JP2000310654A - Current detection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a current detection system that prevents and reduces the occurrence of a current detection error by fluctuation in the internal resistance of a Rogowsky coil. SOLUTION: A DC power supply 3 is connected to a Rogowsky coil 2 in parallel, and a DC current is allowed to flow to the Rogowsky coil 2. The DC current is separated from the output voltage of the Rogowsky coil 2 for detecting by a DC current detector 4, and the current temperature or the resistance value of the Rogowsky coil 2 is calculated by a temperature measurement circuit 81. The current value of a conductor 1 being outputted by an integration circuit 6 is corrected according to the temperature or the resistance value of the Rogowsky coil 2 by an operation circuit 82, thus detecting the current of the conductor 1 without the influence of change in the temperature of the Rogowsky coil 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to improving the accuracy of a system for detecting and measuring a current flowing through a central conductor of a GIS.

[0002]

2. Description of the Related Art Lightning current flowing through a large
2. Description of the Related Art A current detection system using a Rogowski coil is known as a current detection system for measuring a current flowing through a center conductor of an IS. FIG. 8 shows, for example, Japanese Patent Laid-Open No. 63-20156.
FIG. 1 is a configuration diagram of a conventional current detection system using a Rogowski coil disclosed in Japanese Patent Application Laid-Open No. 9-9.

In the figure, 1 is a conductor to be subjected to current detection, 2 is a Rogowski coil mounted around the conductor 1, and 10 is an output of the Rogowski coil 2 at an appropriate level suitable for subsequent electronic circuit processing. An analog circuit for converting the analog output of the analog circuit 10 into a digital signal; and 8 a microcomputer (hereinafter referred to as a CP) for calculating the output of the A / D converter to obtain a detection result.
U).

Next, the operation will be described. When a time-varying current flows through the conductor 1, an electromotive voltage E having a waveform obtained by differentiating this current is generated in the Rogowski coil 2, and the current of E / (R + r) (1) Flows. Here, R is the internal impedance of the Rogowski coil 2 (hereinafter referred to as internal resistance), and r is the input impedance of the analog circuit 10 (hereinafter referred to as input resistance).
However, when the current to be measured is a commercial frequency, these are almost DC resistances.

Then, a voltage of e = E- [E / (R + r)] R = E [1-R / (R + r)] (2) is output to the terminal of the Rogowski coil 2. . This voltage is adjusted to an appropriate level by the analog circuit 10 and input to the A / D converter 7. The CPU 8 performs an operation such as integrating digital data of the A / D converter 7 to calculate a current flowing through the conductor 1.

By the way, in order to control and manage the power system,
When detecting the current flowing through the center conductor of the GIS, the current detection accuracy is generally required to be better than 0.5%. Since the input resistance of the analog circuit 10, that is, r in the equation (2) is constituted by electronic circuit components, it is relatively easy to achieve high accuracy and low temperature fluctuation. Since the Rogowski coil 2 has an extremely large internal resistance of R, that is, R in the expression (2), it is difficult to avoid fluctuation due to temperature in terms of economy and the like.

Therefore, it is desired to obtain a current detection system which is not affected by the temperature change of the internal resistance of the Rogowski coil 2.

[0008]

Since the conventional current detection system using a Rogowski coil is configured as described above, the resistance of the Rogowski coil is greatly affected by a temperature change, and the current detection accuracy is reduced. There was a problem that it could not be raised.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a current detection system which prevents or reduces the occurrence of a current detection error due to a change in internal resistance of a Rogowski coil. I do.

[0010]

A current detection system according to the present invention comprises a Rogowski coil arranged so as to surround a conductor through which a current flows, a DC power supply for applying a DC current to the Rogowski coil, and a Rogowski coil. A DC current detector that detects the DC current from the output signal of the bandpass filter that extracts only the signal of the frequency component of the current flowing through the conductor from the output signal of the Rogowski coil; An integration circuit that integrates and calculates a current value flowing through the conductor, a temperature measurement circuit that determines the temperature or resistance value of the Rogowski coil from a detection current of the DC current detector, and based on the measured temperature or resistance value And an operation circuit for correcting the current value of the conductor calculated by the integration circuit.

In addition, a Rogowski coil disposed so as to surround a conductor, a DC power supply for applying a DC current to the Rogowski coil, and a DC current detector for detecting the DC current from an output signal of the Rogowski coil A band-pass filter that extracts only a signal of a frequency component of a current flowing through the conductor from an output signal of the Rogowski coil, a temperature measurement that obtains a temperature or a resistance value of the Rogowski coil from a detection current of the DC current detector. A circuit comprising: a circuit; an arithmetic circuit for correcting the output voltage of the band-pass filter based on the measured temperature or resistance value; and an arithmetic circuit for integrating the output of the arithmetic circuit to obtain a current value flowing through the conductor. It is.

The DC power supply is a variable voltage DC power supply whose applied voltage can be adjusted by a command signal. The DC power supply sends the command signal to the variable voltage DC power supply to set a predetermined temperature or resistance of the Rogowski coil. Is provided with a constant temperature control circuit that holds the value of

Further, a Rogowski coil arranged so as to surround the conductor, a resistance thermometer arranged close to the Rogowski coil, and an output of the Rogowski coil are integrated to calculate a current value flowing through the conductor. An integrating circuit, a temperature measuring circuit for determining the temperature of the Rogowski coil from the output of the resistance temperature detector, and an arithmetic circuit for correcting the current value of the conductor calculated by the integrating circuit based on the measured temperature. It is provided.

Further, the input resistor of the bandpass filter is made of a material having the same temperature characteristics as the coil material constituting the Rogowski coil, and the bandpass filter has the same temperature environment as the Rogowski coil. It is arranged close to the Rogowski coil.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 FIG. 1 shows a configuration diagram of a current detection system according to Embodiment 1 of the present invention. In the following, in the description of each drawing, the same reference numerals as those in the drawings of the related art indicate the same or corresponding parts, and thus detailed description thereof will be omitted. In the figure, 1 is a conductor to be subjected to current detection, 2 is a Rogowski coil attached so as to surround the conductor 1, and 3 is a Rogowski coil 2.
The DC power supply has a high internal AC resistance Z and a low internal DC resistance. Reference numeral 4 denotes a DC current detector for detecting a DC current flowing through the Rogowski coil 2 by the DC power supply 3.

Reference numeral 5 denotes a band pass filter (hereinafter referred to as BPF) which removes a DC component and a high frequency component from the output of the Rogowski coil 2 and passes only a signal frequency component e of the frequency of the current flowing through the conductor 1. Output of BPF5 (conductor 1
Is integrated (∫e).
dt), an integrating circuit for converting the current into the same current waveform as the current flowing through the conductor 1, an A / D converter 7 for converting an analog value output from the integrating circuit 6 into a digital value, and an A / D converter 7 for 8 This is a CPU that takes in and processes the output of the DC current detector 4 and processes the output, and has a temperature measuring circuit 81 for calculating the temperature or resistance value of the Rogowski coil 2 and an arithmetic circuit 82.

The DC current detector 4 may be of a type that extracts the voltage between both ends of a fixed resistor, or may be a type that uses a semiconductor current conversion element. In FIG. 2, Z is shown to help understand the internal resistance of the DC power supply 3.
In the first embodiment, the DC current flowing from DC power supply 3 to Rogowski coil 2 is at a level at which Rogowski coil 2 is not heated by this current.

Next, the operation will be described with reference to the drawings. BP
The input voltage of F5 is composed of a component obtained by differentiating the current flowing through the Rogowski coil 2 and a DC component generated by the DC power supply 3, and the BPF 5 includes a DC component and a high-frequency noise component from the signal voltage of the Rogowski coil 2. And also remove
Because of the AC resistance Z, only the signal component e passes without the signal component being short-circuited by the DC power supply 3. That is, the effect of applying the DC voltage from the DC power supply 3 by the BPF 5 is removed.

The signal (∫edt) converted into the same waveform as the current flowing through the conductor 1 by the integrating circuit 6 is supplied to the A / D converter 7
Is converted into a digital signal and sent to the CPU 8. CP
The temperature measuring circuit 81 of U8 detects the signal I of the DC current detector 4.
Then, the internal resistance R of the Rogowski coil 2 is calculated from the power supply voltage V of the DC power supply 3 known in advance as R = V / I (3).
It is also possible to simultaneously obtain the temperature from the temperature coefficient of the material of the Rogowski coil 2.

The arithmetic circuit 82 of the CPU 8 comprises a temperature measuring circuit 8
Using the internal resistance R of the Rogowski coil 2, the input resistance value r of the known BPF 5, and the signal data ∫edt from the A / D converter 7, the current value of the conductor 1 is ∫Edt.
Therefore, the current value of the conductor 1 is obtained by using the conventional formula (2) as follows: {Edt = [(R + r) / r]} edt (4) Thus, even if the internal resistance R changes due to a temperature change, the current value of the Rogowski coil 2 from which the influence of the change in the resistance R has been removed can always be obtained by using the value of R at that time in the calculation formula. I can do it.

In the above description, after integrating the output of the BPF 5 to obtain the current waveform of the conductor 1, the CPU 8
The effect of temperature is corrected by
5 is first corrected to obtain E, and then the corrected voltage E
It is needless to say that the same result can be obtained even if the order of the operations is changed so as to integrate. FIG. 3 shows the configuration of the current detection system in the case where calculations are performed in such an order to facilitate understanding. In this case, the function of the integration circuit 6 is CP
It is also possible for U8 to do so if the computational power of CPU 8 is high.

Embodiment 2 FIG. FIG. 4 shows a configuration diagram of a current detection system according to the second embodiment of the present invention. In the figure, 1 is a conductor to be subjected to current detection, 2 is a Rogowski coil attached around the conductor 1, and 5 is a band-pass filter that passes only a signal frequency component in an output signal of the Rogowski coil 2. BPF), 6 is an integrating circuit that integrates the output of BPF 5 (voltage waveform equal to the waveform obtained by differentiating the current of conductor 1) and converts it into a current waveform. 7 converts an analog value output by integrating circuit 6 into a digital value. An A / D converter 8 is a CPU that receives and processes the output of the A / D converter 7 and the output of the DC current detector 4. Reference numeral 9 denotes a resistance temperature detector mounted so as to be wound around the Rogowski coil 2.

Next, the operation will be described. The CPU 8 detects the temperature of the Rogowski coil 2 by taking in the output of the resistance temperature detector 9 and calculates from the temperature coefficient of the Rogowski coil 2 stored in advance or from a data table stored in advance. The internal resistance R of the Rogowski coil 2 corresponding to this temperature can be determined. And A /
Based on the data $ edt from the D converter 7, the input resistance r of the known BPF 5, and the R, the current value of the conductor 1 which is not affected by the temperature based on the equation (4) described in the first embodiment. Can be detected.

In FIG. 4, the BPF 5 is used to remove noise contained in the input signal, and does not have the meaning of separation from the DC signal as described in the first embodiment. Therefore, when there is only a level at which noise is not a problem, the BPF 5 is not necessarily required. BPF
When 5 is not used, the input resistance of the integrating circuit corresponds to r for convenience of explanation. It is also possible to change the operation order as shown in FIG. 3 of the first embodiment.

Embodiment 3 FIG. 5 shows a configuration diagram of a current detection system according to Embodiment 3 of the present invention. In the figure, 1 is a conductor to be subjected to current detection, 2 is a Rogowski coil mounted around the conductor 1, and 3A is a variable voltage DC power supply (a voltage output by an external signal) for applying a DC voltage to the Rogowski coil 2. High internal AC resistance Z
And low internal DC resistance. Reference numeral 4 denotes a DC current detector for measuring a DC current flowing through the Rogowski coil 2 by the variable voltage DC power supply 3A.

Reference numeral 5 denotes a band-pass filter (hereinafter referred to as B) that passes only the signal frequency component e of the output of the Rogowski coil 2.
PF), 6 is an integration circuit for integrating (∫edt) the output of the BPF 5 (voltage waveform equal to a waveform obtained by differentiating the current of the conductor 1) and converting it into a current waveform. An A / D converter 8A converts the value into a value, and a CPU 8A takes in the output of the A / D converter 7 and the output of the DC current detector 4 and processes the same. As shown in detail in FIG. The temperature of the Rogowski coil 2 described in
Alternatively, a Rogowski coil that heats the Rogowski coil 2 while controlling the variable voltage DC power supply 3A to change the DC current flowing through the Rogowski coil 2 and measures the resistance value, Constant temperature control circuit 8 which always keeps the temperature or resistance value of 2 at a predetermined value.
3 and the calculated temperature, the internal resistance value R of the Rogowski coil 2 is calculated (if the resistance value is calculated directly, the value R
And an arithmetic circuit 82 for correcting the current value of the conductor 1 to be measured.

Next, the operation will be described. The CPU 8A controls the variable voltage DC power supply 3A so that the temperature of the Rogowski coil 2 always becomes a predetermined temperature. For example, when the ambient temperature is high, the current is controlled to decrease, and when the ambient temperature is low, the current is increased to heat more strongly. Thus, the internal resistance R of the Rogowski coil 2 is always controlled to a predetermined value. The CPU 8A determines the internal resistance R of the Rogowski coil 2 controlled by itself and the known B
Input resistance r of PF5 and output ∫edt of A / D converter 7
Thus, based on the equation (4) described in the first embodiment, it is possible to detect the current of the conductor 1 without being affected by the installation environment temperature of the Rogowski coil 2.

Embodiment 4 In FIG. 7, the conductor 1, the Rogowski coil 2, the integration circuit 6, and the A / D converter 7 are the same as those in the first embodiment, and therefore description thereof will be omitted. Reference numeral 5A denotes a BPF having an input resistance made of a material having the same temperature change characteristic as the Rogowski coil 2. Also, BP
The F5A is disposed immediately near the Rogowski coil 2 (at a position where the temperature environment becomes the same). The CPU 8 calculates $ Edt based on the data $ edt from the A / D converter 7.

Next, the operation will be described. The input resistance of the Rogowski coil 2 and the input resistance of the BPF 5A have the same temperature characteristics and are arranged in close proximity to each other, so that the voltage input to the BPF 5A is always constant regardless of the temperature. That is, (2) described in the first embodiment
R / (R + r) on the right side of the equation is R ₀ (1 + αt) /, where the respective resistance values at 0 ° C. are R ₀ and r _0.
[R ₀ (1 + αt) + r ₀ (1 + αt)] = R ₀ / [R
₀ + r ₀ ]. This is a constant value. Therefore, the CPU 8 detects the detection data $ ed from the A / D converter 7
From the value of t alone, the value of the current flowing through the conductor 1 without being affected by the temperature can be calculated.

[0030]

As described above, the current detection system according to the present invention provides a conductor obtained by applying a DC current to a Rogowski coil to determine its temperature or resistance and integrating the output voltage of the Rogowski coil. Is corrected, it is possible to obtain an effect of reducing an error due to a temperature change of the Rogowski coil.

Further, since a direct current is applied to the Rogowski coil to determine its temperature or resistance value, and the output voltage of the Rogowski coil is corrected by this resistance value and then integrated, the temperature of the Rogowski coil is increased. The effect of reducing errors due to changes can be obtained.

Further, the power supply for supplying a DC current to the Rogowski coil is a controllable power supply, and the current supplied to the Rogowski coil is controlled by a temperature control circuit to keep the temperature or resistance constant. The effect of further reducing the error due to the temperature change of the Rogowski coil can be obtained.

Further, since the temperature sensor or the resistance value of the Rogowski coil is detected by juxtaposing the temperature sensor with the Rogowski coil, an effect of reducing an error due to a temperature change of the Rogowski coil is obtained. I can do it.

The input resistance of the bandpass filter receiving the output of the Rogowski coil is made of a material having the same temperature characteristics as that of the material of the Rogowski coil. Since it is located at a position where the temperature of the Rogowski coil changes, errors due to temperature changes of the Rogowski coil can be reduced.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a current detection system according to Embodiment 1 of the present invention.

FIG. 2 is a partially detailed explanatory view of FIG. 1;

FIG. 3 is a configuration diagram of a current detection system obtained by modifying FIG.

FIG. 4 is a configuration diagram of a current detection system according to Embodiment 2 of the present invention.

FIG. 5 is a configuration diagram of a current detection system according to Embodiment 3 of the present invention.

FIG. 6 is a partially detailed explanatory view of FIG. 5;

FIG. 7 is a configuration diagram of a current detection system according to Embodiment 4 of the present invention.

FIG. 8 is a configuration diagram of a current detection system using a conventional Rogowski coil.

[Explanation of symbols]

1 conductor, 2 Rogowski coil, 3
DC power supply, 3A variable DC power supply, 4 DC current detector, 5 band pass filter, 6 integration circuit, 7
A / D converter, 8 microcomputer, 9
Resistance temperature detector, 10 service solenoid valve, 81 temperature measurement circuit, 82 arithmetic circuit, 83 constant temperature control circuit.

Claims (5)

[Claims] 1. A Rogowski coil disposed so as to surround a conductor through which a current flows, a DC power supply for supplying a DC current to the Rogowski coil, and a DC current for detecting the DC current from an output signal of the Rogowski coil A detector, a band-pass filter that extracts only a signal of a frequency component of a current flowing through the conductor from an output signal of the Rogowski coil, an integration that integrates an output of the band-pass filter to calculate a current value flowing through the conductor A circuit, a temperature measurement circuit for determining the temperature or resistance value of the Rogowski coil from the current detected by the DC current detector, a current value flowing through the conductor calculated by the integration circuit based on the measured temperature or resistance value And a calculation circuit for correcting the current. 2. A Rogowski coil disposed so as to surround a conductor through which a current flows, a DC power supply for supplying a DC current to the Rogowski coil, and a DC current for detecting the DC current from an output signal of the Rogowski coil A detector, a bandpass filter that extracts only a signal of a frequency component of a current flowing through the conductor from an output signal of the Rogowski coil, and a temperature or resistance value of the Rogowski coil from the current detected by the DC current detector. Required temperature measurement circuit,
An arithmetic circuit for correcting the output voltage of the band-pass filter based on the measured temperature or resistance value, and an arithmetic circuit for integrating an output of the arithmetic circuit to obtain a current value flowing through the conductor. And the current detection system. 3. The DC power supply is a variable DC power supply whose applied voltage can be adjusted by a command signal. The DC power supply sends the command signal to the variable DC power supply to set the temperature or resistance of the Rogowski coil to a predetermined value. 3. The current detection system according to claim 1, further comprising a constant temperature control circuit for holding the current. 4. A Rogowski coil disposed so as to surround a conductor, a resistance temperature detector disposed in the vicinity of the Rogowski coil, and an output of the Rogowski coil is integrated to calculate a current value flowing through the conductor. An integrating circuit, a temperature measuring circuit for obtaining the temperature or resistance value of the Rogowski coil from the output of the resistance temperature detector, and an operation for correcting the current value of the conductor calculated by the integrating circuit based on the measured temperature. A current detection system comprising a circuit. 5. The input resistor of the band-pass filter is made of a material having the same temperature characteristics as the coil material forming the Rogowski coil, and the band-pass filter has the same temperature environment as the Rogowski coil. The current detection system according to claim 1, wherein the current detection system is disposed near the Rogowski coil.