KR101754620B1 - Fire remote management system - Google Patents

Abstract

More particularly, the present invention relates to a fire management remote management system, and more particularly, to a fire detection remote fire extinguishing system that can fire a fire by generating a fire in a contact part when a fire or heat is generated due to a fire, When the fire extinguisher is ruptured, the electronic pressure sensor measures the pressure change in real time. The pressure change value is sent to the manager to inform the occurrence of the fire. The manager remotely senses the fire detection means through the remote management system at the manager terminal, And a fire control remote management system capable of monitoring the state of the tube and the state of the fire extinguishing means without visiting the site.

Description

Fire remote management system {

The present invention relates to a fire management remote management system, and more particularly, to a fire management remote management system in which a fire is generated at a contact portion when a fire or heat is generated due to a fire in a heat sensing fire extinguisher, When the fire extinguisher is ruptured, the electronic pressure sensor measures the pressure change in real time. The pressure change value is sent to the manager to inform the occurrence of the fire. The manager remotely senses the fire detection means through the remote management system at the manager terminal, And a fire control remote management system capable of monitoring the state of the tube and the state of the fire extinguishing means without visiting the site.

Main facilities of unmanned factory, unmanned drainage pump station, substation, drainage pumping station, telecommunication facilities (unmanned exchange base station, unmanned aerial station facility, mobile communication base station) Respectively.

This automatic fire extinguishing system uses halon gas (clean fire extinguishing agent), and when the gas filled in the pressure vessel is simultaneously operated by a plurality of sensors, it is sprayed from the nozzle to the ignition point according to the opening and closing of the automatic valve. have.

However, when gas is injected due to malfunction of the fire detector, the cost of recharging is increased and the reliability of the device is lowered. Therefore, a device for monitoring the fire scene is registered as a patented technology.

The conventional image monitoring apparatus is configured to operate an automatic fire extinguishing system automatically or manually by connecting a fire detector and an automatic fire extinguishing apparatus with a relay. By shooting a fire point with a camera and sending it to a manager monitor at a remote location, And can operate an automatic fire extinguishing system.

However, since the video shot by the CCTV camera is sent to the monitor of the administrator through the video transmitter, the receiver and the video transmission line, there is no obstacle to the construction of the video transmission line in the case of close range. However, In the case where the offices are scattered, connecting them to the central control room and the video transmission line is a very unreasonable disadvantage in terms of cost increase, and the manager has to visit the facilities to be managed directly to check whether or not the fire extinguishing facilities are abnormal, Waste disadvantages and existing fire monitoring system have many disadvantages that they are not managed efficiently because of many malfunctions due to the influence of surrounding environment.

In addition, because the video taken by the CCTV is of the analog type, a VTR for recording it on a tape is required. Since the video shot by the camera is transmitted to the manager monitor via a separate video transceiver and a separate video transceiver, .

Application No. 10-1998-0001791 Fire Extinguishing System Remote Control Method and Remote Control System

According to an aspect of the present invention, there is provided a fire extinguishing system comprising: a heat-sensing fire extinguisher; a fire extinguisher having a fire extinguishing function; It is intended to measure the pressure change in the pressure sensor and send the fire occurrence information to the manager.

In addition, the present invention utilizing an electronic pressure sensor capable of wired / wireless communication can periodically remotely monitor the pressure of a heat-sensing fire extinguishing tube, thereby recognizing only the pressure change of the heat-sensing fire extinguishing tube which rapidly changes upon actual fire, Thereby eliminating the malfunction of the battery.

It is also intended to monitor the fire occurrence without visiting the site by remote sensing the state of the heat-sensing fire extinguisher and the state of the fire extinguishing means through the remote management system by the administrator.

In order to accomplish the above object, there is provided a fire occurrence remote management system (10) capable of measuring a pressure in a heat-sensing fire extinguisher tube by using an electronic pressure sensor to detect a fire occurrence and remotely managing a fire occurrence,

A heat sensing type fire extinguisher which is formed such that fire extinguishing liquid or fire extinguishing material such as fire extinguishing powder or fire extinguishing gas is injected by pressure due to a fire of a certain temperature, A tube 100,

A fire extinguishing means 200 connected to one side of the heat sensing type fire extinguishing tube 100 in which the extinguishing material is pressure-stored so that the extinguishing material can be embedded in the heat sensing type fire extinguishing tube 100;

The fire extinguisher 100 is connected to the other side of the heat sensing fire extinguishing tube 100 to determine whether the heat extinguishing fire extinguishing tube 100 is ruptured by measuring the pressure formed in the heat sensing fire extinguishing tube 100, (Fire detection means unique information + normal pressure value + measured pressure value + fire occurrence information) when it is judged as rupture, and transmits it to the server means 400;

A server unit 400 for generating event occurrence information using the fire occurrence information transmitted from the fire detection unit 300 and transmitting the generated event occurrence information to the administrator terminal 500 using a wireless network;

And an administrator terminal (500) for receiving event occurrence information from the server means (300) and performing remote management of a fire occurring in real time.

The present invention provides an effect of preventing fire from spreading due to rupture in a contact portion when a fire or heat is caused by a fire in a heat-sensing fire extinguisher.

In addition, an electronic pressure sensor is connected to one side of the heat-sensing fire extinguisher to measure the real-time pressure change, so that it senses that the pressure changes when the fire-extinguishing fire extinguisher is ruptured. Provides an effect.

In addition, the administrator terminal allows the administrator to monitor the state of the heat-sensing digestive tube and the state of the digestion means at a remote site without visiting the site, thereby reducing labor costs and other costs.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a system configuration diagram of a fire occurrence remote management system according to the present invention. FIG.
2 is a block diagram of a plurality of systems for a fire occurrence remote management system according to the present invention.
FIG. 3 is a detailed view of a heat-sensing digestive tube for the fire-generated remote management system of the present invention.
4 is a system flow diagram of a fire occurrence remote management system according to the present invention.
FIG. 5 is a block diagram of each configuration means for the fire occurrence remote management system of the present invention.

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

As shown in FIG. 1, the fire management remote management system, which measures the pressure in the heat-sensing fire extinguisher of the present invention by using an electronic pressure sensor to detect the occurrence of fire and remotely manage the fire, Sensing fire extinguishing tube 100 which is formed such that a fire extinguishing liquid such as a fire extinguisher or a fire extinguishing powder or a fire extinguishing gas contained in the fire extinguishing material is injected by pressure ,

A fire extinguishing means 200 connected to one side of the heat sensing type fire extinguishing tube 100 in which the extinguishing material is pressure-stored so that the extinguishing material can be embedded in the heat sensing type fire extinguishing tube 100;

The fire extinguisher 100 is connected to the other side of the heat sensing fire extinguishing tube 100 to determine whether the heat extinguishing fire extinguishing tube 100 is ruptured by measuring the pressure formed in the heat sensing fire extinguishing tube 100, (Fire detection means unique information + normal pressure value + measured pressure value + fire occurrence information) when it is judged as rupture, and transmits it to the server means 400;

A server unit 400 for generating event occurrence information using the fire occurrence information transmitted from the fire detection unit 300 and transmitting the generated event occurrence information to the administrator terminal 500 using a wireless network;

And an administrator terminal (500) for receiving event occurrence information from the server means (300) and performing remote management of a fire occurring in real time.

The heat sensing fire extinguishing tube 100, the fire extinguishing means 200, the fire sensing means 300 and the server means 400 are connected to an unmanned factory, an unmanned drainage pumping station, a substation, a reservoir pumping station, And is installed and used in a facility (an unmanned exchange base station, an unmanned optical power station facility, a mobile communication base station, a wind power generation facility, and the like), a public space having communication facilities and a main facility of a business building.

FIG. 6A shows an example of a fire occurring at a specific point of a facility to be managed, in which a remote fire alarm management system according to the present invention is installed, FIG. 6B shows a fire alarm remote management system according to the present invention, FIG.

As shown in FIG. 6, when a fire occurs at a specific point in the facility to be managed, the part of the heat-sensing fire extinguisher tube 100 adjacent to the point is ruptured. At this time, the rupture is a heat rupture caused by the fire, which is applied to the heat-sensitive digestive tube. That is, when the temperature exceeds a predetermined temperature, a certain portion of the heat-sensing fire extinguisher tube that senses a certain temperature or more is ruptured, and the fire extinguishing material is sprayed to the ruptured space portion. As a result, the efficiency of the fire suppression can be greatly improved by blocking in advance the large-scale occurrence of a small-scale fire occurring in a specific area.

As shown in FIG. 3, the heat-sensing fire extinguishing tube 100 is constructed such that the fire extinguishing material is pressurized through a portion where a fire occurs, specifically, a portion where a certain temperature or more is detected due to fire, And is extinguished by spraying.

The heat-sensing fire extinguishing tube 100 is ruptured by heat generated during a fire. The rupture is caused not by the heat but by the partial rupture of the portion of the fire extinguishing material 100 which is sensed at a certain temperature or higher, As shown in FIG. 3, the rupture has a shape in which a specific point of the tube is spread to the upper and lower sides.

In this case, since the ruptured portion occurs at a portion over a certain temperature, when the specific portion is ruptured, the rupture occurs in many places of the tube where a certain temperature or more is detected.

The heat-sensing fire extinguishing tube 100 is formed of a flexible material. When the temperature of the contact portion is more than a predetermined temperature, the fire extinguishing tube 100 is ruptured and the fire extinguishing material And is injected by pressure to enable initial evolution.

Since the heat-sensing fire extinguishing tube 100 is formed of a flexible material and is formed in a linear shape, it is possible to arrange the fire extinguishing apparatus 100 in a narrow and minute space or a complicated space, It is possible to prevent the occurrence of a large fire at an early stage by enabling a rapid evolution at the ignition point.

In this case, the temperature of the flame or heat contacting the heat-sensing fire-extinguishing tube 100 is preferably 100 ° C. to 110 ° C. When the heat-sensing fire extinguishing tube 100 ruptures at the contact portion, As shown in FIG.

The rupture temperature may be 100 ° C to 110 ° C or higher, depending on the characteristics of the place where the heat-sensing fire extinguishing tube 100 is manufactured.

The fire extinguishing means 200 is connected to one end of the heat sensing fire extinguishing tube 100 and is installed in the fire extinguishing means 200 so that the fire extinguishing material can be embedded in the heat sensing fire extinguishing tube 100 at a predetermined pressure. Characterized in that the extinguishing material is stored under pressure.

Accordingly, when heat or fire due to fire is brought into contact with the heat-sensing fire extinguishing tube 100 in a state in which the extinguishing material is embedded by applying pressure to the heat-sensing fire extinguishing tube 100, And is formed such that the extinguishing material is injected by the pressure provided by the extinguishing means 200. The extinguishing material to be injected with pressure is characterized by using a extinguishing liquid or a extinguishing material such as extinguishing powder or extinguishing gas do.

The fire extinguishing means 200 may further include pressure regulating means capable of adjusting the pressure according to the user's need and means for controlling supply and interruption of the extinguishing material supplied to the heat sensing fire extinguishing tube 100 .

The fire sensing means 300 is connected to the other side of the heat sensing type fire extinguishing tube 100 to measure the pressure built in the heat sensing type fire extinguishing tube 100. When the fire extinguishing tube 100 ruptures due to fire, 100, and determines whether or not the fire extinguishing tube 100 is ruptured. If it is determined that the fire extinguishing tube 100 has been ruptured, the fire detection means unique information, the normal pressure value, the measured pressure value, And transmits the generated fire occurrence information to the server means 400. FIG.

Specifically, the specific information of the fire detection means among the fire occurrence information generated by the fire detection means 300 is for identifying the location or the fire detection means 300 in the remote management system 10, The means-specific information includes at least the installation area of the fire detection means, the installation place, and the details of the fire detection means, and may be set in a code format.

In other words, the specific information of the fire detection means can be set as "installation area_installation_detail_information ", and the setting format of the fire detection means unique information can be set variously according to a method desired by the administrator.

For example, if the unique information of the fire detection means is set as "installation area_installation_detail_information" and the specific information of the fire detection means is generated as a code of the format "042_0003_02" will be.

In this case, the server means 400 generates event occurrence information corresponding to "042_0003_02 ". For example, the server means 400 generates event occurrence information, "Daejeon_Bomunsan_head_2_th relay," using fire detection means unique information "042_0003_02 ".

At this time, in the server means 400, information on the installation area_installation_detail information corresponding to the unique information of the fire detection means indicated by the code may be stored in the DB. The server means 400 searches the DB to generate the information of the competition_bigumon_head_2_th relay corresponding to "042_0003_02".

The installation area, installation place and detailed information code are coded according to the installation order of the fire detection means 300 or the manual of the manager.

The normal pressure value of the fire occurrence information is initialized and set by the fire extinguishing means 200 to the value of the fire extinguishing pressure built in the fire extinguishing fire extinguishing tube 100. In a normal fire extinguishing state, (100). ≪ / RTI >

The measured pressure value in the fire occurrence information is a pressure value inside the heat-sensing fire-extinguishing tube 100 measured in real time, and is a value obtained by measuring a pressure change inside the heat-sensing fire extinguishing tube 100.

The fire occurrence information of the fire occurrence information is information indicating whether or not a fire occurs according to a pressure change caused by the rupture of the heat-sensing fire extinguishing tube 100.

5, the fire sensing unit 300 includes a pressure sensing unit 310 connected to one side of the heat sensing type fire extinguisher 100 to sense the internal pressure of the heat sensing fire extinguisher 100;

A storage unit 320 for storing information on an internal initial normal pressure value of the heat-sensing fire extinguisher 100 and specific information on the fire sensing means;

It is determined whether or not the heat-sensing fire extinguishing tube 100 is ruptured by comparing the pressure value sensed by the pressure sensing unit 310 with the normal pressure value stored in the storage unit, (330);

And a transmission unit 340 configured to transmit the fire occurrence information generated by the determination unit 330 to the server unit 400.

The pressure sensing part 310 is connected to one side of the heat sensing type fire extinguisher tube 100 to detect a change in pressure by measuring the pressure inside the heat sensing fire extinguishing tube 100 in real time. have.

Specifically, when the heat-sensing fire extinguishing tube 100 is normal, the measured value measured in real time by the pressure sensing unit 310 will be the same value as the initial stored normal pressure value.

However, if a part of the heat-sensing fire-extinguishing tube 100 ruptures due to a fire during real-time pressure measurement, the pressure inside the heat-sensing firebox 100 decreases due to leakage of the fire extinguishing material into the rupturing part. The pressure sensing unit 310 measures the reduced pressure.

The pressure sensing unit 310 is installed at one end of the heat sensing type fire extinguishing tube 100 after the heat sensing fire extinguishing tube 100 is installed. And the fire extinguishing means 200 is installed on the other side of the fire extinguishing means 200. The fire extinguishing material having a constant pressure is built in the heat sensing fire extinguishing tube 100 by opening the valve in the fire extinguishing means 200, And then stores the pressure in the heat-sensing fire extinguishing tube 100 measured by the pressure-sensing unit 310 as an initial normal pressure value after a predetermined time elapses.

For example, when the initial pressure value measured at the pressure sensor 310 after the valve opening of the fire extinguishing means 200 is 5 psi, the pressure value is 7 psi after 10 minutes, and when the pressure value is 7 psi after 1 hour, Can be stored as the initial normal pressure value.

In addition, the storage unit 320 may further store information specific to fire detection means.

The determination unit 330 compares the measured pressure inside the heat-sensing fire extinguisher 100 with a normal pressure to determine whether a fire has occurred, and generates fire occurrence information when the fire is determined.

Specifically, when the determination unit 330 determines that a fire is present, it means that the measured pressure measured by the pressure sensing unit 310 falls below the normal pressure value. For example, when the initial normal pressure value is 7 psi If the fire breaks down the heat-sensing fire extinguishing tube 100 and the pressure suddenly drops to 5 psi or 3 psi, it is judged as a fire and the fire occurrence information is generated. The generated fire occurrence information is transmitted to the server means 400 through the transmitter 340.

In the case of generating the fire occurrence information as described above, the fire is generated and the pressure inside the heat-sensing fire extinguishing tube 100 rapidly decreases compared to the normal pressure. In case of natural pressure decrease under normal circumstances, I can not.

Under normal circumstances, the pressure inside the heat-sensing fire extinguisher 100 may be reduced naturally. In this case, a slight pressure decrease occurs over a long period of time rather than a sudden pressure decrease, And the judging unit judges it, and when the natural pressure is decreased, it is not judged that the fire occurs.

For example, when the pressure change rate calculated by the following equation (1) is equal to or lower than the set value, it may not be determined that a fire has occurred.

[Equation 1]

Pressure change rate =

는 t1과 t2 사이의 경과시간)(Pressure value measured at the measured pressure value 1: t1 in the above equation, measured pressure value 2: pressure value measured at t2,

Is the elapsed time between t1 and t2)

That is, if the rate of pressure change calculated by the above-described equation (1) is less than the predetermined value, it is not determined that a fire has occurred.

When it is determined that the heat-sensing fire extinguishing tube 100 has been ruptured, the determination unit 330 generates fire occurrence information including fire detection means unique information, normal pressure value, measured pressure value, and fire occurrence information.

The specific information of the fire detection means in the fire occurrence information is for identifying the location or the fire detection means 300 in the remote management system 10 and the fire detection means specific information is " Information ", and the setting format of the fire detection means-specific information can be variously set by a method desired by the administrator.

For example, the unique information of the fire detection means may be set to "installation area_installation_detail information" or the like, and the unique information of the fire detection means may be generated as a code of the format of "042_0003_02 ".

In addition, the fire occurrence information may include a normal pressure value, a measured pressure value, and a fire occurrence information. For example, when the normal pressure is 7 psi and the current measured pressure is 5 psi, ______________________________________ The fire occurrence information can be generated as "042_0003_02_7psi_5psi_fire" when it is set in the format of "installation location_detail_detail_top_value_current_pressure value_fire occurrence".

The fire occurrence information may be configured in various ways in a manner desired by the administrator.

The transmitting unit 340 transmits the fire occurrence information generated by the determining unit 330 to the server 400 in real time.

The server means 400 generates the event occurrence information using the fire occurrence information when the fire occurrence information is received from the fire detection means 300 and transmits the generated event occurrence information to the administrator terminal 500).

The server unit 400 includes an information receiving unit 410 configured to receive fire occurrence information from the fire detection unit 300;

Information on the position of the fire-generating facility, information on the normal pressure value in the fire extinguishing tube, information on the current measured pressure value in the fire extinguishing tube, information on the fire occurrence information An event information generating unit 420 for generating event occurrence information including information on a fire occurrence time;

An information transmission unit 430 configured to transmit the generated event occurrence information to the administrator terminal 500; And a control unit.

The information receiving unit 410 receives fire occurrence information from the fire detection unit 300.

The fire occurrence information includes fire detection means specific information (installation area_installation_detail_information), a normal pressure value of the fire extinguisher, a measured pressure value of the fire extinguisher, and fire occurrence information.

The event occurrence information generation unit 420 generates event occurrence information using the fire occurrence information of the fire detection unit 300 received through the information reception unit 410. [

The event occurrence information includes information on the fire detection means specific information (information including an installation area, installation place, and detailed information of the fire detection means), information on the normal pressure value in the fire extinguishing tube, information on the current measured pressure value in the fire extinguishing tube , Information on whether or not the fire occurred, and information on the time of occurrence of the fire.

The fire occurrence information transmitted from the fire detection means 300 may be in the form of a code including information on installation location_installation_detail_total pressure value_measured value_fire occurrence information, for example, "042_0003_02_7psi_5psi_fire" .

The event occurrence information generation unit 420 generates event occurrence information using the received fire occurrence information.

For example, if the transmitted fire occurrence information is "042_0003_02_7psi_5psi_fire", it may be "5psi of the current pressure value of 7psi of the normal pressure value of the 2nd relay station of the Baebunsan relay station in Taejon".

The event occurrence information may further include fire occurrence time information. In this case, "fire alarm occurrence at 5 psi at 10:30 in the current pressure value of 7 psi at the second relay station of Daejeon Bomunsan relay station"

At this time, the server unit 400 may store information on the installation area_installation_detail information corresponding to each configuration code of the fire occurrence information indicated by the code in the DB. The server means 400 searches the DB to generate the information of the competition_bigumon_head_2_th relay corresponding to "042_0003_02".

That is, the event occurrence information generation unit 420 generates text event occurrence information using the fire occurrence information in a code format.

The information transmitting unit 430 transmits the event occurrence information generated by the event occurrence information generating unit 420 to the administrator terminal 500.

In addition, the server means 400 may further include an administrator terminal setting unit for setting a plurality of administrator terminal 500 to which event occurrence information is to be transmitted.

When a plurality of administrator terminals transmitting event occurrence information are set through the administrator terminal setting unit, the server means 400 transmits event occurrence information to the set administrator terminal.

1 to 2 and 4, the fire-generating remote management system 10 of the present invention further includes a camera unit 600,

The camera unit 600 starts shooting when generating the fire occurrence information of the determination unit 330 and generates peripheral image information. The generated image information is stored in the storage unit 320 of the fire detection unit 300 And is transmitted to the server unit 300 through the transmission unit 340.

The camera unit 600 is installed in the vicinity of the fire detection unit 300 and starts shooting when generating fire occurrence information.

The server means 400 transmits the received image information together with the event occurrence information to the administrator terminal 500 so as to remotely cope with the occurrence of a fire.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. In addition, it is obvious that various modifications and variations can be made without departing from the scope of the present invention by those skilled in the art.

10: Fire notification system
100: Heat-sensitive fire extinguisher
200: Fire extinguishing means
300: Fire detection means
310: pressure sensing unit 320:
330: determination unit 340:
400: server means 410: information receiving unit
420: Event information generating unit 430: Information transmitting unit
500: administrator terminal
600:

Claims (8)

A fire occurrence remote management system (10) capable of measuring a pressure in a heat-sensing fire extinguisher with an electronic pressure sensor to detect a fire occurrence and remotely managing the occurrence fire,
A heat sensing type fire extinguisher which is formed such that fire extinguishing liquid or fire extinguishing material such as fire extinguishing powder or fire extinguishing gas is injected by pressure due to a fire of a certain temperature, A tube 100,
A fire extinguishing means 200 connected to one side of the heat sensing type fire extinguishing tube 100 in which the extinguishing material is pressure-stored so that the extinguishing material can be embedded in the heat sensing type fire extinguishing tube 100;
The fire extinguisher 100 is connected to the other side of the heat sensing fire extinguishing tube 100 to determine whether the heat extinguishing fire extinguishing tube 100 is ruptured by measuring the pressure formed in the heat sensing fire extinguishing tube 100, A fire detection means 300 for generating fire occurrence information including fire detection means-specific information and transmitting the generated fire occurrence information to the server means 400;
A server unit 400 for generating event occurrence information using the fire occurrence information transmitted from the fire detection unit 300 and transmitting the generated event occurrence information to the administrator terminal 500 using a wireless network;
And an administrator terminal (500) for receiving event occurrence information from the server means (400) and performing remote management of a fire occurring in real time,

The fire detection means (300)
A pressure sensing part 310 connected to one side of the heat sensing type fire extinguishing tube 100 to sense the internal pressure of the heat sensing fire extinguishing tube 100;
A storage unit 320 for storing information on an internal initial normal pressure value of the heat-sensing fire extinguisher 100 and specific information on the fire sensing means;
The pressure change rate of the pressure values at different times measured by the pressure sensing unit 310 is calculated and the calculated pressure change rate is compared with the preset value to determine whether or not the thermosensitive fire extinguishing tube 100 is ruptured A determination unit 330 for generating fire occurrence information when it is determined that the fire is broken;
And a transmission unit 340 configured to transmit the fire occurrence information generated by the determination unit 330 to the server unit 400,
If the pressure change rate is equal to or less than the predetermined value, the determination unit 330 determines that the natural pressure is reduced in a normal state. If the pressure change rate is equal to or greater than the predetermined value, the determination unit 330 determines that the heat-
The characteristic of the heat-sensing fire extinguishing tube 100 for rupturing is that the tube is not melted by heat but a portion of the thermostat-type fire extinguishing tube 100 which is detected at a certain temperature or more is spread to the upper and lower sides, Wherein a rupture occurs in all parts where a temperature over a predetermined temperature is detected.
Equation: Pressure change rate =

(The measured pressure value 1 in the above equation is the pressure value measured at t1, the measured pressure value 2 is the pressure value measured at t2,

Is the elapsed time between t1 and t2)
The method according to claim 1,
The heat-sensing fire extinguishing tube (100)
Characterized in that the fire extinguishing material is sprayed to the ruptured portion by pressure when the temperature of the contact portion is higher than a certain temperature when the heat or flame is contacted, Generating remote management system.
The method according to claim 1,
The fire occurrence information further includes a normal pressure value in the digestive tube, a measured pressure value in the digestive tube,
Wherein the fire detection means-specific information includes at least an installation area of the fire detection means, an installation place, and detailed information of the fire detection means.
delete The method according to claim 1,
The server means (400)
An information receiving unit 410 configured to receive fire occurrence information from the fire detection unit 300;
Information on the position of the fire-generating facility, information on the normal pressure value in the fire extinguishing tube, information on the current measured pressure value in the fire extinguishing tube, information on the fire occurrence information An event information generating unit 420 for generating event occurrence information including information on a fire occurrence time;
And an information transmitter (430) configured to transmit the generated event occurrence information to the administrator terminal (500).
The method according to any one of claims 1, 2, 3, and 5,
The fire-generating remote management system 10 further includes a camera unit 600,
The camera unit 600 starts shooting when generating the fire occurrence information of the determination unit 330 and generates peripheral image information. The generated image information is stored in the storage unit 320 of the fire detection unit 300 Is transmitted to the server means (300) through the transmission unit (340).
The method according to claim 6,
Wherein the server means (400) transmits the received image information together with the event occurrence information so that the manager terminal (500) can remotely cope with the occurrence of a fire.
The method according to claim 1,
The event occurrence information includes information on the fire detection means specific information (information including an installation area, installation place, and detailed information of the fire detection means), information on the normal pressure value in the fire extinguishing tube, information on the current measured pressure value in the fire extinguishing tube A fire occurrence information, and a fire occurrence time.

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