KR20180023662A - Management system of the light buoy and method for operating - Google Patents

Abstract

The present invention relates to a system for managing a light buoy and an operating method thereof. The system for managing a light buoy comprises: a GPS receiver (13) receiving location information of a light buoy (1); a collision detector (15) detecting light buoy external collision; a terminal (11) collecting information including information received by the GPS receiver (13), information detected by the collision detector (15), main power voltage measuring information and information detected by a lantern detector; and an information providing part (31) wirelessly providing information collected by the terminal (11) to a preset server (33). The present invention provides a low cost and high performance light buoy management system using a GPS and a communication company communication network, thereby reducing a maintenance cost of the light buoy and improving operation management ability.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light buoy management system,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backbone management system and an operation method thereof, and more particularly, to a backbone management system using GPS and an operation method thereof.

Light buoys are installed and operated on the sea for the protection of maritime facilities (sea lanes, gas pipes, petroleum pipes) and submarines (power cables, water supply, communication cables, etc.).

The conventional light management system is composed of a communication facility and a transmission / reception terminal, and provides some limited operation management information informing the user of emergencies such as function light position information, position deviation, and charger voltage drop.

Light buoys installed on the sea lead to economic losses as a result of restructuring and lifting due to natural forces (typhoon, tidal current), external factors (such as medium and large ships, ships and barges) have.

In addition to the limited functions, the conventional light management system has a problem in that it can not cope with a failure of the main power source, a lightning device failure, an external cause, and urgent matters occurring thereafter.

In addition, since the conventional light management system includes a separate home station (land communication equipment) and a home station (transmitting / receiving terminal of a backbone), a separate base station configuration is required, which causes a problem of high maintenance cost.

Korean Registered Patent No. 0429361 (name: remote control capable light buoy)

It is an object of the present invention to provide a backbone management system using GPS and an operation method thereof so as to reduce the maintenance cost because an expensive base station configuration is not required.

Another object of the present invention is to provide a backbone management system and an operation method thereof that are improved in operational management ability by providing information such as a main power failure, a name box failure, and a failure due to external factors.

According to an aspect of the present invention for achieving the above object, the present invention provides a GPS receiver including a GPS receiver for receiving light-guide table position information, a collision sensor for detecting a collision with an external light, A terminal collecting information including main information, main power supply voltage measurement information, and information detected by the same name detector, and an information providing unit for providing information collected by the terminal to a predetermined server wirelessly.

The server analyzes the information provided through the information providing unit and transmits the analyzed information to a manager's PC or a mobile phone. If the analyzed information is abnormal, the server transmits the result to the manager's PC or a mobile phone.

The terminal may further include a supplementary rechargeable battery for supplying power to the terminal for a predetermined period of time in response to a function of the main power supply.

The main power source may be a charger using a solar panel.

The information sensed by the isometric sensor may be an amount of current consumed by the equalizer.

The GPS receiver, the collision detector, the terminal, the even-numbered marker detector, and the auxiliary rechargeable battery may be provided in a terminal enclosure installed in the light-

The terminal enclosure may include a ventilation hole for preventing a temperature rise inside the terminal and the terminal enclosure.

And may include a connection line connecting the main power source, the terminal, and the same name generator.

The main power source supplies power to the terminal and the name teller, and the terminal collects and transmits the light guide position information, the external collision, the main power supply voltage measurement information and the name indicator information, and the information providing unit communicates with the terminal wirelessly, Receiving and analyzing information received from the server through the information providing unit and determining whether the information is abnormal; and when the server determines that the information is in an abnormal state, Lt; / RTI >

And a step of supplying power to the terminal for a predetermined period of time by operating the functional auxiliary battery for the function of the main power source.

When the auxiliary battery is supplied with power for a certain period of time, the terminal can transmit main power failure information.

The terminal may be electrically connected to a GPS receiver, a collision detector, a name marker detector in the terminal enclosure to collect the light guide position information, external collision information, and name information.

The terminal may be electrically connected to the main power source through a connection line to collect the main power voltage measurement information.

The information providing unit can communicate with the terminal wirelessly using a communication company communication network.

The server compares the current light level position information provided by the information providing unit with the set light level position information to determine whether the light level is out of the set distance. Lt; / RTI >

The server determines whether the main power supply voltage measurement information provided through the information provider is less than or equal to a set value. If the main power supply voltage measurement information is less than the set value, the server determines that the main power supply is lost and transmits the result to the manager PC or the mobile phone.

If the amount of current consumed by the equalizer is less than the set value at the set time, the server determines that the equalizer is out of order and transmits the result to the manager PC or the mobile phone.

The isobook management system of the present invention is capable of providing information in the event of an emergency such as a fault in the name lamp or an external factor, so that the original function of the back light can be quickly recovered. Also, It is possible to improve the operation management ability of the light buoys.

In addition, the present invention is configured to collect and transmit light-guide position information, external collision, main power voltage measurement information, and name marker information using GPS and communication company communication network, so that installation cost is reduced and main power failure, It is possible to save urgent matters promptly and reduce the maintenance cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a conceptual diagram of a light-guide table management system according to an embodiment of the present invention; FIG.
FIG. 2 is a diagram showing a state in which a light-guide table management system according to an embodiment of the present invention is installed on a light-guide table; FIG.
3 is a diagram showing a configuration of a light-guide table management system according to an embodiment of the present invention.
4 is a flowchart illustrating an operation example of a light management table management system according to an embodiment of the present invention;
5 is a block diagram illustrating an operation example of a light management table management system according to another embodiment of the present invention.
FIG. 6 is a flow chart illustrating a method of collecting collision detection information by a signal processing unit in a backbone management system according to another embodiment of the present invention. FIG.
FIG. 7 is a graph showing a principle for detecting a lightning gauge failure in a backlight management system according to another embodiment of the present invention; FIG.

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

1 and 2, the light-island management system of the embodiment of the present invention includes a terminal 11, a GPS receiver 13, a collision detector 15, a reflector 15, The auxiliary battery 17, the connecting line 19, the terminal enclosure 21, and the ventilation opening 23, as shown in Fig.

The light buoy (1) is a structure that is installed and operated on the sea for the protection of maritime (sea sign, gas pipe, petroleum pipe) and seabed (power cable, water supply,

The terminal 11 performs the function of collecting and transmitting information including light-guide position information, external collision, main-power-voltage measurement information, and name marker failure.

The terminal 11 may be a WCDMA communication module or a Lot Internet communication module. The terminal 11 operates by receiving power from the main power source 3. The main power source 3 is a charger using the solar panel 5.

The main power source 3 supplies power to the terminal 11 and the sleeper 7. The reflector 7 may be an LED illumination that is provided in the light-guide table 1 for night lighting and emits light.

The GPS receiver 13 calculates the current position on the basis of the time transmitted from the GPS 12 and the time difference received from the GPS receiver, and receives the current backbone position information.

The collision detector 15 performs detection of an external collision of the light board 1. The collision detector 15 may be one in which a sensor responds to an external collision to detect a collision and transmit information in an alarm format.

The isometric detector 16 detects the amount of current consumed by the equalizer 7. The amount of current consumed by the equalizer 7 may be equalizer information.

Since the equalizer (7) has a period of equalizing only at night, it can judge the fault of the equalizer by detecting the amount of current consumed by the equalizer during the set time. For example, the lights are lit from 10 pm to 4 am and off during the rest of the day. Using this cycle, if the amount of current consumed by the lighthouse from 10:00 am to 4:00 am is less than the set value, it can be judged as a fault of the lamp.

The auxiliary rechargeable battery 17 can supply power to the terminal for a predetermined period of time to inform the position information of the light-guide table 1 when the main power source 3 fails (failure, discharge, etc.). The auxiliary rechargeable battery 17 can be operated immediately after the failure of the main power source 3 to supply power for 48 to 72 hours. The auxiliary rechargeable battery 17 may be a power source charged by the solar panel 5. [

The connection line 19 is for measuring the main power voltage and measuring the light conditioner operating state. The connection line 19 electrically connects the main power supply 3, the terminal 11, and the sleeper 7.

2 and 3, the terminal 11, the GPS receiver 13, the collision detector 15, the reflector detector 16, and the auxiliary rechargeable battery 17 are provided in the terminal enclosure 21, (1).

The terminal enclosure 21 protects the terminal 11, the GPS receiver 13, the collision detector 15, the reflector detector 16 and the auxiliary rechargeable battery 17 from the external environment to enable normal operation. The terminal enclosure 21 is made of a plastic material for insulation and can be configured to enable selective opening and closing of the inner space.

The terminal enclosure 21 includes a terminal 11 and a ventilation hole 23 for preventing a temperature rise inside the terminal enclosure 21. [ The ventilation hole 23 is connected by a discharge hose to prevent direct foreign matter from entering through the ventilation hole 23. At least one ventilation hole 23 may be provided in the terminal enclosure 21.

And an information providing unit 31 for providing information collected by the terminal 11 wirelessly to a predetermined server. The information providing unit 31 wirelessly provides the server 33 with the information collected by the terminal 11 using the communication company communication network.

The communication network may be a mobile communication network including SKT, KT, and LG.

When the information collected by the terminal 11 is provided wirelessly to the server 33 by using the communication company communication network, the maintenance cost can be reduced because the reception performance is excellent and no additional base station is required.

The server 33 may be an intra-company server that manages the light-guide table 1.

The server 33 can analyze the information received through the information providing unit 31 and transmit the analyzed information to the manager PC or the mobile phone 35. [

Alternatively, the server 33 may determine whether there is an abnormality in the analyzed information, and may transmit the result to the manager PC or the mobile phone 35 when there is an abnormality.

An operation method of the isochronous table management system will be described in detail.

4, a main power source is supplied (S10), a terminal receiving the main power collects light-guide table position information, external collision, main power source voltage measurement information, and name marker information, and transmits (S40). The information providing unit communicates wirelessly with the terminal and receives the information and provides the information to the predetermined server (S50). The server analyzes the information provided through the information providing unit and determines whether there is an error And transmitting the result to the manager PC or the mobile phone when the information is determined to be abnormal by the server (S70).

The main power source 3 supplies power to the terminal 11 and the name changer 7.

The terminal 11 is electrically connected to the GPS receiver 13 and the collision detector 15 in the terminal enclosure 21 to collect light-guide position information and external collision information.

The terminal 11 is electrically connected to the main power source 3 through the connection line 19 to collect main power voltage measurement information.

The terminal 11 is electrically connected to the isometric detector 16 to collect name information.

The information providing unit 31 receives the information collected by the terminal 11 while communicating with the terminal 11 wirelessly using the communication company communication network and provides the information to the server 33. [

The server 33 analyzes the information provided through the information providing unit 31 and determines whether there is an abnormality in the analyzed information. If there is an abnormality, the server 33 can transmit the result to the manager PC or the mobile phone 35.

The server 33 compares the current lightbourse position information provided through the information providing unit 31 with the set lightbroom position information to determine whether the lightbroom 1 is out of the set distance and determines that the lightbroom 1 is out of position if the distance is equal to or greater than the set distance , The manager PC or the mobile phone 35. [

The server 33 compares the collision value provided through the information providing unit 31 with the set value, and if the collision value is equal to or greater than the set value, it determines that the collision is an external collision and transmits the result to the manager PC or the mobile phone 35.

The server 33 determines whether the main power supply voltage measurement information provided through the information providing unit 31 is less than or equal to the set value. If the main power supply voltage measurement information is less than the set value, the server 33 determines that the main power supply is out of order and transmits the result to the manager PC or the cellular phone.

The server 33 can determine the name of the name server by using the name information provided through the information providing unit 31. [

The name information may be the current consumed by the name changer 7. The amount of current consumed by the equalizer 7 can be sensed by the isomere detector 16 in real time.

If the amount of current consumed by the equalizer 7 at the set time is less than the preset value, the server 33 determines that the same name is a failure and can transmit the result to the manager PC or the cellular phone.

For example, if the amount of current consumed by the home computer from 10:00 am to 4:00 am is less than the set value, the server 33 may determine that the home machine is out of order and transmit the result to the manager PC or the mobile phone.

Alternatively, the server 33 may determine that the same name is a failure and send the result to the manager PC or the mobile phone if the information provided through the information providing unit 31 does not include the same name signal information.

As a result of the transmission, the manager can quickly recover the original functions of the light buoy by carrying out emergency lightning, repair, and inspection of the light buoy.

The method further includes a step S20 of determining whether the main power source is lost or not after the main power source is supplied. If it is determined that the main power source is malfunctioning, a step S30 ).

When the auxiliary battery 17 supplies the terminal 11 with power for a predetermined period of time, the terminal 11 can transmit the main power failure information.

That is, the auxiliary battery 17 can provide long-term related information while supplying power to the executing terminal 11 due to the function of the main power source 3.

FIG. 5 is a block diagram illustrating an operation example of a light management table management system according to another embodiment of the present invention. FIG. 6 is a block diagram of a light management system according to another embodiment of the present invention. And FIG. 7 is a graph showing a principle of detecting a lightness marker failure in the backlight management system according to another embodiment of the present invention.

The isochronous table management system of another embodiment of the present invention includes a collision detector 15 for detecting a collision with an external light of a back light, information received by the GPS receiver 13, information detected by the collision sensor 15, And a terminal 11 for collecting information including information sensed by the sensor and providing the collected information to the predetermined server 33 wirelessly.

Since the function of the terminal differs from that of the first embodiment, the functions of the terminal will be described in detail, except for the description of the configuration overlapping with the embodiment.

The terminal 11 can transmit the current light-guide table position information every predetermined period.

The terminal 11 can transmit the light-guide table position information sensed by the GPS receiver 13 to the predetermined server or manager at predetermined intervals using a selected one of WCDMA communication module, Lot Internet communication module and LTE network.

For example, the terminal 11 can transmit the situation to the manager by text or e-mail when the light-guide table 1 deviates from the set position by more than a set distance. Alternatively, the terminal 11 may compare the light-guide table position information with the set light-guide position information to determine whether the light-guide table 1 is out of the set distance, and provide the determined result to the predetermined server 33.

The terminal 11 can detect an abnormal external impact of the light-guide table.

The terminal 11 can provide information to the manager when an abnormal impact that is regarded as an external factor (sailing vessel, barge, etc.) is detected.

The terminal 11 may have a terminal operation status checking function. The terminal 11 may have a function of allowing the manager to remotely request the manager to inform the manager of the presence or absence of the terminal.

The terminal 11 may have a remote upgrade function.

The terminal 11 can be remotely upgraded without visiting the site when the terminal firmware is changed for performance improvement and maintenance of the terminal. In addition, the terminal 11 can remotely set a setting value necessary for the terminal operation, such as a light-island position information transmission period, an impact detection amount level setting, and the like.

The terminal 11 can have a function of confirming whether or not the name changer 7 has failed. The terminal 11 is able to provide the manager with the situation after confirming that the name changer 7 of the light-guide table 1 normally operates, and can provide the information to the manager even in the event of a failure.

For example, if the amount of current consumed by the equalizer 7 in the set time is less than the set value, the terminal 11 can determine that the same name is a failure and provide the determination result to the predetermined server.

The set value is the amount of current consumed by the equalizer 7, and the amount of current may have a regular fluctuation period in accordance with the flicker of the name lamp.

The terminal 11 includes a signal detecting unit 11a, a signal processing unit 11b, a coordinate receiving unit 11c, and a transmitting unit 11d.

The signal sensing unit 11a collects information sensed by the collision sensor 15 and information sensed by the isometric sensor 16.

The collision detector 15 detects an external collision of the light guide 1. For example, it detects the external impact and the impact amount of the light buoy. The isometric detector 16 detects the amount of current consumed by the equalizer 7 over time.

The signal sensing unit 11a may include a circuit for sensing the azimuth and the amount of impact using a 3G acceleration sensor and an impact sensor for collecting collision information. The signal detecting unit 11a may constitute a current measuring circuit capable of measuring up to several tens of microamperes to detect the amount of current according to the flickering signal of the illuminator.

The signal processing unit 11b uses the information collected by the signal detecting unit 11a to determine abnormal shocks and lightning machine failures.

The judgment of the abnormal shock can be judged by using the principle that a large single impact is detected when a large impact or breakage occurs due to an external factor such as a ship or a barge.

As shown in FIG. 6, the determination of the abnormal shock includes a step of counting the number of aperiodic impacts, a step of storing the amount of the impulse of the aperiodic impulse, a step of counting the number of aperiodic impacts stored during the set time, Determining a collision if the number of aperiodic impulses is equal to or less than a predetermined value and the average impulse amount of the aperiodic impulse is equal to or greater than a reference value;

The step of counting the number of non-periodic impacts may include counting the number of non-periodic impacts when the impact is detected (S110), determining whether the interval is within the range of the impact detection interval (S120) If the sensing interval is not within the range, the number of times of non-periodic impact is counted (S140).

The impact detection interval means the time interval during which the impact is detected.

The step of storing the impulse amount of the aperiodic impulse stores the impulse amount of the counted impulse impulse.

The periodic impact and the number of non-periodic impacts are counted simultaneously with the time measurement if an impact occurs and continue for the set time.

The step of determining the collision based on the number of non-periodic impacts stored during the set time and the average impact amount of the non-periodic impact is performed when the impact detection time interval exceeds the maximum value in the process of counting the number of cycles of the periodic impact and the non-periodic impact S150).

The impact detection time interval may be a time set from the time after the first impact detection.

It is determined whether it is an aperiodic impact after the set time (S160). The determination of the non-periodic impact can be determined by comparing the number of non-periodic impacts stored during the set time with the number of periodic impacts.

As a result of the determination, if it is determined as an aperiodic impact, the non-periodic impact number and the non-periodic impact are calculated based on the stored non-periodic impact number and the non-periodic impact amount.

If it is determined that the number of aperiodic impacts is less than the set value and the average impulse of the aperiodic impact is equal to or greater than the reference value, the collision is determined (S170).

As a result of calculation, if the number of aperiodic shocks exceeds the set value, it is determined that the intrusion is intrusion (S180).

For example, the setting value may be 5. If the number of aperiodic impacts is equal to or less than 5, which is the set value, and the average impulse of the aperiodic impact is equal to or greater than the reference value, it can be determined as an external impact.

Intrusion refers to the non-periodic impact detected by a vessel moored on a light buoy and performing a light buoy inspection or fishing operation.

Many types of waves and waved waves due to passing ships have a principle in which a relatively large amount of impact is generated periodically, so that it can be treated as a normal situation.

The periodic impact is treated as a normal situation by the impact caused by waves or waviness, and if the number of impacts during non-periodic impact exceeds the set value, the situation is treated by the impact caused by the ship, fishing boat, If the impact frequency is less than the set value and the average impact quantity of the aperiodic impact is higher than the reference value, it is judged as an external impact due to the ship or the like.

The signal processing unit 11b determines whether the name flasher is normally performed at the set time with the amount of current supplied to the equalizer 7. The signal processing unit 11b is a principle in which the amount of current consumption increases remarkably when compared with the existing consumed current amount when the equalizer 7 is turned on. As shown in Fig. 7, the principle that the amount of current is regularly varied It is possible to judge the fault of the machine name.

The lamp fault is judged as the amount of current consumed by the lamp at the set time is less than the set value. The set value is the amount of current consumed by the name changer.

For example, the fault in the equalizer unit compares the amount of current consumed by the equalizer during the set time with the amount of current consumed by the equalizer during the set time and determines whether the equalizer periodically flickers through the regular fluctuation of the amount of current consumed by the equalizer. The failure can be judged.

The coordinate receiving unit 11c collects and transmits to the transmitting unit the backbone position information received by the GPS receiver 13. [

The transmission unit 11d periodically provides the result determined by the signal processing unit 11b to the predetermined server 33. [ In addition, the transmitting unit 11d transmits the backbone position information received from the coordinate receiving unit 11c to the predetermined server 33. [ The transmission unit 11d may periodically provide the terminal status to the predetermined server, including the terminal voltage, the current, the signal sensing unit status, and the like.

The transmitting unit 11d may perform the function of the information providing unit described in one embodiment.

The transmitting unit 11d may provide the information to the predetermined server 33 wirelessly using a selected one of WCDMA communication module, Lot Internet communication module and LTE network for smooth communication.

The transfer unit 11d may have a means for confirming the status of the communication abnormality itself and automatically recovering through an automatic reboot when an abnormality occurs.

The present invention can be designed by using a combination of necessary configurations among the configurations of the embodiment and other embodiments. The isochronous table management system of the present invention includes a terminal 11 having the same name detector 16, a signal detecting unit 11a, a signal processing unit 11b, a coordinate receiving unit 11c and a transmitting unit 11d The terminal 11 having the collision detector 15 and the signal detecting unit 11a, the signal processing unit 11b, the coordinate receiving unit 11c and the transmitting unit 11d It may be configured to perform only the recorder collision detection function.

The above mentioned light management system can improve the operation management ability of the light management system by enabling maintenance of the functions of the real time light control system.

In addition, the light buoy management system can provide additional information such as location information of light buoys, position deviation, main power voltage measurement, etc., as well as providing additional information such as external collision, lightning fault, main power failure, Maintenance skills can be improved.

In addition, the light buoy management system can reduce the maintenance cost of light buoys by using low cost and high performance by using communication network.

In addition, the light buoy management system can collect real-time location information when natural light (typhoon, strong wind, bird, etc.) is displaced due to abrasion of mooring device and displacement of light buoys and drifting, .

In addition, the light buoy management system can collect information related to external collision (medium and large ships, barges, etc.), and confirm and take countermeasures when the light buoy is displaced or damaged.

In addition, the buoy management system collects the current status information due to the breakdown of the light box, and enables repair and replacement of timely and safe maritime traffic of nearby sailing vessels.

In addition, the backbone management system operates the auxiliary rechargeable battery when the main power source failure (blocking, discharging, etc.) occurs in the backlight management system.

Best Mode for Carrying Out the Invention The present invention has been described with reference to the drawings and the specification. Although specific terms are used herein, they are used for the purpose of describing the present invention only and are not used to limit the scope of the present invention described in the meaning of the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1: light buoy 3: main power
5: Solar panel 7: Lighting device
11: Terminal 11a: Signal detection unit
11b: signal processor 11c: coordinate receiver
11d: Transmission unit 13: GPS receiver
15: crash detector 16: reflector detector
17: auxiliary battery 19: connection cable
21: Terminal enclosure 23: Vents
31: Information provider 33: Server
35: Manager PC or mobile phone

Claims (28)

A GPS receiver that receives light level position information;
A collision detector for detecting an external collision with a light buoy; And
The GPS receiver collects information including information received by the GPS receiver, information detected by the collision detector, main power voltage measurement information, and information detected by the isometric sensor, and transmits the collected information to a server Wherein the light management system comprises: The method according to claim 1,
The server analyzes information provided from the terminal and transmits analyzed information to a manager PC or a mobile phone,
Judges whether there is an abnormality in the analyzed information, and transmits the result to the manager PC or the mobile phone when there is an abnormality. The method according to claim 1,
The terminal operates by being supplied with main power,
And a supplementary rechargeable battery for supplying power to the terminal for a predetermined period of time. The method according to claim 1,
The terminal
A signal detecting unit for collecting information sensed by the collision detector and information sensed by the isometric sensor,
A signal processor for determining an abnormal shock, a name indicator failure using the information collected by the signal detector,
And a transmitter for periodically providing the result of the signal processor to the predetermined server. The method of claim 4,
Wherein the terminal further comprises a coordinate receiving unit for collecting the light guide position information received by the GPS receiver and transmitting the collected light guide position information to the transmitting unit. The method according to claim 1,
Wherein the terminal provides the collected information to a predetermined server wirelessly using a selected one of a WCDMA communication module, a lottery communication module, and an LTE network. The method according to claim 1,
Wherein the information detected by the isometric detector is an amount of current consumed by the reflector over time. The method of claim 3,
Wherein the GPS receiver, the collision detector, the terminal, the even-numbered sensor, and the auxiliary rechargeable battery are provided in a terminal enclosure installed on a backlight table. The method of claim 8,
Wherein the terminal enclosure has a vent for preventing a temperature rise inside the terminal and the terminal enclosure. The method according to claim 1,
And a connection line connecting the main power source, the terminal, and the same name generator. Light fixtures installed on light buoys;
A equalizer detector for detecting an amount of current consumed by the equalizer; And
And a terminal for collecting information sensed by the isometric sensor and for providing the collected information to a predetermined server wirelessly. The method of claim 11,
Wherein the isometric detector detects an amount of current consumed by the equalizer over time. The method of claim 11,
The terminal
A signal detection unit for collecting current amount information sensed by the same-name sensor,
A signal processor for judging a fault in the name generator using the current amount information collected by the signal detector,
And a transmitter for periodically providing the result of the signal processor to the predetermined server. The main power source supplying power to the terminal and the name illuminator; And
The terminal collects the light guide position information, the collision information, the main power supply voltage measurement information, and the name indicator information, and provides the collected information to a predetermined server wirelessly. . 15. The method of claim 14,
Wherein the terminal uses the collision information and the likelihood information to determine an abnormal impact and a name indicator failure, and provides the determined result to the predetermined server. 15. The method of claim 14,
The determination of the abnormal shock
Counting the number of aperiodic impacts;
Storing an impulse amount of the aperiodic impact;
Determining a collision based on the number of aperiodic impacts stored during the set time and the average impact of the aperiodic impact;
And determining that the collision is a collision if the number of aperiodic impacts is equal to or less than a predetermined value and the average impulse amount of the aperiodic impact is equal to or greater than a reference value. 18. The method of claim 16,
Wherein the terminal determines that an intrusion occurs when the number of non-periodic impacts generated during the set time exceeds a set value. 15. The method of claim 14,
The equalizer information is an amount of current consumed by the equalizer,
Wherein the terminal determines that the same name is out of order if the amount of current consumed by the equalizer is less than a set value at a set time. 15. The method of claim 14,
Wherein the terminal compares the light-guide table position information with the set light-guide position information to determine whether the light-guide table is out of the set distance, and provides the determined result to the predetermined server. 15. The method of claim 14,
Wherein the terminal determines whether main power voltage measurement information collected from the terminal is less than or equal to a set value, and provides the determined result to the predetermined server. 15. The method of claim 14,
Wherein the terminal provides the collected information to a predetermined server wirelessly using a selected one of a WCDMA communication module, a Lot Internet communication module, and an LTE network. 15. The method of claim 14,
Further comprising the step of supplying power to the terminal for a predetermined period of time by operating the functional auxiliary battery of the main power source. 23. The method of claim 22,
Wherein the terminal provides the main power failure information to the predetermined server when the step of supplying power to the terminal through the auxiliary battery for a predetermined period of time is performed. 15. The method of claim 14,
The server compares the backbone position information provided through the terminal with the set backbone position information to determine whether the backbone is out of the set distance. If the backbone is out of the set distance, the server determines that the backbone is out of position and transmits the result to the manager PC or the mobile phone Wherein the iso-table management system comprises: 15. The method of claim 14,
Wherein the server determines whether the main power supply voltage measurement information provided through the terminal is less than or equal to a set value and determines that the main power supply is out of order if the power supply voltage is less than the set value and transmits the result to the manager PC or the mobile phone. How it works. The main power source supplying power to the terminal and the name illuminator; And
Detecting the amount of current consumed by the equalizer;
Collecting information sensed by the terminal by the terminal, and providing the collected information to a predetermined server wirelessly. ≪ Desc / Clms Page number 13 > 27. The method of claim 26,
Wherein the terminal determines that the same amount of power consumed by the equalizer at a set time is equal to or less than a set value, and provides the determination result to the predetermined server. 28. The method of claim 27,
Wherein the set value is an amount of current consumed by the existing equalizer, and the amount of current has a regular variation period according to the flicker of the equalizer.

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