KR102353132B1 - Sensor installation method using wireless processing technology to set the installation value of bulk sensor and fire alarm system using the same - Google Patents

Abstract

According to an embodiment of the present invention, a fire alarm system comprises: a fire alarm device for detecting a fire situation; a terminal in which information input from the outside is stored; and a communication element mounted on the terminal, and receiving the information from the terminal. The fire alarm device includes: a plurality of sensors for separately detecting the occurrence of a fire to generate a fire alarm, and performing an RF communication with each other; a repeater for performing the RF communication with the sensors; a receiver for performing the RF communication with the repeater; and a server for performing the RF communication with the receiver, and including a server memory. The communication element can transmit the information to the sensors in wireless communication with the sensors, and the receiver can recognize an arrangement relationship of the of sensors on the basis of the information. Therefore, the reliability of the fire alarm system is improved.

Description

SENSOR INSTALLATION METHOD USING WIRELESS PROCESSING TECHNOLOGY TO SET THE INSTALLATION VALUE OF BULK SENSOR AND FIRE ALARM SYSTEM USING THE SAME

The present invention relates to a fire alarm system, and more particularly, to a method for easily installing a sensor and a fire alarm system using the same.

In general, when installing a sensor that detects a fire in an apartment building, it is installed after inputting the sensor's prior information. The dictionary information may include an installation location, setting information, and the like. In this case, there is a high possibility that the information stored in the sensor does not match with the prior information at the time of installation due to negligence in installation, delivery, or management. If the sensor malfunctions due to the above factors, users may lose trust in the fire alarm system and are more likely to turn off the fire alarm system normally. In this case, users may be exposed to the risk of fire even if an actual fire occurs in the area where the fire alarm system is installed.

An object of the present invention is to provide a method for easily installing a sensor and a fire alarm system using the same.

A fire alarm system according to an embodiment of the present invention includes a fire alarm device for detecting a fire situation, a terminal storing information input from the outside, and a communication element mounted on the terminal and receiving the information from the terminal, , the fire alarm device generates a fire alarm by sensing the occurrence of a fire, a plurality of sensors performing RF communication (Radio Frequency communication) with each other, a repeater performing the RF communication with the plurality of sensors, the a receiver for performing the RF communication with a repeater, and a server for performing the RF communication with the receiver and including a server memory, wherein the communication element wirelessly communicates with the plurality of sensors to transmit the information to the plurality of sensors After transmitting to the sensors, the receiver may determine the arrangement relationship of the plurality of sensors based on the information.

Each of the plurality of sensors may include a memory in which unique address information is not stored, the communication device may transmit the information to the memory, and the memory may store the information.

The information may include unique address information of each of the plurality of sensors, information on an installation location where each of the plurality of sensors is disposed, setting information for each operation of the plurality of sensors, and non-fire alarm condition information can

The information on the installation location includes first location information on a first location and second location information on a second location different from the first location, and the communication element transmits the first location information to the plurality of sensors. Among the sensors, the second location information may be transmitted to a sensor disposed at the first location, and the second location information may be transmitted to a sensor disposed at the second location among the plurality of sensors.

The sensitivity of the sensor storing the first place information may be lower than the sensitivity of the sensor storing the second place information.

The non-fire alarm condition information includes first non-fire information information for a first situation and second non-fire information information for a second situation different from the first situation, and the sensitivity of the sensor in which the first non-fire information is stored is the The second non-fire information may be lower than the sensitivity of the stored sensor.

The communication element may communicate with the plurality of sensors only within a predetermined distance.

The predetermined distance may be 2 meters.

The plurality of sensors may transmit the information to the server, and the server may store the information in the server memory.

The server may transmit a signal to each of the plurality of sensors, and the information may be modified based on the signal and stored in each of the plurality of sensors.

A sensor installation method according to an embodiment of the present invention includes the steps of each including a memory in which unique address information is not stored, installing a plurality of sensors for detecting fire occurrence, and storing information input from the outside in the terminal step, mounting a communication element in a terminal, wirelessly communicating a communication element with a first sensor disposed within a predetermined distance from the communication element among the plurality of sensors, the communication element is the memory of the first sensor It may include transmitting the information to, and storing the information in the memory.

The predetermined distance may be 2 meters.

The method may further include transmitting the information to a server by the plurality of sensors and storing the information in a server memory by the server.

The method may further include, by the server, transmitting a signal to each of the plurality of sensors to correct the information.

The method may further include, by the server, determining an arrangement relationship of the plurality of sensors based on the information.

The method may further include transmitting the information to a receiver and determining, by the receiver, an arrangement relationship of the plurality of sensors based on the information.

As described above, a user may install a plurality of sensors. After that, the user can input information into the terminal. Information may be stored in the terminal. The terminal may transmit information to the communication element. The communication element may transmit information to each of the plurality of sensors. A plurality of sensors may transmit information to a receiver. The receiver may determine the arrangement relationship of the plurality of sensors based on the information. The user can easily determine which sensor detects the fire situation by identifying the arrangement position of each of the plurality of sensors. Accordingly, it is possible to provide a fire alarm system with improved reliability. In addition, after arbitrarily installing a plurality of sensors, information is stored in the plurality of sensors, so that the installation of the plurality of sensors may be easy. Therefore, it is possible to provide a sensor installation method that is easy to install.

1 illustrates a fire alarm system according to an embodiment of the present invention.
2 is a flowchart illustrating a method for installing a sensor according to an embodiment of the present invention.
3 is a perspective view illustrating one sensor among a plurality of sensors according to an embodiment of the present invention.
4 is a perspective view showing a repeater according to an embodiment of the present invention.
5 illustrates a receiver according to an embodiment of the present invention.
6 illustrates a first server according to an embodiment of the present invention.
7A illustrates a terminal and a communication device of a person concerned according to an embodiment of the present invention.
7B illustrates a terminal of a person concerned according to an embodiment of the present invention.
7C illustrates a communication device according to an embodiment of the present invention.
8 illustrates a plurality of sensors, a terminal, and a communication device according to an embodiment of the present invention.
9 is a diagram illustrating an operation of a fire alarm system according to an embodiment of the present invention.
10 is a diagram illustrating an operation of a fire alarm system according to an embodiment of the present invention.

In this specification, when a component (or region, layer, portion, etc.) is referred to as being “on,” “connected to,” or “coupled to” another component, it is directly disposed/on the other component. It means that it can be connected/coupled or a third component can be placed between them.

Like reference numerals refer to like elements. In addition, in the drawings, thicknesses, ratios, and dimensions of components are exaggerated for effective description of technical content.

“and/or” includes any combination of one or more that the associated configurations may define.

Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, terms such as "below", "below", "above", and "upper side" are used to describe the relationship of the components shown in the drawings. The above terms are relative concepts, and are described based on directions indicated in the drawings.

Unless defined otherwise, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Also, terms such as terms defined in commonly used dictionaries should be construed as having a meaning consistent with their meaning in the context of the relevant art, and unless they are interpreted in an ideal or overly formal sense, they are explicitly defined herein can be

Terms such as “comprise” or “have” are intended to designate that a feature, number, step, action, component, part, or combination thereof described in the specification is present, and includes one or more other features, number, or step. , it should be understood that it does not preclude the possibility of the existence or addition of an operation, a component, a part, or a combination thereof.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a diagram illustrating a fire alarm system according to an embodiment of the present invention, and FIG. 2 is a flowchart illustrating a method for installing a sensor according to an embodiment of the present invention.

1 and 2 , the fire alarm system FAS may include a fire alarm device 10 , a terminal MD, and a communication device CD.

The fire alarm device 10 may detect a fire situation. The fire alarm device 10 may include a sensing system 100 , a repeater 200 , a receiver 300 , and a first server 400 .

The sensing system 100 may be a system for detecting whether a fire has occurred. The sensing system 100 may include a plurality of sensors SM. 1 illustrates that the sensing system 100 includes five sensors SM by way of example, but is not limited thereto.

Each of the plurality of sensors SM may include a memory MM (refer to FIG. 3 ). Unique address information may not be stored in the memory (MM, see FIG. 3 ) of the plurality of sensors SM initially installed by the user. A plurality of sensors SM each including a memory (MM, see FIG. 3 ) in which unique address information is not stored may be installed to the user ( S100 ).

The user may install the plurality of sensors SM in a space where a fire is likely to occur. Each of the plurality of sensors SM may be installed to be spaced apart from each other by a predetermined distance.

Each of the plurality of sensors SM may detect the occurrence of a fire. Each of the plurality of sensors MS may transmit the first fire detection signal SG-1 to the adjacent sensors SM and/or the repeater 200 .

The first fire detection signal SG-1 may include a first signal SG-1a and a second signal SG-1b. The first signal SG-1a may be a signal generated by the sensor SM that detects the occurrence of a fire. The second signal SG-1b may be a signal amplified by the sensor SM.

As a method of transmitting and receiving the first fire detection signal SG-1, a radio frequency (RF) communication method may be used. The RF communication method may be a communication method for exchanging information by radiating a radio frequency. It is a broadband communication method using a frequency, so it can have high stability because it is less affected by climate and environment. In the RF communication method, voice or other additional functions may be interlocked and the transmission speed may be high. For example, the RF communication method may use a frequency of 447 MHz to 924 MHz. However, this is exemplary and in an embodiment of the present invention, a communication method such as Ethernet, Wifi, LoRA, M2M, 3G, 4G, LTE, LTE-M, Bluetooth, or WiFi Direct may be used.

In an embodiment of the present invention, the RF communication method may include a Listen Before Transmission (LBT) communication method. This is a frequency selection method that determines whether the selected frequency is being used by another system, and selects another frequency when it is determined that it is occupied. For example, a node intending to transmit may first listen to the medium, determine if it is in an idle state, and then flush the backoff protocol prior to transmission. By distributing data using this LBT communication method, collisions between signals in the same band can be prevented.

The repeater 200 may perform RF communication with a plurality of sensors SM. For example, the repeater 200 may communicate with 40 sensors SM. The repeater 200 may receive the first fire detection signal SG-1 from the plurality of sensors SM. The repeater 200 may convert the first fire detection signal SG-1 into the second fire detection signal SG-2a. The repeater 200 may transmit the second fire detection signal SG-2a to the receiver 300 .

The RF communication method may be used as a method of transmitting the second fire detection signal SG-2a. That is, the repeater 200 and the receiver 300 may perform the RF communication.

The receiver 300 may receive the second fire detection signal SG-2a from the repeater 200 . The receiver 300 may convert the second fire detection signal SG-2a into the third fire detection signal SG-3a. The receiver 300 may transmit the third fire detection signal SG-3a to the first server 400 .

The RF communication method may be used as a method of transmitting the third fire detection signal SG-3a. That is, the receiver 300 and the first server 400 may perform the RF communication.

The first server 400 may determine the fire situation based on the third fire detection signal SG-3a received from the receiver 300 . The first server 400 may determine the validity of the third fire detection signal SG-3a.

The first server 400 may receive big data from an external second server BD. The big data may be stored in the memory of the second server BD. However, this is an example, and the big data according to an embodiment of the present invention may be stored in the server memory of the first server 400 .

The big data may include surrounding environment data for determining whether a fire has occurred. For example, the surrounding environment data includes data corresponding to the probability of occurrence of a fire by date, data corresponding to the probability of occurrence of fire by time, data corresponding to the probability of occurrence of fire by space, data corresponding to the probability of occurrence of fire by temperature, and humidity. It may include at least one of data corresponding to the probability of occurrence of each fire, data corresponding to the probability of occurrence of fire by weather, data corresponding to the probability of occurrence of fire by industry, and data corresponding to the probability of occurrence of fire by user.

For example, the data corresponding to the fire occurrence probability for each date may include a fire occurrence probability for each day of the week and a fire occurrence probability for each month. The data corresponding to the fire occurrence probability for each time may include the fire occurrence probability divided into dawn, morning, afternoon, evening, or late night. The data corresponding to the fire occurrence probability for each space may include the fire occurrence probability divided into a city center, a mountainous area, a beach, or a rural area. The data corresponding to the fire occurrence probability for each temperature may include the fire occurrence probability divided into spring, summer, autumn, or winter. The data corresponding to the fire occurrence probability for each humidity may include a fire occurrence probability for each specific humidity value. The data corresponding to the fire occurrence probability for each weather may include a fire occurrence probability divided into a sunny day, a cloudy day, or a rainy day. The data corresponding to the fire occurrence probability for each industry may include a fire occurrence probability divided into homes, restaurants, factories, or offices. The fire occurrence probability for each user may include a fire occurrence probability divided by age, occupation, or gender.

The big data may be updated periodically.

The first server 400 may include an algorithm including an artificial intelligence model capable of determining non-fire information.

The first server 400 may determine the validity of the third fire detection signal SG-3a based on the big data and the values detected by each of the plurality of sensors SM based on different criteria for each situation. For example, the first server 400 may use the big data to determine whether the values detected by the plurality of sensors SM are invalid data such as water vapor, cigarette smoke, and exhaust gas. have.

When the first server 400 determines that the third fire detection signal SG-3a is a valid signal, a warning message and location information may be transmitted to the plurality of parties 20 .

The plurality of persons 20 may include, for example, a fire station, persons concerned at a place where a fire occurred, the Ministry of Public Safety and Security (or a public institution related to public safety), and the like. The plurality of parties 20 may receive the fire warning message in the form of a text message, a video message, or a voice message through a landline phone, a smart phone, or other portable terminal.

The first server 400 may transmit the fire warning message to the terminal MD.

When the first server 400 determines that the third fire detection signal SG-3a is an invalid signal, the third fire detection signal SG-3a may be ignored. Accordingly, it is possible to prevent non-fire alarms. The non-fire protection means that the fire alarm device 10 operates as a fire even though it is not a fire.

In addition, when the first server 400 determines that the third fire detection signal SG-3 is an invalid signal, the first server 400 controls so that the alarms of the plurality of sensing units SM do not sound. A signal may be transmitted to the plurality of sensors SM.

The terminal MD may be a device owned by a user. The terminal MD may store information INF input from the outside (S200). The information INF may be input by the user into the terminal MD. The information INF may include information about each of the plurality of sensors SM. For example, the information INF includes unique address information of each of the plurality of sensors SM, information on an installation location where each of the plurality of sensors SM is disposed, and operation of each of the plurality of sensors SM. It may include setting information for, and non-fire warning condition information. This will be described later.

The communication device CD may be mounted on the terminal MD (S300). The communication element CD may receive information INF from the terminal MD.

Among the plurality of sensors SM, a sensor disposed within a predetermined distance from the communication device CD may wirelessly communicate with the communication device CD ( S400 ).

The communication device CD may transmit the information INF to the memory of the sensor disposed within the predetermined distance (S500). Information INF may be stored in the memory (S600).

The plurality of sensors SM may transmit the information INF to the first server 400 through the first fire detection signal SG-1. The first server 400 may store the information INF in the server memory (MM-S, see FIG. 6 ).

The first server 400 may determine the arrangement relationship of the plurality of sensors SM based on the information INF.

According to the present invention, a user may install a plurality of sensors SM. Thereafter, the user may input the information INF into the terminal MD. Information INF may be stored in the terminal MD. The terminal MD may transmit the information INF to the communication element CD. The communication element CD may transmit the information INF to each of the plurality of sensors SM. The plurality of sensors SM may transmit the first fire detection signal SG-1 including the information INF to the repeater 200 . The repeater 200 may transmit the second fire detection signal SG-2a including the information INF to the receiver 300 . The receiver 300 may determine the arrangement relationship of the plurality of sensors SM based on the information INF. The user can easily determine which sensor detects the fire situation by identifying the arrangement position of each of the plurality of sensors SM. Accordingly, it is possible to provide a fire alarm system (FAS) with improved reliability. In addition, after arbitrarily installing the plurality of sensors SM, the information INF is stored in the plurality of sensors SM to facilitate installation of the plurality of sensors SM. Therefore, it is possible to provide a sensor installation method that is easy to install.

3 is a perspective view illustrating one sensor among a plurality of sensors according to an embodiment of the present invention.

1 and 3 , each of the plurality of sensors SM may include a fire sensor SS, a memory MM, an amplification unit AMP, a communication unit ATN, and a battery unit TT1. have.

The fire sensor SS may detect at least one of smoke, temperature, humidity, and gas. The fire sensor SS may generate fire information by detecting at least one of smoke, temperature, humidity, and gas. The fire information may include a value measured by the fire sensor SS. 3 illustrates one fire sensor SS by way of example, but is not limited thereto. For example, each of the plurality of sensors SM may include a plurality of fire sensors, and each of the plurality of fire sensors may detect at least one of smoke, temperature, humidity, and gas.

The memory MM may store information about the fire sensor SS and information INF input from the outside. The sensor SM may automatically determine a modulation method generated by the mounted fire sensor SS through information on the fire sensor SS. Through such an automatic modulation method, the fire sensor SS may transmit the first fire detection signal SG-1 conveniently even if any type of fire sensors are mounted on each of the plurality of sensors SM.

The information INF input from the outside may include address information unique to the sensor SM.

An optimal signal transmission path for quickly transmitting the first fire detection signal SG-1 to the repeater 200 may be stored in the memory MM. The signal transmission path may be generated based on the information INF. After the user installs the plurality of sensors SM, the user may store information on a repeater close to the sensor in the terminal MD. The terminal MD may transmit the information to the sensor using the communication element CD.

The memory MM may include a volatile memory or a non-volatile memory. The volatile memory may include DRAM, SRAM, flash memory, or FeRAM. The non-volatile memory may include an SSD or HDD.

The communication unit ATN may transmit the first fire detection signal SG-1 to the repeater 200 . The communication unit ATN may also transmit the first fire detection signal SG-1 to other adjacent sensors SM. The first fire detection signal SG-1 may include fire information generated by the fire sensor SS and the address information. The first fire detection signal SG-1 may include a first signal SG-1a and a second signal SG-1b.

When receiving the fire information from the fire sensor SS, the communication unit ATN may transmit the first signal SG-1a to the repeater 200 . When receiving the fire information from the fire sensor SS, the communication unit ATN may transmit the second signal SG-1b to at least one of the plurality of adjacent sensors SM.

When the sensor SM and the repeater 200 are far away from each other, and it is difficult for the repeater 200 to directly receive the first fire detection signal SG-1, the communication unit ATN transmits the first to another adjacent sensor SM. By transmitting the fire detection signal SG-1, signal transmission to the repeater 200 can be stably performed. The communication unit ATN may receive the first fire detection signal SG-1 from another adjacent sensor SM.

The amplifying unit AMP may amplify the first signal SG-1a and convert it into the second signal SG-1b.

The communication unit ATN may receive the first signal SG-1a from another sensor SM. In the process of receiving the received first signal SG-1a from another adjacent sensor SM, a transmission rate and/or accuracy may be deteriorated due to a transmission distance and noise. The amplifying unit AMP may amplify the degraded first signal SG-1a and convert it into a second signal SG-1b. The transmission rate and/or accuracy of the second signal SG-1b may be improved. The communication unit ATN may transmit the second signal SG-1b to at least one of the plurality of adjacent sensors SM. The second signal SG-1b may increase accuracy, a transmission rate, and a transmission distance of a signal transmitted between the plurality of sensors SM and the repeater 200 .

The second signal SG-1b according to an embodiment of the present invention may be transmitted to another adjacent sensor SM and amplified again by the amplification unit AMP of the other adjacent sensor SM.

According to the present invention, the plurality of sensors SM may stably transmit data to the plurality of sensors SM and the repeater 200 using the amplification unit AMP. Accordingly, the reliability of the plurality of sensors SM may be improved.

The battery unit TT1 may supply power to the fire sensor SS, the memory MM, the amplification unit AMP, and the communication unit ATN.

The communication unit (ATN) according to an embodiment of the present invention may use an RF communication method. The RF communication method may consume less power. Power use of the sensor SM may be minimized, and the sensor SM may be driven with low power. Accordingly, the battery unit TT1 may stably supply power to the fire sensor SS, the memory MM, the amplification unit AMP, and the communication unit ATN for a long time.

In addition, according to the present invention, the plurality of sensors SM is divided into a power saving mode that does not consume power and a normal mode that operates in a fire situation to minimize power use of each of the plurality of sensing units SM. can Accordingly, each of the plurality of sensing units SM may be driven with low power.

4 is a perspective view showing a repeater according to an embodiment of the present invention.

1 and 4 , the repeater 200 may communicate with a plurality of sensors SM. For example, the repeater 200 may communicate with 40 sensors SM. The repeater 200 may include a communication unit ANT-G, a power supply unit PW-G, a battery unit BT-G, and a control unit CC-G.

The communication unit ATN-G may communicate with the plurality of sensors SM and the receiver 300 . The communication unit ATN-G may receive the first fire detection signal SG-1 from each of the plurality of sensing sensors SM. The communication unit ATN-G and the communication unit ATN (refer to FIG. 3 ) of the plurality of sensors SM may communicate wirelessly through an RF communication method. The communication unit ATN-G may transmit the second fire detection signal SG-2a to the receiver 300 . The communication unit ATN-G and the communication unit ATN-R (refer to FIG. 5 ) of the receiver 300 may communicate wirelessly through an RF communication method.

The power supply unit PW-G may receive the first power from the outside. The first power may supply power to the communication unit ATN-G and the control unit CC-G.

The battery unit BT-G may supply the second power. The second power may supply power to the communication unit ATN-G and the control unit CC-G.

According to the present invention, even when the first power supplied from the power supply unit PW-G is cut off, the battery unit BT-G supplies the second power so that the repeater 200 can operate. The repeater 200 may stably receive the first fire detection signal SG-1 from the plurality of sensors SM, and stably transmit the second fire detection signal SG-2a to the receiver 300. have. Accordingly, the reliability of signal transmission may be improved.

The controller CC-G may convert the first fire detection signal SG-1 into the second fire detection signal SG-2a. When the first power from the power supply unit PW-G is not supplied to the communication unit ATN-G, the control unit CC-G transmits the second power from the battery unit BT-G to the communication unit ATN-G. can be supplied to

5 illustrates a receiver according to an embodiment of the present invention.

1 and 5 , the receiver 300 may receive the second fire detection signal SG-2a from the plurality of repeaters 200 . For example, the receiver 300 may communicate with 24 repeaters 200 . That is, the receiver 300 may communicate with 960 sensors SM.

The receiver 300 includes a communication unit (ATN-R), a power supply unit (PW-R), a battery unit (BT-R), an intermediate memory (MM-R), a control unit (CT-R), and a display unit (DA-R) may include

The communication unit ATN-R may communicate with the repeater 200 and the first server 400 . The communication unit ATN-R may receive the second fire detection signal SG-2a from the repeater 200 . The communication unit (ATN-R) and the communication unit (ATN-G, see FIG. 4 ) of the repeater 200 may communicate wirelessly through an RF communication method. The communication unit ATN-R may transmit the third fire detection signal SG-3a to the first server 400 . The communication unit ATN-R and the server transmission unit ATN-B (refer to FIG. 6 ) of the first server 400 may communicate wirelessly through an RF communication method.

The power supply unit PW-R may receive the first power from the outside. The first power may supply power to the communication unit ATN-R, the intermediate memory MM-R, the control unit CT-R, and the display unit DA-R.

The battery unit BT-R may supply the second power. The second power may supply power to the communication unit ATN-R, the intermediate memory MM-R, the display unit DA-R, and the control unit CT-R.

According to the present invention, even when the first power supplied from the power supply unit PW-R is cut off, the battery unit BT-R supplies the second power to enable the receiver 300 to operate. The receiver 300 may stably receive the second fire detection signal SG-2a from the repeater 200 and stably transmit the third fire detection signal SG-3a to the first server 400 . . Accordingly, the reliability of signal transmission may be improved.

Information INF of each of the plurality of sensors SM may be stored in the intermediate memory MM-R. Position information of each of the plurality of sensors SM may be stored in the intermediate memory MM-R based on the information INF.

The display unit DA-R may provide image information corresponding to the state of the plurality of sensors SM or the state of the repeater 200 . The display unit DA-R may include a liquid crystal display panel or an organic light emitting display panel. The display unit DA-R may receive an external input provided by a user. For example, the display unit DA-R may further include a touch unit.

According to the present invention, the information INF stored in each of the plurality of sensors SM is to be transmitted to the receiver 300 through the first fire detection signal SG-1 and the second fire detection signal SG-2a. can The receiver 300 may determine the arrangement relationship of the plurality of sensors SM based on the information INF. The arrangement relationship of the plurality of sensors SM may be displayed on the display unit DA-R based on the information INF. The user can easily determine which sensor detects the fire situation based on the arrangement relationship. Accordingly, it is possible to provide a fire alarm system (FAS) with improved reliability.

The controller CT-R may control each of the plurality of sensors SM. The user may provide an input to the display unit DA-R so that the control unit CT-R controls each of the plurality of sensors SM. For example, the control unit CT-R may include information on a place where each of the plurality of sensors SM is disposed, information against the type of a value sensed by each of the plurality of sensors SM, and/or a plurality of Information on whether each of the sensors SM operates normally may be controlled. The controller CT-R of the receiver 300 may determine the arrangement relationship of the plurality of sensors SM based on the information INF.

The receiver 300 may control the plurality of sensors SM disposed in various places through the repeater 200 .

6 illustrates a first server according to an embodiment of the present invention.

1 and 6, the first server 400 includes a server receiving unit (ATN-A), a control unit (CC), a server memory (MM-S), a server transmitting unit (ATN-B), a display unit (DA), Speaker (SK), microphone (MIC), camera (CM), first to fifth buttons (BT1, BT2, BT3, BT4, BT5), door lock (DL), big data receiving unit (BDR), and non-fire alarm determination unit (UWA) may be included.

The server receiver ATN-A may receive the third fire detection signal SG-3a transmitted by the receiver 300 . The third fire detection signal SG-3a may include information INF transmitted from the plurality of sensors SM.

The controller CC may control the plurality of sensors SM, the repeater 200, and the receiver 300, and determine the fire information and information INF included in the third fire detection signal SG-3a. have.

When the address information of the identified information INF is the same as the previously recognized address information, the controller CC may control the first server 400 to ignore the third fire detection signal SG-3a. When the identified address information is different from the previously identified address information, the control unit CC transmits a warning message to the parties corresponding to the address information identified in the server memory MM-S. can Through such control, it is possible to prevent the warning message from being repeatedly transmitted to the parties 20 .

Information (eg, contact information, address, or name) of the parties 20 may be stored in the server memory MM-S. The information of the parties 20 stored in the server memory MM-S may be matched with the information INF of each of the plurality of sensors SM. Information INF may be stored in the server memory MM-S.

The server memory MM-S may include a volatile memory or a non-volatile memory. Volatile memory may include DRAM, SRAM, flash memory, or FeRAM. Non-volatile memory may include SSD or HDD.

The server transmitter ATN-B may transmit a fire alarm message to the parties 20 . The first server 400 may transmit a fire alarm message to the parties 20 corresponding to the identified address information among the information of the parties 20 stored in the server memory MM-S. At this time, the relevant persons 20 corresponding to the identified address information refer to the owner of the place where the fire occurred, the family of the owner of the place where the fire occurred, the owner of the place adjacent to the place where the fire occurred, the competent fire department, or a related public institution. may include

The server transmitter ATN-B may transmit a reception signal SG-3b indicating that the third fire detection signal SG-3a has been received to the receiver 300 . The receiver 300 receiving the received signal SG-3b may determine that the transmitted third fire detection signal SG-3a has been properly transmitted to the first server 400 .

The server transmitter (ATN-B) may transmit information in a Wideband Code Division Multiple Access (WCDMA) communication method. In WCDMA, the wider the bandwidth, the stronger the frequency-selective fading, and when the same data is transmitted, the bandwidth increases and processing gain increases. In addition, since multipath can be resolved, propagation delay in an indoor environment can be overcome even in the case of microcells. Therefore, WCDMA can be effective in transmitting a fire alarm message in a fire outbreak situation in which a stable message must be transmitted quickly due to an urgent situation. In addition, the bandwidth efficiency per 1 MHz bandwidth is excellent, which is advantageous in terms of subscriber capacity, and the processing gain is increased to reduce the capacity of the power amplifier, thereby reducing the implementation cost. have.

The display unit DA may provide image information corresponding to the state of the receiver 300 or the state of the plurality of sensors SM. The display unit DA may include a liquid crystal display panel or an organic light emitting display panel.

According to the present invention, the information INF stored in each of the plurality of sensors SM is the first fire detection signal SG-1, the second fire detection signal SG-2a, and the third fire detection signal SG. It may be transmitted to the first server 400 through -3a). The first server 400 may determine the arrangement relationship of the plurality of sensors SM based on the information INF. The arrangement relationship of the plurality of sensors SM may be displayed on the display unit DA based on the information INF. The user can easily determine which sensor detects the fire situation based on the arrangement relationship. Accordingly, it is possible to provide a fire alarm system (FAS) with improved reliability.

The speaker SK may emit an alarm sound when the first server 400 receives the third fire detection signal SG-3a.

The microphone MIC may recognize a user's voice in the vicinity of the first server 400 . The microphone MIC may be used to recognize a user's voice command in an emergency situation. In this case, the first server 400 may have a built-in program or system for recognizing the user's voice command.

The camera CM may detect and/or recognize a movement of a user in the vicinity of the first server 400 .

The user may manually report a fire by pressing the first button BT1 or by applying a touch to the fire department. In the initial fire stage before the plurality of sensors SM detects whether or not a fire exists, when people around the first server 400 detect a fire, a fire occurrence report may be quickly reported.

The user may stop generating the alarm sound from the speaker SK by pressing the second button BT2 or applying a touch.

The user may communicate (or call) with an external communication device by pressing the third button BT3 or applying a touch. After pressing the third button BT3, the user may transmit voice information to the other party through the microphone MIC and receive voice information from the other party through the speaker SK.

The user may check the states of the plurality of sensors SM, the repeater 200 , and the receiver 300 by pressing the fourth button BT4 or applying a touch. For example, although no fire has occurred, the first server 400 receives the virtual third fire detection signal SG-3a from the receiver 300 , and the first server 400 receives at least one of the parties 20 . You can send a warning message to one. In this way, it can be checked whether the fire alarm device 10 according to an embodiment of the present invention operates normally.

Also, the first server 400 may transmit an operation check signal to each of the plurality of sensors SM. Each of the plurality of sensors operating in the power saving mode may receive an operation check signal and operate in the normal mode. In this case, each of the plurality of sensors may operate in a power saving mode after transmitting the communication operation state to the first server 400 through the repeater 200 and the receiver 300 .

The user may initialize the signal transmission path stored in the memory (MM, see FIG. 3 ) of each of the plurality of sensors SM by pressing the fifth button BT5 or applying a touch.

The user may open the outer case of the first server 400 by using the door lock DL. After opening the outer case, the built-in parts can be easily inspected.

The big data receiving unit BDR may receive big data from an external second server BD. The big data may be used as data for determining whether a fire has occurred.

The big data receiving unit (BDR) may include a learning model for determining whether a fire occurs by machine learning the big data.

The non-fire warning determination unit UWA may determine the validity of the third fire detection signal SG-3a based on the big data and the values detected by each of the plurality of sensors SM based on different criteria for each situation. For example, the non-fire warning determination unit UWA may use the big data to determine whether the values sensed by each of the plurality of sensors SM are invalid data such as water vapor, cigarette smoke, and exhaust gas. can

The non-fire warning determination unit UWA calculates a fire occurrence probability based on the big data and a value measured by each of the plurality of sensors SM, and the fire occurrence probability is a predetermined value (eg, 80%) In this case, even if each of the plurality of sensors SM does not detect the occurrence of a fire, a warning sound may be generated through the speaker SK.

In one embodiment of the present invention, the fire alarm device 10 calculates the probability of occurrence of a fire using the big data, and when it is determined that the probability of occurrence of a fire is high, it warns in advance before a fire occurs. It can be used as a device.

The non-fire warning determination unit UWA may receive the location information of each of the plurality of sensors SM from the receiver 300 and determine the effectiveness of the third fire detection signal SG-3a based on the location information. have.

The non-fire warning determination unit (UWA) calculates a fire occurrence probability based on the big data and values measured by each of the plurality of sensing units (SM), and when the fire occurrence probability is greater than or equal to a predetermined value, the server transmission unit (ATN) -B) may send a preliminary warning message to the parties 20 .

Although not shown, the first server 400 may include a separate battery therein. In addition, the first server 400 may include a function to record and notify the relevant contents to the concerned people when the power supply applied to the first server 400 is stopped.

The first server 400 may transmit a signal including a correction for the information INF to each of the plurality of sensors. The first server 400 may transmit the received signal SG-3b including the signal to the receiver 300 . The receiver 300 may transmit the received signal SG-2b to the repeater 200 . The repeater 200 may transmit the reception signal SG-1c to the plurality of sensors SM.

The plurality of sensors SM may modify the information INF based on the received signal SG-1c. The corrected information INF may be stored in each of the plurality of sensors SM.

7A is a diagram illustrating a terminal and a communication device of a person concerned according to an embodiment of the present invention, FIG. 7B is a diagram illustrating a terminal of a person concerned according to an embodiment of the present invention, and FIG. 7C is an embodiment of the present invention It shows a communication element according to.

1 and 7A to 7C , the terminal MD may include a smart phone, a desktop, a notebook computer, a tablet PC, or a wearable device. However, this is an example, and the terminal MD of the present invention may include various devices capable of communication. 7 illustrates a smartphone as an example of a terminal (MD) of a person concerned.

A person concerned may remotely control the plurality of sensing units SM, the repeater 200 , the receiver 300 , or the first server 400 using the terminal MD. In this case, the terminal MD may transmit a control signal to the plurality of sensing units SM, the repeater 200 , the receiver 300 , or the first server 400 .

The functions FC1, FC2, FC3, FC4, FC5, and FC6 that can be controlled using the terminal MD include the first function FC1, the second function FC2, the third function FC3, and the fourth function. It may include a function FC4 , a fifth function FC5 , and a sixth function FC6 .

The first function FC1 may be a setting function. The person 20 uses the first function FC1 to input the serial number of each of the plurality of sensing units, input information (contact information) of the parties 20 who will receive the fire alarm message, or a plurality of sensing units. You can input the address of the place where each of the units is installed.

The second function FC2 may be a virtual breaking news test function. The person concerned 20 may use the second function FC2 to check whether the first server 400 normally transmits the fire alarm message from a remote location.

The third function FC3 may be a system check function. The person concerned 20 (refer to FIG. 1 ) uses the third function FC3 to control the operation status of the plurality of sensing units SM, the repeater 200 , the receiver 300 , or the first server 400 (eg, For example, whether the power is normally applied, etc.) can be checked.

The fourth function FC4 may be an upgrade function. The person concerned 20 checks the firmware version of the plurality of sensing units SM, the repeater 200 , the receiver 300 , or the first server 400 remotely using the terminal MD and upgrades the firmware, etc. can proceed.

The fifth function FC5 may be a function in which the user inputs information INF. The information INF includes unique address information of each of the plurality of sensors SM, information about an installation location where each of the plurality of sensors SM is disposed, setting information for each operation of the plurality of sensors SM, and non-fire alarm condition information.

The unique address information of each of the plurality of sensors SM may include a number for distinguishing each of the plurality of sensors SM. The user may input unique address information to be transmitted to one of the plurality of sensors SM into the terminal MD.

Unlike the present invention, in the case of installation after inputting the sensor's prior information (eg, unique address information), the prior information and the information stored in the sensor may not match during installation due to negligence in installation, delivery, or management. have. This may cause the sensor to malfunction. Users are likely to lose confidence in the fire alarm system and be exposed to the risk of fire. However, according to the present invention, the user can input the correct information INF into the terminal MD. That is, the user may input the information INF of each of the plurality of sensors SM after installation. Information discrepancies that may arise due to negligence in installation, delivery, or maintenance can be avoided. Accordingly, it is possible to provide a method for installing a sensor that is easy to install and a fire alarm system (FAS) with improved reliability.

Information on an installation location where each of the plurality of sensors SM is disposed may include an installation location of a sensor installed by a user.

The non-fire warning determination unit UWA of the first server 400 may determine a non-fire warning based on information on an installation location where the sensor included in the third fire detection signal SG-3a is disposed.

The information on the installation location in which each of the plurality of sensors SM is disposed may include first location information on the first location and second location information on a second location different from the first location. For example, the first place may be a restaurant, and the second place may be a house. This will be described later.

The setting information for the operation of each of the plurality of sensors SM may include information about the sensitivity of each of the plurality of sensors SM.

The non-fire alarm condition information may include information about different situations. For example, the non-fire alert condition information may include first non-fire alert information for a first situation and second non-fire alert information for a second situation different from the first situation. This will be described later.

The non-fire warning determination unit UWA of the first server 400 may determine a non-fire report based on the non-fire warning condition information included in the third fire detection signal SG-3a.

Also, the fifth function FC5 may be a function of storing the information INF input by the user.

The terminal connector CN of the terminal MD may be coupled to the communication connector CNT of the communication element CD. The information INF stored in the terminal MD through the fifth function FC5 may be transmitted to the communication device CD and transmitted to the plurality of sensors SM. That is, the information INF may be transmitted through the terminal connector CN and the communication connector CNT.

The communication element CD may be mounted on the terminal MD. The communication device CD may be mounted on the terminal MD to wirelessly communicate with at least one of the plurality of sensors SM. The communication element CD may include a communication connector NCT, a receiver RC, and a transmitter TR.

The communication connector CNT may be coupled to the terminal connector CN of the terminal MD.

The receiver RC may receive the information INF from the terminal MD.

The transmitter TR may transmit the information INF to at least one of the plurality of sensors SM. The transmitter TR and the communication unit ATN (refer to FIG. 3 ) may wirelessly communicate with each other.

Unlike the present invention, in the case of installation after inputting the sensor's prior information (eg, unique address information), the prior information and the information stored in the sensor may not match during installation due to negligence in installation, delivery, or management. have. In this case, the user disassembles each of the installed sensors to re-enter the prior information of the sensor and inputs the prior information. The installation time of the sensor may be prolonged and the installation cost may increase. However, according to the present invention, the user may input the information INF after each of the plurality of sensors SM is installed. A user may wirelessly input information INF into each of the plurality of sensors SM using the communication device CD. Accordingly, it is possible to provide a sensor installation method with reduced installation time and reduced installation cost and a fire alarm system (FAS) using the same.

8 illustrates a plurality of sensors, a terminal, and a communication device according to an embodiment of the present invention.

1 and 8 , a plurality of sensors SMa-1, SMa-2, and SMa-3 may be installed. Each of the plurality of sensors SMa-1, SMa-2, and SMa-3 may be installed to be spaced apart from each other by a predetermined distance DS. The predetermined distance DS may be greater than 2 meters.

The communication device CD may communicate with the plurality of sensors SM only within a predetermined distance PD from the communication device CD. The predetermined distance PD may be 2 meters. The communication device CD may transmit the information INF by selecting one of the plurality of sensors SM disposed within a predetermined distance PD from the communication device CD.

According to the present invention, the information INF may be input to the sensor SMa-1 within a predetermined distance PD. Information INF may not be input to other adjacent sensors SMa-2 and SMa-3. The possibility of incorrectly inputting the information INF into the sensor SMa-1 may be reduced. Accordingly, it is possible to provide a method for installing a sensor with improved reliability and a fire detection system (FAS) using the same.

9 and 10 are views illustrating an operation of a fire alarm system according to an embodiment of the present invention.

1, 9, and 10 , a plurality of sensors SM may be installed and disposed in various places.

For example, FIG. 9 illustrates that a plurality of sensors SMb-1 and SMb-2 are installed in a restaurant where fire is frequently used, and FIG. 10 may be a house that does not use fire frequently. The restaurant may be referred to as a first location, and the house may be referred to as a second location.

A restaurant is likely to use a fire frequently, and the use of a fire can cause smoke. Unlike the present invention, there is a possibility that the plurality of sensors detects the generation of smoke and misjudgs it as a fire situation even though it is not a fire situation. A non-fire report may occur due to the misjudgment. However, according to the present invention, the user may install the plurality of sensors SMb-1 and SMb-2 in the kitchen. Thereafter, the user may input information on the installation location including the first location information on the restaurant to the terminal MD. Information INF including information on an installation location may be stored in the terminal MD. The terminal MD may transmit the information INF to the receiving unit RC (refer to FIG. 7C ) of the communication element CD. The transmitter TR (refer to FIG. 7C ) of the communication element CD may transmit the information INF to the receiver RC (refer to FIG. 7C ). The transmitter TR (refer to FIG. 7C ) may transmit the information INF to each of the plurality of sensors SMb-1 and SMb-2. The plurality of sensors SMb-1 and SMb-2 may transmit the first fire detection signal SG-1 including the information INF to the repeater 200b. The non-fire warning judging unit (UWA) receives data indicating that a fire situation can be misjudged in a space using fire through the big data, and through the third fire detection signal SG-3a including the information INF It is possible to determine the effectiveness of the fire by receiving the first place information. Accordingly, it is possible to provide a fire alarm system (FAS) with improved reliability.

The home is less likely to use a fire and less likely to produce smoke or warm temperatures. Unlike the present invention, if the sensor determines a non-fire report by applying the same criteria as that of a restaurant, the fire situation may be misjudged as a non-fire situation. However, according to the present invention, a user may install a plurality of sensors SMc-1 and SMc-2 in a house. Thereafter, the user may input information on the installation location including the second location information on the house to the terminal MD. Information INF including information on an installation location may be stored in the terminal MD. The terminal MD may transmit the information INF to the receiving unit RC (refer to FIG. 7C ) of the communication element CD. The transmitter TR (refer to FIG. 7C ) of the communication element CD may transmit the information INF to the receiver RC (refer to FIG. 7C ). The transmitter TR (refer to FIG. 7C ) may transmit the information INF to each of the plurality of sensors SMc-1 and SMc-2. The plurality of sensors SMc-1 and SMc-2 may transmit the first fire detection signal SG-1 including the information INF to the repeater 200c. The non-fire warning judging unit (UWA) receives data indicating that a fire situation can be misjudged in a space using fire through the big data, and through the third fire detection signal SG-3a including the information INF By receiving the second location information, it is possible to determine the effectiveness of the fire. Accordingly, it is possible to provide a fire alarm system (FAS) with improved reliability.

That is, the sensitivity of the sensor storing the first place information may be lower than the sensitivity of the sensor storing the second place information.

According to the present invention, the user may install the plurality of sensors SM at any place. Thereafter, the user may input different information INF according to a place where the plurality of sensors SM are installed, and the fire alarm system FAS applies a different fire possibility based on the information INF to generate a fire. can be easily judged. Accordingly, it is possible to provide a method for installing a sensor with improved reliability and a fire alarm system (FAS) using the same.

The information INF may include non-fire alarm condition information. The non-fire alert condition information may include first non-fire alert information for the first situation and second non-fire alert information for the second situation. The daytime period may be referred to as the first situation. The night time zone may be referred to as the second situation.

In a house, it is more likely to use a fire in the kitchen during the daytime, and the use of a fire may cause smoke and/or increase in temperature. Unlike the present invention, there is a possibility that the plurality of sensors detects the generation of smoke or a rise in temperature to erroneously judge the fire situation even though it is not a fire situation. A non-fire report may occur due to the misjudgment. During the night time, the possibility of using a fire in the house is low. When judging a fire based on the same criteria as daytime, it may not be judged as a fire situation even though it is a fire situation. According to the present invention, a user may install a plurality of sensors SMc-1 and SMc-2 in a house. Thereafter, the user may input information on an installation location including the first non-fire information information and the second non-fire information information into the terminal MD. Information INF including non-fire alarm condition information may be stored in the terminal MD. The terminal MD may transmit the information INF to the receiving unit RC (refer to FIG. 7C ) of the communication element CD. The transmitter TR (refer to FIG. 7C ) of the communication element CD may transmit the information INF to the receiver RC (refer to FIG. 7C ). The transmitter TR (refer to FIG. 7C ) may transmit the information INF to each of the plurality of sensors SMc-1 and SMc-2. The non-fire warning judging unit (UWA) receives data indicating that a fire situation can be misjudged according to the situation through the big data, and receives the first fire warning signal (SG-3a) including the information (INF) through the third fire detection signal SG-3a By receiving the disaster information and the second non-fire information information, it is possible to determine the effectiveness of the fire. Accordingly, it is possible to provide a fire alarm system (FAS) with improved reliability.

For example, the sensitivity of the sensor storing the first non-fire information may be lower than the sensitivity of the sensor storing the second fire information.

Although the above has been described with reference to the preferred embodiment of the present invention, those skilled in the art or those having ordinary knowledge in the technical field will not depart from the spirit and technical scope of the present invention described in the claims to be described later. It will be understood that various modifications and variations of the present invention can be made without departing from the scope of the present invention. Accordingly, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

FAS: fire detection system 10: fire alarm system
MD: terminal INF: information
CD: communication element SM: multiple sensors
200: repeater 300: receiver
400: first server

Claims (16)

fire alarm devices that detect fire conditions;
a terminal in which information input from the outside is stored; and
and a communication element mounted on the terminal and receiving the information from the terminal,
The fire alarm device is
a plurality of sensors each of which generates a fire alarm by detecting the occurrence of a fire, and performs RF communication (Radio Frequency communication) with each other;
a repeater performing the RF communication with the plurality of sensors;
a receiver performing the RF communication with the repeater; and
and a server that performs the RF communication with the receiver and includes a server memory,
The communication element transmits the information to the plurality of sensors in wireless communication with the plurality of sensors,
The receiver determines the arrangement relationship of the plurality of sensors based on the information,
The information is
unique address information of each of the plurality of sensors;
information on an installation location where each of the plurality of sensors is disposed;
setting information for each operation of the plurality of sensors; and
Includes non-fire warning condition information,
The non-fire alert condition information includes first non-fire alert information for a first situation and second non-fire alert information for a second situation different from the first situation,
The sensitivity of the sensor storing the first non-fire information is lower than the sensitivity of the sensor storing the second non-fire information. According to claim 1,
Each of the plurality of sensors includes a memory in which unique address information is not stored,
the communication element transmits the information to the memory;
and the memory stores the information. delete According to claim 1,
The information about the installation place includes first place information about a first place and second place information about a second place different from the first place,
the communication element transmits the first location information to a sensor disposed in the first location among the plurality of sensors, and transmits the second location information to a sensor disposed in the second location among the plurality of sensors fire alarm system. 5. The method of claim 4,
The sensitivity of the sensor storing the first place information is lower than the sensitivity of the sensor storing the second place information. delete According to claim 1,
The communication element communicates with the plurality of sensors only within a predetermined distance. 8. The method of claim 7,
The predetermined distance is 2 meters in the fire alarm system. According to claim 1,
The plurality of sensors transmit the information to the server, and the server stores the information in the server memory. According to claim 1,
The server transmits a signal to each of the plurality of sensors,
The information is modified based on the signal and the fire alarm system is stored in each of the plurality of sensors. Installing a plurality of sensors each including a memory in which unique address information is not stored, and detecting the occurrence of a fire;
storing information input from the outside in the terminal;
mounting a communication element in the terminal;
wireless communication between a first sensor and a communication element disposed within a predetermined distance from the communication element among the plurality of sensors;
transmitting, by the communication element, the information to a memory of the first sensor; and
storing the information in the memory; and
The information is
unique address information of each of the plurality of sensors;
information on an installation location where each of the plurality of sensors is disposed;
setting information for each operation of the plurality of sensors; and
Includes non-fire warning condition information,
The non-fire alert condition information includes first non-fire alert information for a first situation and second non-fire alert information for a second situation different from the first situation,
The sensitivity of the sensor storing the first non-fire information is lower than the sensitivity of the sensor storing the second non-fire information. 12. The method of claim 11,
The predetermined distance is a sensor installation method of 2 meters. 12. The method of claim 11,
transmitting the information to a server by the plurality of sensors; and
The sensor installation method further comprising the step of the server storing the information in a server memory. 14. The method of claim 13,
Sensor installation method further comprising the step of the server transmitting a signal to each of the plurality of sensors to correct the information. 14. The method of claim 13,
Sensor installation method further comprising the step of the server identifying the arrangement relationship of the plurality of sensors based on the information. 12. The method of claim 11,
forwarding the information to a receiver; and
The sensor installation method further comprising the step of the receiver identifying the arrangement relationship of the plurality of sensors based on the information.

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