KR101949535B1 - Hot-line approaching warning device using amorphous core - Google Patents

Abstract

There is provided a live wire alarm device using an amorphous core in which if a reference wave is generated, it is determined whether a live wire is accessed based on a signal waveform output from an amorphous antenna to be driven and an alarm is made. An amorphous antenna for outputting a signal waveform corresponding to an electrostatic field which is driven and induced when a reference wave is generated, An amplifier for amplifying a signal waveform output from the amorphous antenna; And an alarm processor for generating a reference wave to the amorphous antenna and for determining whether to access the active line based on the signal waveforms received from the amplifier and generating an alarm.

Description

(HOT-LINE APPROACHING WARNING DEVICE USING AMORPHOUS CORE)

The present invention relates to a live-line approaching alarm device using an amorphous core, and more particularly, to a live-line approaching alarm device using an amorphous core for alerting an operator to a live-line approach during live-line operation.

The live wire approaching alarm is a device that detects the electric field of the high-voltage charging part from the antenna built in the band and the internal electrode installed in the main body, so that the buzzer rings when the voltage exceeds a certain value.

It is used to attach to the worker's wrist, arm, helmet, etc., and to alert the operator to the accident by generating an alarm when the operator approaches the high-voltage charging part, .

A conventional live-wire approaching alarm device uses a detection plate using an electrostatic induction principle as a means for detecting an electrostatic field, or a coil using an electromagnetic induction principle. At this time, since the signal induced in the detection element (detection plate, coil, etc.) is weak, it was a method of reading at a level amplified using a multi-stage amplifier. However, when only the amplifier is used, there is a problem that not only the electrostatic field of the normal high-voltage line but also malfunction due to the result that the similar induced magnetic field or noise is simultaneously amplified.

In addition, since the general battery is used as the operating power source of the live wire approaching alarm device, there is a problem that it is inconvenient to replace the consumed battery during the operation and the capacity of the battery must be checked from time to time.

In a conventional live wire approach alarm device, a method of non-contact detection of an electrostatic field of a live wire can be classified into electrostatic induction and electromagnetic induction (magnetic field detection).

The electrostatic induction method is a method of detecting the active wire approach using the electrostatic induction phenomenon. The electrostatic induction phenomenon is a phenomenon in which a charge of the same polarity as an object is charged when another object comes close to the electrostatic field range of a conductor charged in space. For example, Korean Registered Utility Model No. 20-0262057 (a circuit for a live call access alarm, hereinafter referred to as Prior Art 1) describes a circuit for alerting a live access using an electrostatic induction method. Prior art 1 constitutes an equivalent circuit as shown in Fig. In this case, P is the power line, S is the person, C is the power line and the earth capacitance, Cs is the earth capacitance of the person, Rs is the earth insulation resistance of the person, E is the ground voltage of the power line, Es is earth induced electromotive force of the person, Means the current flowing through the capacitance. In the prior art, each value shown in the equivalent circuit is substituted into the following equation (1) to calculate a ground induction electromotive force of a person.

At this time, since Rs is a considerably large value, the electrostatic induction voltage is proportional to the ground voltage (E) of the power line. Therefore, the safe distances for each high voltage are distinguished by using the different electrostatic induction voltage according to the voltage of the live wire. However, since the human-to-earth insulation resistance value and the human-to-earth capacitance value change depending on the humidity due to the weather or the surrounding environment and the operator's condition, the safety distance according to the condition change is irregularly discriminated when the prior art 1 is used .

In another example, as shown in FIG. 2, in Korean Utility Model Appln. Utility Model No. 20-1984-0001558 (hereinafter referred to as a live wire approach alarm, hereinafter referred to as Prior Art 2), an amount of charge induced in current collectors A and B is amplified, In the case of a fire alarm. Thus, the prior art 2 can solve the problem according to the environment change of the prior art 1. However, the prior art 2 has a problem that the sensitivity varies depending on the directivity of the current collecting plate, and the distance varies depending on the direction angle of the operator and the live wire.

The electromagnetic induction (magnetic field detection) method is a method of detecting the live wire approach using the electromagnetic induction phenomenon. That is, when a current flows in a conductor, a magnetic field is formed around the conductor. At this time, if there is a conductor in the magnetic field range, the current is induced in the conductor (for example, Faraday's Law). For example, Korean Unexamined Patent Application Publication No. 10-2009-0068984 (hereinafter referred to as "hot wire approaching alarm, hereinafter referred to as Prior Art 3) uses a circular detection sensor as an integral unit and is positioned at the center of a shock absorber inside a safety helmet, And the wearer is informed of the danger of electric shock. 3, in the prior art 3, the circular detection sensor 8 is configured to detect an electric field at a constant distance r from the power line in all directions, and as shown in FIG. 4, In Technology 3, a closed circuit between a power line, an alarm, and the ground is formed to detect a live approach through an electromagnetic induction phenomenon. In this case, C0 is the floating capacitance of the power line and the alarm, C1 is the floating capacitance between the alarm and the human body, C2 is the capacitance between the human body and the ground, R0 is the internal resistance of the alarm, and R1 is the human body and earth resistance.

However, the prior art 3 has a problem that the safety distance is irregularly classified according to the environmental change as in the prior art 1, and there is a problem that the problem of the directivity can not be solved like the prior art 2.

As described above, since the prior art is operated by the formation of the closed circuit between the live wire and the ground via the human body, there is a problem of irregular detection distance and directivity between the live wire and the worker due to changes in environmental conditions.

In addition, the prior art also has a secondary problem of using a general battery. Of course, Rectenna technology, which is a compound of Rectifying and Antenna, can be used to solve the power problem, but there is a problem that the weight is increased.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the problems of the prior art described above. In order to solve the irregularity and directionality problem of the detection distance according to the change of the environmental condition, And it is an object of the present invention to provide a live wire approaching alarm device using an amorphous core in which an access to a live wire is judged and alarmed.

According to an aspect of the present invention, there is provided an active lifting alarm apparatus using an amorphous core, comprising: an amorphous antenna for outputting a signal waveform corresponding to an electrostatic field induced by driving a reference wave; An amplifier for amplifying a signal waveform output from the amorphous antenna; And an alarm processing unit for generating a reference wave to the amorphous antenna and for generating an alarm based on the signal waveforms received from the amplifying unit, Calculating a variation error value based on waveforms and a predetermined reference level, storing the variation error value, analyzing whether the received signal waveforms are noisy by comparing the received signal waveforms with a level of a used frequency, And an analysis module for calculating the distance to the live line by integrating the error value of the stored change amount.

The amplifying unit includes: a low-level amplifying module for amplifying the signal waveform at a setting magnification; And a high-level amplification module for amplifying the signal waveform at a higher magnification than the low-level amplification module.

The alarm processing section includes a synchronization module for synchronizing the signal waveforms received from the amplification section with the reference wave.

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The analysis module detects the level by converting the signal waveforms into digital data, and subtracts the detected level from the reference level to calculate an error value of the variation amount.

The analysis module analyzes whether noise is present based on the period of the received signal waveforms and the period of the commercial frequency. If the period of the received signal waveforms changes within the error range of the commercial frequency period, .

The analysis module analyzes whether the reference level is set based on the period of the received signal waveforms whose level is changed and the period of the reference wave. If the period in which the level of the received signal waveforms is changed is within the error range of the reference wave period Analyze with reference level setting.

The analysis module converts the received signal waveforms into digital data and sets the detected level to the reference level.

The alarm processing unit includes a control module for determining whether or not to access the live line based on the distance and the distance setting value to the live line calculated based on the received signal waveforms and controlling the alarm to be generated when the live line approach is determined.

The control module judges that the operator is approaching the active line if the calculated distance to the active line is less than the set distance value.

The control module judges the accessibility of the live line based on the calculated distance to the live line and the plurality of distance set values, and controls the multi-step approach to generate different alerts in each step.

The control module induces a reference wave to the excitation coil of the amorphous antenna and drives it.

The alarm processing unit includes an output module for outputting at least one of sound, light, and vibration, and alerting the operator of the active line approach.

And a power supply unit for supplying operating power to the amplifying unit and the alarm processing unit.

The power supply unit includes at least one of a rectenna module, which is a wireless charging module, and a solar cell.

According to the present invention, a live wire alarm device using an amorphous core can detect an electrostatic field of a live wire by using an amorphous antenna, thereby maintaining a constant detection distance at the time of environmental condition change, and solving the problem of directivity between live wire and worker There is an effect that can be.

In addition, the live wire alarm device using the amorphous core has the effect of solving the capacity confirmation and replacement problem due to the use of the general battery by using the wireless charging and the solar energy charging.

Further, since the live-line alarm device using the amorphous core is composed of the amorphous antenna, the rectenna module, the solar cell, etc., it is possible to reduce the size and weight as compared with the conventional live-line approach alarm device.

1 to 4 are views for explaining a conventional live-line approaching alarm device.
FIG. 5 and FIG. 6 are views for explaining a live-line approaching alarm device using an amorphous core according to an embodiment of the present invention.
FIG. 7 is a view for explaining the amplifying unit of FIG. 5; FIG.
8 is a view for explaining an alarm processing unit of Fig. 5; Fig.
9 is a view for explaining the power supply unit of Fig. 5; Fig.
10 to 12 are diagrams for explaining a circuit configuration of a live-line alarm device using an amorphous core according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. . In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

First, the amorphous core used in the present invention will be described below.

Amorphous cores have uniform characteristics from low to medium frequency and small size. In order to induce a reference oscillation (12 kHz) waveform to the excitation coil of the amorphous antenna 120 as a means for detecting an electrostatic field of the product to be described later, the characteristic for this frequency should also be uniform. In addition, as a method for charging the product with a charger for generating a magnetic field for additional charging, a 12 khz pulse wave is generated in the charger, so that the charged pulse wave is used as a charging current. Since the electrostatic field generated by the live wire is a frequency of 60 Hz, the amorphous core is the most suitable material for detecting this signal. Of course, the nickel core has similar characteristics to the amorphous, but the amorphous to the same size is less lossy and is suitable for light weight.

Hereinafter, a live wire alarm device using an amorphous core according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 5 and 6 are views for explaining a live-line alarm device using an amorphous core according to an embodiment of the present invention. FIG. 7 is a view for explaining the amplifying unit of FIG. 5, FIG. 8 is a view for explaining the alarm processing unit of FIG. 5, and FIG. 9 is a view for explaining the power supply unit of FIG.

5, the active line alarm device 100 using an amorphous core includes an amorphous antenna 120, an amplification unit 140, an alarm processing unit 160, and a power supply unit 180. 6, a live wire alarm device 100 using an amorphous core includes an amplification unit 140, an alarm processing unit 160, and an upper part of a product body 190 including a part of the power supply unit 180 The amorphous antenna 120 is mounted. A solar cell 182 of a power supply unit 180 to be described later is mounted on the upper portion of the amorphous antenna 120.

The amorphous antenna 120 is a means for detecting an electrostatic field of a live wire, and outputs a signal waveform corresponding to the electrostatic field of the live wire. To this end, the amorphous antenna 120 includes an amorphous core, an exciting coil, and a pickup coil.

The excitation coil is formed by winding in parallel to the center of the amorphous core. The excitation coil generates a circumferential magnetic field in the circumferential direction in the circumferential direction of the amorphous core when a reference wave of about 12 kHz caused by the REF OSC signal is induced from the alarm processing unit 160. At this time, when the electrostatic field of the live wire is induced in the excitation coil, a magnetic vector change occurs in the axial direction of the circumference and an electrostatic field is induced.

The pickup coil is formed by winding helically around the amorphous core. The pickup coil outputs the signal waveform to the amplifier 140 as the electrostatic field is induced in the excitation coil. At this time, the pickup coil outputs a signal waveform proportional to the intensity of the electrostatic field (i.e., magnetic vector change) induced in the excitation coil to the amplification unit 140.

The amplification unit 140 amplifies the signal waveform received through the amorphous antenna 120 and transmits the amplified signal waveform to the alert processing unit 160. That is, the amplification unit 140 amplifies the signal waveforms induced in the pickup coil of the amorphous antenna 120 by a factor of 10 and 100, respectively, and transmits the amplified signals to the alert processing unit 160. 7, the amplification unit 140 includes a low-level amplification module 142 for amplifying the signal waveform 10 times and transmitting the amplified signal waveform to the alarm processing unit 160, And a high-level amplification module 144 for transmitting the high-level amplification module 144 to the high-

The alarm processing unit 160 causes the reference wave to be transmitted to the amorphous antenna 120. That is, the alarm processing unit 160 generates a reference wave of about 12 kHz, which is the REF OSC signal, to the excitation coil of the amorphous antenna 120. Thereafter, the alarm processing unit 160 determines whether or not access to the live line is based on the signal waveforms received from the amplification unit 140, and generates an alarm. 8, the alarm processing unit 160 includes a synchronization module 162, an analysis module 164, a control module 166, and an output module 168. [

The synchronization module 162 is composed of an analog-to-digital converter (ADC) and converts the signal waveforms received from the amplifier 140 to a reference wave generated by the control module 166 Wave).

The analysis module 164 calculates and stores a variation error value based on the signal waveform synchronized by the synchronization module 162 and a predetermined reference level. That is, the analysis module 164 detects the level by converting the synchronized signal waveform into digital data. The analysis module 164 calculates an error value of the change amount by subtracting the detected level from the reference level. The analysis module 164 stores the error value of the calculated change amount.

The analysis module 164 analyzes whether or not the signal waveform synchronized in the synchronization module 162 is noise. That is, a commercial frequency (i.e., about 60 kHz or so) induced in the live wire is input together with a reference wave induced in the excitation coil (i.e., about 12 kHz or so). The reference wave is synchronized with the magnitude of the induced commercial frequency to change the level. Accordingly, the analysis module 164 compares the cycle of the level of the synchronized signal waveform with a commercial frequency (i.e., about 60 kHz) to analyze noise. Here, the analysis module 164 analyzes the signal as a normal signal if the period in which the level of the synchronized signal waveform changes is within a range of the error frequency of the commercial frequency (i.e., about 60 kHz). The analysis module 164 analyzes the noise when the period in which the level of the synchronized signal waveform changes is a period deviated from the error range of the commercial frequency (i.e., about 60 kHz).

The analysis module 164 performs a reference level setting by analyzing with a reference wave if the period in which the level of the synchronized signal waveform is changed is within the error range of the reference wave (i.e., about 12 kHz). That is, the analysis module 164 detects the level by converting the synchronized signal waveform into digital data. The analysis module 164 sets the detected level to the reference level.

Of course, the analysis module 164 receives the analog signal for the reference wave (i.e., about 12 kHz) induced in the exciting coil of the amorphous antenna 120 at a predetermined periodic interval from the amplifier 140. The analysis module 164 converts the analog signal input from the amplification unit 140 into digital data to detect the level. The analysis module 164 may set the detected level to the reference level.

When the synchronized signal waveform is analyzed as a normal signal, the analysis module 164 calculates the distance to the live line by integrating the error value of the pre-stored change amount.

The control module 166 guides the reference wave to the amorphous antenna 120. That is, the control module 166 induces a reference wave of about 12 kHz attributable to the REF OSC signal to the excitation coil of the amorphous antenna 120.

The control module 166 controls the output module 168 to alert the operator whether the operator is active or not based on the analysis results of the analysis module 164. That is, the control module 166 controls the output module 168 to alert the operator whether the operator is approaching the active line based on the distance to the active line calculated by the analysis module 164. At this time, the control module 166 compares the distance with the live line and the distance set value to determine whether the live line is accessed. That is, when the distance between the control module 166 and the live line is less than the distance set value, the control module 166 controls the output module 168 to generate an alarm by determining that the worker is approaching the live line. Here, the distance setting value may be set differently depending on the use of the active line alarm device 100 using the amorphous core.

The control module 166 may set a plurality of distance settings and control the output module 168 to generate alerts in different ways depending on each distance setting. For example, when the first distance set value is set to 10 m and the second distance set value is set to 5 m, when the distance between the control module 166 and the live line becomes less than the first distance set value, And can control the output module 168 to output a buzzer sound to alert the active line approach when the distance to the live line is less than or equal to the second distance set value.

The output module 168 alerts the user of active access using at least one of sound, light, and vibration under the control of the control module 166. To this end, the output module 168 comprises at least one of a buzzer, a vibration means, and a lamp. That is, the output module 168 generates a warning sound through the piezo buzzer according to the control of the control module 166, generates a warning vibration by driving the vibration motor, or generates a warning light by blinking the lamp, Lt; / RTI >

The output module 168 may also alert the live access by other methods under the control of the control module 166. That is, the output module 168 selectively outputs sound, light, and vibration according to the distance to the live line and a plurality of distance setting values, thereby alerting the operator of the live-line approach.

The power supply unit 180 supplies operating power to the live-line alarm device 100 using the amorphous core. That is, the power supply unit 180 supplies electric energy to the amplification unit 140 and the alarm processing unit 160. 9, the power supply unit 180 includes a rectenna module 181, a solar cell 182, a charging module 183, and a constant voltage stabilization module 184.

The Rectena module 181 is a wireless charging module using the Rectena technology. The rectenna module 181 charges the charging module 183 in a contactless manner in a separate charging magnetic field generating charger. At this time, the rectenna module 181 receives a current according to a magnetic field induced in the coil of the amorphous antenna 120, or a magnetic field induced by approaching a transformer, a power line, or the like where a magnetic field is induced. The current received through the rectenna module 181 is rectified in the forward direction through the magnetic field charging resistance and the constant voltage stabilization module 184 to prevent reverse current flow and charge the charging module 183. Of course, the rectenna module 181 may be provided with a separate connector to charge the charging module 183 by receiving current through a charger for general mobile phone.

The solar cell 182 is mounted on the amorphous antenna 120 to convert the light energy into electrical energy to charge the charging module 183. At this time, the solar cell 182 converts solar light or the like into electric energy (for example, current) during operation of the operator or exposed to the outside to charge the charging module 183. Of course, the solar cell 182 may directly supply the electric energy converted during the operation of the operator to the operation power of the amorphous antenna 120, the amplification unit 140, and the alarm processing unit 160. The solar cell 182 rectifies the generated electric energy through the constant voltage stabilization module 184 in the forward direction to prevent reverse current and charges the charging module 183. [

The charging module 183 is composed of an electric energy charging means such as a nickel metal hydride rechargeable battery and charges using the current supplied from the rectenna module 181 and the solar cell 182. The charging module 183 supplies the charged electric energy to the amorphous antenna 120, the amplification unit 140, and the alarm processing unit 160.

The constant voltage stabilization module 184 rectifies the electric current (electric energy) applied from the rectenna module 181 or the solar cell 182 in the forward direction to prevent the reverse current from being generated.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a circuit configuration of a live wire alarm apparatus using an amorphous core according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 10 to 12 are diagrams for explaining a circuit configuration of a live wire alarm device using an amorphous core according to an embodiment of the present invention.

10 is a diagram for explaining a circuit configuration of the amorphous antenna and the amplifying unit. 10, when the REF OSC reference wave is inputted from the alarm processing unit 160, the amorphous antenna 120 amplifies the signal waveform proportional to the intensity of the electrostatic field induced in the excitation coil to a low level Amplification module 142 and high-level amplification module 144, respectively. Accordingly, the low-level amplification module 142 amplifies the inputted signal waveform 10 times and transmits the amplified signal waveform to the alarm processing unit 160. [ The high-level amplification module 144 amplifies the input signal waveform 100 times and transmits the amplified signal waveform to the alert processing unit 160. [ The rectenna module 181 of the power supply unit 180 is configured to charge the charging module 183 through an electrostatic field induced in the excitation coil of the amorphous antenna 120.

11 is a diagram for explaining a circuit configuration of the alarm processing unit 160. As shown in Fig. 11, the alarm processing unit 160 includes a synchronization module 162, an analysis module 164, a control module 166, a buzzer 220, a laser diode 230, And an output module 168 composed of a vibration motor 240. The microcomputer 210 calculates the distance to the live line using the amplified signal waveforms inputted from the low level amplification module 142 and the high level amplification module 144 and outputs the calculated distance to the buzzer 220, the laser diode 230, (240) to warn the operator of the live line approach. At this time, the first switch 250 may be configured to set the distance setting value, the selection of the output module 168, and the like with the function selection switch. The second switch 260 may be configured to test whether a live wire alarm device using the amorphous core as a test switch operates normally.

12 is a diagram for explaining the circuit configuration of the power supply unit. 12, the power supply unit 180 includes a solar cell 182, a rectenna module 181, a charging module 183, and a constant voltage stabilization module 184. Electric energy generated through the rectenna module 181 is charged to the charging module 183 through the charging resistor R11 and the charging rectifier D1. Electric energy generated through the solar cell 182 is charged to the charging module 183 through the charging resistor R12 and the charging rectifier D2. At this time, it is configured to prevent reverse current through the constant voltage stabilization module 184.

As described above, the live-line alarm apparatus using the amorphous core detects an electrostatic field of the live wire by using an amorphous antenna, so that a constant detection distance can be maintained when the environmental condition changes, and the problem of directivity between the live wire and the worker can be solved There is an effect that can be.

In addition, the live wire alarm device using the amorphous core has the effect of solving the capacity confirmation and replacement problem due to the use of the general battery by using the wireless charging and the solar energy charging.

Further, since the live-line alarm device using the amorphous core is composed of the amorphous antenna, the rectenna module, the solar cell, etc., it is possible to reduce the size and weight as compared with the conventional live-line approach alarm device.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but many variations and modifications may be made without departing from the scope of the present invention. It will be understood that the invention may be practiced.

100: Live access alarm with amorphous core
120: Amorphous antenna 140: Amplification part
142: Low level amplification module 144: High level amplification module
160: alarm processing unit 162: synchronization module
164: Analysis module 166: Control module
168: Output module 180:
181: Rectena module 182: Solar cell
183: charging module 184: constant voltage stabilization module

Claims (15)

An amorphous antenna for outputting a signal waveform corresponding to an electrostatic field induced by driving when a reference wave is generated;
An amplifier for amplifying a signal waveform output from the amorphous antenna; And
And an alarm processing unit for generating a reference wave to the amorphous antenna and for determining whether to access the active line based on the signal waveforms received from the amplifying unit to generate an alarm,
The alarm processing unit calculates and stores a variation error value based on the signal waveforms received from the amplifying unit and a predetermined reference level and compares the received signal waveforms with the level of the used frequency to analyze noise, And an analysis module for calculating the distance to the live line by integrating the error value of the stored change amount when the received signal waveforms are analyzed as a normal signal. The method according to claim 1,
Wherein,
A low level amplifying module for amplifying the signal waveform at a setting magnification; And
And a high-level amplification module for amplifying the signal waveform at a higher magnification than the low-level amplification module. The method according to claim 1,
The alarm processing unit,
And a synchronization module for synchronizing the signal waveforms received from the amplification unit with a reference wave. delete The method according to claim 1,
Wherein the analysis module comprises:
Wherein the signal waveforms are converted into digital data to detect a level, and an error value of a variation amount is calculated by subtracting the detected level from the reference level. The method according to claim 1,
Wherein the analysis module comprises:
The method includes analyzing whether noise is present or absent based on a cycle of the level of the received signal waveforms and a period of a commercial frequency, and if the period of the received signal waveforms is within a tolerance range of the commercial frequency period, Wherein the amorphous core is used for analyzing a living body. The method according to claim 1,
Wherein the analysis module comprises:
The method includes analyzing whether a reference level is set based on a period in which the level of the received signal waveforms is changed and a period of a reference wave, and when the period in which the level of the received signal waveforms changes is within a tolerance range of the reference wave period, Level alarm, and analyzing the alarm signal by level setting. The method of claim 7,
Wherein the analysis module comprises:
And converting the received signal waveforms into digital data to set the detected level as a reference level. The method according to claim 1,
The alarm processing unit,
And a control module for determining whether to access the active line based on the distance and the distance set value calculated based on the received signal waveforms and controlling the alarm to be generated when it is determined that the active line is approaching. Live access alarm system using. The method of claim 9,
The control module includes:
And determines that the operator is approaching the active line if the calculated distance to the active line is less than or equal to the distance set value. The method of claim 9,
The control module includes:
Wherein the control unit controls the multi-stage determination of whether or not the active lines are approachable based on the calculated distance to the active line and a plurality of distance setting values, and controls to generate different alerts in each step. The method of claim 9,
The control module includes:
And a reference wave is induced in the excitation coil of the amorphous antenna to drive the excitation coil. The method according to claim 1,
The alarm processing unit,
And an output module for outputting at least one of sound, light, and vibration to alert the operator to the active line approach. The method according to claim 1,
Further comprising a power supply unit for supplying operating power to the amplifying unit and the alarm processing unit. 15. The method of claim 14,
The power supply unit,
A rectenna module as a wireless charging module, and a solar cell.

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