KR102335155B1 - Fire detection system providing movement monitoring function - Google Patents

Abstract

Disclosed is a fire detection system providing a movement monitoring function, which can check a video of a fire receiver, which manages a fire detector, even from a remote location of the fire receiver. To this end, the present invention provides the fire detection system providing a movement monitoring function, which includes: a plurality of fire receivers that receives fire information from fire detectors disposed in a monitoring area, generates an output image for monitoring in which fire and non-fire conditions for each fire detector are displayed in color, and transmits fire monitoring information including the output image for monitoring; an integrated control server that receives the fire monitoring information transmitted from each fire receiver to generate an integrated control image based on the fire information provided from each fire receiver and transmits the integrated control image; and a mobile monitoring terminal on which a fire monitoring application is installed, in which the fire monitoring application is connected to the integrated control server through a communication network to manage an output of the integrated control image received through the communication network. According to the present invention, since it is possible to use a low-capacity cable installed in a building as a fire alarm system, additional cables for transmitting the video are not required, thereby reducing construction costs.

Description

FIRE DETECTION SYSTEM PROVIDING MOVEMENT MONITORING FUNCTION

The present invention relates to a fire detection system that provides a movement monitoring function that can monitor a fire generated inside a building while moving, and more particularly, check the image of the fire receiver that manages the fire detector even from a remote location of the fire receiver. It relates to a fire detection system that provides a possible movement monitoring function.

With social development, safety awareness to protect one's property and life is increasing, and awareness of firefighting is also changing, and the importance of firefighting facilities for fire prevention and alertness is being emphasized more and more. am.

Among firefighting facilities, the fire detector of the automatic fire alarm system detects signs of fire such as heat, smoke, and flame early, and sends a signal to the receiver. It is a very important facility that operates the facility and makes the initial fire extinguishing effective. That is, depending on how accurately and quickly the fire detector detects and notifies the fire at the initial stage of the fire, the damage of the fire can vary greatly.

However, in the case of current fire alarm systems, most buildings have general-type detectors that do not have an address function in case of a fire, which makes the structure of the building complex and it is very difficult to find the exact location of the fire in the fire caused by various combustion products.

For example, in gosiwons, karaoke rooms, traditional markets, motels, and apartments, it is very difficult to find the exact location of the fire when a fire occurs due to the complex internal structure and compartmentalization. .

In other words, it is very difficult to find the exact location of a fire only in the boundary zone of the floor unit and the area unit, unless you are a firefighting worker, and it is very difficult to accurately locate the fire and to cope with it.

As such, the fire detector is a facility that responds primarily to fire and plays the most pivotal role in the automatic fire alarm system, but the technology from 20 years ago has been used as it is until now without the development of technology to improve the performance of the fire detector. .

However, recently, as the need for real-time monitoring has emerged for an active response to a fire zone, a fire detector that captures an image of a fire zone and provides it to the control room of a building is being developed.

However, in the past, the fire detector is connected to the fire receiver through the communication network so that it can transmit the detection signal to the fire receiver installed in the disaster prevention room of the building. There was a problem with monitoring the fire receiver for hours.

In addition, since the information output through the fire receiver could only be checked in the disaster prevention room where the fire receiver was installed in the past, information on fire occurrence can be actively viewed in the management room that manages the facilities of the building or the guard room that will guide the firefighters in case of a fire. There was a problem that it was difficult to confirm.

Republic of Korea Registered Utility Model No. 20-0449435 (published on July 12, 2010) Republic of Korea Patent Registration No. 10-0984061 (published on September 28, 2010) Republic of Korea Patent Registration No. 10-2086540 (Announcement on March 10, 2020) Republic of Korea Registered Utility Model No. 20-0414008 (Announcement on April 13, 2006)

Accordingly, it is an object of the present invention to provide a fire detection system capable of confirming fire information collected in a fire receiver even if the manager of a building is located in a management room or a security room, not a disaster prevention room in which the fire receiver is installed.

In order to achieve the above object of the present invention, in one embodiment of the present invention, a plurality of fire detectors for generating fire information by detecting one or more fire elements, and transmitting the fire information, and a fire detector arranged in a monitoring area A fire receiver that receives fire information transmitted from the fire detectors, generates an output image for monitoring in which a fire situation and a non-fire situation by fire detector are displayed in color based on the fire information, and transmits the output image for monitoring, and the Provided is a fire detection system that provides a movement monitoring function, which includes a mobile monitoring terminal connected to a fire receiver through a communication network and installed with a fire monitoring application that manages the output of an output image for monitoring received through the communication network.

In addition, in order to achieve the object of the present invention, in another embodiment of the present invention, a plurality of fire detectors for generating fire information by detecting one or more fire elements, and transmitting the fire information, and a fire detector arranged in a monitoring area Receive fire information transmitted from the fire department, generate an output image for monitoring in which the fire and non-fire conditions by fire detector are displayed in color based on the fire information, and fire monitoring including the fire information and the output image for monitoring A plurality of fire receivers that transmit information, an integrated control server that receives the fire monitoring information transmitted from each fire receiver, generates an integrated control image based on the fire information provided from each fire receiver, and transmits the integrated control image; and a mobile monitoring terminal connected to the integrated control server through a communication network and installed with a fire monitoring application that manages the output of the integrated control image received through the communication network. It provides a fire detection system providing a movement monitoring function. .

According to the present invention, when fire information transmitted by a fire detector essential to a building is received by a fire receiver installed in a disaster prevention room of a building, a monitoring function for the area where a fire occurred is provided even at a remote location of the disaster prevention room. Even outside the disaster prevention room, the manager can actively respond to the fire.

In addition, according to the present invention, in addition to the workers in the disaster prevention room, the workers in the security room and the workers in the management office can monitor the fire generated inside the building in real time.

In addition, the present invention can determine the malfunction of the fire detector, and when a fire occurs, the initial response speed is improved through accurate location identification, and thus fire damage can be minimized.

1 is a configuration diagram for explaining an embodiment of a fire detection system according to the present invention.
2 is a configuration diagram for explaining another embodiment of the fire detection system according to the present invention.
3 is a photograph of a fire receiver and a mobile monitoring terminal according to the present invention.

Hereinafter, a fire detection system (hereinafter abbreviated as 'fire detection system') providing a movement monitoring function according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram for explaining an embodiment of a fire detection system according to the present invention, and FIG. 2 is a configuration diagram for explaining another embodiment of a fire detection system according to the present invention.

1 and 2, the fire detection system according to the present invention includes a plurality of fire detectors 100 that detect the occurrence of a fire in a monitoring area and generate fire information, and a fire situation for each fire detector by receiving the fire information. and a fire receiver 200 that generates an output image for monitoring in which non-fire situations are displayed in color, and a fire monitoring application that receives the output image for monitoring and manages the output (hereinafter abbreviated as 'fire monitoring app') It includes the installed mobile monitoring terminal 300, and may optionally further include an integrated control server 400 for generating an integrated control image based on the fire monitoring information transmitted from each fire receiver 200.

Hereinafter, each component will be described in more detail with reference to the drawings.

Referring to FIG. 1 , the fire detection system according to the present invention includes a fire detector 100 .

The fire detector 100 detects one or more fire elements to generate fire information, and transmits the fire information to the fire receiver 200. Distributed arrangement for each monitoring area in order to monitor a fire occurring in each monitoring area do. In this case, each of the fire detectors 100 may be installed along a wired communication line connected to the fire receiver 200 , and may be wirelessly connected to the fire receiver 200 through a communication network.

The fire detector 100 may use an analog detector that detects heat, smoke, or both, or a digital detector.

More specifically, the fire detector 100 generates real-time measurement information by detecting a fire element, generates fire information including the real-time measurement information and address information, and transmits the fire information to the fire receiver 200 . . In other words, an address-type detector providing address information may be used as the fire detector 100 .

As a specific aspect, the fire detector 100 according to the present invention includes a fire detection module that detects a fire element and generates real-time measurement information, and transmits fire information including real-time measurement information sensed from the fire detection module to a wired communication line or It includes a communication module for transmitting to the communication network, and a management module for generating fire information including real-time measurement information and address information given to the fire detector 100 and transmitting it to the fire receiver 200 through the communication module. At this time, the management module is connected to the fire detection module and the communication module.

The fire detection module constituting the fire detector 100 according to the present invention may be any one of a heat sensor, a smoke sensor, a gas sensor, and a fine dust sensor, but is preferably a heat sensor or a smoke sensor it's good This is because temperature and smoke concentration are best suited to distinguish fire occurrence.

The heat sensor is a sensor for measuring heat (temperature), and may detect heat (temperature) through a constant temperature method using a thermistor. In addition, the thermal sensor combines two temperature sensors to increase the thermal time constant of one side, decrease the thermal time constant of the other side, and detect the temperature increase rate from the detected temperature difference. (temperature) can be detected.

The smoke detection sensor may detect the smoke concentration through a photoelectric method. Such a smoke sensor may increase or decrease the sensitivity to smoke concentration.

The gas detection sensor may detect a gas concentration of an organic material generated by heat generation through an electrochemical method. Here, the organic material generated by heat generation may be any one of carbon monoxide, carbon dioxide, hydrogen chloride, BHT gas, chlorine, and ethylene.

The fine dust detection sensor may detect the atmospheric state in the measurement area through a light scattering method. Here, the light scattering method refers to a method of measuring the amount of scattered light by using the principle that the collided light is scattered in various directions when light is irradiated on a material and obtaining the concentration of fine dust from the value. In addition, fine dust includes carbon compounds such as soil dust, plant pollen, soot generated from burning fossil fuels, methane, alcohol, benzene and phenol generated when organic matter is burned, nitrogen oxides, and, It may be any one or more of any one or more of sulfur oxides.

Such particulate matter (PM) is classified into fine dust (PM10), ultrafine dust (PM2.5), and ultrafine dust (PM1.0) according to particle size. The particle size of the PM10 is 10 μm or less in diameter, the PM2.5 particle size is 2.5 μm or less in diameter, and the PM1.0 has a particle size of 1.0 μm or less in diameter.

The communication module constituting the fire detector 100 according to the present invention is connected to the fire receiver 200 through a wired communication line or a communication network, and transmits fire information to the fire receiver 200 according to the control of the management module. .

The management module constituting the fire detector 100 according to the present invention stores the address information given to the fire detector 100 by itself, and when real-time measurement information is collected from the fire detection module, the address information is added to the real-time measurement information. function is provided. This management module transmits fire information including address information and real-time measurement information to the fire receiver 200 to determine where the fire detector 100 that has detected the occurrence of a fire is installed. ) to help specify

If necessary, the address information may be coordinate information indicating the location where the fire detector 100 is installed, or may be identification information for matching coordinate information stored in the fire receiver 200 .

Referring to FIG. 1 , the fire detection system according to the present invention includes a fire receiver 200 .

The fire receiver 200 receives the fire information transmitted from the fire detectors 100 disposed in the monitoring area, and based on the fire information, the fire and non-fire situations for each fire detector 100 are classified by color. An output image for monitoring is generated and transmitted to the mobile monitoring terminal 300 .

The fire receiver 200 receives fire information from the fire detector 100 through a wired communication line or a communication network, analyzes the fire information including temperature and smoke concentration, and fires in the space where the fire detector 100 is installed. Analyze whether or not it occurs.

If necessary, when it is analyzed that a fire has occurred in the first monitoring area, the fire receiver 200 may be configured to generate an operation signal of the disaster prevention facility and transmit it to the disaster prevention facility installed in the first monitoring area. In this case, the disaster prevention equipment is connected to the fire receiver 200 through a wired communication line or a communication network.

Here, the disaster prevention equipment may include fire prevention equipment such as a fire door or a firewall, fire extinguishing equipment such as a fire hydrant or sprinkler, a smoke exhaust system for smooth evacuation or fire extinguishing, an emergency lighting device, and the like.

As a specific aspect, the fire receiver 200 according to the present invention may include a communication unit 210 , a control unit 220 , and an output image generation unit 230 , and optionally an output unit 240 , a storage unit (not shown). ) may be further included.

The communication unit 210 constituting the fire receiver 200 according to the present invention is connected to a wired communication line or a communication network to receive fire information transmitted from the fire detectors 100 disposed in the monitoring area, and output for monitoring. The image is transmitted to the mobile monitoring terminal 300 .

If necessary, the communication unit 210 may transmit the fire monitoring information including the output image for monitoring to the integrated control server 400 instead of transmitting the output image for monitoring to the mobile monitoring terminal 300 .

In addition, the communication unit 210 may transmit an operation signal to the disaster prevention facility through a wired communication line or a communication network.

In addition, the communication unit 210 may be connected to the mobile monitoring terminal 300 through a communication network. Such communication networks include closed networks such as local area networks (LANs) and wide area networks (WANs) and open networks such as the Internet, as well as code division multiple access (CDMA) and wideband code division multiple access (WCDMA) networks. ), Global System For Mobile Communication (GSM), Long Term Evolution (LTE), Evolved Packet Core (EPC), Wireless Fidelity (Wi-Fi, Wireless Lan (WLAN)), etc. may be used.

The control unit 220 constituting the fire receiver 200 according to the present invention analyzes the fire information received from the plurality of fire detectors 100 through the communication unit 210 to generate fire prediction information, and the fire detector ( 100) to analyze the real-time measurement information transmitted from and determine whether a fire has occurred. More specifically, when the real-time measurement information meets the specified conditions, the control unit 220 determines that a fire has occurred, outputs a notification signal for the occurrence of a fire, generates an operation signal of the disaster prevention facility, and transmits it to the disaster prevention facility.

For example, the control unit 220 extracts a heat (temperature) measurement value from real-time measurement information included in the fire information, and if the heat measurement value is greater than or equal to a predetermined temperature threshold, it is determined that a fire has occurred. Then, the control unit 220 extracts a smoke concentration measurement value from the real-time measurement information included in the fire information, and if the smoke concentration measurement value is greater than or equal to a predetermined smoke concentration threshold value, it is determined that a fire has occurred.

In addition, the control unit 220 may determine whether a fire has occurred by analyzing the smoke by type from real-time measurement information included in the fire information. Here, the type of smoke may be classified into cigarette smoke, combustible gas, toxic gas smoke, smoke from fire, and the like.

In addition, the control unit 220 extracts a gas concentration measurement value from the real-time measurement information, and determines that a fire occurs when the gas concentration measurement value is greater than or equal to a preset gas concentration threshold value. In addition, the control unit 220 extracts the fine dust concentration measurement value from the real-time measurement information, and determines that a fire occurs when the fine dust concentration measurement value is greater than or equal to a predetermined fine dust threshold value.

When it is determined that a fire has occurred by analyzing the detected heat, smoke, gas, fine dust, etc., the control unit 220 may control a fire alarm and an evacuation route notification through an acoustic output device.

The control unit 220 may notify the fact of a fire by transmitting fire information to a fire station server or a control center through the communication unit 210 simultaneously with the occurrence of a fire.

The output image generating unit 230 constituting the fire receiver 200 according to the present invention edits the fire occurrence prediction information so that the manager can intuitively check the fire information collected from the plurality of fire detectors 100 and outputs the monitoring output. By generating an image, an output image for monitoring in which the fire and non-fire conditions for each fire detector 100 are displayed in color based on the fire occurrence prediction information is generated.

The output image generating unit 230 displays all of the fire detectors 100 corresponding to non-fire situations in the same color (green, yellow, white, etc.) through the fire occurrence prediction information, and predicts the fire situation through the fire occurrence prediction information. The corresponding fire detector 100 is represented by a color (red, blue, etc.) that is distinguished from the fire detector 100 in a non-fire situation.

At this time, the monitoring output image may be formed so that the monitoring area of each fire detector 100 is divided into figures such as circles, triangles, squares, and ovals, and the identification number of the fire detector 100 is displayed inside the figure. can be

The output unit 240 constituting the fire receiver 200 according to the present invention is controlled by the control unit 220 to output detailed information, and a monitor having a touch screen installed therein may be used. The output unit 240 receives the output image for monitoring from the output image generating unit 230 under the control of the control unit 220 so that the worker in the disaster prevention room can check the output image for monitoring and outputs it as an image.

The storage unit constituting the fire receiver 200 according to the present invention stores fire information transmitted from the fire detector 100 and stores a system driving program. Here, the system driving program provides an output image for monitoring as the main screen through the output unit 240 when executed, and is an application built to perform processing corresponding to the environment setting and selection of various menus provided on the main screen program.

If necessary, the fire receiver 200 may be configured to generate fire monitoring information including fire information and an output image for monitoring, and then transmit the fire monitoring information to the integrated control server 400 .

Referring to FIG. 2 , the fire detection system according to the present invention may further include an integrated control server 400 .

The integrated control server 400 receives the fire monitoring information transmitted from a plurality of fire receivers 200 and generates an integrated control image based on the fire monitoring information provided from each fire receiver 200, the integrated control image is transmitted to the mobile monitoring terminal 300 . To this end, the plurality of fire receivers 200 transmit fire information and fire monitoring information including an output image for monitoring to the integrated control server 400 .

The integrated control server 400 extracts an output image for monitoring including the fire receiver 200 that provided the fire information when detecting fire information analyzed as a fire occurrence, and first outputs the extracted output image for monitoring It is designated as an image and transmitted to the mobile monitoring terminal 300 . This is a function of easily sharing the monitoring screen of the fire receiver 200 even if the manager holding the mobile monitoring terminal 300 is located in a remote location of the fire receiver 200 that manages the monitoring area where the fire occurred in a fire situation. is to provide

The integrated control image may be formed to include management icons of disaster prevention facilities installed around the fire detector 100 .

The integrated control server 400 generates escape information including information on the location of a fire and an escape route based on the fire monitoring information received from the fire receiver 200, and monitors the escape information through a communication network. It can be transmitted to the terminal 300 . This is to induce workers in the disaster prevention room, security room, and management room to quickly guide residents or visitors to the building by checking the safe escape route.

If necessary, the integrated control server 400 is constructed so that access is possible from the mobile monitoring terminal 300 connected through the communication network, and in the case of a registered administrator, the integrated control server 400 goes through a login process. It is possible to provide a management function for the integrated control server 400 even at a remote location of. In addition, the integrated control server 400 may be constructed to transmit whether a fire has occurred through the Internet to a set fire control center.

In addition, the integrated control server 400 may be configured to generate and output inspection information of the fire detector 100 requiring on-site inspection by analyzing the fire information. At this time, the integrated control server 400 provides inspection information including information on the inspection order and movement route of the fire detector 100 that requires on-site inspection, based on the network address and location information of each fire detector 100 stored by itself. It may be configured to generate and output. To this end, the integrated control server 400 outputs the inspection information through the display screen.

The display screen may be configured to include an integrated control button that receives an external control signal through a touch of the screen. For example, when the manager clicks the integrated control button for the disaster prevention facility, the integrated control server 400 receives the control signal of the disaster prevention facility through the display screen and controls the disaster prevention facility.

In addition, the integrated control server 400 periodically polls through the fire receiver 200 to collect information on the presence or absence of communication abnormalities and the occurrence of an emergency, and the fire detector 100 may be configured to respond to this. . Through this process, it is possible to check whether the cable installed between the fire receiver 200 and the fire detector 100 is disconnected.

The integrated control server 400 may be installed in a disaster prevention room of a large building and, when there are a plurality of persons in charge, may be configured to transmit operation state information to the mobile monitoring terminal 300 of the person in charge connected through a communication network.

In the past, when a fire situation was recognized in the disaster prevention room, a fire management person was manually arranged, and the requested fire management person was notified by voice of the action request for fire suppression, so it is difficult to respond quickly and effectively. There was a problem. In contrast, in the present invention, since the integrated control server 400 recognizes the fire situation and automatically transmits the fire information to the manager's mobile monitoring terminal 300 located at a remote location, prompt and effective fire suppression and evacuation guidance are possible. There are advantages.

3 is a photograph of a fire receiver and a mobile monitoring terminal according to the present invention.

1 to 3 , the fire detection system according to the present invention includes a mobile monitoring terminal 300 .

The mobile monitoring terminal 300 is connected to the fire receiver 200 through a communication network, and a fire monitoring app 310 that manages the output of the monitoring output image received from the fire receiver 200 through the communication network. this is installed In this case, the mobile monitoring terminal 300 may be connected to the integrated control server 400 through a communication network as shown in FIG. 2 instead of being connected to the fire receiver 200 through a communication network.

The monitoring output image may include management icons of disaster prevention facilities installed around the fire detector 100 . In this case, when an ON/OFF signal for controlling the operation of the disaster prevention facility is inputted through the management icon, the mobile monitoring terminal 300 generates a control signal for the disaster prevention facility through the fire receiver 200 . It is transmitted to the selected disaster prevention facility.

In other words, the fire monitoring app 310 receives the on/off signal of the disaster prevention facility through the management icon of the output image for monitoring, generates a disaster prevention facility control signal, and transmits the disaster prevention facility control signal to the fire receiver 200 do.

The fire monitoring app 310 may be limited to generate a disaster prevention facility control signal only in the fire monitoring app 310 authenticated through the ID registered for the disaster prevention room. For example, the fire monitoring app 310 authenticated through the ID registered for the disaster prevention room activates the management icon that can generate the disaster prevention facility control signal, and the fire monitoring app is authenticated through the ID registered for the management room or the guard room. 310 deactivates the management icon capable of generating a disaster prevention facility control signal.

As a specific aspect, the mobile monitoring terminal 300 according to the present invention is connected to the integrated control server 400 through a communication network and a fire monitoring app 310 that manages the output of the integrated control image received through the communication network is installed. can be

When the first output image is received, the fire monitoring app 310 outputs the first output image to the screen of the mobile monitoring terminal 300 instead of the integrated control image. As such, the mobile monitoring terminal 300 can output a 1:1 matching monitoring screen to the fire receiver 200 installed in the disaster prevention room inside the building when a fire occurs or according to the user's selection, so the fire receiver 200 It helps the user who manages the monitoring screen to easily recognize the information on the monitoring screen.

The fire monitoring app 310 receives the on/off signal of the disaster prevention facility through the management icon of the integrated control image, generates a disaster prevention facility control signal, and transmits the disaster prevention facility control signal to the integrated control server 400 .

In addition, the mobile monitoring terminal 300 may provide a function that enables active use of disaster prevention facilities additionally installed in a building outside the disaster prevention room in addition to the basic fire prevention facilities prescribed by the Fire Protection Act.

Specifically, the mobile monitoring terminal 300 is connected to a disaster prevention facility installed in a building through a communication network through an input/output module, an actuator, etc., and transmits a user's control signal to the disaster prevention facility to control the disaster prevention facility.

More specifically, the mobile monitoring terminal 300 is provided from the fire receiver 200 through a wired communication network such as the Internet and a wireless communication network including a plurality of base stations and base station controllers, a mobile communication exchange and a WAP gateway, etc. It means a means for receiving an output image or fire monitoring information provided from the integrated control server 400, and a wireless terminal such as a tablet PC, a notebook computer, or a smart phone can be used.

Here, the fire monitoring app 310 is downloaded from the integrated control server 400 through an Android market, an app store, or a web page and installed in the mobile monitoring terminal 300 .

Although described above with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention as set forth in the following claims. You will understand that you can.

100: fire detector 200: fire receiver
210: communication unit 220: control unit
230: output image generating unit 240: output unit
300: mobile monitoring terminal 310: fire monitoring application
400: integrated control server

Claims (7)

a plurality of fire detectors 100 for generating fire information by detecting one or more fire elements and transmitting the fire information;
Receives the fire information transmitted from the fire detectors 100 disposed in the monitoring area, and generates an output image for monitoring in which the fire and non-fire conditions for each fire detector 100 are displayed in color based on the fire information, a fire receiver 200 for transmitting the output image for monitoring; and
It is connected to the fire receiver 200 through a communication network, receives an output image for monitoring through the communication network, and manages the output of an output image for monitoring that is a monitoring screen that is 1:1 matched to the fire receiver 200 It includes a mobile monitoring terminal 300 installed with a fire monitoring application 310,
The fire receiver 200 is
A communication unit 210 for receiving fire information transmitted from the fire detectors 100 disposed in the monitoring area;
a control unit 220 that analyzes fire information received from a plurality of fire detectors 100 through the communication unit 210 and generates fire prediction information;
An output image generating unit 230 that generates an output image for monitoring in which the fire and non-fire conditions for each fire detector 100 are displayed in color based on the fire occurrence prediction information so that the manager can intuitively check the fire information; and
and an output unit 240 for receiving an output image for monitoring from the output image generating unit 230 under the control of the control unit 220 and outputting the image as an image. According to claim 1,
The monitoring output image includes management icons of disaster prevention facilities installed around the fire detector 100,
The fire monitoring application 310 receives the on/off signal of the disaster prevention facility through the management icon of the output image for monitoring, generates a disaster prevention facility control signal, and transmits the disaster prevention facility control signal to the fire receiver 200 A fire detection system that provides a movement monitoring function, characterized in that. According to claim 2, wherein the fire monitoring application (310)
A fire detection system that provides a movement monitoring function, characterized in that it limits the generation of a disaster prevention facility control signal only in the fire monitoring application 310 authenticated through an ID registered for a disaster prevention room. delete a plurality of fire detectors 100 for generating fire information by detecting one or more fire elements and transmitting the fire information;
Receives the fire information transmitted from the fire detectors 100 disposed in the monitoring area, and generates an output image for monitoring in which the fire and non-fire conditions for each fire detector 100 are displayed in color based on the fire information, a plurality of fire receivers 200 for transmitting fire monitoring information including the fire information and an output image for monitoring;
An integrated control server 400 that receives fire monitoring information transmitted from a plurality of fire receivers 200, generates an integrated control image based on the fire information provided from each fire receiver 200, and transmits the integrated control image; and
It is connected to the integrated control server 400 through a communication network and includes a mobile monitoring terminal 300 installed with a fire monitoring application 310 that manages the output of the integrated control image received through the communication network,
The fire receiver 200 includes a communication unit 210 that receives fire information transmitted from the fire detectors 100 disposed in the monitoring area, and a fire received from a plurality of fire detectors 100 through the communication unit 210 . The control unit 220 that analyzes the information to generate the fire occurrence prediction information, and the fire and non-fire situation for each fire detector 100 based on the fire occurrence prediction information so that the manager can intuitively check the fire information An output image generating unit 230 that generates an output image for monitoring indicated by , and an output unit 240 that receives an output image for monitoring from the output image generating unit 230 under the control of the control unit 220 and outputs it as an image ), including
The integrated control server 400 extracts an output image for monitoring of the fire receiver 200 that has provided the fire information when the fire information analyzed as a fire occurrence is detected, and the extracted monitoring output image is first used as an output image. It is designated and transmitted to the mobile monitoring terminal 300,
When the first output image is received, the fire monitoring application 310 outputs the first output image, which is a 1:1 matching monitoring screen to the fire receiver 200 instead of the integrated control image, to the screen of the mobile monitoring terminal 300. A fire detection system that provides movement monitoring features. delete 6. The method of claim 5,
The integrated control image includes management icons of disaster prevention facilities installed around the fire detector 100,
The fire monitoring application 310 receives the on/off signal of the disaster prevention facility through the management icon of the integrated control image to generate a disaster prevention facility control signal, and transmits the disaster prevention facility control signal to the integrated control server 400 A fire detection system that provides a movement monitoring function, characterized in that.

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