KR102039268B1 - An Alternating and Direct Current Detection Circuit - Google Patents

Abstract

The present invention relates to an AC and DC current detecting circuit. According to the present invention, electrical resistance characteristic values of main_R1 which is a main resistor, and a mirror-R1 which is a reference resistor are the same. The winding number of times of a coil of main-W1 which is a main coil is obtained by winding main_M1 which is a main core by one or multiple times. A power line (312) which is a power supply line, penetrates an internal penetration area of the main_M1 which is the main core. The winding number of times of a coil of mirror_W1 which is a reference coil winding is obtained by winding mirror_M1 which is a reference core by one or multiple times. An internal penetration area of the mirror_M1 which is the reference core does not have a penetrating power line. Electric winding characteristic values of the main_W1 which is the main coil winding and the mirror_W1 which is the reference coil winding are the same. Electric core characteristic values of the main_M1 which is the main core, and the mirror_M1 which is the reference core are the same. When AC or DC current flows through the power line (312), a signal deviation occurs between a node N306 terminal and a node N308 terminal to generate an output signal (310). The magnitude of the output signal (310) is proportional to the AC or DC current of the power line (312), which is a power supply line. In addition, the magnitude of the output signal (310) is proportional to an image current, which is an accident leakage current of the power line (312), which is the power supply line.

Description

AC Alternating and Direct Current Detection Circuit

The present invention is characterized in that one or a plurality of power lines 312 penetrate the inner through region of Main_M1, which is the main core.

The inner through region of Mirror_M1, which is a reference high-core core, is characterized in that no power line penetrates.

The characteristics of the electrical windings of the main coil winding Main_W1 and the reference coil winding Mirror_W1 are the same.

The electrical core characteristic values of Main_M1, which is the main high core, and Mirror_M1, which is the reference high core, are the same.

When an AC or DC current flows through the power line 312, a signal deviation occurs between the Node N306 terminal and the Node N308 terminal to generate an output signal 310.

The magnitude of the output signal 310 is proportional to the alternating current or direct current of the power line 312, which is a power supply wire.

In addition, the magnitude of the output signal 310 is proportional to an image current which is an accidental leakage current of the power line 312 which is a power supply wire.

As a method of measuring direct current flowing through a power line, a direct direct current measurement method in which a direct current measuring device is directly connected to the power line and measured, and an electromagnetic field generated by the current of the power line. There is an indirect DC current measuring method for measuring the DC current of the power line by detecting the by a magnetic field measuring device.

Here, there is a constraint that is difficult to connect the measurement device directly to the power line by the direct DC current measurement method.

Therefore, recently, an indirect DC current measuring method has emerged to escape such a direct DC current measuring method.

An indirect DC current measurement method is a method using a fluxgate method as a representative example. According to the DC current measuring method using the fluxgate method, an alternating current is applied to two cores so that the alternating magnetization directions are opposite to each other, and due to magnetic field waveform distortion occurring in coils wound around the two cores. The magnetic flux is detected by the DC current flowing through the power line by detecting the change of the voltage signal. The magnetic flux caused by the current of the power line is detected by using a separate coil, and the compensating current corresponding to the detected magnetic flux is applied to cancel the electromagnetic field caused by the current flowing through the power line. Measure the flowing direct current.

In the state in which two fluxgate cores are magnetized in opposite directions by applying a current oscillated by a square wave or a sine wave, magnetic field waveform distortion generated in the two cores is detected as a voltage signal by the measured current of the power line. The DC component is detected, and the AC component is detected by a separate core or a separate circuit configuration. Then, the magnetic flux is applied with a compensation current corresponding to the detected component to converge the compensation current so as to cancel the magnetic flux caused by the current to be measured, and the measured compensation current is measured to measure the DC current to be measured.

In the prior arts, when the current according to the oscillation signal is applied to both cores to magnetize with opposite polarity, the cores are connected in series so that both cores have the opposite polarity, and then the oscillation signal is applied to the series connection points of both coils. There is a problem in that the magnetization in opposite directions to each other causes a large deviation in measurement performance.

Patent No. 10-1329240 is a conventional technique for measuring the current by the flux gate method (Fluxgate).

Embodiments of the present invention have the following features.

First, the inner through area of Main_M1, which is the main core, has one or more power lines 312 penetrating through.

Second, the inner through region of Mirror_M1, which is a reference high core, has no characteristic of passing through power lines.

Third, the electrical winding characteristics of the main coil winding Main_W1 and the reference coil winding Mirror_W1 have the same characteristics.

Fourth, the electrical core characteristic values of Main_M1, the main high core, and Mirror_M1, the reference high core, have the same characteristics.

Fifth, the magnitude of the output signal 310 is proportional to the alternating current or direct current of the power line 312, which is a power supply wire.

In addition, the size of the output signal 310 is characterized in that it is proportional to the image current which is the accidental leakage current of the power line 312 which is a power supply wire.

The two terminals of the input AC signal 300 supply (a) square wave signal, (b) triangle wave signal, or (c) sine wave signal of constant frequency to the Node N302 terminal and the Node N304 terminal, respectively.

The electrical resistance characteristics of the main resistor Main_R1 and the reference resistor Mirror_R1 are the same.

The number of coil turns of the main coil winding Main_W1 is characterized by winding the main core core Main_M1 one or more times.

The power line 312, which is a power supply wire, penetrates through the inner through region of Main_M1, which is the main peak core.

The inner through area of Main_M1, which is the main core, is characterized in that one or a plurality of power lines 312 penetrate.

One terminal of the reference coil winding Mirror_W1 is connected to the node N308, and the other terminal of the reference coil winding Mirror_W1 is commonly connected to the node N304.

The number of coils of the mirror coil W1, which is the reference coil winding, may be wound one or more times.

The inner through region of Mirror_M1, which is a reference high-core core, is characterized in that no power line penetrates.

The characteristics of the electrical windings of the main coil winding Main_W1 and the reference coil winding Mirror_W1 are the same.

The electrical core characteristic values of Main_M1, which is the main high core, and Mirror_M1, which is the reference high core, are the same.

Main_M1, the main core, and Mirror_M1, the standard core, include high permeability Permalloy (Nickel) steel sheets.

When an AC or DC current flows through the power line 312, a signal deviation occurs between the Node N306 terminal and the Node N308 terminal to generate an output signal 310.

The magnitude of the output signal 310 is proportional to the alternating current or direct current of the power line 312, which is a power supply wire.

In addition, the magnitude of the output signal 310 is proportional to an image current which is an accidental leakage current of the power line 312 which is a power supply wire.

As described above, the embodiment of the present invention has the following effects.

First, the inner penetrating area of Main_M1, which is the main high-core core, provides an effect that one or more power lines 312 penetrate.

Second, the inner through area of Mirror_M1, the reference high-core core, provides an effect that there is no power line passing through.

Third, the electrical winding characteristics of the main coil winding Main_W1 and the reference coil winding Mirror_W1 have the same characteristic.

Fourth, the electrical core characteristic values of Main_M1, which is the main high core, and Mirror_M1, which is the reference high core, have the same effect.

Fifth, the magnitude of the output signal 310 is proportional to the alternating current or direct current of the power line 312, which is a power supply wire.

In addition, the size of the output signal 310 provides an effect characterized in that it is proportional to the image current which is the accidental leakage current of the power line 312 which is a power supply wire.

In addition, a preferred embodiment of the present invention is for the purpose of illustration, those skilled in the art will be able to various modifications, changes, replacements and additions through the spirit and scope of the appended claims, such modifications and changes are claimed in the following claims It should be seen as belonging to a range.

1 is a configuration diagram of a conventional fluxgate circuit.
2 is an operational waveform diagram of a conventional fluxgate circuit.
3 is a configuration diagram of a DC current sensing circuit of the present invention.
4 is a waveform diagram showing the input AC signal of the present invention.
5 is a waveform diagram of an output signal of the present invention.

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

1 is a configuration diagram of a conventional fluxgate circuit.

It is a schematic block diagram of the fluxgate type non-contact current measuring apparatus.

The conducting wire W0 is a conducting wire through which a current under measurement flows.

The coils W1, W2, and W3 wound on the three cores M1, M2, and M3 pass through the inner hollow to enclose the circumference of the conductor.

The coil W4 is wound around three cores M1, M2, and M3 simultaneously.

Oscillating currents having polarities opposite to each other are applied to the two coils W1 and W2.

The oscillation part 10 oscillates so that cores M1 and M2 may be excited with magnetic flux in directions opposite to each other.

The compensation current generating unit 20 generates a compensation current corresponding to the current induced in the other coil W3.

The saturation return unit 30 detects this when the core self-saturates and demagnetizes it.

The compensating current is applied to the coil W4 wound simultaneously on three cores, so that the detector 40 measures the voltage corresponding to the compensating current to obtain the current to be measured.

2 is an operational waveform diagram of a conventional fluxgate circuit.

When the current to be measured 1 does not flow through the conductive wire W0, the first coil W1 and the second core M2 wound by the oscillated electricity to the first core M1 are wound as described above. As applied to the second coil W1, the voltage signal of the first coil W1 and the voltage signal of the second coil W2 have a 180 ° phase difference with each other.

When these voltage signals are summed, the summed voltage signal becomes '0'.

When a current to be measured having a positive DC component 2 flows through the conductive wire W0, distortion occurs at the anode, such as a voltage signal of the first coil W1 and a voltage signal of the second coil W2. . When the distorted voltage signals are summed up, a value other than '0' is generated in the distorted portion, thereby detecting the DC component of the anode.

When the current to be measured having the direct current component 3 of the cathode flows through the conductive wire W0, distortion occurs at the cathode, such as the voltage signal of the first coil W1 and the voltage signal of the second coil W2. When the distorted voltage signals are added together, a value other than '0' is generated in the distorted portion, thereby detecting the DC component of the cathode.

As described above, when a DC component is included in the current to be measured flowing in the conductive wire W0, the DC component can be detected according to polarity.

3 is a configuration diagram of a DC current sensing circuit of the present invention.

It is a block diagram of the circuit which detects the alternating current or direct current which flows into the power line 312 by a non-contact method.

Two terminals of the input AC signal 300 are connected to the Node N302 terminal and the Node N304 terminal, respectively.

One terminal of the main resistor Main_R1 is connected to the Node N302 terminal, and the other terminal of the main resistor Main_R1 is connected to the Node N306 terminal.

One terminal of the reference resistor Mirror_R1 is commonly connected to the Node N302 terminal, and the other terminal of the reference resistor Mirror_R1 is connected to the node N308 terminal.

The electrical resistance characteristics of the main resistor Main_R1 and the reference resistor Mirror_R1 are the same.

One terminal of Main Coil winding Main_W1 is connected to Node N306, and the other terminal of Main Coil winding Main_W1 is connected to Node N304.

The number of coil turns of the main coil winding Main_W1 is characterized by winding the main core core Main_M1 one or more times.

The power line 312, which is a power supply wire, penetrates through the inner through region of Main_M1, which is the main peak core.

The inner through area of Main_M1, which is the main core, is characterized in that one or a plurality of power lines 312 penetrate.

One terminal of the reference coil winding Mirror_W1 is connected to the node N308, and the other terminal of the reference coil winding Mirror_W1 is commonly connected to the node N304.

The number of coils of the mirror coil W1, which is the reference coil winding, may be wound one or more times.

The inner through region of Mirror_M1, which is a reference high-core core, is characterized in that no power line penetrates.

The characteristics of the electrical windings of the main coil winding Main_W1 and the reference coil winding Mirror_W1 are the same.

The electrical core characteristic values of Main_M1, which is the main high core, and Mirror_M1, which is the reference high core, are the same.

Main_M1, the main core, and Mirror_M1, the standard core, include high permeability Permalloy (Nickel) steel sheets.

When an AC or DC current flows through the power line 312, a signal deviation occurs between the Node N306 terminal and the Node N308 terminal to generate an output signal 310.

By detecting the AC or DC current component by converting the magnetic field waveform distortion difference generated in Main_M1, which is the main core, and Mirror_M1, which is the reference core, by the current of the power line 312 into a voltage signal.

The magnitude of the output signal 310 is proportional to the alternating current or direct current of the power line 312, which is a power supply wire.

In addition, the magnitude of the output signal 310 is proportional to an image current which is an accidental leakage current of the power line 312 which is a power supply wire.

4 is an operational waveform diagram of an input AC signal according to the present invention.

When an AC or DC current of the power line 312 is applied, an input AC signal 300 is applied to the Node N302 terminal and the Node N304 terminal to generate a magnetic field waveform distortion difference between Main_M1, which is the main core, and Mirror_M1, which is the reference core. do.

The input AC signal 300 includes (a) a square wave signal, (b) a triangular wave signal, or (c) a sine wave signal of a constant frequency.

5 is a waveform diagram of an output signal operation of the present invention.

The magnitude of the output signal 310 represents a signal waveform corresponding to the direct current of the power line 312, which is a power supply wire.

The operation waveform in FIG. 5 is an operation signal waveform when a direct current in both directions is supplied to the power line 312 which is a power supply wire.

The operation waveform of FIG. 5 (b) is an operation signal waveform when a negative direct current is supplied to the power line 312 which is a power supply wire.

It can be seen that signals (a) and (b) of FIG. 5 are output voltage signals having opposite polarities.

10: oscillation part
20: compensation current generating unit
30: Saturation return part
40: detection unit

Claims (1)

In the current sensing device, characterized in that for sensing the AC or DC current in a non-contact manner,
Input alternating current signal 300; And
Main_R1; And
Mirror_R1; And
Main_W1; And
Main_M1; And
Mirror_W1; And
Mirror_M1; And
Power line 312; And
At the output signal 310,
Two terminals of the input AC signal 300 are connected to a Node N302 terminal and a Node N304 terminal, respectively.
One terminal of the main resistor Main_R1 is connected to the Node N302 terminal, and the other terminal of the main resistor Main_R1 is connected to the Node N306 terminal.
One terminal of the reference resistance Mirror_R1 is commonly connected to the Node N302 terminal, the other terminal of the reference resistance Mirror_R1 is connected to the node N308 terminal,
The electrical resistance characteristics of the main resistor Main_R1 and the reference resistor Mirror_R1 are characterized by the same value,
One terminal of the main coil winding Main_W1 is connected to the Node N306, the other terminal of the main coil winding Main_W1 is connected to the Node N304,
The power line 312, which is a power supply wire, penetrates through the inner through area of Main_M1, which is a main high core,
In the inner through region of the Main_M1, which is the main deep core, one or a plurality of power lines 312 penetrates,
One terminal of the Mirror_W1 that is a reference coil winding is connected to the Node N308, and the other terminal of the Mirror_W1 that is a reference coil winding is commonly connected to the Node N304,
The inner penetrating region of the Mirror_M1, which is a reference high core, has no power line passing therethrough,
The electrical winding characteristic values of the main coil winding Main_W1 and the reference coil winding Mirror_W1 are the same,
The electrical core characteristic values of the Main_M1, which is the main high core, and the Mirror_M1, which is the reference high core, are identical to each other,
When an alternating current or direct current flows through the power line (312), a signal deviation occurs between the Node N306 terminal and the Node N308 terminal to generate the output signal (310).

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