KR102561528B1 - Fire monitoring system based on priority - Google Patents

Abstract

In the present invention, the risk grade according to the risk of human injury, the value of protected assets, the risk of chain explosion, etc. is set in advance for each area (S) of the industrial site, and at the same time, the corresponding area (S) is classified according to the risk level of each area (S). Priority levels are set for fire extinguishers, but in the event of a fire, fire extinguishers are operated in a differential manner according to the priority levels, so that prompt response to fire is possible and risk factors such as human casualties and chain explosions are reduced. It is possible to minimize the scale of damage caused by fire by blocking it in stages, and by setting the polling frequency of each fire detection sensor in proportion to the risk level of the corresponding area (S), It is possible to increase the accuracy and reliability of fire detection by detecting fire by space, and when a fire occurs, the controller first arranges the control order of fire extinguishers based on the priority class, and then fires with fire extinguishers of the same class. By performing secondary alignment according to the proximity to the location (P) to create a suppression process, the efficiency and speed of fire suppression can be increased, as well as the priority-based fire monitoring system that can more effectively reduce damage caused by fire. it's about

Description

Priority based fire monitoring system {Fire monitoring system based on priority}

The present invention relates to a priority-based fire monitoring system, and more specifically, to set risk levels in advance according to the risk of human damage, the value of protected assets, the risk of chain explosion, etc. for each area (S) of an industrial site. By setting the polling frequency of the fire detection sensor in proportion to the risk level of the corresponding area (S), and controlling the fire extinguisher to operate according to the priority proportional to the risk level of each area (S) in the event of a fire It relates to a priority-based fire monitoring system capable of increasing the accuracy and reliability of fire detection as well as minimizing the scale of damage caused by a fire even if a fire occurs.

Recently, with the development of electronic technology and the advancement of electronic components, facilities composed of a large number of complex wires and parts are scattered in various industrial fields, and accordingly, various problems such as overloading of parts, overheating, short circuit, and poor contact are scattered. Fire accidents are frequent.

Since these fire accidents can lead to large-scale casualties as well as direct and indirect damage to industrial sites, various studies are being conducted on fire monitoring systems to quickly detect and extinguish fires when a fire accident occurs.

A conventional fire monitoring system is composed of fire detection sensors installed in various places in an industrial site to detect a fire, and fire extinguishers for extinguishing a fire by spraying fire extinguishing agents and water upon detection of a fire.

In general, industrial sites have a certain space and are equipped with various types of facilities, and accordingly, the possibility of human casualties and protection depends on various causes such as design structure, utilization media, process media, and density It is characterized by the existence of various areas with high risk and low risk, such as asset value and serial explosion risk.

For example, in the case of a facility using gas or oil that activates fire as a medium, it can be set as a high-risk group with a high risk of human casualty and explosion in case of fire, and more precise fire monitoring for this high-risk group In addition, a preemptive response to the occurrence of a fire must be made.

However, conventional fire monitoring systems do not take into account the characteristics of zones with different levels of risk at all in industrial sites, so fire monitoring is conducted evenly regardless of the level of risk, and fire suppression is carried out evenly in the event of a fire. The scale of damage caused by fire increases, and the accuracy and reliability of fire monitoring are lowered.

1 is a block diagram showing a real-time fire detection and monitoring system disclosed in Korean Patent Registration No. 10-1175202 (Title of Invention: Real-time Fire Detection and Monitoring System).

The real-time fire detection and monitoring system (hereinafter referred to as the prior art) 100 of FIG. 1 includes a fire detection device 110, a monitoring server 120, and a related agency server 130.

The fire detection device 110 includes a sensor unit 111 composed of a plurality of sensors to detect whether or not a fire occurs in a target building, a relay 112 that receives real-time fire information from the sensor unit 111, and each is unique. The main controller 113 installed by floor or zone of the building to check the state of the sensor unit 111 with the address of the building, and the fire information transmitted from the main controller 113 by floor or zone are integrated and analyzed to control the entire building. It consists of a monitoring device 114 that transmits fire information and situation information to the integrated monitoring server.

At this time, the monitor device 114 detects at least one of smoke or flame detection information detected by the sensor unit 111, temperature rise information, information on the concentration of volatile substances in the air that rise abnormally for a short period of time, and information on harmful gases above the reference value. It is configured to determine that a fire has occurred, and to check an ignition point based on fire information and situation information about a point where a sensor unit that first detects a fire is located.

When the monitoring server 120 receives the fire information and situation information received from the fire detection device 110, it is analyzed and a warning level is set, and detailed information on the location and condition of the site is transmitted to the relevant authorities according to the warning level. The server 130 is notified.

The prior art 100 configured as described above has the advantage of being able to remotely monitor the fire detection and status information of each site, as well as to minimize damage caused by fire by enabling rapid response to the occurrence of fire.

However, since the prior art 100 does not have a configuration for calculating the risk of the industrial site in advance at all, no separate monitoring is performed for the high-risk group, resulting in low accuracy and reliability of fire monitoring.

In addition, since the prior art 100 does not have a configuration in which follow-up measures are made differentially according to the degree of risk, chain explosions and human accidents that can be blocked in advance cannot be prevented, resulting in an increase in the scale of damage. do.

In addition, the prior art 100 is suitable for monitoring the fire state of the site, but since the configuration of the fire extinguishing device for suppressing the fire that occurred at the site is not described, when a fire occurs, the fire suppression at the site is primarily Since this is not done, the speed and efficiency of fire suppression are reduced.

The present invention is to solve this problem, and the problem of the present invention is to set in advance the risk grade according to the risk of human injury, the value of protected assets, the risk of chain explosion, etc. for each area (S) of the industrial site, and at the same time According to the risk level of the area (S), a priority level is set for the fire extinguisher in the area (S), but in the event of a fire, the operation of the fire extinguisher is differentiated according to the priority level, so that prompt response to the fire can be achieved. This is to provide a priority-based fire monitoring system that can minimize the scale of damage caused by fire by primarily blocking risk factors such as human casualties and chain explosions as well as possible.

In addition, another problem of the present invention is to set the number of polling of each fire sensor to be proportional to the risk level of the corresponding area (S), thereby detecting the fire by space according to the risk level, which is the degree of risk after the fire. It is to provide a priority-based fire monitoring system that can increase the accuracy and reliability of detection.

In addition, another problem of the present invention is that the controller first arranges the control order of fire extinguishers based on the priority level when a fire occurs, and then determines the proximity to the fire occurrence location (P) for fire extinguishers of the same class. It is an object of the present invention to provide a priority-based fire monitoring system that can increase the efficiency and speed of fire suppression by creating a suppression process by performing secondary alignment according to the present invention, as well as more effectively reduce damage caused by fire.

The solution of the present invention for solving the above problems includes fire detection sensors installed for each predetermined area (S) of the industrial site, fire extinguishers installed for each area (S) to extinguish the fire, and a controller In the priority-based fire monitoring system, the controller includes a risk level setting unit that is executed every predetermined period (T) and sets a risk level of each area (S); A priority level proportional to the risk level of each area (S) by utilizing the risk level information for each area (S) set by the risk level setting unit and the location information of the fire extinguishers, which is executed every period (T) Priority setting unit for giving a fire extinguisher of the corresponding area (S); a fire occurrence determination unit for determining whether a fire has occurred by analyzing measurement values transmitted from the fire extinguishers; a suppression process generation unit that is executed when the fire determination unit determines that a fire has occurred and generates a suppression process representing a control sequence of each fire extinguisher according to a priority level set by the priority setting unit; and a fire extinguisher control unit for transmitting fire suppression data to the fire extinguishers according to the sequence of the suppression process generated by the suppression process generation unit, wherein the risk level setting unit includes at least one of a possibility of life damage, a protected asset value, and a chain explosion risk. Considering one or more, the risk level of each area (S) is set, and when the fire occurrence determination unit determines that a fire has occurred, outputs information on the location (P) of the fire to the suppression process generation unit, When the suppression process generation unit creates the suppression process, after determining the control order of each fire extinguisher according to the priority level set by the priority setting unit, the fire extinguishers of the same priority level are ordered in an adjacent order from the location where the fire occurred. to determine the control sequence of fire extinguishers of the same priority level in the upper order to create a suppression process, and the suppression process generating unit extracts the priority level for each fire extinguisher set by the priority setting unit Priority class extraction module ; a fire occurrence location information input module that receives fire occurrence location (P) information from the fire occurrence determination unit; a priority-based fire extinguisher sorting module for arranging the list of fire extinguishers in the order of priority of each fire extinguisher; Using the previously set location information of each fire extinguisher and the fire occurrence location (P) input by the fire occurrence location information input module, the proximity (Δd) of each fire extinguisher is calculated from the fire occurrence location (P). Proximity calculation module for each fire extinguisher; Using the proximity (Δd) calculated by the proximity calculation module for each fire extinguisher, among the list sorted by the priority-based fire extinguisher sorting module, fire extinguishers of the same priority level have a proximity (Δd). A location-based fire extinguisher sorting module that sorts in order of proximity; A suppression process generation module for generating a suppression process according to the order arranged by the location-based fire extinguisher alignment module, wherein the controller is executed every period T and each area S set by the danger level setting unit ) and the location information of each fire extinguisher, and a polling-count setting unit for setting the polling-count of each fire extinguisher in proportion to the risk grade of the corresponding area (S).

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In addition, in the present invention, the fire detection sensor includes a flame detection sensor and a temperature detection sensor, and the controller further includes a measurement value analyzer that analyzes medium-measured values transmitted from the fire detection sensor, and determines whether the fire occurs. An analysis data input module receiving analysis data detected by the analysis value measurement unit; a flame detection determination module for determining whether a flame has been detected by each flame detection sensor by utilizing the analysis data of the flame detection sensor input through the analysis data input module; It is executed when it is determined that the flame is detected by the flame detection determination module, and the first elapsed time (ΔT1) is measured using a timer, but the flame detection determination module determines that the flame is not detected by the corresponding flame detection sensor. a first elapsed time measurement module for measuring a first elapsed time (ΔT1) until the determination is made; The first elapsed time (ΔT1) by the first elapsed time measurement module is compared with a preset first set value (TH1, Threshold1), and 1) the first elapsed time (ΔT1) is the first set value (TH1). ), it is determined (error) that a flame has been detected due to a temporary error or failure of the corresponding flame detection sensor, and no separate operation is performed. 2) The first elapsed time ΔT1 is the first set value TH1 ) or more, a first determination module for determining that the flame detection was normally performed by the corresponding flame detection sensor; Using the analysis data of the temperature sensor input through the analysis data input module, whether the temperature-measured value measured by each temperature sensor is equal to or greater than a preset threshold is compared, and if the temperature-measured value is greater than or equal to the threshold, the corresponding An abnormal temperature determination module for determining that an abnormal temperature has occurred in the temperature sensor; It is executed when it is determined that the abnormal temperature has occurred in the abnormal temperature determination module, and the second elapsed time (ΔT2) is measured using a timer, and the abnormal temperature occurrence determination module detects the abnormal temperature in the corresponding temperature sensor. a second elapsed time measurement module for measuring a second elapsed time (ΔT2) until it is determined that no has occurred; The second elapsed time (ΔT2) by the second elapsed time measuring module is compared with a preset second set value (TH2, Threshold2), and 1) the second elapsed time (ΔT2) is the second set value (TH2). ), it is determined (error) that an abnormal temperature has occurred due to a temporary error or failure of the corresponding temperature sensor, and no separate operation is performed. ), a second determination module for determining that the temperature measurement was normally performed by the corresponding temperature sensor; When the first determination module determines that the flame detection has been performed normally and at the same time the second determination module determines that the temperature measurement has been performed normally, a fire occurs to finally determine that a fire has occurred in the corresponding detection area (S). It is preferable to include a final determination module.

According to the present invention having the above problems and solving means, the risk grade according to the risk of human injury, the value of protected assets, the risk of chain explosion, etc. for each area (S) of the industrial site is set in advance, and the risk of each area (S) A priority level is set for the fire extinguisher in the corresponding area (S) according to the level, but in the event of a fire, the operation of the fire extinguisher is differentiated according to the priority level. It is possible to minimize the scale of damage caused by fire by first blocking risk factors such as chain explosions.

In addition, according to the present invention, by setting the polling frequency of each fire detection sensor in proportion to the risk level of the corresponding area (S), the fire is detected for each space according to the risk level, which is the degree of risk after the fire, and the accuracy of fire detection and reliability can be increased.

In addition, according to the present invention, when a fire occurs, the controller firstly arranges the control order of fire extinguishers based on the priority class, and then secondarily sorts the fire extinguishers of the same class according to the proximity to the fire occurrence location (P). By creating a suppression process by performing a fire suppression process, it is possible to increase the efficiency and speed of fire suppression, as well as to reduce damage caused by fire more effectively.

1 is a block diagram showing a real-time fire detection and monitoring system disclosed in Korean Patent Registration No. 10-1175202 (Title of Invention: Real-time Fire Detection and Monitoring System).
2 is a configuration diagram showing a priority-based fire monitoring system according to an embodiment of the present invention.
FIG. 3 is a block diagram illustrating the controller of FIG. 2 .
FIG. 4 is a block diagram illustrating a suppression process generation unit of FIG. 3 .
FIG. 5 is a block diagram illustrating a fire determination unit of FIG. 3 .

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

2 is a configuration diagram showing a priority-based fire monitoring system according to an embodiment of the present invention.

Priority-based fire monitoring system 1, which is an embodiment of the present invention, sets risk levels in advance according to the risk of human damage, the value of protected assets, the risk of chain explosion, etc. for each area (S) of an industrial site, and at the same time, each fire Polling of the detection sensor sets the frequency in proportion to the risk level of the corresponding area (S), and in case of fire, it controls the fire extinguisher to operate according to the priority proportional to the risk level of each area (S). Not only can the accuracy and reliability of detection be increased, but even if a fire occurs, it is to minimize the scale of damage caused by a fire.

In addition, as shown in FIG. 2, the priority-based fire monitoring system 1 of the present invention is installed in various places in the industrial site 900 and measures media for determining whether a fire occurs in a pre-allocated area S. When fire detection data is received from the fire detection sensors 5 that transmit this to the controller 3 described later and the controller 3 installed in each area S and described later, the stored fire extinguishing agent is injected to extinguish the fire Fire extinguishers 7, fire detection sensors 5, and a controller 3 that manages and controls the operation of the fire extinguishers 7, the controller 3, the fire detection sensors 5, and the fire extinguishers 7 It consists of a bus 10 that supports wireless communication between

The bus 10 provides a wireless data movement path between the controller 3, the fire detection sensors 5 and the fire extinguishers 7. At this time, the bus 10 may be composed of a network such as Bluetooth, Wifi, Zig-bee, NFC (Near Field Communication), RFID (Radio Frequency Identification), and in detail, LoRa It is preferable to be composed of a network (LoRa).

That is, the fire detection sensors 5 and fire extinguishers 7 of the present invention are designed to enable wireless communication with the controller 3 by connecting to the bus 10 of the lora network.

At this time, a gateway is connected to the controller 3 of the present invention, and 'END-NODE' is connected to each fire detection sensor 5 and each fire extinguisher 70, so that the controller 3 uses the roller network 10 It inputs and outputs END-NODEs and data by channel.

The fire detection sensors (5) are installed for each predetermined area (S) of the industrial site to measure the medium that can determine whether a fire has occurred, and then transmit the detected medium-measured value to the controller (3) through the bus (10). ) is sent to

At this time, the fire detection sensor 5 is composed of a flame detection sensor, a temperature detection sensor, a smoke-detection sensor, a light-sensor, a harmful gas-detection sensor, an air quality-detection sensor, etc., which are commonly used as sensors for detecting fire. It can be.

For example, assuming that the fire detection sensor 5 is a temperature sensor, the temperature sensor measures the temperature of a medium to be measured and transmits the detected temperature-measured value to the controller 3 .

In addition, the fire detection sensors 5 may be installed in facilities that are difficult to access, such as structures or vents such as facilities.

In addition, when the fire detection sensors 5 receive polling-count information from the controller 3 at every predetermined period T, input/output data with the controller 3 according to the received polling-count.

At this time, the controller 3 sets the risk level for each area (S) of the industrial site in consideration of the risk of human damage, the value of protected assets, the risk of chain explosion, etc., and fires installed in the area (S) according to the set risk level. After setting the polling frequency of the detection sensor 5, the set polling frequency information is transmitted to each fire detection sensor 5.

For example, the controller 3 sets the polling frequency of the fire detection sensor in the high-risk area higher than that of the fire detection sensor in the low-risk area, so that fire monitoring in the high-risk area can be performed more precisely.

In addition, the fire detection sensor 5 is connected to the bus 10 and has a communication interface capable of transmitting and receiving data to and from the controller 3 .

When the fire extinguishers 7 are installed in each area S and receive fire suppression data from the controller 3, the fire extinguishing agent stored in the pre-allocated area S is sprayed to achieve primary suppression of the fire.

At this time, it is preferable that the fire extinguishers 7 are installed adjacent to the fire detection sensor 5 in the pre-allocated area S.

In addition, the fire extinguishers 7 are connected to the bus 10 and have a communication interface capable of transmitting and receiving data to and from the controller 3 .

At this time, when setting the risk level of each area (S), the controller 3 sets the priority level of each fire extinguisher 7 in proportion to the risk level of the area (S), and when a fire is detected, the preset priority level By controlling the operation of the fire extinguishers 7 by creating a suppression process including a fire extinguisher control sequence according to the fire suppression of the fire extinguisher 7 in the area (S) with a high risk level, human accidents, chain explosions, etc. By blocking in advance, the scale of damage caused by fire can be minimized.

FIG. 3 is a block diagram illustrating the controller of FIG. 2 .

As shown in FIG. 3, the controller 3 includes a control unit 30, a memory 31, a communication interface unit 32, a risk level setting unit 33, a priority setting unit 34, polling-count It consists of a setting unit 35, a measurement value analysis unit 36, a fire occurrence determination unit 37, a suppression process generation unit 38, and a fire extinguisher control unit 39.

The control unit 30 is an O.S (Operating System) of the controller 3, and the control target 31, (32), (33), (34), (35), (36), (37), (38) , manages and controls (39).

In addition, the control unit 30 executes the risk level setting unit 33, the priority setting unit 34, and the polling-number setting unit 35 for each preset period T, and the risk level setting unit 33, Risk level information of each area (S), priority level of each fire extinguisher (7), and polling-number information of each fire detection sensor (5) by the priority setting unit (34) and polling-number setting unit (35) are set, they are stored in the memory 31.

At this time, when the polling-count information of each fire detection sensor 5 is set by the polling-count setting unit 35, the control unit 30 transmits the polling-count information set to each fire detection sensor 5 through a communication interface. Control section 32.

In addition, when the control unit 30 receives medium-measured values from the fire detection sensors 5 through the communication interface unit 32, it inputs the received medium-measured values to the measurement value analysis unit 36.

In addition, the control unit 30 executes the suppression process generation unit 38 when it is determined that a fire has occurred by the fire occurrence determination unit 37, and when a suppression process is generated by the suppression process generation unit 38, it is generated. The suppression process is input to the fire extinguisher control unit 39.

The location and communication identification information of each fire detection sensor 5 and the location and communication identification information of each fire extinguisher 7 are preset and stored in the memory 31 .

In addition, the memory 31 includes the risk level information of each area S set by the risk level setting unit 33, the priority level setting unit 34, and the polling-number setting unit 35, and the priority of each fire extinguisher 7. The ranking rank and polling-count information of each fire detection sensor 5 are stored.

The communication interface unit 32 transmits and receives data to and from the fire detection sensors 5 and fire extinguishers 7 .

The risk level setting unit 33 is executed every predetermined cycle (T) under the control of the control unit 30, and sets the risk level of each of the predetermined areas (S) in which the industrial site is divided into a plurality of parts.

At this time, the risk level setting can be made by the manager, and the manager considers the risk of human injury, the value of protected assets, the risk of chain explosion, etc. at the place where each fire sensor 5 is installed, and the risk level of each fire sensor 5 can be set.

For example, the risk grade can be classified into 5 stages from 'A' to 'F', and the manager considers the risk of human damage, the value of protected assets, and the risk of chain explosion in the place, and the fire detection sensor (5 ) can be set to one of five levels.

In addition, the risk level information for each area (S) set by the risk level setting unit 33 is stored in the memory 31 under the control of the control unit 30, and at the same time the priority setting unit 34 and the polling-number setting unit It is entered as (35).

Like the risk level setting unit 33, the priority setting unit 34 is executed every preset period T according to the control of the control unit 30.

In addition, the priority setting unit 34 sets the priority level of each fire extinguisher by utilizing the risk level information for each area (S) input from the risk level setting unit 33 and the location information of each fire extinguisher.

At this time, the priority grade of each fire extinguisher 7 means the order in which fire is extinguished when a fire occurs, and may be set in proportion to the risk grade of the installed area (S).

For example, the priority setting unit 34 may set the fire extinguisher 7 installed in the high-risk area S having the highest risk level as the highest priority.

That is, when the priority setting unit 34 receives the risk level information for each area (S) from the risk level setting unit 33, the location information of the fire extinguishers 7 is used to determine the area where each fire extinguisher 7 is installed. Set the priority level according to the risk level.

Like the risk level setting unit 33 and the priority setting unit 34, the polling-count setting unit 35 is executed every preset period T according to the control of the control unit 30.

In addition, the polling-count setting unit 35 utilizes the risk level information for each area (S) set by the risk level setting unit 33 and the location information of each fire sensor, Polling - Set the number of times.

At this time, the polling frequency of each fire detection sensor 5 is set to increase as the risk level of the corresponding area S increases.

That is, the number of pollings of the fire detection sensors 5 is set to be smaller as the risk level of the corresponding area (S) is lower, but the number of pollings is set to be larger as the level of danger is higher.

At this time, the control unit 30 stores the polling-number information for each fire detection sensor 5 set by the polling-number setting unit 35 in the memory 31 and simultaneously controls the communication interface unit 32 to detect each fire Corresponding polling-count information is transmitted to the sensor 5.

That is, in the present invention, in the case of the fire detection sensor 5 of the high-risk group, the polling frequency is set high, but in the case of the fire detection sensor 5 of the low-risk group, the polling frequency is set low, and accordingly, the controller 3 The medium-measured values are received from the fire detection sensors 5 of the low-risk group at a relatively slow cycle, but the medium-measured values are received at a relatively fast cycle from the fire detection sensors 5 of the high-risk group. Fire monitoring is done in a differential manner, so that the accuracy and reliability of fire monitoring can be increased.

The measured value analysis unit 36 analyzes the medium-measured values transmitted from the fire detection sensor 5 .

At this time, the analysis data detected by the measurement value analyzer 36 is input to the fire determination unit 37 .

The fire occurrence determination unit 37 utilizes the analysis data input from the measurement value analysis unit 36 to determine whether a fire has occurred in the industrial site.

For example, when the fire detection sensor 5 is a temperature sensor, the fire occurrence determination unit 37 determines that a fire has occurred in an industrial site if there is a temperature-measured value greater than a predetermined threshold among temperature-measured values. and if the fire detection sensor 5 is a gas detection sensor, the fire occurrence determination unit 37 determines whether there is a gas-measured value greater than or equal to a predetermined threshold value among the gas-measured values, if there is a fire at the industrial site. can be judged to have occurred.

At this time, since the technology and configuration for determining whether a fire has occurred by using the value measured by the sensor is a commonly used technology in a fire monitoring system, a detailed description thereof will be omitted.

In addition, if it is determined that a fire has occurred, the fire determination unit 37 inputs information on a location where a fire has occurred to the suppression process generation unit 38 . At this time, the control unit 30 executes the suppression process generation unit 38 when it is determined that a fire has occurred by the fire occurrence determination unit 37 .

FIG. 4 is a block diagram illustrating a suppression process generation unit of FIG. 3 .

The suppression process generation unit 38 of FIG. 4 is executed under the control of the control unit 30 when the fire determination unit 37 determines that a fire has occurred.

In addition, as shown in FIG. 4, the suppression process generation unit 38 includes a priority level extraction module 381, a fire location input module 382, a priority-based fire extinguisher sorting module 383, and adjacent fire extinguishers. It consists of a degree calculation module 384, a location-based fire extinguisher alignment module 385, and a suppression process generation module 386.

The priority level extraction module 381 searches the memory 31 and extracts the priority level for each fire extinguisher 7 set and registered by the priority setting unit 34 from the memory 31 .

The fire occurrence location input module 382 receives fire occurrence location information, which is a location where a fire occurred, from the fire occurrence determination unit 37 .

The priority-based fire extinguisher sorting module 383 sorts a list of fire extinguishers 7 according to the order of the priority level extracted by the priority level extraction module 381. That is, the priority-based fire extinguisher sorting module 383 aligns fire extinguishers 7 with a high priority level at the top and extinguishers 7 with a low priority level at the bottom.

At this time, since the priority-based fire extinguisher sorting module 383 sorts the list of fire extinguishers 7 according to the priority level, fire extinguishers having the same priority level are arranged in the same position.

The proximity calculation module 384 for each fire extinguisher uses the location information of each fire extinguisher 7 previously set and the fire location P input through the fire location input module 382 to determine the location of the fire (P). ) calculates the proximity (Δd) of each fire extinguisher. At this time, the degree of proximity (Δd) means the distance difference between each fire extinguisher from the location P where the fire occurred.

The location-based fire extinguisher sorting module 385 utilizes the degree of proximity (Δd) calculated by the proximity calculation module 384 for each fire extinguisher, among the lists sorted by the priority-based fire extinguisher sorting module 383, the same Fire extinguishers of the priority level are arranged in the order of proximity (Δd).

For example, assuming that there are 4 fire extinguishers having the same priority level, the 4 fire extinguishers are sorted in the same order by the priority-based fire extinguisher sorting module 383, but the proximity calculation module 384 for each fire extinguisher As a result, the proximity (Δd) is sorted in the order of proximity.

That is, in the present invention, the order for operating the fire extinguisher 7 is determined primarily according to the priority level, but only for fire extinguishers of the same level, it is determined according to the degree of proximity (Δd) to the fire occurrence location P. The damage caused by fire can be minimized.

The suppression process generation module 386 generates a suppression process in which the fire suppression of each fire extinguisher 7 is performed according to the order arranged by the position-based fire extinguisher sorting module 385 .

At this time, the control unit 30 inputs the suppression process generated by the suppression process generating module 386 to the fire extinguisher control unit 39.

The fire extinguisher control unit 39 transmits fire suppression data to each fire extinguisher 5 according to the suppression process input from the suppression process generation unit 38, thereby optimizing the operation sequence of the fire extinguishers 7 when a fire occurs to prevent fire damage. damage can be effectively reduced.

5 is a block diagram showing a fire determination unit.

The fire detection unit 37 of FIG. 5 is applied when the fire detection sensor 5 of each area S is composed of a flame detection sensor and a temperature detection sensor.

As shown in FIG. 5, the fire determination unit 37 includes an analysis data input module 371, a flame detection determination module 372, a first elapsed time measurement module 373, and a first determination module ( 374), an abnormal temperature occurrence determination module 375, a second elapsed time measurement module 376, a second determination module 377, and a fire occurrence final determination module 378.

The analysis data input module 371 receives analysis data input from the measurement value analysis unit 36 .

In addition, the analysis data input module 371 inputs the analysis data of the flame detection sensor to the flame detection determination module 372, and inputs the analysis data of the temperature detection sensor to the heat determination module 375.

The flame detection determination module 372 utilizes the analysis data of the flame detection sensor input through the analysis data input module 371 to determine whether a flame has been detected by the flame detection sensor 51 .

In addition, the flame detection determination module 372 1) if it is determined that the flame is detected by the flame detection sensor 51, the first elapsed time measurement module 373 is executed, and 2) if the flame detection sensor 51 If it is determined that the flame is not detected, a separate operation is not performed.

The first elapsed time measurement module 373 is executed when it is determined that a flame is detected by the flame detection determination module 372 and measures the first elapsed time ΔT1 using a timer.

At this time, the first elapsed time measurement module 373 measures the first elapsed time ΔT1 until the flame is not detected by the flame detection detection module 372 .

That is, the first elapsed time ΔT1 means an elapsed time in which the flame is continuously sensed.

The first determination module 374 compares the first elapsed time ΔT1 measured by the first elapsed time measurement module 373 with a preset first set value TH1 (Threshold1). At this time, the first set value TH1 means the maximum value of the first elapsed time ΔT1 at which it can be determined that the flame detection sensor has detected a flame due to a temporary error or failure.

In addition, the first determination module 374 1) determines (error) that a flame is detected due to a temporary error or failure of the flame detection sensor when the first elapsed time ΔT1 is less than the first set value TH1, A separate operation is not performed, but 2) if the first elapsed time ΔT1 is equal to or greater than the first set value TH1, the flame detection sensor determines that the flame detection has been performed normally.

The abnormal temperature determination module 375 utilizes the analysis data of the temperature sensor 53 input through the analysis data input module 371, and the temperature-measured value measured by the temperature sensor 53 is set in advance. Compare whether it is above the threshold.

In addition, the abnormal temperature occurrence determination module 375 determines that an abnormal temperature has occurred if the temperature-measured value is greater than or equal to a threshold value.

In addition, the abnormal temperature occurrence determination module 375 1) if it is determined that the abnormal temperature has occurred, the second elapsed time measurement module 376 is executed, and 2) if it is determined that the abnormal temperature has not occurred, a separate operation is performed. does not perform

The second elapsed time measurement module 376 is executed when it is determined that the abnormal temperature has occurred in the abnormal temperature determination module 375, and measures the second elapsed time ΔT2 using a timer.

At this time, the second elapsed time measurement module 376 measures the second elapsed time ΔT2 until the abnormal temperature determination module 375 determines that no abnormal temperature has occurred.

That is, the second elapsed time ΔT2 means the elapsed time when it is determined that the abnormal temperature has continuously occurred.

The second determination module 377 compares the second elapsed time ΔT2 measured by the second elapsed time measurement module 376 with a preset second set value TH2 (Threshold2). At this time, the second set value TH2 means the maximum value of the second elapsed time ΔT2 at which the temperature sensor 53 can determine that an abnormal temperature has occurred due to a temporary error or failure.

In addition, the second determination module 377 1) determines (error) that an abnormal temperature has occurred due to a temporary error or failure of the temperature sensor when the second elapsed time (ΔT2) is less than the second set value (TH2), A separate operation is not performed, but 2) if the second elapsed time (ΔT2) is equal to or greater than the second set value (TH2), the temperature sensor determines that the temperature has been measured normally.

The final determination module 378 determines whether or not a fire has occurred 1) when the first determination module 374 determines that the flame detection has been performed normally, and 2) when the second determination module 377 determines that the temperature measurement has been performed normally, It is finally determined that a fire has occurred in the corresponding detection area (S).

In other words, the fire occurrence final determination module 378 determines whether 1) the first elapsed time ΔT1 is greater than or equal to the first set value TH1 by the first determination module 374, and 2) the second determination module In step 377, when the second elapsed time ΔT2 is equal to or greater than the second set value TH2, it is determined that a fire occurs in the corresponding detection area S.

That is, the fire occurrence determination unit 37 of the present invention, as shown in FIG. 5 , when the first elapsed time ΔT1, which is the elapsed time when the flame is detected by the flame sensor, is greater than or equal to the first set value TH1 , When the second elapsed time (ΔT2), which is the elapsed time when the abnormal temperature is measured in the temperature sensor, is greater than the second set value (TH2), each sensor ( In 51) and (53), even if a flame is detected or an abnormal temperature occurs due to a temporary error or failure, these errors and failures are not detected through this verification work using the first and second set values (TH1, TH2). It is possible to significantly reduce damage caused by malfunction of the fire extinguishers (7) by checking.

For example, when a phenomenon in which a flame is detected due to a temporary error or failure in a flame detection sensor or a temperature detection sensor occurs, conventionally, it is mistakenly recognized as a fire, and the fire extinguishers 7 operate, resulting in increased damage, In the present invention, the fire occurrence determination unit 37 compares the first and second elapsed times (ΔT1, ΔT2) with the preset set values (TH1, TH2), respectively, to finally determine the occurrence of a fire, so the flame is detected. Even if a temporary error or failure of the sensor or temperature sensor occurs, it can be checked to determine that no fire has occurred, thereby significantly reducing damage caused by malfunction of the fire extinguisher 7 in the prior art. have

As described above, the priority-based fire monitoring system 1, which is an embodiment of the present invention, presets the risk level according to the risk of human damage, the value of protected assets, the risk of chain explosion, etc. for each area (S) of the industrial site in advance, and at the same time According to the risk level of each area (S), a priority level is set for the fire extinguisher in the area (S), but in the event of a fire, the operation of the fire extinguisher is differentiated according to the priority level to quickly respond to the fire. In addition, it is possible to minimize the scale of damage caused by fire by first blocking risk factors such as human casualties and chain explosions.

In addition, the priority-based fire monitoring system 1 of the present invention sets the number of polling of each fire detection sensor in proportion to the risk level of the corresponding area (S), so that the space is spaced according to the risk level, which is the risk level that will occur after a fire. It is possible to increase the accuracy and reliability of fire detection by detecting fire by each.

In addition, the priority-based fire monitoring system 1 of the present invention first arranges the control order of fire extinguishers based on the priority level when a fire occurs, and then, for fire extinguishers of the same class, By performing secondary sorting according to the degree of proximity to create a suppression process, the efficiency and speed of fire suppression can be increased, and damage caused by fire can be more effectively reduced.

1: Priority-based fire monitoring system 3: Controller
5: fire detection sensor 7: fire extinguisher
10: bus 30: control unit
31: memory 32: communication interface unit
33: risk level setting unit 34: priority level setting unit
35: pooling-number setting unit 36: measurement value analysis unit
37: Fire determination unit 38: Suppression process generation unit
39: fire extinguisher control unit 381: priority level calculation module
382: fire location input module 383: priority-based fire extinguisher sorting module
384: Proximity calculation module for each fire extinguisher 385: Location-based fire extinguisher sorting module
386: suppression process generation module

Claims (6)

In a priority-based fire monitoring system including fire detection sensors installed for each predetermined area (S) of an industrial site, fire extinguishers installed for each area (S) to extinguish a fire, and a controller:
The controller
A risk level setting unit that is executed every preset period (T) to set the risk level of each area (S);
A priority level proportional to the risk level of each area (S) by utilizing the risk level information for each area (S) set by the risk level setting unit and the location information of the fire extinguishers, which is executed every period (T) Priority setting unit for giving a fire extinguisher of the corresponding area (S);
a fire occurrence determination unit for determining whether a fire has occurred by analyzing measurement values transmitted from the fire extinguishers;
a suppression process generation unit that is executed when the fire determination unit determines that a fire has occurred and generates a suppression process representing a control sequence of each fire extinguisher according to a priority level set by the priority setting unit;
And a fire extinguisher control unit for transmitting fire suppression data to the fire extinguishers according to the sequence of the suppression process generated by the suppression process generating unit,
The risk level setting unit
Considering at least one of the possibility of human casualties, the value of protected assets, and the risk of chain explosion, set the risk level of each area (S),
The fire occurrence determination unit
When it is determined that a fire has occurred, outputting information on the location (P) of the fire to the suppression process generator,
The suppression process generation unit
When creating a suppression process, after determining the control order of each fire extinguisher according to the priority level set by the priority setting unit, with respect to fire extinguishers of the same priority level, the order adjacent to the location where the fire occurred is in the upper order Determining the control sequence of fire extinguishers of the same priority class to create a suppression process,
The suppression process generation unit
a priority level extraction module for extracting a priority level for each fire extinguisher set by the priority setting unit;
a fire occurrence location information input module that receives fire occurrence location (P) information from the fire occurrence determination unit;
a priority-based fire extinguisher sorting module for sorting the list of fire extinguishers according to the order of priority levels for each fire extinguisher;
Using the previously set location information of each fire extinguisher and the fire occurrence location P input by the fire occurrence location information input module, each fire extinguisher's proximity (Δd) is calculated from the fire occurrence location P. Proximity calculation module for each fire extinguisher;
Using the proximity (Δd) calculated by the proximity calculation module for each fire extinguisher, among the list sorted by the priority-based fire extinguisher sorting module, fire extinguishers of the same priority level have a proximity (Δd). A location-based fire extinguisher sorting module that sorts in order of proximity;
A suppression process generating module for generating a suppression process according to the order sorted by the location-based fire extinguisher sorting module,
The controller
It is executed every period (T) and uses the risk level information for each area (S) set by the risk level setting unit and the location information of each fire extinguisher, and polling-count of each fire extinguisher is determined in the corresponding area (S ) The priority-based fire monitoring system, characterized in that it further comprises a polling-number setting unit that is set in proportion to the risk rating. delete delete delete delete The method of claim 1, wherein the fire detection sensor comprises a flame detection sensor and a temperature detection sensor,
The controller
Further comprising a measurement value analysis unit for analyzing the medium-measured values transmitted from the fire detection sensor,
The fire occurrence determination unit
an analysis data input module receiving analysis data detected by the measurement value analysis unit;
a flame detection determination module for determining whether a flame has been detected by each flame detection sensor by utilizing the analysis data of the flame detection sensor input through the analysis data input module;
It is executed when it is determined that the flame is detected by the flame detection determination module, and the first elapsed time (ΔT1) is measured using a timer, but the flame detection determination module determines that the flame is not detected by the corresponding flame detection sensor. a first elapsed time measurement module for measuring a first elapsed time (ΔT1) until the determination is made;
The first elapsed time (ΔT1) by the first elapsed time measurement module is compared with a preset first set value (TH1, Threshold1), and 1) the first elapsed time (ΔT1) is the first set value (TH1). ), it is determined (error) that a flame has been detected due to a temporary error or failure of the corresponding flame detection sensor, and no separate operation is performed. 2) The first elapsed time ΔT1 is the first set value TH1 ) or more, a first determination module for determining that the flame detection was normally performed by the corresponding flame detection sensor;
Using the analysis data of the temperature sensor input through the analysis data input module, whether the temperature-measured value measured by each temperature sensor is equal to or greater than a preset threshold is compared, and if the temperature-measured value is greater than or equal to the threshold, the corresponding An abnormal temperature determination module for determining that an abnormal temperature has occurred in the temperature sensor;
It is executed when it is determined that the abnormal temperature has occurred in the abnormal temperature determination module, and the second elapsed time (ΔT2) is measured using a timer, and the abnormal temperature occurrence determination module detects the abnormal temperature in the corresponding temperature sensor. a second elapsed time measurement module for measuring a second elapsed time (ΔT2) until it is determined that no has occurred;
The second elapsed time (ΔT2) by the second elapsed time measuring module is compared with a preset second set value (TH2, Threshold2), and 1) the second elapsed time (ΔT2) is the second set value (TH2). ), it is determined (error) that an abnormal temperature has occurred due to a temporary error or failure of the corresponding temperature sensor, and no separate operation is performed. ), a second determination module for determining that the temperature measurement was normally performed by the corresponding temperature sensor;
When the first determination module determines that the flame detection has been performed normally and at the same time the second determination module determines that the temperature measurement has been performed normally, a fire occurs to finally determine that a fire has occurred in the corresponding detection area (S). A priority-based fire monitoring system comprising a final determination module.