are lines constituting a parallel 2-line transmission line, and 24 is a ground fault accident point. Further, 25 and 26 are instrument transformers that detect the voltage of each transmission line, 20 and 21 are current transformers that detect the current of each line, and 32 and 33 are circuit breakers that shut off the power supply to each line. 1 and 2 are ground fault points 2 based on the voltage and current values from the instrument transformers 25 and 26 and the current transformers 20 and 21.
4 is a ground fault distance relay that derives 4 and controls the corresponding circuit breakers 32 and 33.

In FIG. 4, a ground fault distance relay 1 has an analog input section 27 for A / D converting an analog voltage value from an instrument transformer 25 and an analog current value from a current transformer 20.
And a digital operation unit 28 for deriving the electrical distance to the ground fault accident point 24 based on each digital electricity amount from the analog input unit 27, and an external device for outputting a trip signal according to the output of the digital operation unit 28. And an interface 29. Further, reference numeral 30 is a breaking trip circuit for breaking the breaker 32 in response to the trip signal.

Further, 31 is an optical fiber for data transmission for connecting the ground fault distance relays 1 and 2, and the amount of electricity input to the analog input section 27 of the ground fault distance relays 1 and 2 and A / D converted is Through this optical fiber group 31,
The ground fault distance relays 1 and 2 are mutually transmitted and exchanged,
It is used for deriving the electrical distance to the ground fault accident point 24 in the digital arithmetic unit 28. The internal configuration and connection relationship of the ground fault distance relay 2 omitted in FIG. 4 are the same as those of the ground fault distance relay 1.

Now, in the parallel two-line transmission line of FIG.
When an a-phase ground fault occurs at a certain point 24 on the line 22, the voltage and current on the line 1 change. The analog input unit 27 of the ground fault distance relay 1 is connected to the voltage transformer 2
The change in the voltage and the current of the line 1 22 is detected via the current transformer 5 and the current transformer 20, and the digital calculation unit 28 performs the digital calculation processing based on these data and the data from the ground fault distance relay 2. The electrical distance to the accident point 24 is derived.

Namely, at the time of ground fault occurs, the a-phase current flowing through the line 1 22 I _a, a zero-phase current zero-phase current I _0, 2 Line 23 and I ₀ ■, also positive line 1 22 The phase impedance is Z ₁ , the zero-phase impedance is Z ₀ , the line-to-line mutual impedance is Z _m , the distance between the electric stations 18 and 19 is 1, and the distance from the relay installation point to the ground fault point 24 is X. When (0 ≦ X ≦ 1), the a-phase voltage V _{a at} the relay installation point of Line 1 22 can be expressed by Equation 1.

[0007]

[Equation 1]

[0008] Here, in order to accurately derive the electrical distance from the relay installation point by the number 1 to ground fault point 24, zero-phase current of the zero-phase current I ₀ and next line of its own line I ₀
It can be seen that it is necessary to consider (1), that is, zero-phase current compensation. Therefore, it is necessary to replace the zero-phase current I ₀ ■ each other between the ground fault distance relay 1 and 2 connected to each line, in order to further digital processing, the own line as next line zero-phase current I ₀ ■ The instantaneous values of the a-phase current I _a and the zero-phase current I ₀ at the same time are required, and it is necessary to synchronize the timing of sampling each electric quantity between the ground fault distance relays 1 and 2.

FIG. 5 is a functional block diagram showing a data transmission part between the conventional ground fault distance relays 1 and 2, and the analog input section 27 of the ground fault distance relay 1 includes an analog input circuit 34 for its own line and an adjacent circuit. Line analog input circuit 36
And the analog input section 27 of the ground fault distance relay 2 has an analog input circuit 35 for its own line and an analog input circuit 37 for an adjacent line.
1. Here, the optical fibers 38 and 40 for transmitting the sampling synchronization signal and the optical fibers 39 and 41 for transmitting the _zero- phase current values I ₀ and I ₀ are connected, respectively.

In FIG. 5, when the zero-phase current value I _{0 (} 2) detected by the ground fault distance relay 2 is transmitted to the ground fault distance relay 1, the ground fault distance relay 2 side adjacent line analog input circuit 37.
On the basis of the sampling synchronizing signal from the analog input circuit 34 for the own line on the ground fault distance relay 1 side received via the optical fiber 38, samples the zero-phase current I ₀ (2) of the Line 2 23, and via the optical fiber 39, It is transmitted to the analog input circuit 34 for the own line on the side of the short distance relay 1. The ground line distance relay 1 side own line analog input circuit 34 uses the adjacent line zero phase current I ₀ sampled by the ground line distance relay 2.
The instantaneous value of the
Due to this, zero-phase current compensation is performed. The same applies to the case where the zero-phase current value I ₀ of Line 1 22 sampled by the ground fault distance relay 1 is transmitted to the ground fault distance relay 2.

Therefore, when the data transmission method shown in FIG. 5 is used, the timings at which the electric quantities of the own line and the adjacent line are sampled are synchronized, and as shown in FIG. If a one-line ground fault occurs in the, the impedance Z _a (= X · Z ₁ ) seen from the ground fault distance relay 1 (phase a) of Line 1 is based on the above-mentioned formula 1 and the following formula 2 Can be derived directly by.

[0012]

[Equation 2]

Although the adjacent line zero-phase current value is delayed by the data transmission delay time between the ground fault distance relays 1 and 2, the sampling interval normally used is about twice as many times as the number of sampling times. , The impedance Z _a with high accuracy is derived.

[0014]

Therefore, in such a conventional ground-fault distance relay, an analog input circuit for its own line and an adjacent line is provided as an analog input section for high-speed synchronous data transmission via an optical fiber. Since it is configured to perform, the number of hardware of the analog input section increases, and in particular, when the accuracy of the analog input section is increased to improve the accuracy of the derived impedance, There has been a problem that the scale of the input section becomes enormous and it becomes difficult to mount the analog input section on the relay board. The present invention is intended to solve such a problem, and an object of the present invention is to provide a digital ground fault distance relay capable of simplifying hardware without reducing the operation accuracy of the relay.

[0015]

In order to achieve such an object, the ground fault distance relay according to the present invention has one of the ground fault distance relays as the master side and the other as the slave side, and this slave side ground relay is used. The sampling distance between the two relays is synchronized with the master side relay by subordinate synchronization.

Further, as the amount of electricity transmitted to each other, an admittance equivalent value calculated from a voltage value and a current value sampled from a line to which each local distance relay is connected is used.

[0017]

Therefore, the master side ground fault distance relay transmits the sampling synchronization signal and the quantity of electricity sampled based on this, and the slave side ground fault distance relay transmits the quantity of electricity sampled based on the received sampling synchronization signal. It Further, the admittance-equivalent value is calculated from the voltage and current sampled from the own line by the local distance relay and is transmitted mutually.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the present invention will be described with reference to the drawings. FIG. 1 is a functional block diagram showing a data transmission part between ground fault distance relays that protect a parallel two-line transmission line according to an embodiment of the present invention. Note that, in FIG. 1, the configuration of the parallel two-line power transmission line to which the local distance relay is connected is the same as that described above (FIGS. 3 and 4), and will be omitted here.

In FIG. 1, 1 is a digital ground fault distance relay that protects Route 1 (see FIG. 3), 2 is a digital ground fault distance relay that protects Route 2, and 3 and 4 are local fault distance relays. Analog inputs for own line and adjacent lines provided for 1 and 2, 5 are optical fibers for supplying a sampling synchronization signal from the ground fault distance relay 1 to the ground fault distance relay 2, 6 is from the ground fault distance relay 1 An optical fiber for transmitting the zero-phase current value I ₀ of Line 1 to the ground fault distance relay 2, 6 is from the ground fault distance relay 2 to the ground fault distance relay 1 2
It is an optical fiber for transmitting the zero-phase current value I _{0 (2)} of the signal line.

Data transmission performed between the ground fault distance relays 1 and 2 will be described as an operation of the present invention with reference to FIG. Now, when the ground fault distance relay 1 is set as the master and the ground fault distance relay 2 is set as the slave,
A sampling synchronization signal is transmitted from the ground fault distance relay 1 to the ground fault distance relay 2 via the optical fiber 5. As a result, the slave-side ground fault distance relay 2 is slave-synchronized with the master-side ground fault distance relay 1,
The ground fault distance relay 2 samples the zero-phase current I _{0 (1)} based on this sampling synchronization signal and transmits it to the ground fault distance relay 1 via the optical fiber 7, and the ground fault distance relay 1 internally generates it. The zero-phase current I ₀ is sampled based on the sampling synchronization signal and transmitted to the ground distance relay 2 via the optical fiber 6.

Therefore, according to this data transmission method, the master side, that is, the ground fault distance relay 1 does not need to accurately receive the sampling from the ground fault distance relay 2 of the adjacent line, and the slave side, that is, the ground fault. Since the distance relay 2 does not need to generate and transmit a highly accurate sampling synchronization signal, the analog input unit for the own line and the analog input unit for the adjacent line can be partially shared, and the number of hardware of the analog input unit can be increased. Is reduced. Further, similarly to the conventional data transmission method shown in FIG. 5 described above, for example, the impedance Z _a seen from the ground fault distance relay 1 (a phase) can be directly derived by the equation shown in Formula 2, The local distance relays 1 and 2 operate at high speed and with high accuracy.

Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 2 is a functional block diagram showing a data transmission portion between ground fault distance relays that protect a parallel two-line transmission line according to an embodiment of the present invention. Note that, in FIG. 1, the configuration of the parallel two-line power transmission line to which the local distance relay is connected is the same as that described above (FIGS. 3 and 4), and will be omitted here.

In FIG. 2, 1 is a digital ground fault distance relay that protects Line 1 22 (see FIG. 3), 2 is a digital ground fault distance relay that protects Line 2, and 8 and 9 are local fault distance relays 1. , 2 are analog inputs shared by the own line and the adjacent line, and 10 are admittance equivalent values (I ₀ / V) based on the zero-phase current value I ₀ of Line 1 from the ground fault distance relay 1 to the ground fault distance relay 2. an optical fiber for transmitting _a ), 11 is a ground fault distance relay 2 to a ground fault distance relay 1 2
It is an optical fiber for transmitting the admittance equivalent value (I ₀ / V _a ) based on the zero-phase current value I ₀ (2) of the signal line.

Here, a description will be given of a case where in the local fault distance relay 1, the electrical distance to the ground fault point 24 is derived by using an admittance equivalent value instead of the zero-phase current I _{0 (} 1) of the adjacent line. 3, the a-phase voltage at the ground fault distance relay 1 constellation points Line 1 22 V _a, 2 Line 2
The a-phase voltage at the grounding distance relay 2 placement point of 3 is V _a
Then the voltage of each phase at these points is equal,
That is, since it can be considered that V _a = V _{a (} 3), the following equation 3 holds.

[0025]

[Equation 3]

Therefore, the above equation 2 can be transformed into equation 4.

[0027]

[Equation 4]

Here, the term of I ₀ {circle around (4)} / V _a {circumflex over (4)} in Equation 4 is obtained from the adjacent line zero-phase current I ₀ {circle around (2)} and the a-phase voltage V _a ■ at the ground fault distance relay 2 arrangement point, This can be obtained only by the data that the relay itself can directly obtain in the ground fault distance relay 2.

As a result, when the impedance Z _a is derived in the ground fault distance relay 1, the adjacent line zero phase current I synchronized with the a phase voltage V _a and the zero phase current I ₀ sampled by the ground fault distance relay 1. _It is not necessary to sample ₀ <2> by the ground fault distance relay 2 and transmit it to the ground fault distance relay 1. Further, this I ₀ ■ / V _a is an admittance-equivalent value which is considered to have a very small temporal change during the continuation of the system fault, and the influence of the sampling time difference on the impedance is small. It becomes possible to transmit.

Therefore, the local distance relay 2 is the Route 2 2
A admittance-equivalent value is calculated by a digital operation unit (not shown) based on the voltage and current values sampled from the device 3 at the timing of its own device, and the admittance-equivalent value is asynchronously transmitted from the analog input unit 9. The ground fault distance relay 1 derives impedance based on the adjacent line admittance equivalent value received via the optical fiber 11 and various electric quantities sampled from the own line, and based on this result, the circuit breaker 3
Control the protection action of 2. As a result, it is possible to reduce the configuration for sampling synchronization and the optical fiber for transmitting the sampling synchronization signal in the analog input portions of the local distance relays 1 and 2, and to further simplify the device.

When the admittance-equivalent value is transmitted, since the conductance component and the susceptance component are actually transmitted separately, six data (three phases) are transmitted in one direction. In addition, as a feature of this method, there is no operation delay in an accident (near-end accident) that can operate without adjacent line information.

[0032]

As described above, according to the present invention, the parallel 2
In the ground fault distance relay that protects the line transmission line, one side is the master side and the other side is the slave side, and the slave side is subordinately synchronized by the sampling synchronization signal from the master side. Since the admittance-equivalent value is transmitted as the adjacent line electricity quantity, it is not necessary to perform sampling synchronization in both relays, and the analog input section corresponding thereto is not necessary. Therefore, in the digital ground fault distance relay, there is a special effect that the hardware can be simplified without reducing the operation accuracy of the relay.

[Brief description of drawings]

FIG. 1 is a functional block diagram showing a data transmission part between ground fault distance relays according to an embodiment of the present invention.

FIG. 2 is a functional block diagram showing a data transmission part between ground fault distance relays according to a second embodiment of the present invention.

FIG. 3 is a connection system diagram showing an overall configuration of a general electric power system parallel two-line transmission line.

FIG. 4 is a connection system diagram showing a connection portion of the ground fault distance relay of FIG.

FIG. 5 is a functional block diagram showing a data transmission part between conventional ground fault distance relays.

[Explanation of symbols]

 1, 2 Ground fault distance relay 3,4 Analog input section 5,6,7 Optical fiber 8,9 Analog input section 10,11 Optical fiber 17 Generator 18,19 Electric power station 20,21 Current transformer 22 Parallel two-line transmission line Line 1 23 Line 2 of parallel 2-line transmission line 24 Ground fault accident point 25, 26 Instrument transformer 27 Analog input unit 28 Digital operation unit 29 External interface 30 Circuit breaker trip circuit 31 Optical fiber group 32, 33 Circuit breaker

Claims (2)

[Claims] 1. A ground fault point is arranged on both lines of a parallel two-line power transmission line of an electric power system, mutually transmits the amount of electricity sampled at the same time from each line, and performs digital operation processing based on this amount of electricity to ground fault points. In the ground fault distance relay that derives the electrical distance to, and protects each line according to this result, one of the ground fault distance relays is the master side, the other is the slave side, and this slave side ground A ground-fault distance relay, characterized in that sampling of both of them is performed by subordinately synchronizing the distance relay with the master-side distance relay. 2. Electricity up to the ground fault accident point is arranged on both lines of a parallel two-line power transmission line of the electric power system, the electric quantities sampled from the respective lines are mutually transmitted, and digital calculation processing based on the electric quantities leads to a ground fault accident point. In a ground fault distance relay that derives the target distance and protects each transmission line according to this result, the amount of electricity transmitted to each other is the voltage sampled from the line to which the local distance relay is connected. A ground fault distance relay, which is a value equivalent to an admittance calculated from a value and a current value.