JPH07327315A - Ratio differential relay - Google Patents

Abstract

PURPOSE:To prevent erroneous function due to an operational region in the way of variation when the operation results varies with time toward a fault point due to the influence of a filter, for example, upon occurrence of an external fault. CONSTITUTION:A suppression current input processing section 26 and a differential current input processing section 27 are provided with delay processing sections 60, 61 where a decision is made whether switching is made between the delayed input and a normal input. The characteristics varies such that the locus of fault does not pass through an operational region thus preventing erroneous function. In this regard, the input is switched by discriminating between the occurrence of fault and the removal of fault based on the varying direction of the magnitude of current.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ratio differential relay for detecting an internal accident in a generator or the like.

[0002]

2. Description of the Related Art FIG. 7 is, for example, 8, 1, 6 issued by Denki Shoin Co., Ltd., "Protective relay technology", October 15, 1972.
High speed variable ratio differential relay (P218-P
219) is a block diagram showing an arithmetic type digital protective relay realized by using the technique shown in "Digital Relay", published by The Electric Cooperative Research Group, Vol. 41, No. 4, "Digital Relay". In the figure, reference numeral 1 is an input converter for converting an input such as a current or voltage input to the relay into an appropriate voltage (about several volts).

Reference numeral 2 is a filter circuit for attenuating harmonic components from the input voltage at the input converter 1, 3 is a sample hold circuit for holding the analog input from the filter circuit 2 at a certain sample time at the value at that time, 4 Is a multiplexer circuit for outputting an analog input, which holds a plurality of inputs at the same time by the sample hold circuit 3, to an analog / digital conversion circuit (hereinafter referred to as an A / D conversion circuit) while sequentially switching.

Further, 6 is a buffer circuit for temporarily storing the digital signal from the A / D conversion circuit 5, 7 is a digital input interface circuit for inputting another digital signal from the outside, and 8 is an operating value of the protective relay or use. It is a settling panel that is a switch for inputting a frequency.

Further, 9 is a settling interface circuit for inputting a switch signal from the settling panel 8, 10 is an input from the buffer circuit 6, the digital input interface circuit 7 and the settling interface circuit 9, and performs arithmetic processing of the protective relay. Microprocessor (hereinafter,
Reference numeral 11 denotes a random access memory (hereinafter, referred to as R) for writing and reading data necessary for calculation.
AM).

Further, 12 is a read only memory (hereinafter, referred to as RO
Reference numeral 13 denotes a digital output interface circuit for outputting the calculation result of the CPU 10, which drives the output relay circuit 14 to output a contact to the outside.

Next, the operation will be described. The arithmetic digital protection relay realizes a relay function by periodically sampling input quantities such as current and voltage, converting them into quantized digital quantities, and calculating them according to a program. .

That is, first, the current and voltage input from the power system to be protected are converted into input signals of appropriate levels by the input converter 1, and the harmonic components are removed by the filter circuit 2. The output signal from the filter circuit 2 is periodically sampled, and the sample and hold circuit 3 of each channel holds the instantaneous value at the same time.

Then, the two held analog values for each channel are sequentially selected by the multiplexer circuit 4 and input to the A / D conversion circuit 5, where they are converted into digital signals and then the buffer circuit 6 Through C
It is read by the PU 10.

The operations from the signal output selection by the multiplexer circuit 4 to the reading of the CPU 10 are sequentially executed for each channel, so that the instantaneous value data of each channel at the same time is taken out and the RAM is obtained.
It is stored in 11. Further, in order to obtain these data periodically, the sampling signal to the sample hold circuit 3 is periodically sent from the CPU 10 and controlled.

Further, the CPU 10 executes digital filter calculation, peak value calculation, etc. according to the program in the ROM 12 based on the instantaneous value data for each cycle stored in the RAM 11, and the settling panel 8 through the settling interface circuit 9 The relay operation is calculated by comparing with the input settling data.

Next, FIG. 8 shows an example of a block diagram when a high speed variable comparison relay is realized by this arithmetic digital protection relay. Here, the parts having the same or equivalent functions as those in FIG. 7 are designated by the same reference numerals, and the duplicated description will be omitted.

In FIG. 8, 21 is a generator to be protected, 24 is a current transformer that detects the current on the load side, 23 is a current transformer that detects the current on the neutral point side, and 24 is the current on the load side. I ₁
And a suppression current input transformer that obtains a suppression current by combining the current I ₂ at the neutral point and converts it into an appropriate suppression current signal.

Further, 25 is a differential current input transformer that detects the difference between the current I ₁ and the current I ₂ and converts it into an appropriate differential current signal, and 26 is a filtering process for the suppression current signal.
It is a suppression current input processing unit that performs effective value calculation.

Further, 27 is a differential current input processing section for performing a filtering process or the like on the differential current signal to perform an effective value calculation.
Reference numeral 8 is a non-linearity processing unit that changes the multiple of the input value in the large current region according to the ratio characteristic, and 29 is an operation determination processing unit that performs the operation determination based on the suppression current data and the differential current data.

Next, the operating principle of such a high speed variable ratio relay will be described with reference to FIGS. 9 and 10. Figure 1
0 indicates each current state on the load side and the neutral point side, (a)
Is a sound state, (b) shows an external accident at a current level at which the current transformers 23 and 24 are not saturated, (c) shows an external accident at a current level at which the current transformers 23 and 24 are saturated, and (d) shows an internal accident. ing.

This high speed variable ratio relay has a generator 21
10 (d), only the internal accident is detected to operate, and the other cases shown in FIGS. 10 (a), 10 (b), and 10 (c) do not operate. Therefore, the differential current is I ₁ −I ₂ and the suppression current is I
_{It is obtained by 1} + I _{2 and} operates according to the operation characteristic shown by the ratio characteristic 40 in FIG. In addition, the point a in FIG.
b, c, d correspond to FIGS. 10A, 10B, 10C and 10D, respectively.

That is, in the normal state of FIG. 10A, the current I ₁ on the load side of the generator 21 and the current I ₂ on the neutral point side are
It is the same direction and the same current value. If the current at this time is I
_{If 1} = 1 and I ₂ = 1 are considered, the differential current is I ₁ −
I ₂ = 0 and the suppression current is I ₁ + I ₂ = 2, which corresponds to point a on the suppression current line on the horizontal axis on the characteristic diagram of FIG. 9 and is inoperative.

Further, in the external accident of FIG. 10 (b), it is assumed that the current transformers 22 and 23 are at a small current level at which the current transformers 22 and 23 are not saturated, and the current at this time is assumed to be I ₁ = I ₂ = 2. 10A, since the current direction is the same as that in the normal state of FIG. 10A, the differential current is I ₁ −I ₂ = 0 and the suppression current is I ₁ + I ₂
= 4, which corresponds to point b on the characteristic diagram of FIG. 9 and is inoperative.

Further, FIG. 10 (c) shows an external accident,
The current flowing through the primary side of the current transformers 22 and 23 is I ₁ = I ₂ , but the current value on one side (here, the I ₂ side) 23 is saturated due to the large current value, and the current transformer the output from 22 and 23 on the assumption that a I ₁ ≠ I _2, the current at this time if, saturation and non I ₁ side I ₁ = 5, the saturation to have I
_{On the 2} side, when I ₂ = 2, it seems that a differential current is virtually generated I ₁ −I ₂ = 3, and the suppression current is also I ₁ +
I ₂ = 7.

When the current transformer 23 is saturated in this manner, it appears that a differential current is generated and is apt to malfunction, but in the high speed variable ratio relay, such malfunction at a large current is caused. To prevent this, the curve A of the ratio characteristic 40 in FIG.
As described above, the operating characteristic has a low sensitivity in the large current region, and due to this variable ratio characteristic, it becomes inoperative like point C on the characteristic diagram of FIG.

Next, in FIG. 10 (d), an internal accident of the generator is assumed, and since the accident current flows toward the accident point,
The current I ₂ is the same as that in the normal state, but the current I ₁ is in the opposite direction to that in the normal state. Assuming that the current value at this time is I ₁ = 1 and I ₂ = 2
Then, the differential current becomes I ₁ − (− I ₂ ) = 3, and the suppression current becomes I ₁ + (− I ₂ ) = 1, and it operates at point d on the characteristic diagram of FIG. 9 and detects an accident. can do.

[0023]

Since the conventional high speed variable ratio relay is constructed as described above, the suppression current I
_When an accident occurs in which the accident locus of ₁ and the differential current I ₂ changes from point O (before failure) to point P (after failure) in FIG. 9, due to the influence of the filter circuit 2 in the relay body, It does not change from O to P instantaneously, but it changes to 15 in FIG.
Since it moves linearly like the accident locus 41 in a time of ms to 35 ms, there is a problem in that the relay passes through the operation area during the movement and the relay operates only at that moment.

That is, the static operation characteristic and the input amount, which are the operation characteristics when the input amount is slowly changed due to the malfunction of the relay despite the fact that the input amount is outside the relay operation characteristic, are suddenly increased in an instant. However, there is a problem in that the transient operation characteristic (that is, the transient characteristic indicates the response of the relay when the system fails), which is the operation characteristic when the temperature is changed.

Further, in the above, the occurrence of an accident that changes from the O point to the P point has been taken as an example, but when this accident is released by an external protection device, it will change to P → O on the contrary, Even at this time, there was a problem that the relay passed the operating range just like when an accident occurred and the relay operated only for a moment.

The invention of claim 1 is to solve the above problems, and reduces the difference between the static operation characteristic and the transient operation characteristic, that is, the characteristic required as a relay in the static operation characteristic. It is an object of the present invention to obtain a ratio differential relay having a ratio differential algorithm that can make the relay response at the time of an actual system failure to have the same characteristic as the required characteristic.

According to the second aspect of the present invention, only the differential current input data or only the suppression current input data is delayed depending on whether the external accident occurs or the external accident is canceled, so that the accident locus erroneously passes through the operating range. The purpose is to obtain a ratio differential relay that can prevent

According to the third aspect of the present invention, when the suppression current input and the operating range are entered at the time of an external accident or when the accident is cleared, the operation determination output is prohibited for a time longer than the time of entering this operating range to prevent a transient malfunction. The purpose is to obtain a ratio differential relay that can be prevented.

According to the fourth aspect of the present invention, the operation determination is performed based on each input through each input processing unit of the suppression current and the differential current without a filter, so that an external accident passing through the operation range can be prevented. The objective is to obtain a ratio differential relay that can prevent malfunctions at the time of external accident occurrence and accident cancellation.

[0030]

A ratio differential relay according to the invention of claim 1 is a suppression current input processing section for processing a suppression current input obtained by combining a load side current and a neutral point side current. A differential current input processing unit that processes a differential current input obtained from the difference between the load-side current and the neutral-point-side current, the output of the differential current input processing unit, and the suppression current input processing unit The operation determination is performed based on the output of, and the malfunction preventing means prevents the accident trajectory when an external accident occurs or when the external accident is released from passing through the operating range of the ratio characteristic.

The ratio differential relay according to the invention of claim 2 is
Suppression current input data switching processing unit for switching and outputting either the suppression current input or the suppression current input from the suppression side delay processing unit, and the differential current input from the differential current input and differential side delay processing unit A differential current input data switching processing section for switching and outputting either of the above, and the rising / falling discrimination means is provided with the suppression current input or / and the differential current input and each suppression current input due to these delays or / And the change of the magnitude with the differential current input are discriminated,
The control output is controlled by the suppression current input data switching processing unit and the differential current input data switching processing unit, and the operation determination processing unit is caused to output the normal / inoperative data when an external accident occurs or when the external accident is released. It is a thing.

The ratio differential relay according to the invention of claim 3 is
An operation determination processing unit that determines that the suppression current input and the differential current input transiently pass through the operating range of the ratio characteristic when an external accident occurs or when the external accident is released, and the suppression current input and the differential current input. A determination processing unit for timer switching that sets a predetermined operation region of the ratio characteristic set as a reference as a comparison delay region is provided, and when the suppression current input and the differential current input are within the comparison delay region, the operation is performed. The time switching processing unit is caused to set a time longer than the time within the collation delay region by the timer, and the normal / inoperative data is output during this time.

The ratio differential relay according to the invention of claim 4 is
A first operation determination processing unit that determines whether the suppression current and the differential current due to an external accident pass through the operation region or the non-operation region based on the outputs of the suppression current input processing unit and the differential current input processing unit. A second operation for determining whether the suppression current and the differential current due to an external accident pass through the operation range or the non-operation range based on the outputs of the filterless suppression current input processing unit and the filter-less differential current input processing unit An AND circuit is provided to allow the AND circuit to select the output of the second operation determination processing section during a static operation in which the suppression current input and the differential current input slowly change, while the first circuit is selected during a transient operation in which the change operation rapidly changes. The output of the operation determination processing unit is selected.

[0034]

In the ratio differential relay according to the first aspect of the present invention, it is possible to prevent the accident locus from entering the relay operation area at the time of an external accident by the avoidance processing by the malfunction preventing means.

According to another aspect of the present invention, in the ratio differential relay, the suppression current input and the suppression current input obtained by delaying the suppression current, and the differential current input and the differential current obtained by delaying the differential current are provided. By switching the input and output according to the change in the magnitude of the data before and after delaying either or both of the suppression current and the differential current, when an accident occurs, only the differential current input data is delayed, Also, when the accident is cleared, by delaying only the suppression current input data,
A motion decision is made so that the accident trajectory up to the accident point passes through a non-operation area that avoids the operation area to prevent malfunction due to transient response.

In the ratio differential relay according to the invention of claim 3, when it is judged that the ratio differential relay is in the operating range to pass in the case of an external accident, a straight line accident up to the accident point is carried out in the same manner as the judgment of the conventional ratio characteristic. When the locus is determined and the accident locus is in the operation range, the operation time is lengthened to prevent a transient malfunction.

In the ratio differential relay according to the invention of claim 4, the filterless suppression current input processing section and the filterless differential current input processing section in which the filter circuit causing the response time delay is eliminated, and the first and second operation determinations are made. The processing unit instantaneously locks the operation output of the person who used the filter in the event of an external accident to prevent a transient malfunction.

[0038]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, reference numeral 60 is a delay processing unit for suppression current data, 61 is a delay processing unit for differential current data, and 62 is a current suppression current data output to a motion determination processing unit (first motion determination processing unit) 29. It is a suppression current input data switching processing unit that switches whether to output the suppression current data delayed by the delay processing unit 60 by a switching signal of a process described later.

Reference numeral 63 denotes a differential current input data switching processing section for switching differential current data by the same processing as described above.
Reference numeral 64 indicates the current data of the suppression current data and the delay processing unit 60.
It is a rising / falling discrimination processing section that discriminates a rising edge due to an accident occurrence or a falling edge due to an accident cancellation by using the output data from and outputs a switching signal to each of the switching processing sections 62 and 63. K is an operation range avoiding means constituted by the above processing units.

FIG. 2A shows a differential current input waveform 43 to the ratio differential relay, FIG. 2B shows an output characteristic 44 of the differential current input processing section 27, and FIG. The suppression current input waveform 45 to a ratio differential relay (henceforth a relay) is shown, FIG.2 (d) shows the suppression current input process part 2 inside a relay.
6 shows the output characteristic 46 of No. 6.

Further, FIG. 2 (e) is a ratio differential characteristic diagram, and 41 shows the suppression current and the differential current of the input O → P.
Accident locus that is input to the relay when it changes linearly to
Reference numeral 42 indicates a motion determination locus due to the transient response change at the time of rising described in the first embodiment.

Next, the operation will be described. When an accident occurs, the suppression current and the differential current change linearly and instantaneously as a relay input, but due to the filter circuit 2 and the like in the suppression current input processing unit 26 and the differential current input processing unit 27 inside the relay. Due to the rising delay, the outputs from them have a characteristic that they normally rise with a time of 15 ms to 35 ms as shown in FIGS. 2 (b) and 2 (d), respectively.

For example, when the time T elapses after the occurrence of the accident, the output from the suppression current input processing unit 26 is R _T from the output characteristic 46, and the delay time by the suppression current delay processing unit 60 is t. , The output corresponds to the output at the time point Tt in the output characteristic 46, and at this time, the output voltage is R
_(Tt) .

Therefore, the values of R _T and R _(Tt) are
By calculating R _T −R _{(Tt) in} the rise / fall determination processing unit 64, it is determined that the result is positive and the result is negative when the result is positive.

In the case of FIG. 2, since it is determined to be positive and rising, the output of the suppression input data switching processing unit 62 is R at the time T.
_T , a switching signal is output so that the output of the differential input data switching processing unit 63 becomes the data D _(Tt) at the time point T-t,
The data input to the motion determination processing unit 29 is switched.

[0046] If the conventional, since the operation determination section 29 has been inputted data in the data R _T and T point D _T of the differential current input processor 27 at time point T of suppression current input processing unit 26 In addition, the determination result is P in FIG.
_One point causes a malfunction, but when an accident occurs (rises) due to the above processing, the input processing data by the differential current input processing unit 27 is delayed by the delay processing unit 61 for t time t-t.
Since the data D _{(Tt )} at the time point is switched to, the determination result is positive or inoperative (the determination result is positive, and as a result, inoperative or inactive. The same applies hereinafter) at the point P _{2 in the} inactive region.

That is, the locus of the operation determination when an accident occurs due to the above processing is the curve 42, and the malfunction due to the transient operation characteristic can be prevented.

Next, the processing at the time of canceling the accident (at the time of falling) will be described with reference to FIG. Here, FIG. 3A shows the differential current input 53 to the relay, FIG. 3B shows the output characteristic 54 of the differential current input processing unit 27 inside the relay, and FIG.
FIG. 3C shows the suppression current input 55 to the relay, and FIG.
(D) shows the output characteristic 56 of the suppression current input processing unit 26.

Further, FIG. 3 (e) is a ratio differential characteristic diagram, and 51 is the input suppression current and differential current P → O.
Accident locus that is input to the relay when it changes linearly to
Reference numeral 52 denotes a motion determination locus based on the transient response change at the time of falling described in the first embodiment.

First, when the accident is cleared, as in the case of the occurrence of the accident, a delay occurs in the relay internal input processing. For example, when the time T elapses after the accident is released, the output from the suppression current input processing unit 26 is R _T from the characteristic curve 56, and when the delay time of the suppression current delay processing unit 60 is t, the output is the characteristic. R corresponding to the output at time T-t in the curve 56
_(Tt) .

The values of R _T and R _(Tt) are used as a result of the R _T -R _(Tt) determination in the rising / falling discrimination processing unit 64.
Since the trailing edge is detected negatively, the suppression input data switching unit 6
2 outputs the switching signal so that the output of the differential input data switching unit 63 becomes the data D _T at the time _T, and the output of the differential input data switching unit 63 becomes the data R _(Tt) at the time T-t. The data input to 29 is switched.

As a result, in the conventional case, since the data at the R _T point and the D _T point were input to the motion judgment processing unit 29, the judgment result is that a malfunction occurs at the P ₃ point in the motion range. By the above processing, when the accident is released (falling), the data is switched to the data at the point D _(Tt) , so that the determination result is normal / inoperative at the point P ₄ .

In other words, the locus of the motion judgment at the time of the accident cancellation by the above process becomes the curve 52, and the malfunction due to the transient motion characteristic can be prevented.

It should be noted that in the above, an example of the first embodiment is shown, and it is possible to perform the rise / fall determination by using a differential circuit other than the suppression circuit or a combination of both.

Example 2. In the first embodiment described above, the one in which the increase or decrease of the input is detected and the differential current or the suppression current is delayed is used so as not to transit the operating range transiently. The same purpose can be achieved by using a method of detecting that the operation time is changed and changing the operation time. According to this method, there is no need to detect increase / decrease of input or delay of input, and there is a merit that the processing becomes simple.

The second embodiment of the present invention will be described below with reference to the block diagram of FIG. 4 and the ratio characteristic diagram of FIG. In the figure, the same components as those of the conventional one are designated by the same reference numerals, and the duplicated description will be omitted. In FIG. 4, reference numeral 70 indicates an accident locus of the suppression current and the differential current from O → P.
A timer switching determination processing unit that performs a characteristic determination process for switching the timer during a transition that changes to
It is determined that the straight line OP is below the straight line 72.

Further, in FIG. 5, reference numeral 73 is the original ratio characteristic 40 and the determination straight line 7 for switching the number of collations.
It is a collation delay area as an operation time switching area surrounded by 2. Further, in FIG. 4, 71 is the matching delay area 73.
Is the operation time switching processing unit that switches the number of times of collation when it is inside the two AND gates 7.
4, 75, a timer 76 and an OR gate 77.

Next, the operation will be described. In FIG. 5, when the system fault occurs at the point P, the input current of the relay transiently changes from the point O to the point P due to the influence of the filter 2 and the like, and passes through the operating range, as described above. The passing time is a limited time, and if the time is shorter than the time when the operation determination processing unit 29 determines that the operation is performed, it does not operate as a relay.

The transit time is mainly due to the digital filter processing and the effective value calculation in the filter 2 of the analog circuit and the respective current input processing units 26 and 27. These times are considered to be approximately 15 ms to 35 ms, although they differ depending on the characteristics of the filter and the calculation method.

Therefore, it is sufficient to determine whether the time is within the collation delay area 73 and switch to a timer longer than that, for example, 50 ms.

That is, during the transition, the output of the motion determination processing unit 29 becomes "1" in the operating range between the points P ₁ and P ₂ in FIG. The output of the processing unit 70 also becomes "1", and this 2
The AND gate 74, which makes one of the AND conditions, also outputs "1", starts the timer 76, and the AND gate 75 takes the AND condition with the output of the operation determination processing unit 29 under the inversion condition thereof. AND output is "0"
And there is no operation output to the outside.

On the other hand, since the time of the timer 76 is set longer than the transit time from the point P _{1 to the} point P _{2 in} FIG. 5, the output of the timer 76 never becomes "1". Then, when it comes out of the collation delay area 73, the output of the motion determination processing unit 29 becomes "0", the output of the AND gate 74 also becomes "0", the timer 76 does not start, and the output of the motion determination processing unit 29 remains unchanged. It comes out, but it does not work because it is out of the operating range.

In this way, even in the transient response that passes through the operation range, the malfunction can be prevented by prohibiting the output of the operation determination output by the timer 76. Further, even when the system fault is canceled, the same control can be performed by the output prohibiting operation of the timer 76.

Example 3. In the first and second embodiments, the straight line OP of the suppression current input and the differential current input is transiently prevented from passing through the operation range, or the operation time is changed to temporarily change the characteristics. Although shown, the same object can be achieved by using a method of determining the characteristics without changing the characteristics by separately providing a circuit with minimal transient fluctuation. According to this method, since the characteristics are not changed even temporarily, there is an advantage that more faithful determination can be performed.

The third embodiment will be described below with reference to the operation block diagram of FIG. In the figure, the same reference numerals are given to the parts having the same configurations as the conventional ones, and the duplicated description will be omitted. Unlike the suppression current input processing unit 26, 80 is an unfiltered suppression current input processing unit that performs input processing other than filtering, and 81 is a filterless differential current input processing unit that also performs input processing excluding filtering.

Reference numeral 82 denotes each of these input processing units 80,
An operation processing unit (second operation determination processing unit) that determines the ratio characteristic using the output of 81, and 83 is an output of the conventional first operation determination processing unit 29 and an output of the second operation determination processing unit 82. Is an AND gate as an AND circuit that takes the AND condition of. 28A and 28B are the first and second non-linear processing units.

Next, the operation will be described. As described above, in FIG. 9, when a system fault occurs at point P, the relay input current transiently changes from point O to point P due to the influence of the filter 2 and the like, and passes through the operating range. However, since the filterless suppression current input processing unit 80 and the filterless differential current input processing unit 81 in FIG. 6 exclude the filter 2, an output with almost no transient response can be obtained.
Therefore, since it does not pass through the operating range, malfunctions at the time of accident can be prevented.

However, since the filter 2 is originally provided in order to remove the harmonics contained in the input current and to operate stably with the fundamental wave component, if this is removed, the harmonics are included even in the static characteristic. The calculated value of the current fluctuates greatly.

Since this fluctuation is considered to be random, if a high-speed operation relay fluctuates to the operating side, an immediate output will be output, which will facilitate the operation.

Therefore, by taking an AND condition in the AND gate 83 with the output which has been subjected to the conventional input processing with a filter to determine the operation, it is possible to determine it according to the condition of the first conventional operation determination. In other words, the static characteristic is similar to the conventional one, and the transient characteristic can prevent malfunction.

[0071]

As described above, according to the invention of claim 1, a suppression current input processing section for processing a suppression current input obtained by combining the load side current and the neutral point side current, and the above A differential current input processing unit for processing a differential current input obtained from a difference between a load side current and a neutral point side current, and an output of the differential current input processing unit and an output of the suppression current input processing unit. Since it is configured to make an operation determination based on the above, and to prevent the accident trajectory when an external accident occurs or when an external accident is cleared from passing through the operating range of the ratio characteristic, the suppression current input and the difference By the processing of the dynamic current input, there is an effect that it is possible to reliably prevent the accident trajectory from entering the relay operation area in the event of an external accident.

According to the second aspect of the present invention, a suppression current input data switching processing section for switching and outputting either the suppression current input or the suppression current input from the delay processing section on the suppression side,
A differential current input data switching processing unit for switching and outputting either a differential current input or a differential current input from the delay processing unit on the differential side is provided, and the suppression current input or / And the differential current input and the respective changes in the suppression current input and / or the differential current input due to these delays are discriminated, and the suppression current input data switching processing unit and the differential current input data are detected. Control the switching output by the switching processing unit, and the operation determination processing unit,
Since it is configured to output normal / inoperative data when an external accident occurs or when an external accident is released, only the differential current input data is delayed when an accident occurs, and only the suppression current input data is delayed when an accident occurs. Therefore, there is an effect that it is possible to avoid malfunctions when an external accident occurs and when an external accident is released, with respect to an external failure in which the accident locus up to the accident point linearly passes through the operating range instantaneously.

According to the third aspect of the invention, when the suppression current input and the differential current input are within the verification delay range, the operation time switching processing section is provided with a time longer than the time within the verification delay range. Since it is configured to be set by a timer and the normal / inoperative data is output during this time,
There is no need to detect increase / decrease of suppression current input or differential current input, delay processing, etc., and it is possible to easily prevent malfunctions when an external failure occurs and when an external failure occurs that clears an external failure that passes through the operating range. There is an effect to be obtained.

Further, according to the invention of claim 4, based on the outputs of the suppression current input processing unit and the differential current input processing unit, the suppression current and the differential current due to an external accident pass through the operation region or the non-operation region. Based on the outputs of the first operation determination processing unit that determines whether or not to pass, the suppression current input processing unit without a filter and the differential current input processing unit without a filter, the suppression current and the differential current due to an external accident pass through the operation range. And a second motion determination processing unit for determining whether to pass through the dead zone,
The AND circuit is caused to select the output of the second operation determination processing section during the static operation in which the suppression current input and the differential current input slowly change, while the output of the first operation determination processing section is selected in the transient operation in which the change is rapid. Since it is configured to select, it is possible to perform faithful motion determination without temporarily changing the characteristics, and for external failures that pass the operating range, both when external failures occur and when external failures are released. There is an effect that a malfunction can be easily prevented.

[Brief description of drawings]

FIG. 1 is a block diagram showing a ratio differential relay according to an embodiment of the inventions of claims 1 and 2. FIG.

FIG. 2 is a characteristic diagram showing input characteristics and ratio characteristics of a suppression current input and a differential current input when an accident occurs in the invention of claim 2;

FIG. 3 is a characteristic diagram showing an input characteristic and a ratio characteristic of a suppression current input and a differential current input when an accident is released in the invention of claim 2.

FIG. 4 is a block diagram showing a ratio differential relay according to an embodiment of the inventions of claims 1 and 3;

FIG. 5 is a ratio characteristic diagram showing a ratio characteristic of the ratio differential relay according to the invention of claim 3;

FIG. 6 is a block diagram showing a ratio differential relay according to the inventions of claims 1 and 4.

FIG. 7 is a block diagram showing a conventional arithmetic type digital protection relay.

FIG. 8 is a block diagram showing a conventional ratio differential relay.

FIG. 9 is a ratio characteristic diagram showing a ratio characteristic of a conventional ratio differential relay.

FIG. 10 is an explanatory diagram showing the principle of a conventional ratio differential relay.

[Explanation of symbols]

26 suppression current input processing unit, 27 differential current input processing unit, 29 motion determination processing unit (first motion determination processing unit),
60, 61 Delay processing unit, 62 Suppressing current input data switching processing unit, 63 Differential current input data switching processing unit, 64
Rise / fall determination processing unit, 70 timer switching determination processing unit, 71 operating time switching processing unit, 80 no-filter suppression current input processing unit, 81 no-filter differential current input processing unit, 82 operation processing unit (second operation) (Determination processing unit), 83 AND gate (AND circuit), K operating range avoidance means.

Claims (4)

[Claims] 1. A suppression current input processing unit that processes a suppression current input obtained by combining a load side current and a neutral point side current, and a difference between the load side current and the neutral point side current. In the differential current input processing unit that processes the obtained differential current input, and in the ratio differential relay that performs the operation determination based on the output of the differential current input processing unit and the output of the suppression current input processing unit, an external fault Ratio differential characterized in that an operating range avoiding means is provided for preventing an accident locus at the time of occurrence or at the time of releasing an external accident from passing through the operating range of the ratio characteristic based on the output of the differential current input processing unit. relay. 2. A suppression side delay processing unit for delaying a suppression current input obtained by combining a current on the load side and a current on the neutral point side by an operating range avoiding means, the suppression current input and the suppression side. Difference current input data switching processing unit for switching and outputting one of the suppression current inputs from the delay processing unit and the difference for delaying the differential current input obtained from the difference between the load side current and the neutral point side current. Drive side delay processing section, a differential current input data switching processing section for switching and outputting either the differential current input or the differential current input from the differential side delay processing section, and the suppression current input or / And the change in magnitude between the differential current input and each suppression current input or / and differential current input due to these delays is discriminated, and the suppression current input data switching unit and the differential current input data switching unit Switching output by Based on the rising / falling discrimination processing section to be controlled and the respective data of the suppression current input and the differential current input switched according to the judgment result by the rising / falling discrimination means, the normal / inoperative data at the time of the occurrence of the external accident or the cancellation of the external accident. The ratio differential relay according to claim 1, further comprising an operation determination processing unit that outputs 3. A difference obtained from a difference between a suppression current input obtained by combining the load side current and the neutral point side current and the difference between the load side current and the neutral point side current by the operating range avoiding means. The dynamic current input is set based on the operation determination processing unit that determines that the dynamic characteristic input transiently passes through the operating range of the ratio characteristic when an external accident occurs or when the external accident is released, and the above suppression current input and differential current input. A determination processing unit for timer switching that sets a predetermined operation range of the ratio characteristic as a matching delay range, and a time within the matching delay range when the suppression current input and the differential current input are within the matching delay range. The ratio differential relay according to claim 1, further comprising: an operating time switching processing unit that sets a longer time by a timer and outputs normal / inoperative data during this time. 4. A suppression current input processing section and a suppression current input processing section without a filter for inputting a suppression current obtained by synthesizing a current on the load side and a current on the neutral point side by operating range avoiding means, and the load. Current input processing section and differential current input processing section without filter for inputting a differential current obtained from the difference between the current on the side of the neutral point and the current on the side of the neutral point, and the above suppression current input processing section and differential current input processing A first operation determination processing unit that determines whether the suppression current and the differential current due to an external accident pass through the operation region or the non-operation region based on the output of the unit, the above-described filter-less suppression current input processing unit, and no filter A second operation determination processing unit that determines whether the suppression current and the differential current due to an external accident pass the operating region or the non-operation region based on the output of the differential current input processing unit, and the suppression current input and the difference. Dynamic current input And an AND circuit that selects and outputs the output of the second operation determination processing unit when the static operation changes slowly, and selects and outputs the output of the first operation determination processing unit when the transient operation changes rapidly. The ratio differential relay according to claim 1.