JPH05207640A - Digital relay for protection of higher harmonic filter facility - Google Patents

Abstract

PURPOSE:To extract even sub-integer order higher harmonic components as well as integer order higher harmonic components positively by determining Fourier coefficients through discrete approximation while employing values contained in two periods of basic wave obtained by sampling output waveform of current flowing into a shunt of higher harmonic filter while equally dividing one period of basic wave into 2K sections. CONSTITUTION:Current is shunted from a higher harmonic filter circuit 1 through a CT and auxiliary converted 11 to produce a voltage which is then subjected to sample & hold 12, multiplexing 13, performing A/D conversion 14 and stored 21 over a predetermined cycle. Effective value 22 of all higher harmonics and an effective value 24 determined through Fourier operation 23 are subjected to subtraction 25 and level decision 27, and a relay 28 is actuated when the duration in which the level is higher than a predetermined one exceeds a time limit 26. Fourier operation is carried such that one period of basic wave is equally divided by 2K and the basic wave for two periods is taken out from sampled values in order to determine sine and cosine components of n/2-th order thus determining an effective value. Since higher harmonics shunting a higher harmonic filter facility can be caught surely, a highly reliable relay can be obtained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital relay provided to protect harmonic filter equipment.

[0002]

2. Description of the Related Art In order to absorb a large amount of harmonic current generated in a grid, a harmonic filter facility is installed in parallel with the ground. One of the accidents in the harmonic filter equipment is the failure of the capacitor element or the reactor element due to the flow of a large amount of harmonic current in the harmonic filter equipment. In order to prevent these failures, it is necessary to cut the current flowing through the harmonic filter equipment by a relay when a large amount of harmonic current flows. Method 1 for detecting harmonic current
One is the effective value of the total current flowing through the harmonic filter equipment,
Detecting the root mean square value of the fundamental current flowing through the harmonic filter equipment, and subtracting the root mean square value of the fundamental current from the effective value of all currents to calculate the root mean square value of the harmonic current. Is.

For this purpose, it is necessary to accurately detect the fundamental current flowing through the harmonic filter equipment. A generally adopted method is to sample the current value and perform A / D
In this method, the second harmonic, the third harmonic, ..., The nth harmonic, ... As the digital filter operation,
Generally, the Fourier integration method is used. In this method, each Fourier sine coefficient and cosine coefficient when a current waveform is subjected to Fourier series expansion are obtained by integration over one period of the fundamental wave, and the square of the nth Fourier sine coefficient and the nth Fourier cosine coefficient are calculated. This is a method of calculating the sum of the square and the n-th order component.

The Fourier integration method will be briefly described. The instantaneous value i (t) of the current is converted into the fundamental wave component In (n = 1) and the harmonic wave component I.
In general, it can be written as a Fourier series using n (n = 2, 3, ...). n is the order, ω is the frequency of the fundamental wave, and θ n is the phase of the nth-order wave, and the sum Σ is taken for n (hereinafter, the sum Σ is taken for n unless otherwise specified).

The Fourier coefficient of each order is

[0006]

[Equation 3]

[0007]

[Equation 4]

Can be written as Here, one cycle 2π / ω is 2k
When i (t) is sampled at each equally divided time point tm and the sample value im is used to obtain the integral by the discrete approximation method,

[0009]

[Equation 5]

[0010]

[Equation 6]

[0011] According to this formula, the fundamental wave is divided into 2 k equal parts, and the sampling value im for each time point tm is used,
This is an equation for obtaining the nth-order wave component. Therefore, n
When = 1 is set, it is possible to configure a digital filter that transmits only the fundamental wave and cuts off the nth harmonic component other than the fundamental wave component.

[0012]

However, recently, since non-linear loads such as inverters and thyristors are increasing as loads in the system, integer-order harmonics such as the second and third harmonics are removed. By itself, the exact fundamental wave component cannot be obtained. For example, since harmonics such as the 2.6th harmonic, the 3.5th harmonic, and the 4.5th harmonic have increased, a digital filter capable of cutting these harmonics has been demanded. ..

The present invention has been made in view of the above problems, and provides a digital relay for protecting harmonic filter equipment capable of reliably extracting not only integer harmonic components but also half integer harmonic components. The purpose is to provide.

[0014]

SUMMARY OF THE INVENTION In order to achieve the above-mentioned object, a harmonic filter equipment protection digital relay of the present invention comprises a current detecting means for detecting a current flowing into a shunt of the harmonic filter equipment, and a current detecting means. From the sampling means for sampling the output wave of the detecting means at each time point obtained by equally dividing one cycle of the fundamental wave into 2k and the sample value im (m is an integer indicating the sampling point) obtained by the sampling means, Sample values im, i included in two wave cycles
Using m + 2k (m = 0, ..., 2k-1),

[0015]

[Equation 7]

[0016]

[Equation 8]

The n / 2nd-order cosine component In / 2, c and the n / 2nd-order sine component In / 2, s are obtained by the following equations, and In / 2, c and In / 2, c are obtained.
s and a calculating means for calculating a root mean square value and extracting as a n / 2nd-order wave component, and an n / 2nd-order wave component calculated by the calculating means for a root mean square of the output wave itself of the current detecting means. It is provided with subtraction means for subtracting from the value and determination means for determining the harmonic overcurrent by comparing the output level of the subtraction means with a predetermined reference value.

[0018]

[Operation] The instantaneous value i (t) of the current is converted into the fundamental wave component In (n = 1)
And a harmonic component In (n = 2,3, ...) In general, using a Fourier series, the Fourier coefficient of each order is
As previously mentioned,

[0019]

[Equation 9]

[0020]

[Equation 10]

Can be written as Here, one cycle of 2π / ω is 4k
When i (t) is sampled at each equally divided time point tm and the sample value im is used to obtain the integral by the discrete approximation method,

[0022]

[Equation 11]

[0023]

[Equation 12]

It becomes Here, a wave having a frequency twice that of the fundamental wave is considered again as a fundamental wave. Then, it will be replaced by n → n / 2, and the above equation becomes

[0025]

[Equation 13]

[0026]

[Equation 14]

[0027] This equation is an equation for dividing the newly regarded fundamental wave into 2k equal parts and using the sampling value im for each time point tm to obtain the n / 2nd order component. Therefore, when the operation corresponding to this equation is executed, the n / 2nd
A digital filter that allows the next component to pass can be constructed.

FIG. 2 is a graph showing the calculation results when one cycle of the target wave is divided into 24 equal parts, the target wave is sampled at each time point, and n / 2 = 1. The order of G and the horizontal axis is n / 2. From the figure, it can be seen that the filter is a filter that cuts through the fundamental wave, direct current, and integer and half integer harmonics.

Therefore, it is possible to realize a digital relay capable of operating with an integer-order and half-integer-order higher harmonics based on the output signal of the arithmetic means.

[0030]

Embodiments will be described in detail below with reference to the accompanying drawings showing embodiments. FIG. 1 is a block diagram showing a filter circuit 1 and a digital relay 2 that protects the filter circuit 1. The filter circuit 1 is a series circuit of a capacitor C and a reactor L. The current flowing through the filter circuit 1 is the current transformer CT
Is detected by, is input to the auxiliary transformer 11, and is extracted as a voltage proportional to the current. This voltage value is sampled by the sample hold circuit 12, serially converted by the multiplexer circuit 13, digitally converted by the A / D conversion circuit, and input to the digital relay 2.

The digital relay 2 includes a RAM 21 for storing data for a predetermined cycle, an RMS arithmetic circuit 22 for obtaining effective values of all components including a fundamental wave and a harmonic wave, and an integer order and half order by performing Fourier calculation of the present invention. Fourier arithmetic circuit 23 for extracting the fundamental wave component from which the harmonic component of the integer order is removed, RMS arithmetic circuit 24 for obtaining the root mean square value of the fundamental wave sine component and cosine component, the output of the RMS arithmetic circuit 22 and the RMS arithmetic circuit A subtraction circuit 25 that extracts a harmonic component by performing a subtraction with the output of 24, compares the harmonic level with a reference value, and if a state higher than the reference value continues for a time determined by a time limit circuit 26, a relay drive It has a level determination circuit 27 that outputs an output, and a relay 28 that includes an opening / closing contact.

The sample and hold circuit 12 outputs the output voltage of the auxiliary transformer 11 for a fixed time Δt (Δt is, for example, 0.0016).
Set to 7 seconds. If the frequency is 50 Hz, the phase angle is 30
Corresponding to °, the sampling number is 2k = 12. ) Is to be sampled for each. RMS operation circuit 22
Is to calculate an effective value (1/12) Σim ^{2 1/2} based on the digitally converted sample value (denoted as im) (sum Σ is from m = 0 to 11).

The Fourier calculation circuit 23 has sample values im, im + 2k (m = 0, ..., 2k-1) included in two cycles of the fundamental wave.
Using k = 6, n = 2,

[0034]

[Equation 15]

[0035]

[Equation 16]

Is a circuit for obtaining the 2nd / 2nd order cosine component I 2/2, c and the 2nd / 2nd order sine component I 2/2, s. , c and I2 / 2, s
The second mean square value is obtained and extracted as the second-order or fundamental wave component. The operation of the digital relay 2 will be described below. A sample value im sampled by the sample-and-hold circuit 12 every fixed time Δt and digitally converted by the A / D conversion circuit 14.
Are momentarily stored in the RAM 21. Fourier calculation circuit 2
3 is a value im sampled at an arbitrary time t = tm and a value i sampled one cycle later.
m + 12 and m + 12 are read from the RAM 21 to calculate the Fourier cosine component and the sine component of the fundamental wave. The integer and half-integer harmonic components contained in the calculated data are cut,
As described above with reference to FIG. 2, only the fundamental wave remains.

The subtraction circuit 25 can extract all harmonic components by performing subtraction between the output of the RMS operation circuit 22 and the output of the RMS operation circuit 24. Then, the harmonic component thus obtained is compared with the reference level in the level determination circuit 27, and if the state higher than the reference level continues for the time determined by the time limit circuit 26 or more, the harmonic filter circuit 1 is operated. Outputs relay drive output for better disconnection. Thereby, the current flowing through the harmonic filter circuit 1 can be cut off. In this case, the operation signal may be output without attaching the timed relay even when the state in which the reference value or more is exceeded appears momentarily.

As described above, by removing integer-order and half-integer-order harmonic components and extracting only data including the fundamental wave component, all the harmonic components can be obtained and the relay can be operated. Therefore, the protection relay of the filter equipment for shunting the higher harmonic wave can be suitably configured. The present invention is not limited to the above embodiment. For example, in the above embodiment, the sampling interval Δt
Was the time corresponding to the phase angle of 30 °, but is not limited to this. Generally, the smaller the sampling angle, the higher the number of harmonics that can be handled (sampling theorem), but the larger the sampling angle, the smaller the amount of data that can be processed. The order decreases. Various other design changes can be made without departing from the scope of the present invention.

[0039]

As described above, according to the digital relay for protecting the harmonic filter equipment of the present invention, the harmonic including the n / 2nd order component (n = 0, 1, 3, 4, ...). Since a digital filter that outputs wave components can be configured,
Harmonics that shunt the harmonic filter equipment can be reliably captured. Therefore, a highly reliable relay can be obtained and the harmonic filter equipment can be protected appropriately.

[Brief description of drawings]

FIG. 1 is a block configuration diagram of a digital relay for protecting harmonic filter equipment.

FIG. 2 is a graph showing a gain characteristic of the digital filter according to the present invention.

[Explanation of symbols]

 1 harmonic filter circuit, 2 harmonic filter equipment protection relay, 12 sample hold circuit 22 RMS arithmetic circuit 23 Fourier arithmetic circuit 24 RMS arithmetic circuit 25 subtraction circuit 27 level judgment circuit

Claims (2)

[Claims] 1. A current detecting means for detecting a current flowing into a shunt of a harmonic filter facility, and a sampling means for sampling an output wave of the current detecting means at each time point when one cycle of a fundamental wave is equally divided into 2k. And the sample value im (m
Is an integer indicating the sampling point), sample values im, im + 2k (m = 0, ..., 2k-) included in two cycles of the fundamental wave.
Using 1), the formula [Equation 2] Then, the n / 2nd-order cosine component In / 2, c and the n / 2nd-order sine component In / 2, s are obtained, and the root mean value of In / 2, c and In / 2, s is obtained. Calculating means for extracting as an n / 2nd-order wave component; subtracting means for subtracting the n / 2nd-order wave component obtained by the calculating means from the effective value of the output wave of the current detecting means; and an output level of the subtracting means And a determination means for determining a harmonic overcurrent by comparing with a predetermined reference value. 2. A digital relay for protecting a harmonic filter facility according to claim 1, wherein said calculating means extracts a fundamental wave component when n = 2.