KR102501053B1 - Complex fire detector and fire monitoring system comprising the same - Google Patents

Abstract

The present invention relates to a composite fire detector and a fire monitoring system including the same.
The composite fire detector according to the present invention includes a temperature sensor for detecting temperature and transmitting a temperature detection signal, a flame sensor for detecting flame and transmitting a flame detection signal, and a smoke sensor for detecting smoke and transmitting a smoke detection signal. And, it is configured to include a control unit that determines whether a fire has occurred by complexly analyzing detection signals transmitted by sensors constituting the sensor unit, and a communication unit that performs communication with the outside under the control of the control unit.
According to the present invention, by complexly analyzing the data collected through various sensors installed at the surveillance site according to the criteria set appropriately for the environment of the surveillance site, the accuracy and reliability of the determination of whether a fire has occurred can be improved. It works.

Description

Complex fire detector and fire monitoring system including the same {COMPLEX FIRE DETECTOR AND FIRE MONITORING SYSTEM COMPRISING THE SAME}

The present invention relates to a composite fire detector and a fire monitoring system including the same. More specifically, the present invention is to improve the accuracy and reliability of judgment on whether or not a fire has occurred by complexly analyzing data collected through various sensors installed at the surveillance site according to criteria set appropriately for the environment of the surveillance site. It relates to a complex fire detector and a fire monitoring system including the same.

In general, facilities such as buildings are equipped with firefighting equipment in preparation for a fire situation. Here, the firefighting equipment refers to equipment necessary for firefighting, the installation of which is mandated by firefighting-related laws and regulations.

These types of firefighting equipment include fire extinguishing equipment to directly extinguish fire, alarm equipment to detect and notify fire in case of fire or to engage in fire extinguishing activities, evacuation equipment used to prevent loss of life in case of fire, There are fire extinguishing water facilities for storing fire extinguishing water necessary for fire suppression and fire extinguishing activity facilities for carrying out fire extinguishing activities in the event of a fire.

In addition, in order to check the presence of abnormalities in firefighting equipment, firefighting equipment installed in facilities such as buildings is regularly checked by the local fire department once or twice a year in accordance with the Framework Act on Fire Protection and the Act on Installation, Maintenance and Safety Management of Firefighting Equipment. The management of firefighting equipment is carried out by conducting inspections.

However, due to manpower and costs for the operation and management of firefighting equipment, the management of facilities such as buildings is not normally performed properly, and the inspection of firefighting equipment installed in facilities such as buildings by the fire station is also not regular, but at a specific time There is a limit to determining whether or not there is an abnormality in the firefighting equipment.

In addition, in the case of a conventional fire monitoring system, when a plurality of sensors installed in facilities such as buildings detect and operate a fire, a fire receiving panel connected to the plurality of sensors operates. Whether or not a fire has occurred is determined, but there is a problem in that it is difficult to distinguish between a case in which the sensor operates and a case in which the sensor malfunctions according to actual fire occurrence situations.

In addition, the conventional fire monitoring system is configured to determine whether a fire has occurred by collecting fire-related data from various types of sensors for detecting a fire, but in determining the fire, the characteristics of the data and the characteristics of the fire monitoring site There is a problem in that the reliability of fire judgment is low because it does not reflect the

Korean Patent Publication No. 10-2010-0053128 (published on May 20, 2010, name: network-based fire monitoring system)

A technical problem of the present invention is to provide a complex fire detector and a fire monitoring system including the same that can improve the reliability and speed of determining whether or not a fire has occurred.

In addition, the present invention can improve the accuracy and reliability of judgment on whether or not a fire has occurred by complexly analyzing data collected through various sensors installed at the surveillance site according to criteria set appropriately for the environment of the surveillance site. It is a technical challenge to provide a composite fire detector and a fire monitoring system including the same.

In addition, the present invention primarily determines whether a fire has occurred based on the data collected from the sensors, and secondarily allows the manager to check the fire scene through related images, thereby improving the accuracy of judgment on whether or not a fire has occurred. It is a technical task to provide a complex fire detector that can improve and a fire monitoring system including the same.

A complex fire detector according to the present invention for solving these technical problems is a temperature sensor for detecting temperature and transmitting a temperature detection signal, a flame sensor for detecting a flame and transmitting a flame detection signal, and a smoke detection signal for transmitting a smoke detection signal. A sensor unit including a smoke sensor that controls the sensor unit, a control unit that determines whether a fire has occurred by complexly analyzing detection signals transmitted by sensors constituting the sensor unit, and a communication unit that communicates with the outside under the control of the control unit. can include Here, the controller generates collected data for each detection signal by assigning weights to detection signals transmitted by sensors constituting the sensor unit, and determines whether one of the collected data for each detection signal is a fire determination for each detection signal set in advance. If the standard value is exceeded, it can be determined that a fire has occurred. In addition, the control unit generates collected data for each detection signal by assigning weights to detection signals transmitted by sensors constituting the sensor unit, and a value obtained by summing the collected data for each detection signal is a preset complex fire determination standard value. If it exceeds, it can be judged that a fire has occurred. The sensor unit may further include a humidity sensor that detects humidity and transmits a humidity detection signal, and the control unit assigns weights to detection signals transmitted by the temperature sensor, the flame sensor, and the smoke sensor to transmit the detection signal. The humidity value corresponding to the humidity value included in the humidity detection signal transmitted by the humidity sensor with reference to the fire determination standard value storage unit for each detection signal that generates the collected data and stores the fire determination standard value for each detection signal set to be proportional to the humidity value. Fire determination criteria for each detection signal are selected, and when any one of the collected data for each detection signal exceeds the selected fire determination standard for each detection signal, it may be determined that a fire has occurred. The sensor unit may further include a humidity sensor that detects humidity and transmits a humidity detection signal, and the control unit assigns weights to detection signals transmitted by the temperature sensor, the flame sensor, and the smoke sensor to transmit the detection signal. A composite fire determination standard value corresponding to the humidity value included in the humidity detection signal transmitted by the humidity sensor by referring to a composite fire determination standard value storage unit in which the star collection data is generated and the composite fire determination standard value set to be proportional to the humidity value is stored. is selected, and when a value obtained by summing the collected data for each detection signal exceeds the selected composite fire determination standard, it may be determined that a fire has occurred. In addition, unique identification numbers may be assigned to the sensors constituting the sensor unit. The sensor unit may further include an image capture unit composed of cameras for capturing an area where the sensors constituting the sensor unit are installed, and the control unit transmits a detection signal indicating the occurrence of a fire as a result of analyzing the detection signals transmitted by the sensors. If there is a sensor that does this, a camera corresponding to the sensor may be controlled to capture an area where the sensor is installed.

In another aspect of the present invention, a sensor including a temperature sensor for detecting temperature and transmitting a temperature detection signal, a flame sensor for detecting a flame and transmitting a flame detection signal, and a smoke sensor for detecting smoke and transmitting a smoke detection signal wealth; and a control unit that determines whether or not a fire has occurred by complexly analyzing detection signals transmitted by sensors constituting the sensor unit, wherein the control unit determines whether or not a fire has occurred, and the control unit determines whether or not a fire has occurred. A weight is assigned to each to generate collected data for each detection signal, and the control unit determines that a fire occurs when the sum of the collected data for each detection signal exceeds a first reference value when there is a confusion factor according to the determination of fire occurrence. Combination fire detectors may be provided.

Here, the control unit may determine that a fire occurs when any one of the collected data for each detection signal exceeds a preset second reference value when there is no confusion factor according to the fire occurrence determination.

In addition, the control unit may adjust the weight of the detection signal according to the confusion factor.

In addition, the weight of each of the detection signals may be normalized based on the second reference value. In addition, the sensor unit further includes a humidity sensor that detects humidity and transmits a humidity detection signal, and the control unit is set to a spontaneous ignition environment according to humidity and a third reference value in which humidity in a time interval according to the humidity detection signal is preset. If it exceeds, it is determined as a high fire risk, and if it is set as a non-ignition non-environment according to humidity and the humidity of the time interval according to the humidity detection signal is less than a preset fourth reference value, it can be determined as a high fire risk. In addition, the control unit may adjust the reference value in proportion to the humidity value according to the humidity detection signal in the case of a spontaneous ignition environment according to the humidity. In addition, the control unit may adjust the reference value in inverse proportion to the humidity value according to the humidity detection signal in the case of a non-natural ignition environment according to the humidity.

A composite fire monitoring system according to the present invention includes a temperature sensor for detecting temperature and transmitting a temperature detection signal, a flame sensor for detecting a flame and transmitting a flame detection signal, and a smoke sensor for detecting smoke and transmitting a smoke detection signal. A complex fire detector including a sensor unit, a control unit that determines whether a fire has occurred by complexly analyzing detection signals transmitted by sensors constituting the sensor unit, and a communication unit that communicates with the outside under the control of the control unit, and It may include a fire detection control module connected to the complex fire detector through ZigBee communication and connected to a remote fire control system through Ethernet communication.

Here, a fire receiver connected to the complex fire detector through an RS-485 communication method may be further included. In addition, the control unit assigns weights to detection signals transmitted by sensors constituting the sensor unit to generate collected data for each detection signal, and determines which one of the collected data for each detection signal is a fire for each detection signal set in advance. If the standard value is exceeded, it can be determined that a fire has occurred. In addition, the control unit generates collected data for each detection signal by assigning weights to detection signals transmitted by sensors constituting the sensor unit, and a value obtained by summing the collected data for each detection signal is a preset complex fire determination standard value. If it exceeds, it can be judged that a fire has occurred. The sensor unit may further include a humidity sensor that detects humidity and transmits a humidity detection signal, and the control unit assigns weights to detection signals transmitted by the temperature sensor, the flame sensor, and the smoke sensor to transmit the detection signal. The humidity value corresponding to the humidity value included in the humidity detection signal transmitted by the humidity sensor with reference to the fire determination standard value storage unit for each detection signal that generates the collected data and stores the fire determination standard value for each detection signal set to be proportional to the humidity value. Fire determination criteria for each detection signal are selected, and when any one of the collected data for each detection signal exceeds the selected fire determination standard for each detection signal, it may be determined that a fire has occurred. The sensor unit may further include a humidity sensor that detects humidity and transmits a humidity detection signal, and the control unit assigns weights to detection signals transmitted by the temperature sensor, the flame sensor, and the smoke sensor to transmit the detection signal. A composite fire determination standard value corresponding to the humidity value included in the humidity detection signal transmitted by the humidity sensor by referring to a composite fire determination standard value storage unit in which the star collection data is generated and the composite fire determination standard value set to be proportional to the humidity value is stored. is selected, and when a value obtained by summing the collected data for each detection signal exceeds the selected composite fire determination standard, it may be determined that a fire has occurred.

According to the present invention, there is an effect of providing a composite fire detector and a fire monitoring system including the same that can improve the reliability and speed of determining whether a fire has occurred.

In addition, a complex fire detector that can improve the accuracy and reliability of judgment on whether a fire has occurred by analyzing the data collected through various sensors installed at the monitoring site in a complex manner according to the criteria set appropriately for the environment at the monitoring site. And there is an effect that a fire monitoring system including this is provided.

In addition, based on the data collected from the sensors, it is primarily possible to determine whether a fire has occurred, and secondarily, by allowing the manager to check the fire scene through related images, the accuracy of determining whether a fire has occurred can be improved. There is an effect of providing a complex fire detector and a fire monitoring system including the same.

1 is a view showing a composite fire detector according to an embodiment of the present invention.
2 is a diagram for explaining one example of a specific operation of a composite fire detector according to an embodiment of the present invention.
3 is a diagram for explaining another example of a specific operation of a composite fire detector according to an embodiment of the present invention.
4 is a diagram for explaining yet another example of a specific operation of a composite fire detector according to an embodiment of the present invention.
5 is a diagram for explaining another example of a specific operation of a composite fire detector according to an embodiment of the present invention.
6 is a diagram illustrating a fire monitoring system according to an embodiment of the present invention.
7 and 8 are flowcharts of an operating method of a composite fire detector according to another embodiment of the present invention.

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

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. These terms are only used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention. The terms and/or include any combination of a plurality of related recited items or any of a plurality of related recited items.

It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be. On the other hand, when an element is referred to as “directly connected” or “directly connected” to another element, it should be understood that no other element exists in the middle. In addition, that the first component and the second component on the network are connected or connected means that data can be exchanged between the first component and the second component in a wired or wireless manner.

In addition, the suffixes "module" and "unit" for the components used in the following description are simply given in consideration of ease of preparation of this specification, and do not themselves give a particularly important meaning or role. Accordingly, the “module” and “unit” may be used interchangeably.

When these components are implemented in actual applications, two or more components may be combined into one component, or one component may be subdivided into two or more components as needed.

1 is a view showing a composite fire detector according to an embodiment of the present invention.

Referring to FIG. 1 , a complex fire detector 1 according to an embodiment of the present invention may include a sensor unit 10, an image capturing unit 20, a control unit 30, and a communication unit 40.

The sensor unit 10 performs a function of collecting fire-related data. The sensor unit 10 includes a temperature sensor 110 that detects temperature and transmits a temperature detection signal, a humidity sensor 120 that detects humidity and transmits a humidity detection signal, and a flame sensor that detects a flame and transmits a flame detection signal. 130 and a smoke sensor 140 for detecting smoke and transmitting a smoke detection signal. Unique identification numbers may be assigned to the sensors constituting the sensor unit 10 .

The image capture unit 20 may include cameras for capturing an area in which sensors constituting the sensor unit 10 are installed.

The control unit 30 may perform a function of determining whether a fire has occurred by complexly analyzing detection signals transmitted by sensors constituting the sensor unit 10 .

For example, as a result of additionally installing cameras in the area where the sensors are installed and the control unit 30 analyzing the detection signals transmitted by the sensors, if there is a sensor that transmits a detection signal indicating the occurrence of a fire, the detection signal A camera corresponding to the transmitted sensor may be controlled to capture an area where the sensor is installed.

As an example, the control unit 30 assigns weights to detection signals transmitted by sensors constituting the sensor unit 10 to generate collected data for each detection signal, and selects one of the collected data for each detection signal in advance. When the fire determination standard for each set detection signal is exceeded, it may be determined that a fire has occurred.

As another example, the control unit 30 assigns weights to detection signals transmitted by sensors constituting the sensor unit 10 to generate collected data for each detection signal, and a value obtained by summing the collected data for each detection signal is set in advance. If the composite fire judgment standard is exceeded, it may be configured to determine that a fire has occurred.

As another example, the control unit 30 assigns weights to the detection signals transmitted by the temperature sensor 110, the flame sensor 130, and the smoke sensor 140 to generate collected data for each detection signal, and determines the humidity value. With reference to the fire determination standard value storage unit for each detection signal in which the fire determination standard values for each detection signal set to be proportional are stored, the fire determination criteria for each detection signal corresponding to the humidity value included in the humidity detection signal transmitted by the humidity sensor 120 and when any one of the collected data for each detection signal exceeds a fire determination standard value for each selected detection signal, it may be configured to determine that a fire has occurred.

As another example, the control unit 30 assigns weights to the detection signals transmitted by the temperature sensor 110, the flame sensor 130, and the smoke sensor 140 to generate collected data for each detection signal, and determines the humidity value. A composite fire determination standard value corresponding to the humidity value included in the humidity detection signal transmitted by the humidity sensor 120 is selected with reference to the composite fire determination standard value storage unit in which the composite fire determination standard value set to be proportional is stored, and collected for each detection signal. When the sum of the data exceeds the selected composite fire determination standard, it may be configured to determine that a fire has occurred.

The communication unit 40 performs a function of performing communication with the outside under the control of the control unit 30, and, for example, RS-485 communication unit 420 for RS-485 communication and Zigbee communication. It may be configured to include a Zigbee communication unit 410 for

Hereinafter, an example of a specific operation of the complex fire detector according to an embodiment of the present invention will be described with additional reference to FIGS. 2 to 5 .

Referring additionally to FIG. 2 , the control unit 30 assigns weights to detection signals transmitted by sensors constituting the sensor unit 10 to generate collected data for each detection signal, and selects one of the collected data for each detection signal. If one exceeds the fire determination standard for each detection signal set in advance, it may be determined that a fire has occurred. In the following description, weights are values set by a manager, and are respectively set for temperature, flame, and smoke, and weights may be adjusted according to the structure or internal finishing materials of a place where the sensor unit 10 is located. Weights can be varied by time values such as day and night or seasons.

First, in step S12, the temperature sensor 110 detects the temperature of the fire monitoring area and transmits a temperature detection signal to the control unit 30.

In step S14 , a process of generating temperature data by assigning a temperature weight to the temperature data transmitted by the temperature sensor 110 by the control unit 30 is performed.

In step S16, a process in which the control unit 30 compares the temperature data with a preset and stored temperature reference value is performed. As a result of the comparison in step S16, when the temperature data exceeds the temperature reference value, the transition is made to step S60, and the controller 30 determines the current situation as a fire occurrence situation. As a result of the comparison in step S16, when the temperature data does not exceed the temperature reference value, the process is switched to step S12 and the temperature sensor 110 detects the temperature is repeated.

In step S22, a process in which the flame sensor 130 detects a flame in the fire monitoring area and transmits a flame detection signal to the control unit 30 is performed.

In step S24, a process in which the controller 30 generates flame data by assigning a flame weight to the flame data transmitted by the flame sensor 130 is performed.

In step S26, the control unit 30 compares the flame data with a previously set and stored flame reference value. As a result of comparison in step S26, when the flame data exceeds the flame reference value, the transition is made to S60, and the control unit 30 determines the current situation as a fire occurrence situation. As a result of the comparison in step S26, when the flame data does not exceed the flame reference value, the process is switched to step S22 and the process of the flame sensor 130 detecting the flame is repeated.

In step S32, a process in which the smoke sensor 140 detects smoke in the fire monitoring area and transmits a smoke detection signal to the control unit 30 is performed.

In step S34, a process of generating smoke data by giving smoke weights to the smoke data transmitted by the smoke sensor 140 by the controller 30 is performed.

In step S36, a process in which the control unit 30 compares the postponement data with a previously set and stored postponement reference value is performed. As a result of the comparison in step S36, when the smoke data exceeds the smoke reference value, the process is switched to S60, and the controller 30 determines the current situation as a fire occurrence situation. As a result of the comparison in step S36, when the smoke data does not exceed the smoke reference value, the process is switched to step S22 and the process of detecting smoke by the smoke sensor 140 is repeated.

In step S70, a process of determining whether a final operation end signal is input by the manager is performed, and when the end signal is not input, the above-described operation is repeated.

Referring additionally to FIG. 3 , the control unit 30 assigns weights to detection signals transmitted by sensors constituting the sensor unit 10 to generate collected data for each detection signal, and sums the collected data for each detection signal. If the value exceeds the preset composite fire judgment standard, it is determined that a fire has occurred.

Since operations in steps S12, S14, S22, S24, S32, S34, and S70 are the same as those described with reference to FIG. 2, duplicate descriptions will be omitted.

In step S40, the controller 30 performs a process of summing collected data for each detection signal, that is, temperature data, flame data, and smoke data. Although there may be cases where it is difficult to conclusively determine the occurrence of a fire with only one data, it is possible to comprehensively and reliably determine the occurrence of a fire in various aspects through step S40 and step S50 described below.

In step S50, the controller 30 compares the sum of the data with a preset and stored complex fire determination reference value. As a result of comparison in step S50, when the sum of the data exceeds the composite fire determination standard, the process is switched to S60, and the control unit 30 determines the current situation as a fire occurrence situation. As a result of the comparison in step S56, if the sum of the data does not exceed the composite fire determination standard, the process of detecting temperature, flame, and smoke is repeated.

Referring additionally to FIG. 4 , in step S310, the control unit 30 assigns weights to the detection signals transmitted by the temperature sensor 110, the flame sensor 130, and the smoke sensor 140 to collect data for each detection signal. The process of creating them is performed.

In step S320, the control unit 30 refers to the fire determination standard value storage unit for each detection signal in which the fire determination standard values for each detection signal set to be proportional to the humidity value are stored, and included in the humidity detection signal transmitted by the humidity sensor 120. A process of selecting fire determination reference values for each detection signal corresponding to the humidity value is performed. For example, considering the realistic correlation between humidity and fire occurrence, the control unit 30 may select fire determination criteria for each detection signal having a higher value as the humidity increases.

In step S330, when any one of the collected data for each detection signal exceeds the fire determination standard value for each detection signal, a process of determining that a fire has occurred is performed.

Referring additionally to FIG. 5 , in step S410, the control unit 30 assigns weights to the detection signals transmitted by the temperature sensor 110, the flame sensor 130, and the smoke sensor 140 to collect data for each detection signal. The process of creating them is performed.

In step S420, the control unit 30 refers to the composite fire determination reference value storage unit in which the composite fire determination reference values set to be proportional to the humidity value are stored, and corresponds to the humidity value included in the humidity detection signal transmitted by the humidity sensor 120. A process of selecting a composite fire judgment standard value is performed.

In step S430, when the value obtained by summing the collected data for each detection signal exceeds the selected composite fire determination standard, a process of determining that a fire has occurred is performed.

6 is a diagram illustrating a fire monitoring system according to an embodiment of the present invention.

Referring to FIG. 6 , a fire monitoring system according to an embodiment of the present invention includes a complex fire detector 1, a fire detection control module 2, and a fire receiver 3.

Since the complex fire detector 1 has been described in detail above, duplicate descriptions will be omitted.

The fire detection control module 2 is connected to the complex fire detector 1 through ZigBee communication, and is connected to a remote fire control system through Ethernet communication. The administrator may input a command to operate the complex fire detector 1 through the fire detection control module 2 or communicate with an external fire control system in real time.

The fire receiver 3 is connected to the composite fire detector 1 through RS-485 communication, and is installed near the fire monitoring area to notify workers whether or not a fire has occurred.

As described in detail above, according to the present invention, there is an effect of providing a composite fire detector capable of improving the reliability and speed of determining whether a fire has occurred and a fire monitoring system including the same.

In addition, a complex fire detector that can improve the accuracy and reliability of judgment on whether a fire has occurred by analyzing the data collected through various sensors installed at the monitoring site in a complex manner according to the criteria set appropriately for the environment at the monitoring site. And there is an effect that a fire monitoring system including this is provided.

In addition, based on the data collected from the sensors, it is primarily possible to determine whether a fire has occurred, and secondarily, by allowing the manager to check the fire scene through related images, the accuracy of determining whether a fire has occurred can be improved. There is an effect of providing a complex fire detector and a fire monitoring system including the same.

7 and 8 are flowcharts of an operating method of a composite fire detector according to another embodiment of the present invention. See Figures 1 and 6.

7 and 8 , the control unit 30 includes a temperature sensor 110 that detects the temperature of the sensor unit 10 and transmits a temperature detection signal, and a flame sensor 130 that detects a flame and transmits a flame detection signal. ) and multiple detection signals transmitted by the smoke sensor 140 that detects smoke and transmits a smoke detection signal (S510). Unique identification numbers indicating a location may be assigned to each sensor of the sensor unit 10, but is not limited thereto. Identification information corresponding to a location may be assigned to the sensor unit 10 itself. After determining the fire or fire risk to be described later, the location correspondence identification information is transmitted to another control module 2 or the fire control system 4 through the communication unit to inform the manager of the location of the fire. . The control unit 30 may be located at substantially the same place as the sensor unit 10 or disposed at a space apart from each other. The controller 30 may be located in the control module 2 or topic control system 4 described in FIG. 6 . Each sensor of the sensor unit 10 may be composed of one sensor or multiple sensors. For example, the flame sensor 130 may include a combination of an infrared sensor and an ultraviolet sensor, and a flame detection signal by the flame sensor 130 may include an infrared detection signal and an ultraviolet detection signal.

The control unit 30 may generate collected data for each detection signal by assigning a weight to each of the multiple detection signals (S520). The weight can be set by combining various factors necessary for fire determination. Factors to consider in determining fire are: structure of the place where the sensor unit 10 is placed, ventilation conditions, environmental conditions (humidity, temperature, etc.), ignition inside the place where the sensor unit 10 is placed, type and amount of inflammable materials, and placement (material characteristics or thickness, etc.) etc. may vary. It is not limited to adjusting the weight according to these consideration factors. For example, the control unit 30 may adjust a reference value to be compared with collected data or data to be described later.

Collected data may be values processed by the control unit 30 in various ways to help determine fire. For example, in the case of smoke data according to the smoke signal, the absolute amount of smoke (or relative amount within a certain range), the average value or median value during a specific time interval, and the pitch value (instantaneous It may be a value processed as an average value or a median value excluding a value), a change amount during a specific time period, and the like.

The control unit 30 may adjust scales of weights so that each weight normalizes collected data for each detection signal. For example, weights may be adjusted so that smoke data according to a detection signal by a smoke sensor and flame data by a flame sensor have the same weight when determining a fire.

The control unit 30 may determine whether there is a confusion factor according to determining whether a fire has occurred (S530). In cases where there are confusing factors such as poor climatic environmental conditions, such as places where temperature or humidity is not controlled, places where smoke and arcs from welding work, etc. Even though it is not, it is often judged as a fire. According to the present invention, it is possible to accurately determine a fire by appropriately using detection signals of various sensors of the sensor unit 10 by dividing a case with and without such a confusing factor.

If it is determined that there is a confusion factor or if it is preset, the control unit 30 may change weights given to collected data. For example, when it is set to a place where a lot of smoke or dust is generated, a value of a weight for a preset smoke signal may be lowered. Each collected data due to the lowered weight prevents erroneous judgment due to confusion factors and can have the same weight in fire judgment. Such normalization can help a manager easily determine which detection signal is relatively higher than other detection signals when controlling fire. The controller 30 may determine whether or not there is a fire by excluding sensor data related to the confusion factor, or determine whether there is a fire using only specific detection signals, or determine whether there is a fire by a combination of each signal. Not limited. For example, when the ambient temperature by the temperature sensor increases by 40 degrees or more within 1 second than the temperature of the object by the flame sensor, the controller 30 may determine that it is a fire.

If there is a confusion factor, the control unit 30 compares the sum of each of the weighted collected data with a first reference value (S540), and if the sum of the collected data exceeds the first reference value, the sensor unit 10 is disposed. It can be determined that a fire is occurring in the place where it has been (S550). The control unit 30 may give a fire warning to a manager through the communication unit 40 or a display device (not shown), saying that a fire is occurring or that such a risk is very high. For this embodiment, the embodiment mentioned in FIG. 3 may be referred to.

If it is determined that there is no confusion factor or if it is preset, the control unit 30 determines whether any one of the collected data exceeds the second reference value (S545), and if it is exceeded, a fire alarm can be issued (S550). For this embodiment, the embodiment mentioned in FIG. 2 may be referred to. Since each collected data is normalized and can be compared with one value (second reference value), circuit or program coding can be simplified. In addition, it is preferable that the first reference value is substantially equal to the product of the second reference value and the number of detection signals that are the basis for determining a fire. That is, the first reference value can be easily derived from the second reference value.

The control unit 30 can detect the humidity of the sensor unit 10 and know the humidity of the place where the sensor unit 10 is disposed from the humidity detection signal of the humidity sensor 120 that transmits the humidity detection signal. The control unit 30 may determine whether the place where the sensor unit 10 is disposed is a spontaneous ignition environment according to humidity (S560). Moisture may act as a catalyst for ignition depending on the material. This is because proper moisture plays a role in facilitating heat transfer. The case where humidity acts as a catalyst will be referred to as a spontaneous ignition environment according to humidity. It is known that spontaneous combustion due to high humidity often occurs in places such as storage warehouses. On the other hand, in the case of wooden buildings, the higher the humidity, the lower the probability of fire.

In the case of a spontaneous ignition environment according to humidity, the controller 30 may increase each weight given to multiple detection signals in a predetermined time period in proportion to the humidity (S570). In addition, the control unit 30 may determine that the risk of fire is high when the humidity during a specific time period exceeds a preset third reference value, and may notify the manager (S590). For example, if it is set as a granary, the control unit 30 may issue a fire warning when the humidity is 70% or more and continues for 15 days or more.

If it is not a spontaneous ignition environment according to humidity, the control unit 30 may increase each weight given to multiple detection signals during a predetermined time interval in inverse proportion to the humidity (S575). In addition, the control unit 30 may determine that the risk of fire occurrence is high when the humidity during a specific time period is less than a preset fourth reference value, and may notify the manager of this (S590). For example, in the case of a wooden area, building, or structure, the control unit 30 may issue a fire warning when the humidity is 30% or less and continues for 7 days.

The present invention can also be implemented as computer readable codes on a computer readable recording medium. A computer-readable recording medium includes all types of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage devices, and also those implemented in the form of carrier waves (for example, transmission through the Internet). include In addition, the computer-readable recording medium is distributed in computer systems connected through a network, so that computer-readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily inferred by programmers in the art to which the present invention belongs.

Although the technical idea of the present invention has been described above with the accompanying drawings, this is an exemplary embodiment of the present invention, but does not limit the present invention. In addition, it is obvious that anyone skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

1: complex fire detector 2: fire detection control module
3: fire receiver 10: sensor unit
20: image capture unit 30: control unit
40: communication unit 110: temperature sensor
120: humidity sensor 130: flame sensor
140: smoke sensor 410: Zigbee communication unit
420: RS-485 communication unit

Claims (5)

A temperature sensor that detects temperature and transmits a temperature detection signal, a flame sensor that detects flame and transmits a flame detection signal, a smoke sensor that detects smoke and transmits a smoke detection signal, and detects humidity and transmits a humidity detection signal. a sensor unit having a humidity sensor;
a controller that determines whether a fire has occurred by complexly analyzing detection signals transmitted by sensors constituting the sensor unit; and
A communication unit for performing communication with the outside under the control of the control unit;
The control unit assigns weights to signals detected by the temperature sensor, the flame sensor, and the smoke sensor to generate collected data for each detection signal;
When the control unit is set to a spontaneous ignition environment according to humidity and the humidity of the time interval according to the humidity detection signal exceeds a preset third reference value, it is determined that the fire risk is high, and it is set to a spontaneous ignition non-environment according to humidity, and the humidity If the humidity in the time interval according to the detection signal is less than the fourth predetermined reference value, it is determined that the fire risk is high,
The control unit adjusts the reference value in proportion to the humidity value according to the humidity detection signal in the case of a spontaneous ignition environment according to the humidity,
The control unit determines that a fire has occurred when the sum of the collected data for each detection signal exceeds a first reference value when there is a confusion factor according to the determination of the occurrence of a fire,
The control unit determines that a fire has occurred when any one of the collected data for each detection signal exceeds a preset second reference value when there is no confusion factor according to the fire occurrence determination,
The composite fire detector, wherein weights of each of the detection signals are normalized based on the second reference value. delete According to claim 1,
The control unit adjusts the reference value in proportion to the humidity value according to the humidity detection signal in the case of a spontaneous ignition environment according to the humidity,
The control unit adjusts the reference value in inverse proportion to the humidity value according to the humidity detection signal in the case of a non-natural ignition environment according to the humidity,
Unique identification numbers are assigned to the sensors constituting the sensor unit,
Further comprising an image capturing unit composed of cameras for capturing an area in which sensors constituting the sensor unit are installed,
The control unit
As a result of analyzing the detection signals transmitted by the sensors, if there is a sensor transmitting a detection signal indicating the occurrence of a fire, the camera corresponding to the sensor is controlled to photograph the area where the sensor is installed,
A product of the first reference value and the number of detection signals by the sensor unit is substantially equal to the second reference value. delete delete

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