KR20120059892A - Apparrutus and method to inspect obstruction light for flight, and system using thereof - Google Patents

Abstract

PURPOSE: An apparatus and a method for inspecting an obstruction light for a flight and a system using the same are provided to determine a fail of an obstruction light by directly monitoring a light source of the obstruction light. CONSTITUTION: An apparatus for inspecting an obstruction light for a flight comprises a lamp monitoring part(210) and a voltage/temperature measuring part(220). The lamp monitoring part is installed adjacent to an obstruction light for a flight and determines a fail of an obstruction light for a flight by comparing a measured flickering number with a reference flickering number per unit time. The lamp monitoring part monitors off of the obstruction light in operation. The voltage/temperature measuring part measures the voltage and temperature of a power supply source supplying power to the obstruction light, where the power supply source includes a solar panel, a charger, and a battery.

Description

Apparatus and method for inspecting aviation faults, and aviation fault inspection system using the same {APPARRUTUS AND METHOD TO INSPECT OBSTRUCTION LIGHT FOR FLIGHT, AND SYSTEM USING THEREOF}

The present invention relates to a aviation failure light inspection device and a aviation failure light inspection system and method using the same, and specifically monitors the aviation failure lights directly, by measuring the voltage and temperature of the power supply of the aviation failure lights, etc. An apparatus and system for determining the goodness of a supply.

Tall buildings, bridges, chimneys, pylons and tall structures, transmission towers and overhead lines in urban areas are equipped with aviation obstructions that flash red or white flashes. This is to prevent the accident by indicating the location of obstacles that may interfere with the flight of the aircraft or helicopter at night low light conditions. According to the aviation law, high-rise buildings, steel towers, and transmission towers are required to install aviation obstacle indicators that indicate the location of obstacles to pilots in flight to prevent accidents. Structures, transmission towers, and overhead ships are equipped with aviation obstacles that indicate the location of obstacles to aircraft or helicopter pilots.

However, due to the large number of transmission towers or overhead lines for aerial lines, they are difficult to inspect and troubleshoot, especially when they are installed on rugged terrain. There is this. Accordingly, there has been a need for a system that can remotely check for aviation disturbances.

In addition, there is a problem that the existing system needs to be reinstalled in order to convert the already installed aviation failure system into a remote system. In addition, when a separate circuit is implemented to detect faults such as aviation faults, there is a problem in that faults cannot be checked when a fault occurs in the circuit itself.

In order to solve the above problems, it is an object of the present invention to provide a device and system that can directly check the light source, such as aviation failures to check the aviation failures. In addition, the present invention has another object to enable to check the aviation failures remotely through the aviation failure inspection device and system, and to create an environment that can check the aviation failures without implementing a separate circuit, the inspection system Another goal is to make it easy to take action in case something goes wrong. In addition, by establishing a device that can use the existing aviation failure lights system, there is another object to provide a aviation failure lights inspection device and system without replacing the existing aviation failure lights and aviation failure lights system.

The first invention of the present application for solving the above problems, aviation failure light inspection device, the light source monitoring unit for monitoring the emission of aviation failure lights; A flashing frequency measuring unit measuring a flashing frequency of the aviation obstacle during a predetermined time based on a monitoring signal of the light source monitoring unit; A fault determination unit for comparing the number of blinks of the aviation fault and the like with the number of blinks per unit time when the aviation faults operate normally; A communication module for transmitting a determination result on whether the failure; And a power supply unit supplying power to operate each functional unit.

The second invention of the present application for solving the above problems, the aviation failure light inspection system is installed on the top of the aviation obstacle flash flight driven; Lamp monitoring unit for measuring the number of flashes, such as the aviation failure for a predetermined time; And a management server that detects whether or not the air fault is broken based on the number of blinks of the air fault.

The third invention of the present application for solving the above problems, the aviation failure light checking method comprises the steps of determining whether the aviation failure lights control unit aviation failure lights; Operating the lamp monitoring unit by the operation control unit; A light source monitoring unit monitoring light emission of the aviation obstacle lamp; Measuring the number of blinks of the aviation obstacle for a predetermined time based on the number of blinks measuring unit based on the signal detected by the lamp monitoring unit; Transmitting a flashing number of times such as an air traffic fault to a management server; And determining, by the management server, whether a failure of an aviation failure or the like is based on the received data.

According to the present invention according to the above configuration, by providing a system that can remotely check the aviation failure, the administrator can easily check the aviation failure scattered on the mountain wallpaper. In addition, by directly monitoring the light source, such as aviation failures to determine whether there is a failure, it is possible to check the aviation failures without the implementation of a complex failure inspection circuit. In other words, when a problem occurs in the failure checking system, the number of blinks, such as an aviation failure, is not received, so that the problem of the failure checking system can be diagnosed without the addition of a separate function unit. In addition, the present invention can fully utilize the existing aviation failure system, it is possible to minimize the waste of goods in the construction of a remote inspection system, such as aviation failure.

1 is a block diagram of a general aviation failure system,
2 is a block diagram of a device for checking a aviation failure according to an embodiment of the present invention,
3 is a detailed configuration diagram of a lamp monitoring unit according to an embodiment of the present invention;
4 is a detailed configuration diagram of a voltage / temperature measurement unit according to an embodiment of the present invention;
5 is a aviation failure inspection system using a aviation failure inspection apparatus according to an embodiment of the present invention,
6 is a flow chart of a method for checking aeronautical disturbances and the like according to an embodiment of the present invention, and
7 is a flow chart of a method for checking a fault in the air according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components, and the same reference numerals will be used to designate the same or similar components. Detailed descriptions of known functions and configurations are omitted.

1 is a block diagram of a general aviation failure light system. According to Figure 1, the aviation failure light system is composed of aviation failure light 100, and aviation failure light control device 110. Aviation obstacle lamp 100 may be divided into a flashing light and a floating light according to the type, the flashing light means an aviation failure light that blinks at a predetermined time interval and the floating light means an aviation failure light that is continuously turned on during operation. Aviation obstacle light 100 operates according to the control signal of the aircraft failure light control device 110, and blinks or lights continuously for a predetermined time period, it can be informed that the obstacle is adjacent to the flight during the night flight. Aviation failure light control device 110 includes a power supply (not shown) for supplying power to the aircraft failure light 100, the operation of the aircraft failure lights such that the aircraft failure lights 100 to operate after sunset. To control.

When the aviation obstacle lamp 100 is installed in the transmission tower, it is generally 60 meters or more away from the ground, it is difficult to install the aviation obstacle lamp control device 110 together with the aviation obstacle lamp. Therefore, the aviation failure lamp 100 is located at the top of the transmission tower, the aviation failure lamp control device 110 is generally installed in the lower portion of the transmission tower so that the administrator can easily check.

2 is a block diagram of a device for checking a aviation failure according to an embodiment of the present invention. According to FIG. 2, the aviation failure inspection apparatus includes a lamp monitoring unit 210 and a voltage / temperature measuring unit 220.

When the aviation failure light 100 is a flashing light, the lamp monitoring unit 210 is installed adjacent to the aviation failure light 100 to monitor the emission of the aviation failure light 100, based on the aviation failure light for a predetermined time. Measure the number of flashes of (100). The lamp monitoring unit 210 determines whether the aviation failure lamp 100 is broken by comparing the blinking frequency measurement result with a reference blinking frequency per unit time when the aviation failure lamp 100 operates normally.

In the case of the aviation failure light 100, the lamp monitoring unit 210 monitors whether the aviation failure light 100 is turned off during operation, and determines whether the aviation failure light 100 is turned off within the operating time range of the aviation failure light 100. It is determined whether the back (100) is broken.

The voltage / temperature measuring unit 220 measures the voltage and temperature of the power supply source for supplying power to the aviation failure lamp 100 so that the aviation failure lamp 100 can operate. In general, the power supply source included in the aviation failure control device 110 is composed of a solar panel, a charging unit and a battery. During the day, the solar panel absorbs sunlight, and the voltage applied from the solar panel is charged by the battery after the voltage is adjusted in the charging unit. After sunset, the voltage charged in the battery is discharged and the aviation obstacle lamp 100 operates. At this time, the voltage / temperature measuring unit 220 measures the charging voltage of the solar panel to calculate the normal charging days of the solar panel. The manager can determine the health of the solar panels whether the solar panel is good or bad. In addition, the voltage / temperature measuring unit 220 measures the discharge voltage of the battery, thereby determining the battery life and the discharge capacity of the battery. The voltage / temperature measuring unit 220 measures the internal / external temperature of the power supply source to determine the normal charge / discharge of the battery.

By installing the lamp monitoring unit 210 adjacent to the aviation failure lamp 100, there is an advantage that can be used as it is without replacing or modifying the existing aviation failure lamp system. The voltage / temperature measurement unit 220 is preferably installed included in the aviation failure control device 110. At this time, the lamp monitoring unit 210 and the voltage / temperature measuring unit 220 may be connected to each other by a wired or wireless connection. When the lamp monitoring unit 210 and the voltage / temperature measuring unit 220 communicates wirelessly, Zigbee or Bluetooth communication may be used for efficient use of power. However, this does not exclude that the lamp monitoring unit 210 and the voltage / temperature measuring unit 220 are included in the inspection apparatus 200 and are integrally implemented. That is, the lamp monitoring unit 210 and the voltage / temperature measuring unit 220 may be included in the inspection apparatus 200 to be integrally implemented.

3 is a detailed configuration diagram of a lamp monitoring unit according to an embodiment of the present invention.

According to FIG. 3, the lamp monitor includes a light source monitor 310, a blinking number measuring unit 320, a reference number setting unit 330, a fault determining unit 340, a first communication module 350, and a power supply unit 360. And an operation control unit 370.

The light source monitoring unit 310 may monitor light emission of the aviation obstacle lamp 100. In order for the light source monitoring unit 310 to effectively monitor the emission of the aviation obstacle lamp 100, the light source monitoring unit 310 is preferably located near the aviation obstacle lamp 100. The light source monitoring unit 310 may be an optical sensor, and may be, for example, any one of a Cds, a photodiode, a phototransistor, and a photoyristor.

The blinking frequency measuring unit 320 measures the blinking frequency of the aviation obstacle lamp 100 for a predetermined time from the monitoring signal of the light source monitoring unit 310. Since the characteristics of the light source monitoring unit 310 are drastically changed depending on whether the aviation obstacle lamp 100 emits light, the number of blinking times may be measured using the characteristic change of the light source monitoring unit 310. For example, it is possible to measure the number of flashes by using a rapid change in the current flowing through the light source monitoring unit 310.

The reference frequency setting unit 330 sets the number of flashes per unit time when the aviation obstacle lamp 100 operates in a normal state. In the case of the general aviation failure lamp 100, the frequency of flickering 60 times per minute, the number of flashes per unit time can be set to 1 Hz. If the number of flashes per unit time is not 1Hz, the administrator can directly input the number of flashes per unit time, or by utilizing a database of the number of flashes per unit time by the specifications of the aviation failure, such as 100, can utilize the number of flashes per unit time.

The failure determining unit 340 compares the number of flashes of the aviation fault lamp 100 measured for the predetermined time by the blinking frequency measuring unit 320 with the number of flashes per unit time of the reference number setting unit 330, such as the aviation fault lamp (100). ) Check if there is any malfunction. If the difference between the number of blinks of the aviation fault lamp 100 and the number of blinks per unit time is within the error range, it is determined that the state of the aviation fault lamp 100 is good, and if it is out of the error range, the aviation fault lamp 100 is determined to be broken. .

When the aviation failure light 100 is continuously turned on during the operation time without blinking, the failure of the aviation failure light 100 may be determined without the blinking frequency measuring unit 320 and the reference frequency setting unit 330. . The light source monitoring unit 310 monitors whether the aviation failure lamp 100 emits light, and the failure determination unit 340 detects a failure of the aviation failure lamp 100 by detecting a characteristic change of the light source monitoring unit 310. can do. For example, when the aviation failure light 100 is turned off before sunrise, the characteristics of the optical sensor that can be used as the light source monitoring unit 310 are changed, and the failure determination unit 340 detects the characteristic change of the optical sensor, such as aviation failure. The failure can be determined.

The first communication module 350 is for communicating with the voltage / temperature measuring unit or the upper server, whether the aviation fault lamp 100 is broken, whether the aviation fault lamp 100 is turned off, and the aviation fault lamp 100 blinks. Etc. are transmitted to the mobile terminal of the voltage / temperature measuring unit 220, the upper server or the manager. Through the first communication module 350, the administrator can remotely input the number of flashes per unit time to the reference number setting unit 330. In general, the first communication module 350 may use a wired communication method or a wireless communication method.

The power supply unit 360 supplies power to each part so that the lamp monitoring unit 210 can operate. The power supply unit 360 includes a solar panel 361, a charging unit 362, a battery 363, an overcharge detector 364, and an overdischarge detector 365.

During the day, the solar panel 361 absorbs sunlight, and the voltage applied from the solar panel 361 is charged by the battery 363 after the voltage is adjusted in the charging unit 362. At this time, in the charging process, the overcharge detection unit 364 detects overcharge of the battery 363 and prevents the battery 363 from being overcharged. The lamp control unit 210 operates by discharging the voltage charged in the battery 363 at night. At this time, the overdischarge detection unit 365 detects overdischarge of the battery 363 and prevents the battery 363 from overdischarging.

In order to prevent the lamp monitoring unit 210 from discharging the power supply unit 360 during the day, it is preferable that the lamp monitoring unit 210 operates after sunset or after the aviation failure lamp 100 operates to monitor the aviation failure lamp 100.

According to an embodiment of the present invention, the operation controller 370 sets the reference voltage value and compares the reference voltage value with the voltage of the solar panel 361, so that the lamp monitor 210 can operate after sunset. do. For example, when the reference voltage value is set and the voltage of the solar panel 361 is lower than the reference voltage value, the battery 363 may be discharged to allow the lamp monitoring unit 210 to operate. The lower the brightness of the solar panel 361 is, the less the amount of light is collected, so that a sufficient voltage cannot be output. Therefore, sufficient light cannot be obtained after sunset, and thus the output voltage is reduced. By using this, when the voltage of the solar panel 361 falls below a predetermined reference voltage, it is determined that the sunset and the lamp monitor 210 is operated.

According to another embodiment of the present invention, the operation controller 370 may operate the lamp monitor 210 by recognizing a sudden change in the light source monitor 310. For example, since the ambient brightness value does not change rapidly during the day or at night, the current value flowing through the light source monitoring unit 310 is almost unchanged for a short time, while the aviation failure lamp 100 operates by blinking. During the short time, the amount of light monitored by the light source monitoring unit 310 changes rapidly, and the current value flowing through the light source monitoring unit 310 changes repeatedly for a short time. The operation control unit 370 may monitor the change in the current value of the light source monitoring unit 310 to be repeated a predetermined number of times or more, thereby recognizing the operation of the aviation obstacle lamp 100 and operating the lamp monitoring unit 210.

4 is a detailed configuration diagram of a voltage / temperature measurement unit according to an embodiment of the present invention.

Referring to FIG. 4, the voltage / temperature measuring unit 220 includes a voltage measuring unit 410, a temperature measuring unit 420, a central processing unit 430, a second communication module 440, and a voltage / temperature measuring unit 220. And a power supply unit 450 for supplying power to operate the aviation fault lamp 100 and an aviation fault control unit 460 for adjusting the operation time of the aviation fault lamp so that the aviation fault light can operate after sunset. .

The voltage measuring unit 410 measures the output voltage of the solar panel 451 of the power supply unit for supplying power to the aviation failure lamp 100, and the battery 453 is charged through a voltage applied from the solar panel 451. Measure the charge and discharge voltages of

The temperature measuring unit 420 measures the temperature inside and outside the voltage / temperature measuring unit 220. The internal temperature of the voltage / temperature measuring unit 220 refers to the internal temperature of the enclosure in which the battery 453 is stored.

The central processing unit 430 measures the voltage / temperature measurement value, the measurement time, and the number of flashes of the aviation failure lamp 100 received by the second communication module 440 from the voltage measuring unit 410 and the temperature measuring unit 420. The data is processed to be transmitted to the management server through the second communication module 440, and the data is transmitted to the management server through the second communication module 440.

The second communication module 440 transmits data regarding a voltage / temperature measurement value, a measurement time point, and a flickering frequency of the aviation failure lamp 100 to the management server. The second communication module 440 may use wireless communication or wired communication, and when using wireless communication, any one of WI-FI, Wibro, D-TRS, WiMax, LTE, HSDPA, WLAN, (Binary) CDMA, and UWB In case of using wired communication, it may be one of OPGW optical communication, optical communication, ADSL, cable modem, and xDSL. Alternatively, one or more of the communication methods listed above may be used.

The power supply unit 450 serves to supply power to operate the voltage / temperature measuring unit 220 and the aviation obstacle lamp 100. The power supply unit 450 includes a solar panel 451, a charging unit 452, a battery 453, an overcharge detection unit 454, and an over discharge detection unit 455.

During the day, the solar panel 451 absorbs sunlight, and the voltage applied from the solar panel 451 is charged by the battery 453 after the voltage is adjusted in the charging unit 452. At this time, in the charging process, the overcharge detection unit 454 detects overcharge of the battery 453 and prevents the battery 453 from being overcharged. The light source supervisory value is operated by discharging the voltage charged in the battery 453 at night. At this time, the overdischarge detection unit 455 detects overdischarge of the battery 453 and prevents the battery 453 from overdischarging.

The aviation fault lamp control unit 460 sets the reference voltage value and compares the reference voltage value with the voltage of the solar panel 451, so that the aviation fault lamp 100 can operate after sunset. For example, when the reference voltage value is set and the voltage of the solar panel 451 is lower than the reference voltage value, the battery 453 may be discharged so that the aviation failure lamp 100 may operate. The lower the brightness of the solar panel 451, the smaller the amount of light collected, the insufficient voltage is not output, and thus, after sunset, sufficient light cannot be secured so that the output voltage decreases. By using this, when the voltage of the solar panel 451 falls below a predetermined reference voltage, it is determined that sunset and the aviation failure lamp 100 is operated. When the aviation failure lamp 100 operates, the aviation failure lamp control unit 460 may transmit a control signal to the lamp monitoring unit 210 through the second communication module 440 to operate the lamp monitoring unit 210. .

That is, the operation controller 370 may receive a control signal from the aviation failure light controller 460 and operate the lamp monitor 210 based on the control signal. For example, the aviation failure light control unit 460 operates the aviation failure light 100 after sunset, and transmits a control signal to the operation control unit 370 when the aviation failure light 100 is operated. The operation control unit 370 receiving the control signal may operate the lamp monitoring unit 210 based on this.

FIG. 5 is a diagram illustrating a system for checking a traffic light by using a system for checking a traffic light according to an embodiment of the present invention. Referring to FIG. 5, the aviation failure light inspection system using the aviation failure light inspection device includes a lamp monitoring unit 510 for measuring the number of flashes of the aviation failure light 100 and the voltage of the voltage supply source of the aviation failure light 100. Receives the number of flashes of the voltage / temperature measuring unit 520 and the aviation fault lamp 100 to measure the temperature and voltage and temperature information of the voltage supply source, and whether the aviation fault lamp 100 is broken based on the received data. The management server 530 to determine.

The lamp monitoring unit 510 measures the number of blinks of the aviation fault lamp 100 adjacent to the aviation fault lamp 100, and transmits the measured number of blinks to the management server 530 or the voltage / temperature measuring unit 520. do. The blinking frequency of the aviation failure lamp 100 measured by the lamp monitoring unit 510 is transmitted to the final management server 530, and is used as a determination data of the failure of the aviation failure lamp 100.

The voltage / temperature measuring unit 520 measures the voltage and temperature of the voltage source (not shown) together with the measurement time point to examine the health of the voltage source for supplying the voltage for driving the aviation obstacle lamp 100. The management server 530 transmits.

The management server 530 detects the failure of the aviation failure lamp 100 through the blinking frequency of the aviation failure lamp 100, the voltage measurement value of the voltage supply source, the temperature measurement value and the measurement time. By comparing the number of flashes per unit time when the aviation failure lamp 100 operates normally with the number of blinks of the aviation failure lamp 100 for a predetermined time, it is determined whether the aviation failure lamp 100 operates normally. If the difference between the number of blinks of the aviation fault lamp 100 and the number of blinks per unit time is within the error range, it is determined that the aviation fault light 100 is in good condition, and if the deviation is out of the error range, the aviation fault light 100 is determined to be broken. do. The number of flashes per unit time is basically set to 60 times per minute, that is, 1 Hz, but may be set to a different value depending on the type and situation of the aviation failure lamp 100.

The management server 530 calculates the normal charging days after the solar panel normally charged the battery through the measured value of the solar panel output voltage, and determines the goodness of the solar panel based on the calculation result.

The management server 530 determines the voltage and the time when the battery starts to discharge, based on the measured voltage value of the battery, and determines the voltage and the time when the discharge is completed, the operation time and sunset of the aviation failure lamp 100. After that, check whether it works normally. In addition, the management server 530 analyzes the battery health, such as the performance of the battery, the remaining life of the battery through the result of the measurement of the voltage at the start of discharge of the battery, the voltage at the completion of discharge and the temperature measuring unit 520.

When a failure occurs in the aviation failure light 100 or when it is determined that the state of the solar panel or the battery is poor, the management server 530 outputs a warning signal such as an alarm sound or a warning message to inform the manager, and the management server 530. Alert signal is sent to the mobile terminal 540 of the user registered in the).

In this embodiment, the light source monitor and the voltage / temperature measurer 520 are depicted as separate devices that are spatially separated. In this system, a plurality of aviation failure lights (100) system already installed, by installing a light source monitoring unit near the aviation failure lights (100), by improving the control device of the aviation failure lights (100) aviation using a light source monitoring method Failure lamp 100 can implement a system for determining whether or not. That is, there is an advantage that the present system can be constructed by using the existing aviation obstacle light control device 100 as it is. However, the present invention does not exclude that the light source monitoring unit and the voltage / temperature measuring unit 520 are installed in one device, and the light source monitoring unit and the voltage / temperature measuring unit 520 may be implemented as an integrated device in actual use. Can be.

6 is a flow chart of a method for checking a aviation failure according to an embodiment of the present invention.

Referring to FIG. 6, first, the aviation failure lamp 100 determines whether the aviation failure lamp 100 operates (S510). Aviation failure light control unit so that the flight failure light 100 does not operate during the day, and when the amount of ambient light is insufficient after sunset, the flight failure light 100 is set to operate. When the aviation failure lamp 100 is operated, the lamp monitoring unit is operated by the operation control unit (S520). The light source monitoring unit of the lamp monitoring unit monitors light emission of the aviation obstacle lamp 100 (S530). Based on the signal detected by the light source monitoring unit, the blinking frequency measuring unit measures the blinking frequency of the aviation obstacle lamp 100 for a predetermined time (S540). The failure judging unit compares the number of flashes of the aviation fault lamp 100 with the number of flashes per unit time when the aviation fault lamp 100 operates normally, or whether the aviation fault lamp 100 is broken based on whether the aviation fault lights are off. (S550). When the aviation fault lamp is a blinker, the blinking frequency per unit time of the aviation fault lamp may be set by using data stored in a database or by manually inputting the blinking frequency per unit time by the administrator. The failure determination result of the aviation failure light 100 is transmitted to the upper server or the mobile terminal through the communication module (S560).

7 is a flow chart of a method for checking a fault in the air according to another embodiment of the present invention.

Referring to FIG. 7, first, the aviation failure lamp 100 determines whether the aviation failure lamp 100 is operated (S610). When the aviation failure lamp 100 is operated, the lamp monitoring unit is operated by the operation control unit (S620). The light source monitoring unit of the lamp monitoring unit monitors light emission of the aviation obstacle lamp 100 (S630). The blinking frequency measuring unit measures the blinking frequency of the aviation obstacle lamp 100 for a predetermined time based on the signal detected by the light source monitoring unit (S640). Aviation fault lamp 100 flashing frequency measurement unit flashing frequency measurement result is transmitted to the voltage / temperature measuring unit through the first communication module (S650). The voltage / temperature measuring unit measures the voltage of the power supply unit for supplying power to the aviation obstacle lamp 100, the surrounding environment, and the temperature of the power supply unit (S660). The voltage / temperature measuring unit transmits the number of blinks of the aviation fault lamp 100, the measured voltage, the surrounding environment, and the temperature measurement result of the power supply unit to the management server (S670). The management server determines the failure of the aviation fault lamp 100 and the health of the power supply unit based on the data received from the voltage / temperature measuring unit (S680). As a result of the determination, when a failure occurs in the aviation failure lamp 100 or when the battery of the power supply is defective, the management server outputs a warning signal to the manager (S690).

In order to easily explain the operation process of FIG. 7, the monitoring process (S630) of the light source monitoring unit and the voltage / temperature measurement process (S660) of the voltage / temperature measuring device are sequentially illustrated. It is not necessary to proceed sequentially, but may be performed simultaneously in parallel.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and are not construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

100: aviation failure lights 110: aviation failure lights control device
200: Aviation failure inspection device 210: Lamp monitoring unit
220: voltage / temperature measuring unit 310: light source monitoring unit
320: blinking frequency measurement unit 330: reference frequency setting unit
340: fault determination unit 350: first communication module
360: power supply unit 370: operation control unit
410: voltage measuring unit 420: temperature measuring unit
430: central processing unit 440: second communication module
450: power supply unit 460: air failure control unit

Claims (26)

A light source monitoring unit for monitoring light emission of aeronautical obstacles that are driven by blinking at predetermined intervals;
A flashing frequency measuring unit measuring a flashing frequency of the aviation obstacle during a predetermined time based on a monitoring signal of the light source monitoring unit;
A fault determination unit for comparing the number of blinks of the aviation fault and the like with the number of blinks per unit time when the aviation faults operate normally;
A communication module for transmitting a determination result on whether the failure; And
A power supply unit for supplying power to operate the light source monitoring unit, the blinking frequency measuring unit, the fault determining unit, and the communication module
Aviation failure check device comprising a.
A light source monitoring unit for monitoring light emission such as an aviation obstacle that continuously emits light for a predetermined time;
A failure determination unit determining whether a failure of the aviation failure is based on a monitoring signal of the light source monitoring unit;
A communication module for transmitting a determination result on whether the failure; And
A power supply unit supplying power to operate the light source monitoring unit, the fault determination unit, and the communication module
Aviation failure check device comprising a.
The method of claim 1 or 2, wherein the power supply unit,
Solar panels for absorbing sunlight to generate electrical energy;
A battery charging electrical energy generated by the solar panel;
An overcharge detector for detecting whether the battery is overcharged during charging; And
An over-discharge detector for detecting over-discharge during discharge of the battery
Aviation failure check device comprising a.
The method of claim 3, wherein
Air traffic light inspection device further comprises an operation control unit for controlling the operation so that the air traffic light inspection device can operate after sunset.
The method of claim 4, wherein the operation control unit,
Aviation failure light inspection device, characterized in that for controlling the operation of the aviation failure light inspection device by comparing the voltage of the solar panel with a predetermined reference voltage value.
The method according to claim 1 or 2,
Air traffic light inspection device further comprises an operation control unit for controlling the operation so that the air traffic light inspection device can operate after the operation of the air traffic lights.
The method of claim 6, wherein the operation control unit,
Aviation failure light inspection device, characterized in that for controlling the operation of the aviation failure light inspection device based on the characteristics of the light source monitoring unit that changes according to the flashing of the aviation failure lights.
The method of claim 1,
And a reference frequency setting unit for setting the number of flashes per unit time such as the aviation obstacle.
The method of claim 7, wherein
An apparatus for checking a aviation fault, such as by the administrator to remotely set the number of flashes per unit time through the communication module.
An aviation obstacle lamp that is installed on top of an aviation obstacle and continuously lights or blinks;
A lamp monitoring unit that monitors whether the aviation lights are turned off for a predetermined time or measures the number of flashes; And
Management server for detecting whether the aviation failure, such as the failure based on whether the aviation failure lights out or the number of flashes of the aviation failure, etc.
Aviation failure check system comprising a.
The method of claim 10, wherein the lamp monitoring unit,
A light source monitoring unit for monitoring light emission from an aircraft obstacle;
A flashing frequency measuring unit measuring a flashing frequency of the aviation obstacle during a predetermined time based on the monitoring signal of the light source monitoring unit;
A first communication module for transmitting the number of blinks of the aviation fault to the management server; And
A first power supply unit supplying power to operate the lamp monitoring unit, the light source monitoring unit, the blinking frequency measuring unit, and the first communication module;
Aviation failure inspection system including
The method of claim 11, wherein the first power supply unit,
Solar panels for absorbing sunlight to generate electrical energy;
A battery charging electrical energy generated by the solar panel;
An overcharge detector for detecting whether the battery is overcharged during charging; And
And an over-discharge detector for detecting over-discharge during the discharge process of the battery.
The method of claim 12, wherein the lamp monitoring unit,
And an operation control unit for controlling the operation of the lamp monitoring unit so that the lamp monitoring device can operate after sunset.
The method of claim 13, wherein the operation control unit,
And comparing the voltage of the solar panel with a predetermined reference voltage to control operation of the lamp monitoring unit.
The method of claim 11,
And an operation control unit for controlling the operation of the lamp monitoring unit so that the lamp monitoring unit can operate after the operation of the aviation failure lamp.
The method of claim 15, wherein the operation control unit,
Aviation failure lamp inspection system, characterized in that for controlling the operation of the flight warning light inspection device based on the characteristics of the light source monitoring unit that changes as the flight failure lamp flashes.
11. The method of claim 10,
Aviation fault check system further comprises a voltage measuring unit for measuring the voltage of the power supply for supplying power to the fault.
The method of claim 17, wherein the voltage measuring unit,
A second power supply unit supplying power to the aviation obstacle;
A voltage measuring unit measuring a voltage of the second power supply unit;
A second communication module for transmitting the measured voltage of the voltage measuring unit to the management server; And
Aviation obstacle light control unit for adjusting the operating time of the aviation obstacle lights so that the aviation failure lights operate after sunset
Aviation failure light inspection system comprising a.
The method of claim 18, wherein the voltage measuring unit
Aviation failure check system further comprises a temperature measuring unit for measuring the environment and the temperature of the second power supply.
The method of claim 19, wherein the management server,
And determining the health of the second power supply unit based on a voltage or temperature measurement result of the voltage measurement unit.
11. The method of claim 10,
The management server outputs a warning light warning system, characterized in that for outputting a warning signal when a failure occurs in the air failure light.
The method of claim 18,
The aviation failure light control unit transmits an aviation failure light operation signal to the operation control unit when the operation of the aviation failure lights, the operation control unit aviation characterized in that for controlling the operation of the lamp monitoring unit based on the operation signal of the aviation failure lights. Fault checking system.
Determining, by the air traffic light control unit, whether or not the air traffic light operates;
Operating the lamp monitoring unit by the operation control unit;
A light source monitoring unit monitoring light emission of the aviation obstacle lamp;
Measuring the number of blinks of the aviation obstacle for a predetermined time based on the number of blinks measuring unit based on the signal detected by the lamp monitoring unit;
Transmitting a flashing number of times such as an air traffic fault to a management server; And
Determining whether the management server has a failure based on the received data.
Checking methods such as aviation failures.
The method of claim 23,
Measuring, by a power measuring unit, a voltage of a power supply unit supplying power to the aviation obstacle;
Transmitting the voltage of the power supply unit to a management server; And
Determining, by the management server, the health of the power supply unit based on the received data.
Checking methods such as aviation failure further comprising.
The method of claim 23,
A temperature measuring unit measuring an ambient environment and a temperature of the power supply unit;
Transmitting the temperature of the power supply unit to a management server; And
Determining, by the management server, the health of the power supply unit based on the received data.
Checking methods such as aviation failure further comprising.
The method of claim 23,
And the operation control unit receives the aviation failure light operation signal from the aviation failure light control unit to operate the lamp monitoring unit.

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