KR20120008823A - System for measuring ground impedance in high frequency band - Google Patents

Abstract

PURPOSE: A ground impedance measuring system is provided to evaluate the ground performance for transient currents from surges or commercial frequency faults. CONSTITUTION: A ground impedance measuring system(S) comprises a sine wave generator(100), a current amplifier(200), a setup unit(300), a measuring unit(400), a noise eliminator(500), a calculator(600), and a display unit(700). A sine wave generator generates the sinusoidal wave power source between 65Hz - 1.3MHz. A current amplifier amplifies inputted power and applies power to a current auxiliary electrode(C) and a ground bar(E). The setup unit sets up a measurement frequency band and sets up the measurement range for impedance. The measuring unit measures the current from the ground bar and measures voltage shown by the current applied on the ground from an electric potential auxiliary electrode(P). The calculator calculates the ground impedance by voltage and current and calculates the phase at a fixed measurement frequency band. The display unit outputs the phase and ground impedance values, corresponding to each frequency in a graph.

Description

Ground impedance measurement system in high frequency band {SYSTEM FOR MEASURING GROUND IMPEDANCE IN HIGH FREQUENCY BAND}

The present invention relates to a ground impedance measurement system, and more particularly, to a high frequency band (65 [Hz] to 1.3 [MHz]) for evaluating the grounding performance of a transient current such as a commercial frequency fault current or surge. A ground impedance measurement system in a high frequency band capable of measuring ground impedance.

Currently, the performance of the grounding system is evaluated by applying a low frequency current of 1 [kHz] or less to the ground. However, in the event of a ground fault or lightning strike, a transient current with frequency components of several [kHz] to several [MHz] flows, and the rise time of the waveform is also in the range of several hundreds [ns] to several [μs]. There is a significant difference from the rise of the earth potential, which is calculated from one ground resistance.

When the low-frequency current flows into the ground electrode, the reactance component of the ground electrode is very small, so it is simply measured as a resistance component.However, when transient and high-frequency currents such as surge current enter the ground, the ground-pole reactance and ground capacitance become very large. Appears as an impedance component. Therefore, the performance of the grounding system should be evaluated with wide bandwidth in consideration of high frequency components as well as low frequency. That is, the conventional ground impedance measuring apparatus measured at a fixed frequency in the low frequency band of less than 1 [kHz]. However, the actual grounding system generates high frequency currents of several hundreds [kHz] to several [MHz] depending on the fault condition. Accurate grounding impedance measurements are required.

The present invention has been made in view of the above problems, and the object of the present invention is to measure a high impedance component according to the inflow of the ground impedance, that is, the transient current and the high frequency current such as the surge current in the high frequency range as well as the low frequency. have.

The present invention for achieving the technical problem relates to a ground impedance measurement system in a high frequency band, the sinusoidal wave generator for generating a sinusoidal power in the frequency band 65 [Hz] to 1.3 [MHz]; Amplifying the input power to 30 [V _pp ] and 0.5 [A], and then applying the current amplifier to the current auxiliary electrode C and the ground electrode E embedded in the ground; A setting unit for setting a measurement frequency band and setting an impedance measurement range; A measuring unit measuring a current from the ground electrode E and measuring a voltage represented by a current applied to the ground from the potential auxiliary electrode P; A calculator for calculating a ground impedance value using the input voltage and current, and calculating a phase in a set measurement frequency band; And a display unit outputting a phase and ground impedance value corresponding to each frequency in a graph form based on the result calculated by the operation unit. Characterized in that it comprises a.

In addition, a voltage follower may be formed between the sinusoidal wave generator and the current amplifier to transfer the original signal to the current amplifier regardless of the output impedance of the sinusoidal wave generator.

The control unit may set the measurement frequency band to 65 [Hz] to 1.3 [MHz] and the impedance range to 1 [Ω] to 200 [Ω].

In addition, by using a band rejection filter (BRF), the noise removal unit for removing the noise caused by the inflow of power supply noise when measuring voltage and current; It characterized in that it further comprises.

In addition, the operation unit measures a ground impedance as a ratio of the maximum voltage V (t ₁ ) and the maximum current i (t ₂ ) through [Equation 4].

[Equation 4]

According to the present invention as described above, high frequency bands (65 [Hz] to 1.3 [MHz]) also for information communication devices and electronic devices that generate a high frequency current of several hundred [kHz] to several [MHz] depending on a fault condition. It is possible to measure the precise ground impedance at.

1 is an overall configuration diagram of a ground impedance measurement system in a high frequency band according to the present invention.
Figure 2 is an exemplary view showing an experimental system for evaluating the performance of the ground impedance measurement system in the high frequency band according to the present invention.
3 is a graph showing the measured voltage and current waveforms when the measurement frequency 650 [Hz] and external noise 60 [Hz] are simulated on three consecutive ground electrodes according to the present invention.
4 is a graph showing a change in the ground impedance according to the frequency according to the present invention.

Specific features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. In the meantime, when it is determined that the detailed description of the known functions and configurations related to the present invention may unnecessarily obscure the subject matter of the present invention, it should be noted that the detailed description is omitted.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

The ground impedance measurement system in the high frequency band according to the present invention will be described with reference to FIGS. 1 to 4.

1 is an overall configuration diagram of a ground impedance measurement system S in a high frequency band according to the present invention, and as shown, a sine wave generator 100, a current amplifier 200, a setter 300, and a measurement The unit 400 includes a noise removing unit 500, an operation unit 600, and a display unit 700.

The sinusoidal wave generator 100 generates a sinusoidal wave power in the frequency band of 65 [Hz] to 1.3 [MHz].

The current amplifier 200 amplifies the input power up to 30 [V _pp ], 0.5 [A] and then applies it to the current auxiliary electrode C and the ground electrode E embedded in the ground.

At this time, between the sine wave generator 100 and the current amplifier 200, a voltage follower 110 (Voltage Follower) for outputting the input voltage as it is configured, regardless of the output impedance of the sine wave generator 100 The original signal is transmitted to the current amplifier 200.

The setting unit 300 sets a measurement frequency band and sets an impedance measurement range. That is, the setting unit 300 sets the measurement frequency band to 65 [Hz] to 1.3 [MHz], and sets the impedance range to 1 [Ω] to 200 [Ω].

The measurement unit 400 measures a current from the ground electrode E, and measures a voltage represented by a current applied to the ground from the potential auxiliary electrode P.

On the other hand, when 60 [Hz] power supply noise is present, an error occurs if the noise is not removed from the waveform. Therefore, in the present invention, the band elimination filter is applied for accurate ground impedance calculation.

That is, the noise removing unit 500 removes noise generated by the inflow of power supply noise when measuring voltage and current by using a band rejection filter (BRF).

The calculation unit 600 calculates a ground impedance value using the input voltage and current, and calculates a phase in the set measurement frequency band.

On the other hand, the ground impedance is defined as the ratio of the transient voltage to the transient current flowing into the ground electrode, as shown in the following [Equation 1].

[Equation 1]

In addition, the parameter representing the ground impedance may be represented by the following [Equation 2] to [Equation 5] based on the maximum value of the voltage and the current.

[Equation 2]

[Equation 3]

[Equation 4]

[Equation 5]

Here, Z ₁ is the maximum value of the voltage and current ratio, Z ₂ is the ratio of the maximum value of the voltage and the current value when the voltage reaches the maximum value (t ₁ ), Z ₃ is the maximum voltage and the maximum current Z ₄ is the ratio of the voltage and the current value when the current reaches the maximum value (t ₂ ).

In particular, Z ₃ is the effective surge impedance.

That is, the calculator 600 calculates the ground impedance value based on the voltage and current values as shown in [Equation 4], and calculates the phase in the set measurement frequency band.

The display unit 700 outputs a phase and ground impedance value corresponding to each frequency in the form of a graph based on the result calculated by the operation unit 600.

Hereinafter, an experiment system will be configured to evaluate the performance of the ground impedance measurement system in the high frequency band. Evaluation of the ground impedance measurement system S in the high frequency band at the three-junction ground electrode was performed by the potential drop method as shown in FIG. 2. IEEE Std. According to 80-2000, the distance between each ground electrode is 10 [m], and it is arranged at 90 degrees to reduce the error caused by mutual inductive coupling between lead wires.

The power supply device 10 for simulating external noise can supply a maximum of 300 [V] and 5 [A] at a frequency of 45 [Hz] to 999 [Hz], and has provided noise applying electrodes g1 and g2.

First, we analyzed the performance of the ground impedance measurement system in an environment with external noise. FIG. 3 shows the measured voltage and current waveforms when the measurement frequency 650 [Hz] and external noise 60 [Hz] are simulated on the three-junction ground electrode.

(A) and (b) of FIG. 3 are current and voltage waveforms appearing at each electrode, and FIGS. 3 (c) and (d) are current and voltage components of the same frequency component as the measurement frequency in the digital bandpass filter of the measuring instrument. It is shown only. It can be seen that all components other than the power frequency applied for the measurement are removed by the designed signal processing algorithm and are not affected by external noise.

Figure 4 shows the change in the ground impedance with frequency, the characteristics of the capacitive decrease with increasing frequency from 65 [Hz] to 1.3 [MHz].

As described above and described with reference to a preferred embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described as described above, it is a deviation from the scope of the technical idea It will be understood by those skilled in the art that many modifications and variations can be made to the invention without departing from the scope of the invention. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

S: ground impedance measurement system in high frequency band
100: sinusoidal wave generator 200: current amplifier
300: setting unit 400: measuring unit
500: noise removing unit 600: calculating unit
700: display unit

Claims (5)

A sine wave generator for generating a sine wave power in the frequency band of 65 [Hz] to 1.3 [MHz];
Amplifying the input power to 30 [V _pp ] and 0.5 [A], and then applying the current amplifier to the current auxiliary electrode C and the ground electrode E embedded in the ground;
A setting unit for setting a measurement frequency band and setting an impedance measurement range;
A measuring unit measuring a current from the ground electrode E and measuring a voltage represented by a current applied to the ground from the potential auxiliary electrode P;
A calculator for calculating a ground impedance value using the input voltage and current, and calculating a phase in a set measurement frequency band; And
A display unit for outputting a phase and ground impedance value corresponding to each frequency in the form of a graph based on the result calculated by the operation unit; Grounding impedance measurement system in a high frequency band comprising a.
The method of claim 1,
A voltage follower is formed between the sinusoidal wave generator and the current amplifier to transmit a raw signal to the current amplifier regardless of the output impedance of the sinusoidal wave generator. .
The method of claim 1,
The control unit,
A ground impedance measurement system in a high frequency band, wherein the measurement frequency band is set to 65 [Hz] to 1.3 [MHz] and the impedance range is set to 1 [Ω] to 200 [Ω].
The method of claim 1,
A noise removal unit for removing noise generated by inflow of power supply noise when measuring voltage and current by using a band rejection filter (BRF); Ground impedance measurement system in the high frequency band further comprises.
The method of claim 1,
The calculation unit,
A ground impedance measurement system in a high frequency band characterized by measuring the ground impedance as the ratio of the maximum voltage V (t ₁ ) and the maximum current i (t ₂ ) through [Equation 4].
[Equation 4]

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