KR102261459B1 - Dualband wireless fire detector, fire detection system including the same, and method thereof - Google Patents

Abstract

A dual-band wireless fire detector is disclosed. The dual-band wireless fire detector includes: a first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol; a fire detection sensor; a control device configured to: generate detection information based on a detection signal output from the fire detection sensor and determines whether a fire has occurred using the detection information; generate a connection request to be transmitted to each of the smart devices and transmit the connection request to the first wireless communication circuit, when it is determined that a fire has occurred; and receive a connection response transmitted from each of the smart devices in response to the connection request through the first wireless communication circuit.

Description

DUALBAND WIRELESS FIRE DETECTOR, FIRE DETECTION SYSTEM INCLUDING THE SAME, AND METHOD THEREOF

An embodiment according to the concept of the present invention relates to a wireless fire detector, and in particular, a dual-band wireless fire detector capable of communicating with a smart device using a wireless communication method of a 2.4 GHz frequency band and communicating with a gateway using a wireless communication method of a 400 MHz frequency band It relates to a detector, a fire detection system including the same, and a method of operating the fire detection system.

In the event of a fire, there are physical and chemical changes in heat, smoke, or flame. A fire detector is a device that detects at least one of physical and chemical changes in heat, smoke, and flame, determines that the detected change is more than a certain amount and continues for a certain period of time or more, and transmits a fire signal to the receiver. is the first to detect The amount of physical and chemical change that is the standard for determining that a fire detector is fire is determined by the detector type approval and verification technology standard rules, and this is called sensitivity.

The wireless fire detector for firefighting is a device that transmits a fire signal to the receiver in the form of a wireless signal, and the most important thing in the wireless fire detector for firefighting is a technology that maximizes the battery replacement cycle according to the capacity of the built-in battery and long-distance communication is possible even with low power It is to implement a low frequency band communication function to make it possible.

Unexamined Patent Publication: Publication No. 10-2019-0108443 (published on September 24, 2019) Registered Patent Publication: Registration No. 10-1421542 (2014.07.23. Announcement) Laid-Open Patent Publication: Publication No. 10-2019-0103522 (published on September 5, 2019)

A technical problem to be achieved by the present invention is a dual-band wireless fire detector capable of communicating with a smart device using a wireless communication method of a 2.4 GHz frequency band and communicating with a gateway using a wireless communication method of a 400 MHz frequency band, and a fire detection system including the same , and to provide a method of operating the fire detection system.

A dual-band wireless fire detector according to the present invention includes a first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol, a fire detection sensor, and a detection signal output from the fire detection sensor. Generates detection information, determines whether a fire occurs using the detection information, generates a connection request to be transmitted to each of the smart devices when it is determined that a fire occurs, and transmits it to the first wireless communication circuit, and the connection and a control device for receiving a connection response transmitted from each of the smart devices in response to the request through the first wireless communication circuit.

The wireless fire detector further includes a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol, and when it is determined that the fire has occurred, the control device is configured to control the smart device based on the connection response Connection information for each of the devices is generated, fire information is generated by adding the connection information to the detection information, and the fire information is transmitted to the gateway through the second wireless communication circuit.

A wireless fire detector according to the present invention includes a first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol, and a second wireless communication circuit capable of communicating with a gateway using a second wireless communication protocol. and, a fire detection sensor, generating detection information based on a detection signal output from the fire detection sensor, determining whether a fire has occurred using the detection information, and determining whether a fire has occurred, the first wireless communication circuit and a control device for controlling operations of both the second wireless communication circuit and controlling only the second wireless communication circuit when it is determined that a fire has not occurred.

A fire detection system for detecting a fire in a building according to the present invention includes a server including a processor executing a monitoring program, a gateway communicating with the server through a wired network, and a dual-band wireless fire detector, The band wireless fire detector includes a first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol, and a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol; Generates detection information based on a fire detection sensor and a detection signal output from the fire detection sensor, determines whether a fire occurs using the detection information, and determines whether a fire has occurred in the building, the first wireless communication and a control device for controlling the operation of both the circuit and the second wireless communication circuit, and controlling only the second wireless communication circuit when it is determined that no fire has occurred in the building.

In a fire detection method using a fire detection system for detecting a fire in a building according to the present invention, the fire detection system includes: a server including a processor executing a monitoring program; a gateway communicating with the server through a wired network; 1 A first wireless communication circuit capable of communicating with smart devices using a wireless communication protocol, a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol, a fire detection sensor, and control The fire detection method includes: receiving, by the control device, a detection signal output from the fire detection sensor; and the control device generating detection information based on the detection signal and using the detection information Determining whether a fire has occurred, and when it is determined that a fire has occurred in the building, the control device controlling the operation of both the first wireless communication circuit and the second wireless communication circuit; and controlling only the second wireless communication circuit when it is determined that it has not occurred.

A dual-band wireless fire detector, a fire detection system including the same, and a method of operating the fire detection system according to an embodiment of the present invention communicate with a smart device in a wireless communication method of a 2.4 GHz frequency band and perform wireless communication in a 400 MHz frequency band There is an effect that can communicate with the gateway in this way.

In order to more fully understand the drawings recited in the Detailed Description of the Invention, a detailed description of each drawing is provided.
1 is a block diagram of a fire detection system according to an embodiment of the present invention.
Fig. 2 is a detailed block diagram of the single installation group shown in Fig. 1;
3 is a block diagram of the wireless fire detection terminal shown in FIG.
FIG. 4 is a block diagram of the gateway shown in FIG. 2 .
5 and 6 are flowcharts for explaining the operation of the fire detection system shown in FIG.

1 is a block diagram of a fire detection system according to an embodiment of the present invention.

Referring to FIG. 1 , a fire detection system 100 that detects whether a fire has occurred in a building in real time and quickly processes the detection result is a single installation group (this is also referred to as 'sub fire detection systems'. 200-1 ~ 200-k, k is a natural number equal to or greater than 3), and a server 500 . Each of the single installation groups 200-1 to 200-k may be installed on the same floor of a building or may be installed on different floors.

At least one wireless fire detector (also referred to as a 'dual-band wireless fire detector') included in each single installation group 200-1 to 200-k of the fire detection system 100 may be used in two different frequency bands. As a wireless fire detector that can be used, a dual-band (dualband) wireless communication method (eg, a first wireless communication protocol (eg, a Bluetooth protocol of a 2.4 GHz frequency band) using a first wireless communication method and a second wireless communication method) All protocols (eg, a second wireless communication method using an Industrial, Scientific and Medical (ISM) protocol of a 400 MHz frequency band) may be used.

Each single installation group 200-1 to 200-k includes one gateway (or one wired and wireless gateway; 400-1 to 400-k) and at least one wireless fire detector installed in at least one detection zone. include It is assumed that at least one smart device exists in the at least one detection zone.

A smart device is a portable wireless communication device capable of outputting a wireless connection response in response to a wireless connection request output from a wireless fire detector, wherein the wireless fire detector and the smart device provide a wireless signal or can receive For example, the smart device and the wireless fire detector may establish a communication link by giving or receiving a wireless connection request and a wireless connection response through handshaking. For example, the smart device may be a smart phone capable of executing a mobile application capable of receiving and displaying a fire alarm (or a fire alarm message) output from a wireless fire detector, but is not limited thereto.

The wireless fire detector and the gateway may transmit or receive a wireless signal using the second wireless communication method.

Each gateway 400-1 to 400-k may transmit or receive a signal to or from a communication device (eg, transceiver) 530 of the server 500 through each wired network NT1 to NTk.

In normal times when a fire does not occur, each gateway 400-1 to 400-k sends report information including each detection information and detector status information of each wireless fire detector to the server ( NT1 to NTk) through each wired network (NT1 to NTk). 500) is sent.

Here, the detection information is a signal (eg, converted into a digital signal) generated by processing (eg, converting into a digital signal) an analog detection signal output from the fire detection sensor included in the wireless fire detector (this is simply referred to as a 'sensing signal'). For example, it means information or data corresponding to a signal converted to be received and processed by a gateway and/or a monitoring program).

Detector status information includes Received Signal Strength Indicator (RSSI) of the wireless fire detector, the voltage level of the battery included in the wireless fire detector, and whether the fire detection sensor included in the wireless fire detector has an error (or malfunction). , and/or whether there is an error (or malfunction) of the wireless fire detector itself. For example, the received signal strength of the wireless fire detector may mean a numerical value of how much power is received from each smart device and/or gateway.

However, when a fire occurs, each gateway 400-1 to 400-k transmits fire information including each detection information and each terminal information to the server 500 through each wired network NT1 to NTk. do.

The terminal information includes detector state information and connection information, and the connection information includes information about each of the smart devices connected to the wireless fire detector using the first wireless communication method (eg, unique identification information of each smart device) and location information of each of the smart devices).

Fig. 2 is a detailed block diagram of the single installation group shown in Fig. 1;

Among the single installation groups 200-1 to 200-k, the structure and operation of the first single installation group 200-1 will be representatively described.

As shown in FIG. 2 , the first single installation group 200-1 includes each wireless fire detector 300-1 to 300- installed in each detection zone (210-1 to 210-m, m is a natural number greater than or equal to 3). m), and one gateway 400-1.

One wireless fire detector 300-1 to 300-m and at least one smart device may exist for each detection zone 210-1 to 210-m. For example, in the first detection zone 210-1, the first wireless fire detector 300-1 and a number of smart devices (220-1 to 220-a, where a is a natural number equal to or greater than 3) may exist. , in the second detection zone 210-2, the second wireless fire detector 300-2 and b smart devices (230-1 to 230-b, b is a natural number greater than or equal to 3) may exist, and the mth In the detection zone 210-m, there may be an mth wireless fire detector 300-m and c smart devices 240-1 to 240-c, where c is a natural number equal to or greater than 3).

Although, in FIGS. 1 and 2, each of k, m, a, b, and c is illustrated as representing a natural number of 3 or more for convenience of explanation, the technical idea of the present invention is included in the fire detection system 100. It is applied regardless of the number of single installation groups, the number of detection zones included in each of the single installation groups, and the number of smart devices present in each of the detection zones.

1 and 2 , each wireless fire detector 300-1 to 300-m uses a first wireless communication method for smart devices 220-1 to 220-a and 230-1 to 230-b. , and 240-1 to 240-c) and built-in a first wireless transceiver, and using the first wireless transceiver, smart devices 220- present in each detection zone 210-1 to 210-m. 1 to 220-a, 230-1 to 230-b, and 240-1 to 240-c) each have a function of acquiring connection information.

Each of the wireless fire detectors 300-1 to 300-m included in the first single installation group 200-1 and the first gateway 400-1 communicate using the second wireless communication method, and the first gateway 400 - 1 and the server 500 communicate through the first wired network NT1 .

Each of the wireless fire detectors included in the second single installation group 200-2 and the second gateway 400-2 communicate using the second wireless communication method, and the second gateway 400-2 and the server ( 500 communicates through the second wired network NT2.

Each of the wireless fire detectors included in the k-th single installation group 200-k and the k-th gateway 400-k communicate using the second wireless communication method, and the k-th gateway 400-k and the server ( 500) communicates through the k-th wired network NTk.

When each wireless fire detector is first installed within each single installation group (200-1 to 200-k), unique identification information that uniquely identifies each wireless smoke detector is the location and location where each wireless smoke detector is installed. In accordance with the above assigned to each wireless fire detector.

When each gateway 400-1 to 400-k is initially installed within each single installation group 200-1 to 200-k, it is uniquely able to uniquely identify each gateway 400-1 to 400-k. Identification information is given to each gateway 400-1 to 400-k, and each unique identification information to uniquely identify each wired network NT1 to NTk wiredly connected to the communication device 530 of the server 500 (For example, an IP address) is assigned to each wired network NT1 to NTk.

Therefore, the monitoring program 520 executed in the server 500 can accurately determine the location of the fire using the unique identification information of each wireless fire detector and the unique identification information of each gateway 400-1 to 400-k. can

Unique identification information for each wireless smoke detector contained within each single installation group (200-1 to 200-k), unique identification information for each gateway (400-1 to 400-k), and each wired network (NT1 to NTk) The unique identification information of is stored in the storage device 540 of the server 500 for each single installation group, and the monitoring program 520 executed by the processor 510 of the server 500 is each stored in the storage device 540 . Manages (eg, reads, writes, retrieves, deletes, and/or updates) unique identification information. The storage device 540 may be a database accessible by the server 500 .

Depending on the structure of the building, the installation environment of the fire detection system 100, and/or the installation scale of the fire detection system 100, the number of single installation groups 200-1 to 200-k to be installed in the building may vary. it is decided

3 is a block diagram of the wireless fire detection terminal shown in FIG.

Since the structure and operation of each of the wireless fire detectors installed in each single installation group 200-1 to 200-k are the same as each other, the first wireless fire detector 300-1 installed in the first single installation group 200-1 ) structure and operation are representatively described.

Referring to FIG. 3 , the first wireless fire detector 300 - 1 includes one or more fire detection sensors 302 , 304 , and/or 306 , a dual-band microcontroller (or control device) 310 , a state A button 360 , an output device 362 , a battery 364 , a radio frequency (RF) switch 370 , a first matching circuit 372 , a first antenna 374 , a second matching circuit 376 , and and a second antenna 378 .

In the conventional wireless fire detector, the wireless transmitting/receiving antenna of the 400 MHz frequency band protrudes to the outside of the housing of the wireless fire detector, but the antennas 374 and 378 according to the present invention are the first wireless fire detector 300- 1) is installed inside the housing to surround and protect, so that the antennas 374 and 378 do not protrude to the outside of the housing.

The first wireless fire detector 300 - 1 may include one fire detection sensor 302 , 304 , or 306 for detecting heat, smoke, or flame, but in FIG. 3 , for convenience of description, three fire detection sensors are used. A first wireless fire detector 300 - 1 including sensors 302 , 304 , and 306 is described.

It is assumed that the first fire detection sensor 302 is a heat detector, it is assumed that the second fire detection sensor 304 is a smoke detector, and it is assumed that the third fire detection sensor 306 is a flame detector.

Each fire detection sensor 302 , 304 , and 306 is configured to detect a fire detection operation whenever a physicochemical change occurs in each detection object (eg, heat, smoke, and flame) or at each detection cycle. Detects the physical and chemical change (or amount of change) of the dual-band microcontroller, and generates each analog detection signal (SS1, SS2, and SS3) corresponding to the detection result, and sends each analog detection signal (SS1, SS2, and SS3) to the dual-band microcontroller 310 to the sensor controller 312 .

The dual-band microcontroller 310 manufactured by one chipset generates (or collects) each sensing information corresponding to each analog sensing signal SS1, SS2, and SS3 (S110), and the first wireless Detector state information for the fire detector 300-1 is generated (or collected) (S115).

The dual-band microcontroller device 310 generates detection information FI1 based on the analog detection signal SS1, SS2, or SS3 output from the fire detection sensor 302, 304, or 306, and the detection information FI1 ) to determine whether a fire has occurred, and when it is determined that a fire has occurred, the operation of the first wireless communication circuit (eg, operation of sending or receiving wireless signals with smart devices, etc.) is controlled and then the second wireless The operation of the communication circuit (eg, the operation of sending or receiving a wireless signal with the gateway, etc.) is sequentially controlled, and when it is determined that a fire has not occurred, the operation of the first wireless communication circuit is not controlled and only the second wireless communication circuit is controlled. It only controls the operation of the communication circuit.

Although step S110 is shown to be performed before step S115 in FIG. 5 , steps S110 and S115 may be performed simultaneously or in parallel, or step S115 may be performed prior to step S110 in FIG. 5 . ) can be performed earlier.

The dual-band microcontroller device 310 includes a sensor controller 312, a main controller (main CPU or control unit; 315), a wireless modem (or 'dual-band wireless modem'; 320), an interface 335, and a memory device ( 340).

The sensor controller 312 receives the analog detection signal SS1 , SS2 , or SS3 output from the fire detection sensor 302 , 304 , or 306 and transmits it to the main controller 315 .

The main controller 315 controls the operation of each of the sensor controller 312 , the wireless modem 320 , the interface 335 , and the memory device 340 .

The main controller 315 converts the first analog detection signal SS1 into a first digital detection signal, converts the second analog detection signal SS2 into a second digital detection signal, and a third analog detection signal SS3 is converted into a third digital sensing signal.

The main controller 315 has a function of encoding a signal to be transmitted through a first wireless communication circuit (or a first wireless communication channel) or a second wireless communication circuit (or a second wireless communication channel) into a signal form capable of wireless transmission; , performs a function of decoding a signal received through the first wireless communication circuit or the second wireless communication circuit into a signal form that can be processed by the main controller 315 .

In order to determine whether a fire has occurred, the main controller 315 compares the first detection value corresponding to the first digital detection signal with the first reference value stored in the memory device 340 and corresponds to the second digital detection signal. The second sensed value and the second reference value stored in the memory device 340 are compared, and the third sensed value corresponding to the third digital sensed signal is compared with the third reference value stored in the memory device 340 (S120). .

When a fire occurs in the first detection zone 210-1 (YES in S125), the operation of the fire detection system 100 will be described with reference to FIGS. 1 to 6 .

When the detection value corresponding to the detection signal SS1, SS2, and/or SS3 output from at least one fire detection sensor among the fire detection sensors 302, 304, and 306 is greater than the reference value, for example, When the first detection value is greater than the first reference value, the second detection value is greater than the second reference value, or the third detection value is greater than the third reference value (YES in S125), the main controller 315 is It is determined that a fire has occurred in the first detection zone 210-1, and only then a connection request is generated and the connection request is transmitted to the first wireless transceiver 322 of the wireless modem 320 (S140). In order to reduce power consumption of the first wireless fire detector 300 - 1 , the main controller 315 generates a connection request only when a fire occurs.

The wireless modem 320 includes a first wireless transceiver 322 that transmits and receives a wireless signal (eg, a wireless signal in a 2.4 GHz frequency band) using a first wireless communication method and a wireless signal ( For example, it includes a second radio transceiver 324 for transmitting and receiving (a radio signal of a 400 MHz frequency band).

For example, when each manufacturer of the wireless transceivers 322 and 324 is different and uses different hardware, simply combining the wireless transceivers 322 and 324 to make one conventional wireless modem module, the main controller 315 must use different protocols for distributed control of different hardware. Accordingly, the power consumption of the wireless modem module is large.

However, in the present invention, as the first wireless transceiver 322 and the second wireless transceiver 324 are built-in (or integrated) into one wireless modem 320, the dual-band microcontroller 310 and the wireless modem 320 ) each hardware structure is minimized, and thus the power consumption of each of the dual-band microcontroller 310 and the wireless modem 320 is minimized. That is, since the power consumed by the wireless modem 320 according to the present invention is smaller than the power consumed by the conventional wireless modem module, the replacement cycle of the battery 364 is maximized or longer.

For example, the first wireless transceiver 322 may perform a function of a beacon or a Bluetooth beacon. A beacon is a wireless communication device capable of automatically recognizing smart devices in a short distance and transmitting necessary information.

Each of the radio transceivers 322 and 324 modulates a signal to be transmitted to the RF switch 370 and demodulates a signal to be transmitted to the main controller 315 .

The first wireless transceiver 322 modulates the connection request into a wireless connection request, and transmits the modulated wireless connection request to the smart devices 220-1 existing in the first detection area 210-1 through the first wireless communication circuit. ~220-a) to broadcast (or transmit) (S140). In order to reduce crosstalk and communication errors with other wireless fire detectors, the first wireless fire detector 300-1 is a smart device that exists within a predetermined distance (eg, 5m) from the first wireless fire detector 300-1. A distance may be limited to communicate with the devices 220-1 to 220-a.

The first wireless communication circuit includes a first wireless transceiver 322 , an RF switch 370 , a first matching circuit 372 , and a first antenna 374 .

The RF switch 370 transmits the signal transmitted from the first wireless transceiver 322 to the first matching circuit 372 , and transmits the signal transmitted from the first matching circuit 372 to the first wireless transceiver 322 . do. The RF switch 370 may be a duplexer. The first matching circuit 372 is used to match the impedance of the RF switch 370 and the impedance of the first antenna 374 .

When each smart device 220-1 to 220-a that has received the wireless connection request generates a wireless connection response and transmits it to the first antenna 374, the wireless connection response is transmitted to the first matching circuit 372 and the RF switch It is transmitted to the first wireless transceiver 322 through 370, and the first wireless transceiver 322 demodulates the wireless connection response of each smart device 220-1 to 220-a as a connection response, and the demodulated connection The responses are transmitted to the main controller 315 (S142). The main controller 315 generates connection information for each smart device 220-1 to 220-a based on the received connection responses.

According to an embodiment, the main controller 315 periodically generates a connection request in order to determine whether the wireless communication state with each smart device 220-1 to 220-a is normal to each smart device 220-1 to 220-a. -a) can perform an operation for sending. In this case, as described above, the main controller 315 may generate connection information for each smart device 220-1 to 220-a based on the received connection responses.

For example, the main controller 315 may estimate a distance between each of the smart devices 220 - 1 to 220 -a and the main controller 315 using each of the connection responses. Accordingly, the main controller 315 may estimate the location of each of the smart devices 220-1 to 220-a. For example, the main controller 315 may determine how many smart devices exist in the first detection zone 210 - 1 using the connection responses.

Upon receiving the connection response of each smart device 220-1 to 220-a, the main controller 315 generates a fire alarm (or fire alarm message), and first detects the fire alarm through a first wireless communication circuit. It is immediately broadcast to the smart devices 220-1 to 220-a existing in the zone 210-1 (S144).

A mobile application executed in each of the smart devices 220-1 to 220-a receives the fire alarm and displays it on a display device of each of the smart devices 220-1 to 220-a. Accordingly, the owner of each of the smart devices 220-1 to 220-a can recognize the occurrence of a fire and evacuate quickly.

After immediately broadcasting the fire alarm to the smart devices 220-1 to 220-a existing in the first detection zone 210-1 (S144), the main controller 315 transmits the first wireless fire detector 300 -1) generates terminal information TI1 including detector status information DSI1 and connection information CI1 (S146), and detector fire information SIF2 including detection information FI1 and terminal information TI1 ) and transmits the detector fire information (SIF2) to the second wireless transceiver 324 of the wireless modem 320 using the second wireless communication method.

The detector fire information SIF2 includes a signal indicating that a fire has occurred in the first detection zone 210-1, and the connection information CI1 includes the first wireless fire detector 300 through steps S140 and S142. -1) includes connection information of each of the smart devices 220-1 to 220a connected to it. The detector fire information (SIF2) includes detector report information (SIF1) and connection information (CI1), and each of the detector report information (SIF1) and detector fire information (SIF2) is unique to the first wireless fire detector 300-1. It may include identification information SID1.

The second wireless transceiver 324 transmits the detector fire information SIF2 to the antenna 447 of the first gateway 400-1 through the second wireless communication circuit (S148).

The second wireless communication circuit includes a second wireless transceiver 324 , an RF switch 370 , a second matching circuit 376 , and a second antenna 378 .

The RF switch 370 transmits the signal transmitted from the second wireless transceiver 324 to the second matching circuit 376 , and transmits the signal transmitted from the second matching circuit 376 to the second wireless transceiver 324 . do. The second matching circuit 376 is used to match the impedance of the RF switch 370 and the impedance of the second antenna 378 .

The first gateway 400-1 receives the detector fire information SIF2 transmitted from the first wireless fire terminal 300-1 and generates an ACK (Acknowledge) signal in response thereto to generate an ACK (Acknowledge) signal. 1) is sent to The main controller 315 of the first wireless fire terminal 300-1 receives and analyzes the ACK signal through the second wireless communication circuit.

As a result of analyzing the ACK signal, when it is confirmed that the detector fire information SIF2 has been normally transmitted to the first gateway 400-1, the main controller 315 terminates the transmission of the detector fire information SIF2.

However, the ACK signal is not received from the first gateway 400-1 within a predetermined time, or as a result of analyzing the received ACK signal, the detector fire information SIF2 is not normally transmitted to the first gateway 400-1. When this is confirmed, the main controller 315 starts an operation of transmitting the detector fire information SIF2 back to the first gateway 400 - 1 . Accordingly, the detector fire information SIF2 may be stably transmitted to the first gateway 400 - 1 .

When a fire occurs, the main controller 315 generates a control signal and transmits the control signal to the output device 362 through the interface 335 . According to the control of the main controller 315, the interface 335 may control the output device 362 to notify the outside of the fire. The output device 362 may include a speaker or LEDs.

When the output device 362 includes LEDs, the interface 335 may control a color and/or a blinking period of each of the LEDs according to the control of the main controller 315 .

For example, a first LED of the LEDs is operated in conjunction with the first fire detection sensor 302 , a second LED of the LEDs is operated in conjunction with a second fire detection sensor 304 , and the third LED of the LEDs When is operated in conjunction with the third fire detection sensor 306, people around the first wireless fire detector 300-1 can check whether a fire is detected by a specific fire detection sensor according to the operation of a specific LED. .

Battery 364 supplies an operating voltage PW to dual band microcontroller 310 and at least one of components 302 , 304 , 306 , 360 , 362 , 370 , 372 , and 376 . The battery 364 may be a lithium polymer battery, but is not limited thereto. The operating voltage PW collectively refers to one voltage or more voltages.

Referring to FIG. 4 , the detector fire information SIF2 is transmitted to the modem (or wireless modem) 425 through the wireless communication circuit of the first gateway 400-1. The wireless communication circuit may include an antenna 447 and a matching circuit 445 , and may further include an RF switch 440 according to an embodiment. The RF switch 440 may be a duplexer. The function of the RF switch 440 is the same as that of the RF switch 370 , and the function of the matching circuit 445 is the same as that of the matching circuit 372 or 376 .

The modem 425 demodulates the detector fire information (SIF2) and transmits it to the main controller 420, and the main controller 420 decodes the demodulated detector fire information (SIF2) to generate the gateway fire information (GIF2), The gateway fire information GIF2 is transmitted to the host central processing unit 460 through the interface 435 .

The gateway fire information (GIF2) generated by the main controller 420 includes unique identification information (GID1) of the first gateway 400-1, unique identification information (SID1) of the first wireless fire detector 300-1, detection information FI1, detector state information DSI1 of the first wireless fire detector 300-1, and smart devices 220-1 to 220-a connected to the first wireless fire detector 300-1 connection information (CI1) for

Under the control of the host central processing unit 460 , the Ethernet controller 470 transmits the gateway fire information GIF2 to the communication device 530 of the server 500 through the first wired network NT1 ( S150 ).

The processor 510 of the server 500 stores the gateway fire information (GIF2) received through the communication device 530 in the storage device 540 . The storage device 540 stores design drawing information (DWI) of a building in which the fire detection system 100 is installed and installation location information (DII) for each of all wireless fire detectors included in the fire detection system 100 .

The monitoring program 520 executed by the processor 510 collects and analyzes the gateway fire information GIF2, and processes the analysis result.

In the event of a fire, the monitoring program 520 starts an operation of transmitting an emergency message notifying the occurrence of a fire to the operating entity and/or related organizations (eg, a fire station and/or a police station) (S152).

The monitoring program 520 uses the connection information (CI1), the design drawing information (DWI), and the installation location information (DII) included in the gateway fire information (GIF2) in the first detection zone 210-1. The total number of existing smart devices 220-1 to 220-a and/or the locations of each of the smart devices 220-1 to 220-a may be displayed on the monitor 550 in real time (S154) .

For example, the connection information for the smart device 230-1 that exists in the portion where the first detection zone 210-1 and the second detection zone 210-2 overlap is the first single installation group 200- It is included in the first connection information of the first gateway fire information output from 1) and is also included in the second connection information of the second gateway fire information output from the second single installation group 200 - 2 .

Since the connection information for the smart device 230-1 is redundant information, the monitoring program 520 removes the connection information for the smart device 230-1 from any one of the first connection information and the second connection information, As a result of the removal, the total number of smart devices existing in the detection zones 210-1 and 210-2 using the design drawing information (DWI), and the installation location information (DII) (eg, the total number = a+b-1) and/or the location of each of the smart devices may be displayed on the monitor 550 in real time (S154).

Therefore, the monitoring program 520 determines which smart device is a dangerous location (eg, whether it is blocked from the outside or isolated inside) among the smart devices 220-1 to 220-a, and through the monitor 550 Thus, the rescuer can selectively and urgently rescue people from among the people included in the first detection zone 210-1, and there is an effect that can take measures for rapid fire suppression.

Referring to FIG. 4 , the first gateway 400 - 1 includes a DC power supply 450 , a charging circuit (or charging control circuit) 452 , and a battery 454 .

The DC power source 450 serves to supply a DC voltage to the first gateway 400 - 1 , and the charging circuit 452 controls a charging operation of the battery 454 using the DC voltage. The battery 454 supplies a charging voltage to the components of the first gateway 400 - 1 in preparation for a temporary power outage or an emergency situation. The DC voltage of the DC power source 450 and the charging voltage of the battery 454 are selected from the control unit 410 , the host central processing unit 460 , and at least one of the components 440 , 445 , 465 , 470 , and 475 . Supplied in configuration.

When an unexpected error occurs in the first gateway 400-1 due to internal or external factors, the reset button 465 of the first gateway 400-1 resets the first gateway 400-1. Used to reset or reboot.

The output device 475 of the first gateway 400-1, for example, LEDs, is connected to the first wired network NT1 according to the control of the host central processing unit 460 whether the voltage of the DC power source 450 is supplied or not. It displays whether the Ethernet controller 470 is connected and/or whether information (SIF1 or SIF2) transmitted from each wireless fire detector 300-1 to 300-m is received (or reception status), and the like. Accordingly, since the manager of the first gateway 400-1 can check the blinking state and/or blinking period of each of the LEDs, management of the first gateway 400-1 can be facilitated.

The first gateway 400-1 includes a control device 410 and an Ethernet controller 470 that are independently separated from each other, and the host central processing unit 460 includes at least one peripheral device connected to the control device 410 and Since at least one peripheral device connected to the Ethernet controller 470 can be controlled in a distributed manner, the host central processing unit 460 can stably process a large amount of data and process a large amount of resources.

The first gateway 400-1 monitors the report information (SIF1) and/or the fire information (SIF2) transmitted at regular intervals from each of the wireless fire detectors 300-1 to 300-m, and the missing information and / or detect erroneous information, and report information (SIF1) and / or fire to the wireless fire detector that transmits the missing and / or erroneous information among the wireless fire detectors (300-1 to 300-m) Retransmission of information (SIF2) may be requested.

The monitoring program 520 analyzes the report information (SIF1) and/or the fire information (SIF2) transmitted from each of the wireless fire detectors 300-1 to 300-m for each wireless fire detector and/or for each time period, and analyzes The result may be stored in the storage device 540 . Accordingly, as the report information SIF1 and/or the fire information SIF2 is utilized, it is possible to provide a stable operation service for the fire detection system 100 .

When a fire does not occur in the first detection zone 210-1 (NO in S125), the operation of the fire detection system 100 will be described with reference to FIGS. 1 to 5 .

When the first detection value is less than or equal to the first reference value, the second detection value is equal to or less than the second reference value, and the third detection value is less than or equal to the third reference value, the main controller 315 fires is determined not to have occurred and generates the sensor report information SIF1 including the detection information FI1 and the sensor status information DSI1, and transmits the sensor report information SIF1 to the second wireless transceiver 324 of the wireless modem 320. ) is sent to

The second wireless transceiver 324 transmits the sensor report information SIF1 to the antenna 447 of the first gateway 400-1 through the second wireless communication circuit (S130).

The first gateway 400-1 receives the detector report information SIF1 transmitted from the first wireless fire detector 300-1, and in response generates an ACK signal to the first wireless fire terminal 300-1. send. The main controller 315 of the first wireless fire terminal 300-1 receives and analyzes the ACK signal through the second wireless communication circuit.

As a result of analyzing the ACK signal, if it is confirmed that the sensor report information SIF1 has been normally transmitted to the first gateway 400-1, the main controller 315 ends the transmission of the sensor report information SIF1.

However, as a result of not receiving the ACK signal from the first gateway 400-1 within a predetermined time or analyzing the received ACK signal, the detector report information SIF1 was not normally transmitted to the first gateway 400-1. If this is confirmed, the first wireless fire terminal 300-1 starts an operation of transmitting the detector report information SIF1 back to the first gateway 400-1.

Referring to FIG. 4 , the sensor report information SIF1 is transmitted to the modem 425 through the wireless communication circuit of the first gateway 400 - 1 .

The modem 425 demodulates the sensor report information (SIF1) and transmits it to the main controller 420, and the main controller 420 decodes the demodulated sensor report information (SIF1) to generate the gateway report information (GIF1), The gateway report information GIF1 is transmitted to the host central processing unit 460 through the interface 435 .

The gateway report information (GIF1) generated by the main controller 420 includes unique identification information (GID1) of the first gateway 400-1, unique identification information (SID1) of the first wireless fire detector 300-1, It includes detection information FI1 and detector state information DSI1 of the first wireless fire detector 300-1.

Under the control of the host central processing unit 460 , the Ethernet controller 470 transmits the gateway report information GIF1 to the communication device 530 of the server 500 through the first wired network NT1 ( S132 ).

The processor 510 of the server 500 stores the gateway report information GIF1 received through the communication device 530 in the storage device 540 . The monitoring program 520 executed by the processor 510 collects and analyzes the gateway report information GIF1, and processes the analysis result (S134).

The report information collectively refers to the detector report information (SIF1) and the gateway report information (GIF1), and the fire information collectively refers to the detector fire information (SIF2) and the gateway fire information (GIF2).

In combination with hardware (eg, control device 310 or 315 ) a medium (eg, main controller 315 ) for processing (eg, generating and transmitting) reporting information or fire information according to the present invention. The computer program (or firmware) stored in the internal memory or memory device 340) is based on the detection information FI1 based on the analog detection signal SS1, SS2, or SS3 output from the fire detection sensor 302, 304, or 306. ), determine whether a fire has occurred using the detection information FI1, and when it is determined that a fire has occurred, the operation of the first wireless communication circuit (for example, the operation of sending or receiving wireless signals with smart devices; etc.), then sequentially control the operation of the second wireless communication circuit (eg, operation of sending or receiving a wireless signal with the gateway, etc.), and when it is determined that a fire has not occurred, the operation of the first wireless communication circuit It is possible to control only the operation of the second wireless communication circuit without controlling the .

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

100: fire detection system 200-1~200-k: single installation group
300-1~300-m: wireless fire detector 302, 304, 306: fire detection sensor
310: dual-band microcontroller 312: sensor controller
315: main controller 320: wireless modem
322: first radio transceiver 324: second radio transceiver
335: interface 340: memory device
360: status button 362: output device
364: battery 370: RF switch
372: first matching circuit 374: first antenna
376: second matching circuit 378: second antenna
400-1 to 400-k: Gateway 410: Control Unit
420: main controller 425: modem
460: host central processing unit 470: Ethernet controller
500: server 510: processor
520: monitoring program 530: communication device
540: storage device
550: monitor

Claims (17)

In the dual-band wireless fire detector present in the detection zone,
a first wireless communication circuit capable of communicating with smart devices existing in the detection zone using a first wireless communication protocol;
fire detection sensor; and
Generates detection information based on the detection signal output from the fire detection sensor, determines whether a fire occurs using the detection information, and generates a connection request to be transmitted to each of the smart devices when it is determined that a fire has occurred and a control device for transmitting to the first wireless communication circuit and receiving a connection response transmitted from each of the smart devices in response to the connection request through the first wireless communication circuit,
The control device is a dual-band wireless fire detector for estimating the location of each of the smart devices using the connection response transmitted from each of the smart devices and determining how many smart devices are present in the detection area. According to claim 1,
Further comprising a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol,
When it is determined that the fire has occurred, the control device generates connection information for each of the smart devices based on a connection response transmitted from each of the smart devices, and adds the connection information to the detection information to provide fire information and transmitting the fire information to the gateway through the second wireless communication circuit,
The connection information for each of the smart devices includes unique identification information of each of the smart devices and location information of each of the smart devices. 3. The method of claim 2,
When it is determined that the fire has occurred, the control device generates a fire alarm, transmits the fire alarm to each of the smart devices that have transmitted the connection response through the first wireless communication circuit, and transmits detector fire information A dual-band wireless fire detector that is generated and transmitted to the gateway through the second wireless communication circuit. 3. The method of claim 2,
further comprising an output device;
When it is determined that the fire has occurred, the control device controls the output device to display a fire occurrence. 3. The method of claim 2,
When it is determined that the fire has not occurred, the control device generates report information including the detection information, and transmits the report information to the gateway through the second wireless communication circuit. a first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol;
a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol;
fire detection sensor; and
To generate detection information based on the detection signal output from the fire detection sensor, determine whether a fire has occurred using the detection information, and transmit a fire alarm to the smart devices when it is determined that a fire has occurred. 1 After controlling the wireless communication circuit, sequentially controlling the second wireless communication circuit to transmit the detector fire information to the gateway, and controlling only the second wireless communication circuit when it is determined that the fire has not occurred. Dual-band wireless smoke detector included. 7. The method of claim 6,
When it is determined that the fire has occurred, the control device acquires connection information for each of the smart devices communicating with the first wireless communication circuit, and adds connection information for each of the smart devices to the detection information generating fire information and transmitting the fire information to the gateway through the second wireless communication circuit;
When it is determined that the fire has not occurred, the control device generates report information including the detection information and transmits the report information to the gateway through the second wireless communication circuit. 8. The method of claim 7,
further comprising a battery,
whether the control device receives signal strength for at least one of the first wireless communication circuit and the second wireless communication circuit, the level of the battery, whether the fire detection sensor is malfunctioning, and whether the dual-band wireless fire detector itself is faulty generating detector state information comprising
When it is determined that the fire has occurred, the control device generates the fire information by adding connection information for each of the smart devices to the detection information and the sensor state information,
When it is determined that the fire has not occurred, the control device generates the report information including the detection information and the detector status information. 8. The method of claim 7,
When it is determined that the fire has occurred, the control device generates the fire alarm and transmits the fire alarm to each of the smart devices through the first wireless communication circuit. In the fire detection system for detecting the occurrence of fire in a building,
a server including a processor executing a monitoring program;
a gateway communicating with the server through a wired network; and
Includes a dual-band wireless smoke detector,
The dual-band wireless fire detector,
a first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol;
a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol;
fire detection sensor; and
Generates detection information based on the detection signal output from the fire detection sensor, determines whether a fire occurs using the detection information, and sends a fire alarm to each of the smart devices when it is determined that a fire has occurred in the building After controlling the first wireless communication circuit to transmit, the second wireless communication circuit is sequentially controlled to transmit detector fire information to the gateway, and when it is determined that the fire has not occurred in the building, the second wireless communication A fire detection system comprising a control device that only controls the circuit. 11. The method of claim 10,
When it is determined that a fire has occurred in the building,
The control device obtains connection information for each of the smart devices communicating with the first wireless communication circuit, and adds connection information for each of the smart devices to the detection information to generate the detector fire information transmit to the gateway through a second wireless communication circuit;
the gateway transmits the detector fire information to the server through the wired network,
The monitoring program is a fire detection system for generating the total number of the smart devices and the location information of each of the smart devices by using the connection information for each of the smart devices. 12. The method of claim 11,
The server further comprises a storage device for storing design drawing information for the building and installation location information of the dual-band wireless fire detector,
The monitoring program uses the design drawing information, the installation location information, and the connection information for each of the smart devices to generate the total number of the smart devices and the location information of each of the smart devices in the dangerous location fire detection system. 12. The method of claim 11,
When it is determined that a fire has occurred in the building,
The control device is
Generates a connection request to be transmitted to each of the smart devices and transmits it to the first wireless communication circuit, and receives a connection response transmitted from each of the smart devices in response to the connection request through the first wireless communication circuit, , generate connection information for each of the smart devices based on the connection response,
A fire detection system for generating the fire alarm and transmitting the fire alarm to each of the smart devices that have transmitted the connection response through the first wireless communication circuit. 12. The method of claim 11,
When it is determined that the fire has not occurred in the building,
The control device does not acquire the connection information using the first wireless communication circuit,
generating report information including the detection information and transmitting it to the gateway through the second wireless communication circuit;
the gateway transmits the report information to the server through the wired network;
The monitoring program is a fire detection system for generating analysis information by analyzing the report information. In a fire detection method using a fire detection system for detecting a fire in a building,
The fire detection system is
a server including a processor executing a monitoring program;
a gateway communicating with the server through a wired network; and
A first wireless communication circuit capable of communicating with smart devices using a first wireless communication protocol, a second wireless communication circuit capable of communicating with the gateway using a second wireless communication protocol, a fire detection sensor; comprising a control device;
The fire detection method comprises:
receiving, by the control device, a detection signal output from the fire detection sensor;
generating, by the control device, detection information based on the detection signal, and determining whether a fire has occurred using the detection information;
When it is determined that a fire has occurred in the building, the control device controls the first wireless communication circuit to transmit a fire alarm to each of the smart devices, and then the second wireless communication to transmit detector fire information to the gateway sequentially controlling the circuit; and
and controlling only the second wireless communication circuit when it is determined that the fire has not occurred in the building. 16. The method of claim 15,
When it is determined that a fire has occurred in the building,
obtaining, by the control device, connection information for each of the smart devices communicating with the first wireless communication circuit;
Step, by the control device, adding connection information for each of the smart devices to the detection information to generate the detector fire information and transmitting it to the gateway through the second wireless communication circuit:
transmitting, by the gateway, the detector fire information to the server through the wired network; and
The method further comprising the step of generating, by the monitoring program, the total number of the smart devices and location information of each of the smart devices by using the connection information for each of the smart devices. 17. The method of claim 16,
When it is determined that the fire has not occurred in the building,
generating, by the control device, report information including the detection information, and transmitting the report information to the gateway through the second wireless communication circuit;
transmitting, by the gateway, the report information to the server through the wired network; and
Fire detection method further comprising the step of generating analysis information by analyzing the report information by the monitoring program.

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