KR100886474B1 - Protective relay equipment - Google Patents

Abstract

An object of the present invention is to provide a protection relay device which acquires a system electric quantity of a power system and automatically performs a predetermined protective A / D relay calculation using the electric quantity.

The protective relay 10 is configured to convert the electric power level of the system electric quantity a of the electric power system, and the analog electric quantity b from the input conversion means 12 to the digital electric quantity c. Of the A / D conversion means 13, the first characteristic value calculation means 15 for calculating the characteristic value d of the A / D conversion means 13, and the input conversion means 12. Second characteristic value calculating means 16 for calculating the characteristic value e, first storage means 21 for storing the characteristic value d of the calculated A / D conversion means 13, and calculated The second storage means 22 for storing the characteristic value e of the input conversion means 12 and the characteristic value d of the A / D conversion means 13 stored in the first storage means 21. And correction value calculating means 17 for obtaining a correction value h from the characteristic value e of the input conversion means 12 stored in the second storage means 22 and the correction value h. With correction means 18 for correcting the value will be.

Description

Protective relay device {PROTECTIVE RELAY EQUIPMENT}

1 is a block diagram showing a first embodiment of a protective relay device according to the present invention.

FIG. 2 is a configuration diagram of input conversion means included in the protection relay of FIG. 1. FIG.

3 is a block diagram of A / D conversion means included in the protection relay of FIG.

4 is a diagram illustrating a connection relationship between a voltage transformer of an input conversion means and a filter of the A / D conversion means included in the protection relay of FIG. 1.

5 is a diagram illustrating a connection relationship between a voltage transformer of an input conversion means and a filter of the A / D conversion means included in the protection relay of FIG. 1.

FIG. 6 is a view for explaining input to a multiplexer of A / D conversion means included in the protective relay of FIG. 1; FIG.

FIG. 7 is a view for explaining an input relationship in "A / D conversion means characteristic value calculation mode" in the protective relay of FIG.

FIG. 8 is a flowchart showing a process of calculating characteristic values of A / D conversion means included in the protection relay of FIG. 1. FIG.

FIG. 9 is a view for explaining an input relationship at the time of "input conversion means characteristic value calculation mode" in the protective relay of FIG.

10 is a flowchart showing a process of calculating a characteristic value of an input converting means included in the protective relay of FIG.

Fig. 11 is a block diagram showing a second embodiment of the protective relay device according to the present invention.

12 is a block diagram showing a third embodiment of the protective relay device according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: protective relay

12: input conversion means

13: A / D conversion means

14: calculation means

15; First characteristic value calculating means

16: second characteristic value calculating means

17: correction value calculation means

18: correction means

19: protective relay calculation means

21: first storage means

22: second storage means

24: digital input / output means

25: breaker

27: voltage transformer

28; Current transformer

31: filter

32: multiplexer

33: A / D Converter

35 cable

36: switch

40: third storage means

41: communication interface

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique for handling grid electricity of a power system, and more particularly, to a digital protective relay device for acquiring grid electricity of a power system, performing a protective relay operation using the electricity, and protecting a power system. .

When the power system is protected by a digital protective relay, it is first input to convert the system electric quantity of the analog amount obtained by the voltage transformer or current transformer of the power system into digital data required for relay operation in the digital processor. The conversion means converts the data into a size that is easy to process, and then removes the high frequency components unnecessary for calculation by the analog filter, and then samples them at predetermined intervals. By converting analog data into digital data.

In this type of protective relay device, various methods have been proposed for correcting an error in an input portion of a system electric quantity of a power system, a so-called analog input portion. For example, Patent Document 1 corrects a system electricity amount without combining an input conversion means for converting the system electricity amount into an electricity amount of a predetermined magnitude and an A / D conversion means for converting the output (analog) electricity amount of the input conversion means into a digital electricity amount. A configuration is disclosed in which values can be calculated manually individually.

That is, the protective relay device inputs the system electric quantity to the input conversion means of the protection relay through the voltage transformer or the current transformer installed in the power system. The input converting means is composed of a voltage transformer and a current transformer, and converts a system electric quantity of a power system into an electric quantity of a predetermined size and outputs it to the A / D conversion means. The A / D converting means filters the output electric quantity from the input converting means through a filter circuit, and then performs A / D conversion to output the electric quantity of the digital value.

Since elements such as resistors and capacitors and elements such as logic ICs used as elements constituting each means from the input conversion means to the A / D conversion means have individual differences, the phase between the input data and the output data is different. However, since a difference occurs in the amplitude value, it is necessary to perform a process of correcting these differences when performing calculation by the relay calculating means.

The protective relay device described in Patent Literature 1 includes first storage means for storing an error of an input conversion means, and second storage means for storing an error of an A / D conversion means, and is stored in the first and second storage means. The input data are corrected using error data (hereinafter referred to as characteristic values).

[Patent Document 1] Japanese Unexamined Patent Application Publication No. 2004-274930

In the protective relay device described in Patent Document 1, it is necessary to manually store data in the first storage means in advance. That is, the error of the phase difference between the input electricity amount and the output electricity amount of the input conversion means and the error of the amplitude value (gain: gain) are measured using a measuring instrument such as a voltmeter or an ammeter, and the value based on the measured value is stored in the storage means. Saving.

All of the data storage for inputting the phase difference error of the electric quantity by these measuring devices and the measured value of the gain error to the first storage means must be done manually in advance. For this reason, a lot of effort and time are consumed in a data storage operation, and since a data storage operation is complicated, it becomes a factor which produces a correction error.

SUMMARY OF THE INVENTION The present invention has been made in consideration of the above-described circumstances, and by using a system electric quantity received from a power system, a correction operation and a protection relay operation for an error of a predetermined input means and an error of an A / D conversion means are performed. An object of the present invention is to provide a protective relay device that protects the circuit.

Another object of the present invention is to protect the unnecessary work of calculating the correction value by combining the respective means at the time of exchanging the target object when the failure of the input conversion means or the A / D conversion means is replaced. It is to provide a relay device.

It is still another object of the present invention to provide a protective relay device which reduces the effort for storing the characteristic values of the input conversion means and the A / D conversion means, and does not reduce the work and generate a correction error.

MEANS TO SOLVE THE PROBLEM In order to solve the above-mentioned subject, in order to solve the above-mentioned subject, in the protection relay apparatus which samples A / D conversion of the system electric quantity of a power system, and performs a protective relay calculation using this A / D conversion value, the electric quantity of the said system electric quantity is carried out. Input conversion means for converting a level, A / D conversion means for converting an analog electric quantity from the input conversion means into a digital electric quantity, first characteristic value calculating means for calculating a characteristic value of the A / D conversion means, Second characteristic value calculating means for calculating a characteristic value of said input conversion means, first storage means for storing characteristic values of said A / D conversion means calculated by said first characteristic value calculating means, and said second characteristic Second storage means for storing the characteristic value of the input conversion means calculated by the value calculating means, characteristic values of the A / D conversion means stored in the first storage means, and input stored in the second storage means. Correction value calculation means for obtaining a correction value from the characteristic value of the force conversion means, and correction means for correcting the A / D conversion value using the correction value.

(Example)

EMBODIMENT OF THE INVENTION Embodiment of the protective relay apparatus which concerns on this invention is described with reference to an accompanying drawing.

[First Embodiment]

1 is a block diagram showing a first embodiment of a protective relay device according to the present invention.

This protective relay device 10 has an input converting means 12 into which the system electric quantity a of the electric power system is received, and the electric quantity of a predetermined magnitude that the system electric quantity a is easy to process by the input converting means 12. (Output electricity amount) (b). The output (analog) electric quantity b from the input converting means 12 is input to the A / D converting means 13, and the analog electric amount is filtered after filtering by this A / D converting means 13 to remove the high frequency component. It is converted into the digital electricity amount c and input to the calculation means 14.

The computing means 14 is composed of a microprocessor such as an MPU, a CPU, a memory, etc., the first characteristic value calculating means 15 for calculating the characteristic value of the A / D conversion means 13, and the input conversion means 12. 2nd characteristic value calculation means 16 which calculates the characteristic value of (), correction value calculation means 17 which calculates the correction value of the input conversion means 12, and A / D conversion means 13, and this correction value Correction means 18 for correcting the A / D conversion data using the correction value obtained by the calculation means 17, and relay operation or the like using the data of the A / D converted value after correction by the correction means 18. It consists of the protective relay calculation means 19 which performs a protective relay calculation.

The characteristic value d of the A / D conversion means 13 calculated by the first characteristic value calculating means 15 is input to the first storage means 21 and stored. The characteristic value e of the input conversion means 12 calculated by the second characteristic value calculation means 16 is input to the second storage means 22 and stored. The first and second storage means 21, 22 are constituted of, for example, a nonvolatile memory.

The first and second storage means 21, 22 input the stored values (characteristic values) (f, g) into the correction value calculating means 17, respectively, and output the correction value h to the correction means 18. do. The correction means 18 is inputted with the output (digital electric quantity) c of the A / D conversion means 13 and the correction value h of the correction value calculation means 17, respectively, to the protective relay calculation means 19. The A / D converted value i after correction is output.

The digital input / output means 24 is connected to the protective relay calculation means 19 of the protective relay device 10 so that the circuit breaker 25 is opened and closed by the digital input / output means 24. By the opening and closing operation of the circuit breaker 25, the safety of an electric power system can be raised and protected.

The protective relay device 10 constitutes a digital protective relay device for protecting a power system. And if the protective relay calculation means 19 and the digital input / output means 24 are removed from the protective relay apparatus 10, the electricity quantity acquisition apparatus which acquires the system electricity amount a of a power system will be comprised.

The input conversion means 12 of the protective relay device 10 is comprised as shown in FIG. 2, and is comprised from the some voltage transformer 27 and the some current transformer 28. As shown in FIG. A resistor 29 is connected to the output side of the current transformer 28, and the input current value Iin becomes a voltage value Vout of a predetermined voltage level and is output.

3 shows a block diagram of the A / D conversion means 13 of the protective relay device 10. The A / D conversion means 13 includes a plurality of filters 31 for removing harmonic components unnecessary for operation, a multiplexer 32 for sequentially switching and outputting a plurality of inputs from which harmonic components have been removed by filtering, and An A / D converter 33 for converting the output (analog signal) from the multiplexer 32 into a digital signal (electric quantity) that can be processed is provided.

4 is a diagram showing a connection relationship between the voltage transformer 27 of the input converting means 12 and the filter 31 of the A / D converting means 13. The voltage transformer 27 and the filter 31 are connected via a detachable cable 35 that separates the contact between the voltage transformer 27 and the filter 31.

In FIG. 4, when the cable 35 is removed, the voltage can be directly applied from the outside to the input portion of the filter 31 of the A / D conversion means 13, that is, the terminal A portion. The connection relationship between the current transformer 28 of the input conversion means 12 and the filter 31 of the A / D conversion means 13 is also the same.

5 shows a modification of the connection relationship between the input conversion means 12 and the A / D conversion means 13.

In this modification, the voltage transformer 27 of the input converting means 12 is connected to the filter 31 of the A / D converting means 13 via a switch 36 so as to be openable and openable. When the switch 36 is opened, the voltage can be applied directly to the terminal A from the outside to the filter 31 of the A / D conversion means 13. The connection form in the case of the current transformer 28 of the input conversion means 12 and the filter 31 of the A / D conversion means 13 is also the same.

On the other hand, the multiplexer 32 provided in the A / D conversion means 13 sequentially switches the output (analog signal) filtered by the plurality of filters 31, as shown in FIGS. 3 and 6. It outputs to the / D converter 33. One input of the multiplexer 32 is provided with a terminal B portion to which a filter 31 or the like is not connected. The terminal B portion is capable of directly applying a voltage from the outside.

In addition, the digital electricity amount c subjected to A / D conversion by the A / D conversion means 13 is input to the calculation means 14. As described above, since there are individual differences between devices such as resistors and capacitors constituting the input conversion means 12 and A / D conversion means 13, and elements such as logic ICs, there is a difference between the input data and the output data. Differences occur in phase or amplitude (gain: gain).

In addition, the input conversion means 12 converts the system (input) electricity amount a obtained from the power system into the required analog (output) electricity amount b, and converts the analog electricity amount b into the A / D conversion means 13. By removing the harmonics, the sample is sampled, converted into a digital electric quantity c, and input to the calculation means 14. In the case of the protective relay calculation of the digital electric quantity c by the calculation means 14, such as a relay calculation, it is necessary to correct | amend the difference of these phase and amplitude values.

The calculating means 14 inputs the digital electric quantity c from the A / D converting means 13 to calculate the first characteristic value calculating means 15 for calculating the characteristic value d of the A / D converting means 13. Have The characteristic value d is a value relating to the amplitude value (gain) and the phase difference between the input and output when the sinusoidal wave is input to the A / D conversion means 13.

In order to calculate the characteristic value d of the A / D conversion means 13, it is manually set to "A / D conversion means characteristic value calculation mode" via a man machine interface not shown from the outside.

It is a figure explaining the input relationship at the time of "A / D conversion means characteristic value calculation mode." Before setting to the "A / D conversion means characteristic value calculation mode", the sine wave voltage of a predetermined frequency and the rated frequency are applied to the input of the filter 31 previously from a terminal A part. In addition, a voltage having a predetermined phase difference is applied to the terminal B portion at a predetermined magnitude and at the same frequency as the sine wave voltage applied to the terminal A portion. The simplest example of a given phase difference is the case of 0 °.

The process of calculating the characteristic value of the A / D conversion means 13 is performed according to the flowchart of FIG.

The process of calculating the characteristic value of the A / D conversion means 13 (step S ₁ ) is determined in step S ₂ of whether or not it is the "A / D conversion means characteristic value calculation mode". If the "A / D conversion means characteristic value calculation mode", the calculated amplitude value (step S ₃₎ is performed.

In the amplitude value calculation (step S ₃ ), an amplitude value (voltage value) is obtained by using the data after A / D conversion corresponding to the voltage input to the filter 31 of the A / D conversion means 13, that is, the voltage input to the terminal A portion. ) Is calculated. The calculation method of the amplitude value of the sine wave using the data after A / D conversion, ie, the instantaneous value, is performed using the following equation (1).

The sinusoidal wave (voltage value) V _cal is represented by the following equation (1),

Is displayed.

However, both V ₀ and V ₁ are instantaneous values (voltage values), and the phase difference between V ₀ and V ₁ is 90 °.

The ratio between the amplitude value V _cal obtained in Equation 1 and the abnormal amplitude value V _idl when no error exists in the A / D conversion means 13 is obtained by the following equation (2).

V _rad = V _idl / V _cal

In the phase calculation (step S ₄ ), the data after A / D conversion corresponding to the input of the filter 31 of the A / D conversion means 13, that is, the voltage input to the terminal A portion, and the voltage input to the terminal B portion The phase difference θ _ad is calculated from the data after A / D conversion corresponding to.

The method of calculating the phase difference of two sinusoidal waves using an instantaneous value calculates phase difference (theta) _ad , for example using the well-known zero-cross method. The amplitude value calculation (step S ₃ ) and the phase calculation (step S ₄ ) are performed for each of the plurality of filters 31, respectively.

In the characteristic value storage (step S ₅ ), the amplitude ratio V _rad and the phase difference θ _ad are stored in the first storage means 21 for each filter 31 as the characteristic value d.

On the other hand, the second characteristic value calculating means 16 in the calculating means 14 calculates the characteristic value e of the input converting means 12. And when calculating the characteristic value e of the input conversion means 12, it sets to "the input conversion means characteristic value calculation mode."

Also in the case of the "input conversion means characteristic value calculation mode", it sets manually via the external machine interface etc. similarly to the case of the "A / D conversion means characteristic value calculation mode" mentioned above.

It is a figure explaining the input relationship at the time of an "input conversion means characteristic value calculation mode." Before setting to the "input conversion means characteristic value calculation mode", as shown in FIG. 9, the sine wave voltage of a predetermined frequency and the sine wave current are input to the input conversion means 12 with predetermined magnitude | size, and is input previously. .

On the other hand, the multiplexer 32 of the A / D conversion means 13 has a predetermined phase difference from the terminal B portion at a predetermined magnitude and at the same frequency as the sinusoidal voltage applied to the input conversion means 12 or the input sinusoidal current. Apply an excitation voltage. The predetermined phase difference is the same value as the phase difference between the voltages applied to the terminal A portion and the B portion in the first characteristic calculation means 15.

The process of calculating the characteristic value of the input conversion means 12 (step S ₇ ) is performed according to the flowchart of FIG.

If the input conversion means to whether characteristic value calculation mode (step S _8), "the input conversion means characteristic value calculation mode" is carried out is calculated amplitude value (step S _9). The amplitude value calculation (step S ₉₎ calculates the amplitude value using the data after the A / D conversion corresponding to the voltage or the input current applied to the input conversion means (12). Calculation of this amplitude value is the same as that of Formula (1).

Then, the ratio between the amplitude value V _cal obtained by the equation (1) and the abnormal amplitude value V _idltotal when no error exists in the input conversion means 12 and the A / D conversion means 13 is _calculated . _{Speaking of} (V _rtotal ),

V _rtoal = V _idltotal / V _cal

Obtained by

In order to detect the phase difference following amplitude value calculation (step S ₉ ), phase calculation (step S ₁₀ ) is performed. In the phase calculation (step S ₁₀ ), the data after the A / D conversion corresponding to the voltage or input current applied to the input conversion means 12, and the terminal B portion in the multiplexer 32 of the A / D conversion means 13 The phase difference is calculated from the data after the A / D conversion with respect to the voltage input from the. Also for this phase difference calculation, phase difference (theta) _total is computed by the well-known zero-cross method, for example.

After calculating the phase difference θ _total , the characteristic value of the input conversion means 12 is calculated by input conversion characteristic calculation (step S ₁₁ ). The characteristic value e (V _ript , θ _ipt ) of the input converting means 12 is obtained by the following equations (4) and (5).

V _ript = V _rtotal / V _rad

θ _ipt = θ _total -θ _ad

Here, V _rad and θ _ad use data stored in the first storage means 21.

In addition, the amplitude value calculation, the phase calculation and the input conversion means characteristics of the step S ₁₁ ~S ₉ value calculation is carried out respectively for a plurality of each of the voltage transformer 27 and current transformer 28 shown in Fig.

The characteristic value e (V _ript , θ _ipt ) of the input conversion means 12 calculated for each voltage transformer 27 and the current transformer 28, respectively, is determined by the second storage means by the characteristic value preservation (step S ₁₂ ). It is preserved in 22.

The first characteristic value calculating means 15 and the second characteristic value calculating means 16 included in the calculating means 14, before operating the digital protective relay device 10, calculate the "A / D conversion means characteristic value. Mode "or" input conversion means characteristic value calculation mode ". When operating the protective relay device 10, it is not necessary to set to the state of "A / D conversion means characteristic value calculation mode" or "input conversion means characteristic value calculation mode."

The correction value calculating means 17 of the calculating means 14 obtains the correction value h for correcting the characteristic error of the input conversion means 12 and the A / D conversion means 13. The correction value calculating means 17 stores the characteristic value f (V _rad , θ _ad ) stored in the first storage means 21, and the characteristic value g (V _ript ,) stored in the second storage means 22. From θ _ipt ), the general characteristic values V _rtotal and θ _total of the input conversion means 12 and the A / D conversion means 13 are obtained by the following equations (6) and (7).

V _rtotal = V _ript / V _rad

θ _total = θ _ipt -θ _val

In addition, in order to correct the characteristic error of the input conversion means 12 and the A / D conversion means 13 using this correction value h (V _rtotal , θ _total ), The correction value h (k ₀ , k ₁ ) is obtained by equation (9).

k ₀ = V _rtotalsin (θ _T -θ _tgt + θ _total ) / sin (θ _T )

k ₁ = V _rtotalsin (θ _tgt -θ _total ) / sin (θ _T )

However, θ _T = 2π × (f ₀ / f _s ) and θ _tgt are predetermined values, where f ₀ is a rated frequency and f _s is a sampling frequency.

Subsequently, the A / D conversion data is corrected by the correction means 18 using the following equation (10) using the correction value h (k ₀ , k ₁ ) obtained by the correction value calculating means 17. .

_{Y (m) = k 0 ·} X (m) + k 1 · X (m-1)

X (m) is the latest sampling, X (m-1) is the A / D converted data at the time of the previous sampling, and Y (m) is the data after correction.

The correction means 18 correct | amends A / D conversion data by Formula (10) using the correction value h (k ₀ , k ₁ ) obtained by the correction value calculation means 17, and the correction means 18 The A / D converted data (A / D converted value i) corrected by is input to the protective relay calculating means 19, and the protective relay calculation is performed. By the protection relay calculation in the protection relay calculation means 19, the circuit breaker 25 is operated through the digital input / output means 24, and a power system is protected.

From the digital protective relay 10 shown in FIG. 1, the input conversion means 12, the A / D conversion means 13, and the first and second storage means 21, 22 can be separated independently. I can connect it. In addition, the attachment / detachment of the input conversion means 12, the A / D conversion means 13, and the first and second storage means 21 and 22 from the protective relay device 10 is a known coupling such as a connector or a socket. It is performed using an element.

Next, the operation of the protective relay device 10 will be described.

The electric components (elements) constituting the input conversion means 12 and the A / D conversion means 13 of the protective relay device 10 have been described above.

A sinusoidal wave voltage of a predetermined frequency is applied to the input converting means 12 of the protective relay device 10 or a sinusoidal wave propagation is input. For example, a sinusoidal voltage or a sinusoidal current applied to or input from the terminal B portion shown in FIG. 9 to the multiplexer 32 of the A / D conversion means 13 in a predetermined size and to the input conversion means 12. When a voltage having a predetermined phase difference is applied at the same frequency, an error occurs in the data after A / D conversion corresponding to the input of the input converting means 12 with respect to a predetermined value of both the gain (gain) and the phase difference.

The degree of gain error, that is, the characteristic value is the amplitude ratio V _rtotal according to Equation 3, and the characteristic value of the phase difference is the phase difference θ _total .

Currently, the input of the input conversion means 12,

Let V _in sin (ω ₀ t).

However, ω ₀ = 2πf ₀ .

When the conversion data at the time of ideal sampling required by the input conversion means 12 and the A / D conversion means 13 is X (m), X (m) is represented by the following formula (11).

_{X (m) = k idl ·} V in · sin (-θ tgt)

Is displayed.

Actually, due to the characteristic error of the components constituting the input conversion means 12 and the A / D conversion means 13, the A / D conversion data X (m) is represented by the following equation (12),

_{X (m) = (k idl} / V rtotal) · V in · sin (-θ total)

The A / D converted data X (m-1) before one sampling is expressed by the following equation (13).

X (m-1) = ( k idl / V rtotal) · V in · sin (-θ total -θ T)

Becomes

On the other hand, if the A / D conversion data X (m) and X (m-1) are corrected using the correction value h (k ₀ , k ₁ ) calculated by the correction value calculating means 17, then the corrected A The / D converted data Y (m) is expressed by the following equations (14) by (8).

_{Y (m) = k 0 ·} X (m) + k 1 · X (m-1)

= {V _rtotalsin (θ _T -θ _tgt + θ _total ) / sin (θ _T )}

_{· K idl / V rtotal · V} in · sin (-θ total)

+ {V _rtotalsin (θ _tgt -θ _total ) .sin (θ _T )}

_{· K idl / V rtotal · V} in · sin (-θ total -θ T)

= {k _{idlV in} / sin (θ _T )}

(sin (θ _T -θ _tgt + θ _total ) · sin (-θ _total )

_{+ sin (θ tgt -θ total)} · sin (-θ total -θ T)}

= {k _{idlV in} / sin (θ _T )}

[{cos (θ _T -θ _tgt + 2θ _total ) -cos (θ _T -θ _tgt )} / 2

+ {cos (θ _tgt + θ _T ) -cos (θ _tgt -2θ _total -θ _T )} / 2]

= {k _{idlV in} / sin (θ _T )}

[{cos (θ _tgt -θ _T -2θ _total ) -cos (θ _tgt -θ _T )} / 2

+ {cos (θ _tgt + θ _T ) -cos (θ _tgt -θ _T -2θ _total )} / 2]

= (k _{idlV in} / sin (θ _T )} · (cos (θ _tgt + θ _T ) -cos (θ _tgt -θ _T )} / 2

= {k _{idlV in} / sin (θ _T )} · sin (-θ _tgt ) sin (θ _T )}

_{= k idl · V in · sin} (-θ tgt)

Is displayed.

Equation (14) is the same as in Equation (11), and the ideal A / D conversion data Y (m) required can be obtained by the correction process of Equation 10.

The characteristic value is divided into the characteristic value e of the input converting means 12 and the characteristic value d of the A / D converting means 13.

The amplitude ratio (gain characteristic value) V _rtotal and the phase difference θ _total represent the _total characteristic values obtained by _adding the input converting means 12 and the A / D converting means 13.

When the characteristic value e of the input conversion means 12 is (V _ript , θ _ipt ) and the characteristic value d of the A / D conversion means 13 is (V _rad , θ _ad ), The values V _rtotal and θ _total may be decomposed as shown in Equations 6 and 7.

Then, the first characteristic value calculating means 15 can directly obtain the characteristic value d (V _rad , θ _ad ) of the A / D conversion means 13.

However, the characteristic value d (V _rad , θ _ad ) of the A / D conversion means 13 is obtained by directly cutting the input conversion means 12 by opening the cable 35 or the switch 36. However, the characteristic value e (V _ript , θ _ipt ) of the input conversion means 12 cannot be directly obtained.

Therefore, in the first half of the second characteristic value calculating means 16, the characteristic values V _rtotal and θ _total of the sum of the input converting means 12 and the A / D converting means 13 are first obtained. Then, by using Equations 4 and 5, which are modifications of Equations 6 and 7, indirectly, the characteristic value e of the input conversion means 12 (V _ript , θ _ipt ) is obtained.

In this manner, the characteristic value d of the A / D conversion means 13 (V _rad , θ _ad ) is stored in the first storage means 21, and the input conversion means 12 is stored in the second storage means 22. ) Is stored (e) (V _ript , θ _ipt ). The characteristic value d of the A / D conversion means 13 and the characteristic value e of the input conversion means 12 are individually maintained in the first and second storage means 21 and 22.

If at least one of the input converting means 12 and the A / D converting means 13 fails during the operation of the protective relay device 10, the failed input converting means 12 or the A / D converting means 13 are normally Is exchanged for a new one.

If the input converting means 12 has failed, it is exchanged with the normal new input converting means 12, and the second storage means 22 is also replaced with the stored characteristic value e of the new input converting means 12. do. In this way, when the input conversion means 12 are replaced, the second storage means 22 is also replaced, so that a corrective work for correcting the error of the analog input unit is unnecessary, thereby enabling a quick replacement.

In addition, even when the A / D conversion means 13 are replaced, the same effect can be obtained by simultaneously exchanging the first storage means 21 at the same time.

In addition, when the characteristic value e of the input conversion means 12 is preserve | saved, the operation | work which saves the measured value measured using the measuring device, such as a voltmeter and an ammeter, manually in the 2nd storage means 22 becomes unnecessary. By only a predetermined voltage application or input of a current, the characteristic value e of the input conversion means 12 is automatically stored in the second storage means 22.

Second Embodiment

11 is a block diagram illustrating a second embodiment of the protective relay device according to the present invention.

The protective relay device 10A shown in the second embodiment is obtained by adding the third storage means 40 to the protective relay device 10 of the first embodiment, and the other configuration and action are the protective relays of the first embodiment. Since it is not substantially different from the apparatus 10, the same code | symbol is attached | subjected to the same structure, and overlapping description is abbreviate | omitted.

The third storage means 40 copies and preserves the characteristic value d of the A / D conversion means 13 stored in the first storage means 21, while the input conversion is stored in the second storage means 22. The characteristic value e of the means 12 is also copied and preserved. The characteristic value d of the A / D conversion means 13 stored in the third storage means 40 can be copy-preserved in the first storage means 21. Similarly, the characteristic value e of the input conversion means 12 stored in the third storage means 40 can also be copy-preserved in the second storage means 22.

The digital protective relay 10A shown in FIG. 11 is the first storage means 21 and the third storage means 40 by a program embedded in a CPU or MPU based on commands from a man machine interface (not shown). Data preservation is possible between. Similarly, data copy storage between the second storage means 22 and the third storage means 40 is also possible.

The digital protective relay device 10A shown in the second embodiment includes the first storage means 21 and the input conversion means 12 which record and store the characteristic value d of the A / D conversion means 13. The second memory means 22 for recording and storing the characteristic value e has an excellent function in case of failure.

If the first storage means 21 breaks down during the operation of the protective relay device 10A, it is exchanged for a normal new first storage means 21. However, the characteristic value d of the A / D conversion means 13 is not stored in the new first storage means 21.

For this reason, the characteristic value d of the A / D conversion means 13 is copied and preserve | saved beforehand in the 3rd memory means 40, and this characteristic value d is transferred to the new 1st storage means 21 exchanged. Copy preserved. By copying and storing the characteristic value d in the new first storage means 21, a calibration operation for correcting the error of the analog input portion of the A / D conversion means 13 becomes unnecessary, and can be quickly replaced.

Even when the second storage means 22 fails, the replacement of the second storage means 22 can be performed quickly and efficiently in a short time in the same work order as when the first storage means 21 has failed.

[Third Embodiment]

12 is a block diagram showing the third embodiment of the digital protective relay according to the present invention.

The digital protective relay device 10B shown in the third embodiment shows a modification of the protective relay device 10A shown in the second embodiment, and the configuration other than the communication interface 41 is the same as in the second embodiment. Therefore, the same structure is attached | subjected to the same code | symbol, and duplication description is abbreviate | omitted.

The communication interface 41 is connected to the first storage means 21 and the second storage means 22, respectively. The communication interface 41 can communicate with an external communication device (not shown) such as a personal computer through wireless or wired communication means (not shown).

In the digital protective relay device 10B shown in the third embodiment, the characteristic value d of the A / D conversion means 13 stored in the first storage means 21 is a personal computer via the communication interface 41. It is possible to communicate with an external communication device such as a personal computer, and the characteristic value d of the A / D conversion means 13 stored in an external device such as a personal computer is transferred to a new first storage means 21 from an external remote location. Transmission preservation is possible.

The characteristic value e of the input conversion means 12 stored in the second storage means 22 can also be transferred and stored in the new second storage means 22 by communication from the outside via the communication interface 41. have.

In the case where the first storage means 21 or the second storage means 22 fail, similarly to the protective relay device 10A shown in the second embodiment, the digital protective relay device 10B shown in the third embodiment. It is possible to exert an excellent function and to replace the failed first storage means 21 or the second storage means 22 without the need for calibration work.

If the first storage means 21 fails during the operation of the protective relay device 10B, it is exchanged with a normal new first storage means 21. However, the characteristic value d of the A / D conversion means 13 is not stored in the new first storage means 21.

For this reason, when the 1st memory means 21 is communicatively connected to the external communication device via the communication interface 41, and the 1st memory means 21 is faulty and is replaced with the new 1st memory means 21, Of the A / D conversion means 13 stored in an external device such as a personal computer in order to transfer and store the characteristic value d of the A / D conversion means 13 to the new first storage means 21. The characteristic value d is transmitted to and stored in the first storage means 21.

In this case as well, the characteristic value d of the A / D conversion means 13 stored in an external device such as a personal computer can be copied and stored in the exchanged new first storage means 21 via a communication means. The calibration work for correcting the error of the analog input portion of the D conversion means 13 becomes unnecessary, and the quick replacement work can be performed efficiently.

Input conversion stored in an external device such as a personal computer even when the characteristic value e of the input conversion means 12 is stored and the stored second storage means 22 is replaced with a new second storage means 22. By using the communication means using the characteristic value e of the means 12, it is possible to easily and easily transfer and preserve the characteristic value e of the input conversion means 12 to the new second storage means 22 exchanged. Can be.

In the protection relay device according to the present invention, the power system can be protected by A / D conversion of the amount of system electricity received from the power system, and by performing a predetermined protection relay calculation using the A / D converted value.

When the input converting means or the A / D converting means has failed, when the failure target means is replaced with a new one, the characteristic value corresponding to the characteristic value of the new means exchanged at the time of the exchange can be exchanged at the same time. The calibration work to correct the error of the analog input part is unnecessary, and a quick replacement work can be performed efficiently and efficiently in a short time.

Further, only by applying a predetermined voltage or inputting current, a characteristic value corresponding to the input conversion means or A / D conversion means can be automatically obtained and stored in the storage means.

Claims (5)

In the protective relay device which samples the system electricity of the power system and performs A / D conversion, and performs the protective relay calculation using this A / D conversion value, Input converting means for converting an electricity level of said system electricity; A / D conversion means for converting an analog electric quantity from said input converting means into a digital electric quantity; First characteristic value calculating means for calculating a characteristic value of the A / D conversion means; Second characteristic value calculating means for calculating a characteristic value of the input converting means; First storage means for storing characteristic values of said A / D conversion means calculated by said first characteristic value calculating means; Second storage means for storing a characteristic value of said input conversion means calculated by said second characteristic value calculating means; Correction value calculating means for obtaining a correction value from the characteristic value of the A / D conversion means stored in the first storage means and the characteristic value of the input conversion means stored in the second storage means; Correction means for correcting the A / D conversion value using the correction value; Protective relay calculation means for performing protective relay calculation using the A / D converted value corrected by the correction means. Protective relay device comprising a. The protective relay device according to claim 1, wherein the input conversion means, the A / D conversion means, the first storage means, and the second storage means are provided so as to be separated from the protective relay device independently of each other. 3. A third method according to claim 1 or 2, wherein at least one of a characteristic value of the A / D conversion means stored in the first storage means and a characteristic value of the input conversion means stored in the second storage means is copied and stored. A protective relay device comprising storage means. The external device according to claim 1 or 2, wherein at least one of a characteristic value of the A / D conversion means stored in the first storage means and a characteristic value of the input conversion means stored in the second storage means is connected to an external device. A protective relay device comprising a communication interface for sending and receiving. The characteristic value of the A / D conversion means calculated by the said 1st characteristic value calculation means, and the characteristic value of the input conversion means calculated by the said 2nd characteristic value calculation means calculate a correction value from these characteristic values. The protection relay device which is input to the correction value calculating means.

Images