KR100955805B1 - The device for detecting live wire state of the high voltage wire using the wireless communication method - Google Patents

Abstract

PURPOSE: A device for detecting a live wire state of a high voltage wire using a wireless communication is provided to prevent the safety accident by detecting voltage in a live wire of high voltage line through a reader communicating with a wireless ID tag. CONSTITUTION: An apparatus comprises a detection apparatus(100) and a radio identification reader. A rectifying circuit part(131) is located around of a high-voltage line. A high voltage sensor(132) senses the high voltage outputted through the rectifying circuit part. The high voltage sensor inputs data to the radio identification tag. A dip switch part(133) establishes a voltage level according to the size of the high voltage. A diac(134) is charged by the voltage outputted from the dip switch part. A thyristor(135) is turned on while the voltage charged into the diac is discharged.

Description

The device for detecting live wire state of the high voltage wire using the wireless communication method}

The present invention relates to an apparatus mounted on a line of each phase of a switchboard to open and close the line to detect whether the line voltage is live or inactive.

More particularly, the present invention relates to a device for detecting a live state by communicating a radio frequency reader and a radio frequency reader attached to a power distribution panel by installing the high voltage line live state detection device for each line.

Conventionally, for the safety of workers when working with various power equipment or high voltage lines, when the power line is approached live, that is, when the power is supplied, not only the risk of electric shock but also the human body may be damaged by radiated electromagnetic fields. Electric power generation systems such as transmission stations and substations and power facility systems such as outdoor overhead lines or underground lines are discriminated against such high-voltage liveliness, and care is taken in handling or approaching liveliness.

Conventionally, a method of determining whether a high voltage current flows through a wire by using a measuring instrument such as a tester has been used for the determination of such a live wire, but it is possible to measure only when the measuring instrument and the live wire are electrically connected to each other. It was possible to cause an accident itself. In the case of direct connection to a high voltage line after holding a detector of a certain length by hand to check liveness, for example, very high electric / Since a magnetic field was formed, there was a risk of electric shock even when not directly in contact with the high voltage line.

In addition, in the measurement of high pressure, the measurement process is inconvenient because the measurement is possible only after transforming into a separate voltage drop transformer.

1 is a configuration diagram showing a live voltage detection method of a high voltage line according to the prior art. Referring to FIG. 1, one line of a high pressure sensing unit to which a voltage is applied has a high voltage for dividing the voltage with a sufficient insulation distance with the high voltage line. The capacitor is equipped with a voltage drop at low voltage, and the other line is connected to ground.

However, the conventional method does not connect the high pressure sensing unit directly to the high voltage line but must install the high pressure sensing unit while securing the insulation distance through the high voltage capacitor. Therefore, the high pressure capacitor installed is not only expensive but also high voltage in the high voltage line. A cable for constructing a line to the capacitor and a high voltage sensing unit from the high voltage capacitor, and a cable for connecting the ground to each other, are required separately, and thus there is a problem in that equipment is not easy and high cost is required.

In addition, if the cable to the ground is missing or disconnected from the connection was a problem that can not be measured and the safety is seriously concerned.

In order to solve the above problems, an object of the present invention is to provide a live state detection device configured to be supplied with power through a sensor driven by being supplied with power while being directly connected to each high voltage line.

In addition, by using a reader that communicates wirelessly with a conventional radio identification tag to recognize the voltage in the live state of the high-voltage line to provide a live state detection device that can prevent the safety accidents that occur when approaching the high-voltage line The purpose.

In addition, an object of the present invention is to provide a live state detection device that is driven in a manner that does not require a separate power battery for driving a wireless identification tag.

In addition, the live line detection device displays a warning message in all directions through a light emitting diode emitting light at a predetermined period, and provides a live line detection device configured to easily detect a state of a high voltage line at any position. do.

In order to achieve the above object, the present invention is a device for detecting the live state of the high voltage line of each phase of the switchboard, each of the high-voltage line of each phase is equipped with a ring portion is supplied with power to detect the live voltage to detect the built-in wireless identification A rectifier circuit part connected to the high voltage line and one line directly connected to the high voltage line and having a built-in ring sensor and the other line connected to the power supply so as to record data in a tag; And a dip switch unit configured to sense a high voltage output through the high voltage detection unit for inputting data into the wireless identification tag, and to set a voltage level that drops according to the magnitude of the high voltage output through the rectifier circuit unit. The diac is charged by applying the voltage output from the position portion, and the voltage charged in the diac is discharged to turn A thyristor, a light emitting diode that emits light while the thyristor is turned on, and a voltage output through the dip switch unit is applied, and a voltage regulator while maintaining the voltage output through the dip switch unit as a constant voltage through the zener diode as the thyristor is turned on A live voltage detection device including a micro power supply unit amplifying a predetermined voltage through a circuit and inputting the same to the radio identification tag; And
A transmitter for transmitting a frame pulse signal to the radio identification tag to detect the live state of each high voltage line by receiving data while performing wireless communication while supplying power to the radio identification tag of the live voltage detection device; A data receiver for receiving a frame pulse signal including high voltage data transmitted from a tag as a response signal, a data analyzer for analyzing the live state and high voltage value of each high voltage line by analyzing the response signal received from the data receiver; And a wireless identification reader including a driving unit for outputting a transmission signal to monitor the data analyzed by the data analyzing unit from the outside. To present.
The live voltage detection device may include a vision unit having a polygonal shape in front of the light emitting diode so as to scatter light emitted from the light emitting diode in all directions.
The wireless identification tag accumulates power output from the micro power supply unit to extend a transmission output distance of a transmission signal, and uses the frame pulse signal transmitted from the wireless identification reader to detect data of the wireless identification tag as energy. Energy conversion unit for switching; A data storage unit for inputting and storing high voltage data sensed by the high pressure detecting unit; And a high frequency transmission / reception unit configured to receive the frame pulse signal transmitted from the wireless identification reader and to transmit a frame pulse signal including the high voltage data to the wireless identification reader as a response signal.
The energy conversion unit of the wireless identification tag of each phase sequentially receives a 3-frame pulse signal of a 5 second period transmitted from the wireless identification reader, converts it into energy, and simultaneously supplies power accumulated and supplied from each micro power supply unit for 1 second. While using as a cycle, it may be configured to sequentially transmit the response signal for 1-frame in the high frequency transmission and reception unit when the power supplied and accumulated in the fine power unit is used.

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The following effects can be achieved by an apparatus for detecting a live state of a high-voltage line by a wireless communication method according to the present invention.

First, the microcurrent generated by the ring sensor built in the live voltage detection device according to the present invention can be easily driven even without a separate battery by supplying power even if only the loop portion of the live voltage detection device is mounted on a high voltage line. It works.

Secondly, the present invention has the effect that it can be easily mounted on a high-voltage line even without expensive equipment such as a separate voltage cable or a high-voltage capacitor required in the conventional method.

Third, according to the present invention, the apparatus for detecting the live state of a high-voltage line by a wireless communication method is applied with a constant voltage through a fine power supply unit without a separate power source such as a battery for driving a wireless identification tag, thereby enhancing the output power. The wireless identification reader and the transmission distance can be increased.

Fourth, by transmitting the data stored in the wireless identification tag to the wireless identification reader mounted on the switchboard panel by the wireless communication method to detect the live state of the high voltage line by wireless communication method, Real time voltage size can be recognized.

Fifth, the light emitting diode of the live voltage detection device according to the present invention has the effect of visually recognizing the state of the high-voltage line by causing the light to flash at regular intervals by the charging time, RC time constant, and thyristor of the diac.

Sixth, the vision unit coupled to the light emitting diode of the live voltage detection apparatus according to the present invention scatters the light emitted from the light emitting diodes in all directions, thereby enabling people located at various angles to recognize the live state of the high voltage line. .

Hereinafter, an apparatus for detecting a live state of a high voltage line by a wireless communication method according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a mounting configuration of a live voltage detection device for detecting a high voltage in a high voltage line according to the present invention, referring to the bar shown in the high voltage line of each phase to detect the live state of each phase of the high voltage line (R, S , T) is equipped with a ring portion 110 of the live-voltage detection device 100. The live voltage detection device 100 is configured with a radio identification tag 150 for storing the live data of the high voltage line of each phase.

The wireless identification tag 150 configured in the live voltage detection device 100 for each high voltage line has data such as the live state of the high voltage line of each phase while performing wireless communication with the wireless identification reader 200 attached to the switchboard panel. Will be sent.

3 is a cross-sectional view of the live voltage detection device according to the present invention, Figure 4 is a configuration diagram of the live voltage detection device according to the present invention, referring to the live voltage detection device 100 is a high-voltage line of each phase The ring unit 110 is mounted on the ring 110 to detect the live voltage and store data in the embedded wireless identification tag 150.

In order to supply power to the PCB 130 of the live voltage detection device, the current flows while +/- is present only when two wire lines are connected to the rectifying circuit unit 131. Referring to FIG. When the power is supplied from the high voltage line of the live voltage detection device 100, one line of the rectifier circuit 131 is connected to the ring portion 110 directly connected to the high voltage line, and the other line is a ring sensor 120. ).

The ring sensor 120 is made of copper as a flat ring sensor, and is composed of 3mm × 0.6t, 30 pi in diameter, and detects live voltage through inter-ground capacitance generated near the high-voltage line through the ring sensor 120. Energy is induced in the device 100.
In other words, a small current is induced and flows into the rectifier circuit unit 131 of the live voltage detection device 100.
In more detail, an electric field is generated between the ring sensor 120 and the earth through the inter-ground capacitance generated near the high-voltage line, that is, the ring sensor 120 and the earth, which function as electrodes, are directly connected to the conductor. Since the entire circuit power supply line is connected to the ground without being connected, the live circuit voltage detector 100 has a closed circuit to generate a small current.

In other words, as the ring sensor 120 serving as a circular antenna near the high-voltage line is used as one detection electrode in the rectifier circuit unit 131, a small voltage is induced to configure a microcurrent to be generated in the rectifier circuit unit 131. Will be.

After all, in the case of the present invention, when the ring 110 is mounted on the high voltage line only by the ring sensor 120 built in the live voltage detection device, the current flows in the rectifier circuit 131 so that the current flows separately. There is no need for a ground (GND) connection cable.
Therefore, referring to FIG. 1 mentioned above, the problem of the live voltage detection method of the high voltage line according to the related art according to the related art will be described in detail. One line of the high voltage detecting unit to which the voltage is applied has a sufficient insulation distance from the high voltage line. It is equipped with a high voltage capacitor to divide the voltage and lowers the voltage to low voltage. The other line is connected to the ground. However, the conventional method does not connect the high pressure sensing unit directly to the high voltage line but must install the high pressure sensing unit while securing the insulation distance through the high voltage capacitor. Therefore, the high pressure capacitor installed is not only expensive but also high voltage in the high voltage line. The cable to the capacitor and the line to the high-pressure sensing unit from the high-voltage capacitor, respectively, and the cable that connects the rectifier circuit and the ground as shown separately is required separately, the equipment is not easy and expensive requires a problem of the present invention It has an effect that can be solved by the live voltage detection device with a ring sensor.
That is, the rectifier circuit unit 131 is driven by using the micro induction current generated by the inter-ground capacitance generated by the ring sensor near the high-voltage line, so it can be easily driven without a separate driving battery. have.

The high voltage detecting unit 132 illustrated detects the high voltage output through the rectifying circuit unit and inputs high voltage (HV) data to the wireless identification tag 150, and the dip switch unit 133 is the rectifying circuit unit 131. It sets the voltage level dropping according to the magnitude of the high voltage of the high voltage line of each phase.

Through the dip switch unit 133, for example, by dividing the high voltage level into four levels, such as 3,300V ~ 6,600V, 6,600V ~ 22,900V, 22,900V ~ 154,000V, 154,000V ~ 354,000V, The lower voltage, such as 3,300V ~ 6,600V, is set to increase the capacitor capacity and resistance value in the dip switch. On the contrary, the higher voltage, such as 154,000V ~ 354,000V, is set to reduce the capacitor capacity and resistance value in the dip switch.

Since the magnitude of the current induced through the ring sensor is actually a microamp unit, the energy actually induced is too small, ranging from 2 to several tens of PF. In addition, since the high brightness light emitting diode 140 is turned on when the voltage is 1.4 V or more and 0.5 mA or more, the current is increased through the dip switch unit 133 to fill the energy, and a high voltage is applied to the circuit. In order to prevent damage, the voltage is lowered to protect the devices such as the thyristor 135 from being damaged.

Hereinafter, a method of emitting light of the high luminance light emitting diode according to the present invention will be described.

The voltage output from the dip switch unit 133 is applied to the diac 134 and charged. The diac 134 has a charging capacity of 30 V, and the voltage output through the dip switch unit 133 is turned on as the thyristor 135 is turned on while the voltage charged in the dia a 134 is discharged. Is applied to 140.

That is, the charging time of the diaak 134 becomes a turn-on period of the thyristor 135, which is about 2 to 5 seconds, and the discharge time of the diaak 134, that is, the time when the thyristor 135 is turned on is a resistance. Due to the RC time constant part 136 by R and the condenser C, a pulse signal of a predetermined period is generated while being set to about 0.5 second. Therefore, the width of the light emitting diode 140 may be set to 0.5 second by the RC time constant part 136. Can be, the flashing cycle is 2 to 5 seconds.

Therefore, the high-brightness LED blinks at a certain period, thereby visually informing the live warning message to those approaching the high-voltage line.

The illustrated micro power supply unit 137 maintains the voltage regulator circuit 137b while maintaining the voltage output through the dip switch unit 133 at a constant voltage of 3.5V through the zener diode 137A while the thyristor 135 is turned on. By amplifying the fine current through the wireless identification tag 150 inputs a small voltage 3.5V.

As shown in FIG. 3, the live voltage detection device includes a vision unit having a polygonal shape on a front surface of the light emitting diode so as to scatter light emitted from the light emitting diode in all directions.

The vision unit 160 may be configured to be coupled to the front of the live voltage detection device, and is configured to scatter light in a prism manner with a multi-faceted diamond type of transparent crystal.

In other words, the light emitted from the light emitting diode 140 is refracted by the multi-sided scattering prism method by the vision unit 160 having a polygonal surface that is prismized by diamond cutting, thereby scattering the light not only in the straight direction but also in the lateral direction. Whether the light emitting diode 140 is turned on can be easily checked from the front side as well as from the side of the live voltage detection device.

Therefore, when the light emitting diodes 140 periodically emit light at a predetermined period in the live state of the high voltage line of each phase, the vision unit 160 of the present invention has a straight direction in which the light emitting diodes 140 of the live voltage detection device emit light. In addition, it is possible to easily check the liveliness in each position of the people working on the side to promote safety.

5 is a configuration diagram of a wireless communication between a wireless identification tag and a wireless identification reader period of the live voltage detection device according to the present invention.

The energy conversion unit 152 of the wireless identification tag 150 receives a voltage of 3.5V detected by the micro power supply unit 137 and a signal transmitted from the wireless identification reader 200 to convert the transmission output voltage from the energy converted. It is authorized.

In general, the recognizable transmission output distance between the conventional universal wireless identification tag 150 and the wireless identification reader 200 is a very short distance of about 10 cm, and in the case of the present invention, a live voltage detection device and a distribution board mounted on a high-voltage line are practically present. Since the transmission distance of at least 5m should be secured during the wireless identification reader period mounted on the panel, the conventional universal wireless communication equipment cannot be used.

FIG. 6A is a state diagram illustrating a state in which the microvoltage of the micropower unit according to the present invention is input to the energy conversion unit of the radio identification tag. Referring to FIG. 6A, a transmission to the energy conversion unit 152 of the radio identification tag 150 is performed. The fine power output from the fine power supply unit 137 is accumulated to extend the transmission output distance of the signal, and the accumulated energy is transmitted by the wireless identification reader 200 to detect data of the wireless identification tag 150. It is configured to increase the transmission power while being combined with the energy converted in the signal to be longer the transmission distance. In this case, it is preferable to use the 900 MHz band for the transmission and reception frequency band.

As a result, even if there is no battery for supplying a separate power to the wireless identification tag 150, the transmission distance can be sufficiently secured.

The high pressure detected by the high pressure detecting unit 132, for example, 22,900 V, is input to the wireless identification tag 150 and stored as data in the data storage unit 154.

In addition, the signal transmitted from the radio identification reader 200 to the radio identification tag 150 is received through the high frequency transmission and reception unit 156, the radio identification tag 150 is again a data storage unit through the high frequency transmission and reception unit 156. A response signal including the high voltage data of 154 is output.

The wireless identification reader 200 receives a signal from a transmitter 210 for transmitting a signal to the wireless identification tag 150, a data receiver 220 for receiving a response signal from the wireless identification tag 150, and a wireless identification tag 150. The data analysis unit 230 and the data analysis unit for analyzing the live state and high voltage value of the high-voltage line of each phase, such as the presence of voltage, the type of voltage, and the like by receiving the received response signal and the contents stored in the already stored data. It is configured to include a driver 250 for outputting a transmission signal to monitor the data analyzed through the 230 from the outside.

Therefore, it is possible to recognize the live state of the high-voltage line of each phase from the external monitor through the drive unit, it is possible to recognize the voltage of the high-voltage line in real time.

In addition, the wireless identification reader 200 further includes a transmission / reception time controller 240 that controls transmission / reception time of the transmitter 210 and the data receiver 220.

Hereinafter, a wireless communication method between the wireless identification tag and the wireless identification reader according to the present invention will be described in detail.

6B is a state diagram illustrating a wireless communication method of a wireless identification tag and a wireless identification reader period mounted on a switchboard panel of the live voltage detection apparatus according to the present invention.

5 and 6B, the transmitter 210 of the wireless identification reader 200 transmits and receives a signal to read data of each wireless identification tag 150 of the live voltage detection device 100 mounted on the high voltage line of each phase. Controlled by the time control unit 240 is configured to send a transmission output 3 frame (FRAME) pulse signal every 5 seconds.

At this time, each radio identification tag 150 of each phase sequentially receives a three-frame (FRAME) pulse signal and converts it into energy while using the power supplied from each micro power supply unit 137 accumulated in one second period while the high voltage One frame pulse signal including data is transmitted as a response signal, which is sequentially received by the data receiver 220 of the wireless identification reader 200.

In more detail, each of the energy conversion unit 152 of the wireless identification tag 100 for each high-voltage line sequentially sequential frame pulse signal of the 5 second period transmitted from the wireless identification reader 200 for three frames The high frequency transceiver 156 is used when the power supplied and accumulated by the micro power unit 137 is used, while receiving and converting the energy into energy and using the power supplied and accumulated by each micro power unit 137 at a one-second cycle. Are sequentially transmitted for 1-frame.

As shown in FIG. 6B, when a 3-frame pulse signal is received from the wireless identification reader 200, the wireless identification tag 150 embedded in the live voltage detection device 100 mounted on each phase is the frame pulse signal. 1 frame pulse including high voltage data as a response signal indicating a live state in each high frequency transmitter / receiver 156 in a state where the voltage detected and accumulated by the microdetector 137 is discharged at a one second cycle while receiving and converting the energy into energy. It will output as a signal.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art will be able to make various modifications, changes and additions within the spirit and scope of the present invention. Additions should be considered to be within the scope of the following claims.

1 is a block diagram showing a live voltage detection method of a high voltage line according to the prior art.

2 is a configuration diagram of a live voltage detection device for detecting a high voltage in a high voltage line according to the present invention.

3 is a cross-sectional view of the live-voltage detection device according to the present invention.

4 is a configuration diagram of a live voltage detection apparatus according to the present invention.

5 is a configuration diagram of a wireless communication between a wireless identification tag and a wireless identification reader period of the live voltage detection device according to the present invention.

6A is a state diagram illustrating a state in which the microvoltage of the micropower unit according to the present invention is input to the energy conversion unit of the radio identification tag.

6B is a state diagram illustrating a wireless communication method of a wireless identification tag and a wireless identification reader period mounted on a switchboard panel of the live voltage detection apparatus according to the present invention.

* Description of Symbols for Major Parts of Drawings *

100: live voltage detection device 110: ring portion

120: ring sensor 130: PCB

131: rectifier circuit unit 132: high pressure detection unit

133: dip switch unit 134: diamond

135: thyristor 136: RC time constant

137: fine power unit 137a: zener diode

137b: voltage regulator circuit 140: light emitting diode

150: radio identification tag 152: energy conversion unit

154: data storage unit 156: high frequency transmission and reception unit

160: Vision Division

200: wireless identification reader 210: transmitter

220: data receiver 230: data analyzer

240: transmission and reception time control unit 250: driving unit

Claims (6)

In the apparatus for detecting the live state of the high-voltage line of each phase of the switchboard, Each ring is mounted on the high voltage line of each phase to be supplied with power to detect live voltage and write data to a built-in wireless identification tag. A rectifier circuit unit connected to one line directly connected to the high voltage line and the ring portion and positioned near the high voltage line, and connected to one of the built-in ring sensors and the other line to receive power; A high pressure detecting unit detecting data of a high voltage output through the rectifying circuit unit and inputting data to the wireless identification tag; A dip switch unit configured to set a voltage level dropped according to the magnitude of the high voltage output through the rectifier circuit unit; A diak charged with a voltage output from the dip switch unit; A thyristor that is turned on while the voltage charged in the diaak is discharged; A light emitting diode which emits light while the thyristor is turned on and is applied with a voltage output through the dip switch unit; A live voltage detection device including a micro power supply unit amplifying a predetermined voltage through a voltage regulator circuit while inputting the wireless identification tag while maintaining the voltage output through the dip switch unit while the thyristor is turned on; And In order to detect the live state of each high voltage line by receiving data while performing wireless communication while supplying power to the wireless identification tag of the live voltage detection device, A transmitter for transmitting a frame pulse signal to the radio identification tag; A data receiver which receives a frame pulse signal including high voltage data transmitted from the radio identification tag as a response signal; A data analyzing unit analyzing the live state and high voltage value of each high voltage line by analyzing the response signal received from the data receiving unit; And a wireless identification reader including a driving unit for outputting a transmission signal to monitor the data analyzed by the data analysis unit from the outside. The method of claim 1, The live voltage detection device may detect a live state of a high voltage line by a wireless communication method, comprising: a vision unit having a polygonal shape on a front surface of the light emitting diode so as to scatter light emitted from the light emitting diode in all directions. Device. The method of claim 1, The wireless identification tag accumulates power output from the micro power supply unit to extend a transmission output distance of a transmission signal, and uses the frame pulse signal transmitted from the wireless identification reader to detect data of the wireless identification tag as energy. Energy conversion unit for switching; A data storage unit for inputting and storing high voltage data sensed by the high pressure detecting unit; And And a high frequency transmission / reception unit for receiving the frame pulse signal transmitted from the radio identification reader and transmitting the frame pulse signal including the high voltage data to the radio identification reader as a response signal. Device for detecting live state of high voltage line. The method of claim 3, The energy conversion unit of the wireless identification tag of each phase sequentially receives a 3-frame pulse signal of a 5 second period transmitted from the wireless identification reader, converts it into energy, and simultaneously supplies power accumulated and supplied from each micro power supply unit for 1 second. While using it as a cycle, And a high frequency line in a wireless communication system, characterized in that the high frequency transmission / reception unit sequentially transmits a response signal for 1-frame when the power supplied and accumulated by the micro power unit is used. delete delete

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