KR102508926B1 - Fire monitoring system that can manage the lifespan of photoelectric fire detectors - Google Patents

Abstract

Disclosed is a fire monitoring system that can determine the replacement cycle of photoelectric fire detectors by checking the performance of the photoelectric fire detector even if a site inspector does not directly visit the site where the photoelectric fire detector is installed. To this end, provided is the fire monitoring system that can manage the lifespan of photoelectric fire detectors, the system comprising: a plurality of photoelectric fire detectors that transmit information on smoke concentration, received light amount, and set light amount as response information when an inspection signal is received from the outside; a communication line connected to each fire detector to provide an inspection signal to the fire detector set as the target, and to return the response information provided from the fire detector; and a fire receiver that transmits the inspection signal to a fire detector through the communication line, receives response information to the inspection signal through the communication line, and analyzes real-time sensitivity based on the response information. According to the present invention, instead of directly performing a smoke detection test on site to check the sensitivity of the photoelectric fire detector to smoke concentration, the lifespan can be predicted in advance by checking the current state value of the photoelectric fire detector.

Description

A fire monitoring system capable of managing the life span of photoelectric fire detectors

The present invention relates to a fire monitoring system capable of checking the performance of a photoelectric fire detector, and more particularly, by inspecting the performance of a photoelectric fire detector without a field inspector directly visiting the site where the photoelectric fire detector is installed. It relates to a fire monitoring system that can identify the replacement time of type fire detectors.

A typical fire monitoring system consists of a fire detector, transmitter, repeater, receiver, and sound device.

The fire detector is installed near the ceiling in the building to detect heat or smoke when a fire occurs, converts it into a unique signal, and transmits it to a receiver directly through a wire or through a repeater, thereby generating a fire alarm signal. it was made to

A plurality of these fire detectors are connected in parallel in the same fire detection area, and when a fire occurs, when one of the fire detectors operates, the fire detectors connected in the area generate a fire alarm signal, while any one of the fire detectors If the fire detector is inoperable or the line is disconnected, the alarm signal will not be generated in case of fire.

In this way, if the fire detector that alerts the occurrence of a fire is operated abnormally, many human and material damages occur. Accordingly, building managers and fire officials regularly check whether the fire detector operates normally using a fire detector tester. It is necessary to check the fire detector, and if necessary, the operation of the fire detector is tested.

The fire receiver displays the location of the fire and sends an operation signal to sound devices or broadcasting equipment and fire extinguishing equipment to induce evacuation and fire extinguishing activities. play a role

On the other hand, recently, smoke detectors characterized by rapid fire detection are mainly adopted as fire detectors, and among smoke detectors, a scattering type photoelectric detector with a simple configuration and excellent sensitivity is generally used.

These photoelectric fire detectors must alarm a fire when a smoke concentration higher than the standard value is detected. However, if a malfunction occurs below the standard value due to the elapse of the period of use, a fire alarm is issued even if no fire has occurred, for example, in the case of cigarette smoke. It may ring and cause commotion, such as residents evacuating.

In addition, the photoelectric fire detector has a problem in that if the inside is contaminated and malfunctions above a standard value, it does not detect it even when a fire actually occurs, which can cause a large-scale accident.

Republic of Korea Patent Registration No. 10-1098969 (Announced on December 28, 2011) Republic of Korea Patent Registration No. 10-0502181 (published on July 20, 2005) Republic of Korea Patent Registration No. 10-1770251 (Announced on August 22, 2017) Republic of Korea Patent Registration No. 10-1363276 (Announced on February 13, 2014)

Therefore, it is an object of the present invention to determine the replacement time by checking information on the performance of the photoelectric fire detector from a remote location without the need to visit the site where the photoelectric fire detector is installed and test the performance of the photoelectric fire detector. To provide a fire monitoring system.

In order to achieve the above object of the present invention, in one embodiment of the present invention, a plurality of photoelectric fire detectors for transmitting smoke concentration, received light amount, and set light amount information as response information when an inspection signal is received from the outside; A communication line that is connected to the fire detector to provide an inspection signal to the fire detector set as a target and returns response information provided from the fire detector, and transmits an inspection signal to the fire detector through the communication line, A fire monitoring system capable of managing the lifespan of a photoelectric fire detector including a fire receiver that receives response information through a communication line and analyzes sensitivity in real time based on the response information is provided.

According to the present invention, instead of directly performing a smoke detection test in the field to check the sensitivity of the photoelectric fire detector to the smoke concentration, the life of the photoelectric fire detector can be predicted in advance by checking the current state value.

In addition, since the present invention can check the state of the photoelectric fire detector in a disaster prevention room in which the fire receiver is installed, the inspection speed of the fire detector is improved and the manpower required to check the fire detector is reduced.

In addition, since the present invention can select and replace fire detectors with poor performance, it is possible to respond quickly to the occurrence of a fire by collecting signals received from the fire detectors, and it is possible to reduce the probability of occurrence of false alarms.

1 is a block diagram showing a fire monitoring system according to the present invention.
2 is a configuration diagram for explaining a fire monitoring system according to the present invention.
3 is a configuration diagram showing a fire monitoring system according to an embodiment of the present invention.

Hereinafter, a fire monitoring system (hereinafter, abbreviated as 'fire monitoring system') capable of managing the lifespan of a photoelectric fire detector according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a fire monitoring system according to the present invention, Figure 2 is a configuration diagram for explaining the fire monitoring system according to the present invention.

1 and 2, the fire monitoring system according to the present invention includes a plurality of photoelectric fire detectors 100 that are distributed and arranged for each monitoring area, detect fire elements to generate fire information, and transmit the fire information; It includes a communication line 200 connected to each photoelectric fire detector 100, and a fire receiver 300 receiving fire information provided from each photoelectric fire detector 100 through the communication line 200.

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

Referring to Figures 1 and 2, the fire monitoring system according to the present invention includes a photoelectric fire detector (100).

The photoelectric fire detector 100 detects one or more fire elements to generate a real-time fire signal, transmits fire information including the real-time fire signal, and may be an analog fire detector that detects smoke.

In addition, when an inspection signal is received from the outside through the communication line 200, the photoelectric fire detector 100 generates response information including smoke concentration, received light amount, and set light amount, and then transmits the response information through the communication line. It is transmitted to the fire receiver 300 through (200).

In addition, the fire detector 100 generates fire information including a real-time fire signal when a fire element is detected, transmits the fire information to the fire receiver 300 through the communication line 200, and generates response information when an inspection signal is received. After that, it is transmitted to the fire receiver 300.

As a specific aspect, the fire detector 100 according to the present invention detects one or more fire elements and generates fire information including a real-time fire signal, and a fire detection module 110 generated from the fire detection module 110 The communication module 120 transmits fire information to the fire receiver 300 or repeater through wired communication, and when an inspection signal is received, response information is generated and then inspected for transmission to the fire receiver 300 or repeater through wired communication. module 130.

The fire detection module 110 constituting the fire detector 100 according to the present invention basically includes a smoke detection sensor, a light receiver, and a light emitter, and optionally any of a heat detection sensor, a gas detection sensor, and a fine dust detection sensor. One or more may be included.

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

The thermal sensor is a sensor for measuring heat (temperature), and a constant temperature thermal sensor or a differential thermal sensor may be used. At this time, the constant temperature type heat sensor may detect heat (temperature) using a thermistor. In addition, the differential thermal sensor combines two temperature sensors to increase the thermal time constant of one and reduce the thermal time constant of the other, and detects the temperature rise rate from the detected temperature difference to detect heat (temperature). can detect

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

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

As an embodiment, the fire detector 100 according to the present invention determines the real-time sensitivity of the light receiver based on the smoke concentration detected through the smoke sensor, the received light amount detected by the light receiver, and the set light amount emitted by the light emitter. analysis, and if the real-time sensitivity is less than a preset value, a failure signal may be generated and transmitted to the fire receiver 300. At this time, the sensitivity below a preset value may be set to a sensitivity of 30% to 60% or less.

As another embodiment, the fire detector 100 according to the present invention stores the initial sensitivity, and based on the smoke concentration detected through the smoke detection sensor, the amount of received light detected by the receiver, and the set amount of light emitted by the light emitter, Analyzes the real-time sensitivity of, and may be configured to transmit to the fire receiver 300 after generating a failure signal when the ratio of the initial sensitivity to the real-time sensitivity is less than a preset value. At this time, the preset value may be set to 30% to 60%.

The communication module 120 constituting the fire detector 100 according to the present invention is connected to the fire receiver 300 or the repeater through wired communication, and transmits fire information to the fire receiver 300 or the repeater. In addition, the communication module 120 receives the inspection signal transmitted from the fire receiver 300 or the repeater, and transmits response information to the fire receiver 300 or the repeater.

When the inspection signal is received by the communication module 120 of the fire detector 100, the inspection module 130 constituting the fire detector 100 according to the present invention responds with response information including smoke concentration, received light amount, and set light amount information. is generated and transmitted to the fire receiver 300 or the repeater, the smoke concentration is collected through the smoke detection sensor of the fire detection module 110, and the received light quantity is collected through the light receiver of the fire detection module 110, Response information is generated by collecting the set amount of light emitted by the light emitter of the fire detection module 110 .

In this way, even if the fire detection module 110 does not generate fire information, the fire detector 100 generates response information by using the check signal provided from the fire receiver 300 or the repeater by the check module 130, and then transmits it to the communication line. It is transmitted to the fire receiver 300 through 200 to check the performance of the fire detection module 110.

Meanwhile, the fire detector 100 may be configured such that the amount of received light sensed by the light receiver maintains a constant level even when the inside of the fire detection module 110 is contaminated due to the elapse of a usage period. To this end, the fire detector 100 may further include a management module 140 that analyzes the amount of light received detected by the light receiver and automatically adjusts the amount of light emitted to maintain the amount of received light at a constant level.

The management module 140 monitors the amount of light received by the light receiver in real time and automatically adjusts the amount of light emitted by the light emitter so that the amount of light received by the light receiver is maintained at a constant level.

Accordingly, the fire detector 100 according to the present invention changes the threshold value even if the amount of light emitted from the light emitter decreases due to the inflow of pollutants such as dust into the fire detector 100 as a long time elapses after installation. Fire element can be detected normally.

1 and 2, the fire monitoring system according to the present invention includes a communication line (200).

The communication line 200 is connected to each fire detector 100 to provide an inspection signal to the fire detector 100 set as a target, and response information provided from the fire detector 100 that provided the inspection signal to the fire receiver. Reply to (300).

This communication line 200 connects each fire detector 100 to the fire receiver 300 or connects a repeater to the fire receiver 300.

In addition, the communication line 200 not only serves as a communication line between each fire detector 100 and the fire receiver 300, but also serves to supply power to each fire detector 100. To this end, the communication line 200 may be configured as a power line capable of transmitting fire information, an inspection signal, and response information through power line communication.

More specifically, the communication line 200 may be composed of a power line including a power line for supplying power to the fire detector 100 and a communication line for transmitting and receiving data between the fire detector 100 and the fire receiver 300.

Referring to Figures 1 and 2, the fire monitoring system according to the present invention includes a fire receiver (300).

The fire receiver 300 is connected to a plurality of fire detectors 100 through a communication line 200 to receive fire information transmitted from each fire detector 100, and continuously detects fire detectors through the fire information. (100) Monitors the occurrence of fire in the space where it is installed.

In other words, the fire receiver 300 analyzes the occurrence of a fire by analyzing the smoke concentration of the space in which the fire detector 100 is installed through the fire information transmitted from the fire detector 100 .

In addition, the fire receiver 300 transmits an inspection signal to the fire detector 100 through the communication line 200, receives response information to the inspection signal through the communication line 200, and based on the response information to analyze real-time sensitivity. If necessary, the fire receiver 300 may analyze sensitivity in real time based on response information received through the communication line 200 and preset fire detection module information. In this case, the preset fire detection module information may include an aperture ratio of the light receiver.

These check signals are generated by the fire receiver 300 when an input signal for some or all of the fire receivers 300 is input from the manager, and then transmitted to the corresponding fire detector 100, or the fire receiver 300 communicates periodically. It can be transmitted to all fire detectors 100 connected to the line 200. If necessary, the fire receiver 300 transmits an inspection signal to the repeater 400 and receives response information provided from the repeater 400 .

As an embodiment, the fire receiver 300 according to the present invention may be configured to detect the fire detector 100 having sensitivity equal to or less than a preset value by analyzing response information. At this time, the preset value may be set to 30% to 60%.

Specifically, the fire receiver 300 extracts the smoke concentration, received light amount, and set light amount of the response information, and then analyzes the sensitivity of the light receiver according to Equation 1 below.

[Equation 1]

Sensitivity of the receiver = measured quantity of the receiver / quantity of light emitted by the emitter

Here, the receiver measurand is obtained according to Equation 2 below.

[Equation 2]

Receiver measured quantity = Receiver received light quantity × Receiver gain

In Equation 2, the amount of light received by the light receiver = the amount of light emitted by the emitter × the set light amount × light diffusion rate × aperture ratio of the receiver, and the light diffusion rate = basic diffusion rate (LSb) + smoke diffusion rate (LSs). Here, the set amount of light is a designated value, the aperture ratio of the receiver and the aperture ratio of the receiver are fixed values, and when the smoke concentration is converted to 0%, it becomes the basic diffusion rate light, which also becomes a fixed value.

Here, if the gain of the receiver is designed so that the photometric amount of the receiver is the same as the amount of light emitted by the emitter, the standard reception sensitivity becomes 100. The standard sensitivity of the sensor changes depending on the installation environment along with the usage time.

As another embodiment, the fire receiver 300 according to the present invention stores the initial sensitivity for each photoelectric fire detector 100, analyzes the real-time sensitivity based on response information, and determines the ratio of the real-time sensitivity to the initial sensitivity in advance. It may be configured to detect the fire detector 100 that is less than a set value. At this time, the preset value may be set to 30% to 60%.

When the fire detector 100 whose replacement time has arrived is detected, the fire receiver 300 outputs the replacement information of the fire detector 100 in the form of video, audio, or both so that a manager can recognize it.

As a specific aspect, the fire receiver 300 according to the present invention may include a determination unit 310, a failure check unit 320, a communication unit 330, and a notification unit 340.

The determination unit 310 may analyze fire information transmitted from the fire detector 100 to determine whether a fire has occurred. That is, the determination unit 310 may output fire occurrence information when it is determined that one or more of the fire elements is a fire occurrence. At this time, the fire occurrence information may include location information of the fire detector 100 that provided fire information determined to have occurred and information on an evacuation route around the fire detector 100 .

More specifically, the determination unit 310 may analyze the smoke detected from the smoke signal included in the fire information by type and determine whether a fire has occurred. Here, the type of smoke may be classified into cigarette smoke, combustible gas, toxic gas smoke, smoke due to fire, and the like.

The determination unit 310 extracts the smoke concentration measurement value from the smoke signal included in the fire information, and compares and analyzes the smoke concentration measurement value with a preset reference value based on the difference in concentration for each type of smoke to determine whether a fire has occurred. can do.

The determination unit 310 extracts the heat (temperature) measurement value included in the fire information, and compares and analyzes the heat measurement value with the outdoor temperature reference value when a fire occurs to determine whether a fire has occurred.

The determination unit 310 may extract a gas concentration measurement value from a gas signal included in the fire information and compare and analyze the gas concentration measurement value with a preset gas concentration reference value to determine whether a fire has occurred.

The determination unit 310 may extract the fine dust concentration measurement value from the fine dust signal included in the fire information, and compare and analyze the fine dust concentration measurement value with the fine dust threshold value to determine the standby state. At this time, the determination unit 310 controls information of the determined standby state to be notified through the notification unit 340 .

The determination unit 310 mutually analyzes the detected heat, smoke, gas, and fine dust to output fire occurrence information through the notification unit 340 when it is determined that a fire has occurred.

The fault checking unit 320 periodically or selectively transmits an inspection signal to the fire detector 100 or repeater, receives response information for the inspection signal from the fire detector 100 or repeater, and converts the received response information to By analyzing, it is possible to determine whether the fire detector 100 is out of order. At this time, the fault checking unit 320 detects the fire detector 100 in which the sensitivity of the fire detection module 110 is less than or equal to a predetermined value, or the ratio of the initial sensitivity to the real-time sensitivity of the fire detection module 110 is less than or equal to a preset value. When the fire detector 100 is detected, the corresponding fire detector 100 is selected as a fire detector to be replaced, and alarm information including the installation location of the fire detector to be replaced and the current state value is output.

In other words, the breakdown check unit 320 may receive response information collected from the fire detector 100 by periodically transmitting an inspection signal according to a manager's setting or selectively transmitting an inspection signal according to a manager's input. .

As such, the present invention can selectively or periodically check the performance of the fire detector 100 in a disaster prevention room in which the fire receiver 300 is installed, even if the fire detector 100 is not operated by visiting the site.

The communication unit 330 includes wired communication means connected to the communication module 120 of the repeater or fire detector 100 by wire and receiving fire information and response information transmitted from the repeater or fire detector 100.

If necessary, the communication unit 330 may include a wireless communication means for receiving fire information and response information transmitted from the repeater through a communication network. To this end, the wireless communication means is connected to the repeater through a communication network. At this time, as the communication unit 330, a wired and wireless communication means in which a wired communication means and a wireless communication means are integrated may be used.

These communication networks include closed networks such as LAN (Local Area Network) and WAN (Wide Area Network), open networks such as the Internet, CDMA (Code Division Multiple Access), WCDMA (Wideband Code Division Multiple Access) ), GSM (Global System For Mobile Communication), LTE (Long Term Evolution), EPC (Evolved Packet Core), Wi-Fi (Wireless Fidelity, Wireless Lan (WLAN)), etc. can be used.

The notification unit 340 may be configured in the form of a monitor or TV capable of outputting image information, and may further include a speaker capable of outputting sound. The notification unit 340 outputs the fire occurrence information when the determination unit 310 determines that a fire has occurred, generates fire occurrence information, and provides the fire occurrence information.

In addition, the notification unit 340 may output a guide sound for a quick evacuation route according to a fire. Here, the warning sound and the evacuation route guidance sound may be output as an audio output after being recorded by a voice chip.

In addition, the notification unit 340 outputs the alarm information when the trouble checking unit 320 generates and provides alarm information for the fire detector to be replaced.

If necessary, the fire receiver 300 may further include a storage unit. The storage unit may store fire information and response information transmitted from the fire detector 100 and may store an initial sensitivity of the fire detector 100 .

3 is a configuration diagram showing a fire monitoring system according to an embodiment of the present invention. Referring to FIG. 3 , the fire monitoring system according to the present invention may further include a repeater 400 .

The repeater 400 is installed on the communication line 200 and is connected by wire to a plurality of fire detectors 100 distributed in a specific monitoring area, and the fire information collected from the fire detectors 100 and The response information is transmitted to the fire receiver 300.

This repeater 400 is basically installed on the communication line 200 and can transmit fire information to the fire receiver 300 through the communication line 200, but is connected to the fire receiver 300 through a communication network to prevent fire Information and may be transmitted to the fire receiver 300.

At this time, the repeater 400 can serve as a double safety device that can check the location of the monitoring area where the fire occurred and the identification number of the activated fire detector 100 at a glance. To this end, the repeater 400 reads the address information of the fire detector 100 and adds the self-set address of the repeater 400 to the fire information collected from the fire detector 100 and transmits it to the fire receiver 300. It can be.

Specifically, the relay 400 may include a communication module 120, a remote inspection module 130, and a relay module. If necessary, the repeater 400 may further include any one or more of a storage module, a power module, and an address setting module.

The communication module 120 is connected to the fire receiver 300 through a communication line 200, transmits fire information and response information through mutual communication with the fire receiver 300, and communicates to receive control commands for fire extinguishing equipment. (COM+, COM-) means. More specifically, the communication module 120 receives the inspection signal provided from the fire receiver 300 through the communication line 200, and transmits the fire information and response information received from the fire receiver 300 to the fire receiver 300. relay with

In addition, the communication module 120 is connected to the fire detector 100 through the communication line 200 or an auxiliary communication line and transmits a check signal through mutual communication with the fire detector 100 . More specifically, the communication module 120 receives an inspection signal from the fire receiver 300 and provides the inspection signal to the fire detector 100 . In this way, the communication module 120 is connected to the fire detector 100 through a plurality of grouped electrical wires per input circuit. At this time, in the communication module 120, 5 to 30 fire detectors 100 per input circuit may be connected in parallel.

In addition, the communication module 120 may be connected to the fire extinguishing equipment and transmit a control signal of the fire receiver 300 to the fire extinguishing equipment.

The remote inspection module 130 is connected to the communication module 120, and when an inspection signal is received through the communication module 120, the inspection signal is provided to the fire detector 100 that is the target of the inspection signal, and the fire detector The response information transmitted from (100) is provided to the fire receiver (300) through the communication module (120).

If necessary, the remote inspection module 130 reads the response information and detects the fire receiver 300 to be replaced. Further, the remote inspection module 130 generates replacement target information including the current state value of the detected fire detector 100, and provides the replacement target information to the fire receiver 300 through the communication module 120. .

The relay module is connected to the communication module 120, and provides fire information collected from the fire detector 100 managed by the relay 400 to the fire receiver 300 through the communication module 120. In addition, the relay module reads the address and fire information, and transmits the real-time status to the fire detector 100 and the input/output control of the fire extinguishing equipment and the fire receiver 300.

In the storage module, reference numerical information of fire elements monitored by the fire detector 100 assigned to the repeater 400 is set to be managed by the repeater 400 . As necessary, the storage module sets a reference value for the received light amount of the light receiver installed in the fire detector 100.

The readjustment module is connected to the communication module 120 and the storage module, and periodically collects detection values of the amount of received light for the fire detectors 100 that manage it in a daily situation in which a fire does not occur, and detects the amount of received light. The set light intensity of the light emitter installed in the fire detector 100 is automatically readjusted so that the numerical value is maintained at a constant level.

More specifically, when the detection value of the received light amount is detected as a value smaller than the received light amount reference value set in the storage module, the readjustment module gradually increases the set light amount of the emitter so that the received light amount detection value reaches the received light amount reference value. let it

In addition, the readjustment module gradually reduces the set light amount of the light emitter so that the detection value of the received light amount reaches the received light amount reference value when the detected value of the received light amount is detected as a value greater than the received light amount reference value set in the storage module.

The power module is a power supply means for receiving power from the fire receiver 300 or a commercial power supply and supplying power to self-use and connection facilities.

The address setting module is a means for processing the self-address setting of the repeater 400, and may include a dip switch. Through this dip switch, the repeater 400 can set its own address in the form of a number. This address setting module adds a predetermined identification number before the fire information and response information are transmitted to the fire receiver 300. In this way, the relay module may add an address to the fire information and response information collected from the fire detector 100 managed through the address setting module, and then provide the address to the fire receiver 300.

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

100: fire detector 110: fire detection module
120: communication module 130: inspection module
140: management module 200: communication line
300: fire receiver 310: determination unit
320: fault checking unit 330: communication unit
340: notification unit 400: repeater

Claims (7)

A fire detection module that detects one or more fire elements and generates fire information including a real-time fire signal, a communication module that transmits the fire information generated from the fire detection module to a fire receiver, and a check signal through the communication module A plurality of photoelectric fire detectors including an inspection module that generates and transmits response information including smoke concentration, received light quantity, and set light quantity information when received;
a communication line connected to each fire detector, providing an inspection signal to the target fire detector, and returning response information provided from the fire detector; and
Receives fire information transmitted from each fire detector through the communication line, transmits an inspection signal to each fire detector through the communication line, receives response information to the inspection signal through the communication line, and receives each photoelectric fire Initial sensitivity is stored for each detector, real-time sensitivity is analyzed based on the response information, fire detectors whose ratio of real-time sensitivity to initial sensitivity is less than 30% to 60% are detected, and fire detectors with poor performance are selected and replaced. It includes a fire receiver that selects the detected fire detector as a replacement target fire detector and outputs alarm information including the installation location and current state value of the replacement target fire detector,
The fire detection module includes a smoke detection sensor, a light receiver, a light emitter, and a management module that analyzes the amount of light received detected by the light receiver and automatically adjusts the amount of light emitted by the light emitter so that the amount of received light is maintained at a constant level. A fire monitoring system capable of managing the lifespan of a photoelectric fire detector, characterized in that. delete delete delete delete delete According to claim 1,
It is connected to fire detectors distributed in each surveillance area, provides inspection signals received from fire receivers through the communication line to fire detectors that manage themselves, and provides response information collected from each fire detector to the fire receivers through the communication line. A fire monitoring system that can manage the lifespan of a photoelectric fire detector including a repeater that transmits to

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