KR20170003377A - Apparatus for watching fire remotely and method therof - Google Patents

Abstract

The present invention relates to an apparatus and a method to remotely monitor a fire, capable of precisely providing the location of an outbreak of fire. The apparatus of the present invention comprises: a plurality of fire detection sensors which detect a fire; a P-shaped receiver which receives a fire detection signal transmitted by a fire detection sensor detecting the fire among the fire detection sensors; and a fire signal repeater which receives the fire detection signal received by the P-shaped receiver to initialize the fire detection sensor transmitting the fire detection signal, and transmits, to a control server, the fire signal including identification information of the fire detection sensor transmitting the fire detection signal, again when the initialized fire detection sensor transmits the fire detection signal.

Description

FIELD OF THE INVENTION The present invention relates to a device for monitoring a fire remotely,

FIELD OF THE INVENTION The present invention relates to fire monitoring technology, and more particularly, to an apparatus and method for remotely monitoring a fire.

A P-type receiver receives a fire signal from a detector or a transmitter through a direct or repeater and receives signals in a common signal. The meaning of the P type is proprietary proprietary, and uses P in the sense of occupancy, monopoly, and so on. When a P-Class 1 receiver receives a fire signal, it shall automatically display the red fire and the boundary zone where the fire occurred, and shall automatically indicate the main sound system and the earth sound system. The fire signal should be clearly displayed even when receiving two signals at the same time, and the time from receipt start to fire marking should be within 5 seconds. The switch does not automatically return to the correct position when the switch is in operation. In addition, the fire indication must be maintained unless it is manually restored, and there is a fire indication test device that can easily confirm the operation, a conduction test device which can easily check the conduction of the detector signal circuit per circuit, And a voltmeter capable of monitoring the circuit voltage. The structure and function of the P-type Grade 2 receiver are almost the same as those of the P-type Grade 1 receiver, but the number of lines that can be connected is limited to 5 lines or less.

Korean Published Patent No. -2009-0081942 Published on July 29, 2009 (Name: Fire Extinguishing System Monitoring Device)

It is an object of the present invention to provide an apparatus and a method for remotely monitoring a fire by providing a fire signal repeater in addition to a P-type receiver installed in the past to more precisely provide a fire occurrence location.

It is another object of the present invention to provide a device for monitoring a fire capable of providing a precise evacuation route by providing an announcement based on precise location of fire occurrence, and a method therefor.

In particular, it is another object of the present invention to provide an apparatus and method for monitoring a fire capable of providing an environment for allowing people to safely escape by preventing smoke from diffusing from a predetermined area at the beginning of a fire.

According to another aspect of the present invention, there is provided an apparatus for monitoring a fire, comprising: a smoke diffusion delay device installed in each of a plurality of zones of a building; A P-type receiver for receiving a fire detection signal transmitted from a fire detection sensor that detects a fire among the plurality of fire detection sensors, a P-type receiver for receiving a fire detection signal A fire signal repeater for transmitting a fire signal including identification information and sensor information of the fire detection sensor to the fire detection sensor through the identification information of the fire detection sensor, , Setting a part of a plurality of zones of the building as a delay zone based on the location of the fire occurrence, And a control server for transmitting a delay command for causing the delay device to discharge smoke caused by the fire.

Wherein the control server receives the fire signal, and a control unit for controlling the control unit in accordance with the physical properties of the material including walls, ceiling and floor, the combustion area according to the temperature increase rate and the smoke amount increase rate for each material, An escape time which is an estimate of the time it takes for a person in the building to escape to the exit of the building to the farthest person from the exit of the building after the fire signal is received; Estimating a combustion area that is an area of a material that can be burned during the escape time, deriving an amount of smoke generated in accordance with the estimated combustion area, and calculating, based on the amount of the derived smoke, And a control unit for selecting a delay zone, which is at least one zone that can accommodate the smoke to prevent the smoke from diffusing to the outside.

에 따라 상기 탈출 시간을 산출하며, 상기 Te는 탈출 시간이고, 상기 Dp는 복도의 거리이고, 상기 Vp는 사람이 복도를 걷는 속도이고, 상기 Ds는 계단의 거리이고, 상기 Vs는 사람이 계단을 걷는 속도이고, 상기 Cd는 도어의 수이며, 상기 Td는 사람이 문을 여닫을 때 걸리는 시간인 것을 특징으로 한다. The controller

Where Dp is the distance of the corridor, Vp is the speed at which a person walks the corridor, Ds is the distance of the stairs, Vs is the distance between the person and the stairs, Walking speed, Cd is the number of doors, and Td is a time taken for a person to open and close the door.

And the control unit transmits a delay command through the communication unit, the delay command including a smoke exhaust path for causing the smoke diffusion delay device in the delay zone to discharge the smoke.

According to another aspect of the present invention, there is provided a method for monitoring a fire, the method comprising the steps of: receiving a fire detection signal transmitted from a fire detection sensor of a plurality of fire detection sensors to a P- Transmitting a fire signal including identification information and sensor information of a fire detection sensor that has transmitted a fire detection signal to a control server; and identifying the fire occurrence location through the identification information of the fire detection sensor And setting a part of a plurality of zones of the building as a delay zone based on the location of the fire occurrence and transmitting a delay command for causing the smoke diffusion delay device of the delay zone to discharge smoke caused by the fire.

The step of transmitting the delay command may include calculating an escape time, which is an estimate of a time required for a person in the building to escape to the exit of the building from a person farthest from the exit of the building after receiving the fire signal from the control server Estimating a combustion area that is an area of a material that can be burned during the escape time by the control server, deriving an amount of smoke generated according to the estimated combustion area, And selecting the delay zone, which is at least one zone that can accommodate the smoke out of the plurality of zones during the escape time so that the smoke does not diffuse to the outside.

에 따라 상기 탈출 시간을 산출하며, 상기 Te는 탈출 시간이고, 상기 Dp는 복도의 거리이고, 상기 Vp는 사람이 복도를 걷는 속도이고, 상기 Ds는 계단의 거리이고, 상기 Vs는 사람이 계단을 걷는 속도이고, 상기 Cd는 도어의 수이며, 상기 Td는 사람이 문을 여닫을 때 걸리는 시간인 것을 특징으로 한다. Wherein the step of calculating the escape time comprises:

Where Dp is the distance of the corridor, Vp is the speed at which a person walks the corridor, Ds is the distance of the stairs, Vs is the distance between the person and the stairs, Walking speed, Cd is the number of doors, and Td is a time taken for a person to open and close the door.

The step of transmitting the delay command includes transmitting a delay command including a smoke-emitting path for causing the smoke-diffusion delay device in the delay zone to discharge smoke.

According to an aspect of the present invention, there is provided an apparatus for monitoring a fire, including a plurality of fire detection sensors for detecting a fire, and a fire detection sensor for detecting a fire among the plurality of fire detection sensors Type receiver that receives a fire detection signal received by the P-type receiver, initializes a fire detection sensor that transmits a fire detection signal, and the initialized fire detection sensor detects a fire again And a fire signal repeater for transmitting a fire signal including the identification information of the fire detection sensor which transmitted the fire detection signal to the control server.

And a plurality of beacons provided corresponding to each of the plurality of fire detection sensors, wherein each of the plurality of beacons includes a guide point for guiding a evacuation route derived based on a fire occurrence position, And transmits the announcement message to the user device so as to output the announcement message.

Wherein each of the plurality of beacons transmits to the user device an announcement notice indicating a direction of evacuation from a reference object within a predetermined distance from a position where each of the plurality of beacons is installed.

The fire detection system according to any one of claims 1 to 3, further comprising: a fire detection unit for detecting a fire occurrence location based on the identification information of the fire detection sensor that transmitted the fire detection signal, deriving a fire escape route based on the specified fire occurrence location, Further comprising a control server for generating an announcement announcing a evacuation direction from a reference object within a predetermined distance from a position where each of the plurality of beacons is installed and transmitting the generated announcement message .

According to another aspect of the present invention, there is provided a method for monitoring a fire, the method comprising the steps of: receiving a fire detection signal transmitted from a fire detection sensor of a plurality of fire detection sensors to a P- The method comprising the steps of: initializing a fire detection sensor to which the fire detection signal has been transmitted; and, when the initialized fire detection sensor transmits a fire detection signal again, And transmitting the fire signal to the control server.

Further comprising the step of transmitting the announcement to the user device so that a user device that has entered the communication range outputs an announcement that guides the evacuation route derived based on the fire occurrence location through each of the plurality of beacons.

According to the present invention as described above, the fire signal repeater can be installed in the P-type repeater to accurately detect the location of the fire. Furthermore, since the evacuation route is derived based on the position where the fire occurs, and the derived evacuation route is guided through the beacon, the user can safely evacuate along the evacuation route.

1 is a block diagram for explaining a fire monitoring system according to an embodiment of the present invention.
2 is a block diagram for explaining a fire monitoring apparatus related to one P-type receiver in the fire detection system of FIG.
3 is a block diagram for explaining a detailed configuration of a fire signal repeater in the fire detection system of FIG.
4 is a block diagram illustrating a configuration of a control server according to an embodiment of the present invention.
5 is a flowchart illustrating a method for monitoring a fire according to an embodiment of the present invention.
6 is a timing chart for explaining a method for determining whether a fire has occurred according to an embodiment of the present invention.
7 is a flowchart for explaining a method for providing a notification according to an embodiment of the present invention.
8 is a view for explaining an announcement item according to an embodiment of the present invention.
9 is a view for explaining a method of providing a guide ment according to an embodiment of the present invention.
10 and 11 are views for explaining a smoke diffusion delay device 500 according to an embodiment of the present invention.
12 and 13 are flowcharts for explaining a method for monitoring a fire according to another embodiment of the present invention.
14 is a view for explaining a method for monitoring a fire according to another embodiment of the present invention.

Prior to the detailed description of the present invention, the terms or words used in the present specification and claims should not be construed as limited to ordinary or preliminary meaning, and the inventor may designate his own invention in the best way It should be construed in accordance with the technical idea of the present invention based on the principle that it can be appropriately defined as a concept of a term to describe it. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some of the elements in the accompanying drawings are exaggerated, omitted, or schematically shown, and the size of each element does not entirely reflect the actual size.

First, a fire monitoring system including an apparatus for monitoring a fire according to an embodiment of the present invention will be described. 1 is a block diagram for explaining a fire monitoring system according to an embodiment of the present invention. FIG. 2 is a block diagram for explaining a fire monitoring apparatus related to one P-type receiver in the fire detection system of FIG. 1, FIG. 3 is a block diagram for explaining a detailed configuration of a fire signal repeater in the fire detection system of FIG. .

Referring to FIG. 1, a fire monitoring system according to an embodiment of the present invention includes a P-type receiver 100, a fire signal repeater 200, a sensor unit 300, and a control server 400. In each of the plurality of P-type receivers 100, a fire signal repeater 200 is configured, and a plurality of sensor units 300 are connected correspondingly to the respective P-type receivers 100. In addition, the plurality of P-type receivers 100 and the fire signal repeater 200 are connected to the control server 400. Here, the control server 400 is a computing device, and may be exemplified by a personal computer, a server-class computer, and the like.

Referring to FIG. 2, the sensor unit 300 includes a plurality of fire detection sensors 310 and a plurality of beacons 320. According to the embodiment of the present invention, the pair of fire detection sensors 310 and the beacons 320 are installed at the same position. The fire detection sensor 310 is for detecting a fire. The fire detection sensor 310 may be a heat detection sensor, a smoke detection sensor, or the like. When any of the fire detection sensors 310 detects a fire, it transmits a fire detection signal. The beacon 320 may be a communication device according to the Bluetooth 4.0 BLE. The beacon 320 automatically connects with another user device 600 within a predetermined communication range to transmit the announcement message according to the embodiment of the present invention. Here, the user device 600 is a portable device having a communication function capable of performing short-range communication, for example, Bluetooth communication, and can be typically a smart phone.

The P-type receiver 100 includes a P-type receiver control unit 110. The P-type receiver control unit 110 may receive a fire detection signal from the fire detection sensor 310. Meanwhile, the fire signal repeater 200 is installed inside the P-type receiver 100. In particular, the fire signal repeater 200 is installed to receive a fire detection signal transmitted by the fire detection sensor 310 and to transmit a control signal for initializing the fire detection sensor 310. The fire signal repeater 200 is connected to each beacon 320 and receives announcements to be transmitted from the control server 200 to the beacons 320 to the user device 600 to be transmitted to the beacons 320 do.

The conventional P-type receiver 100 notifies the occurrence of a fire when receiving a fire detection signal from any one of the plurality of connected fire detection sensors 310. do. When the P-type receiver 100 notifies the occurrence of the fire, information on the location of the provided fire is provided on a district basis. In other words, since the position where the plurality of fire detection sensors 310 connected to the P-type receiver 100 are located can not be known, if any one of the fire detection sensors connected to the P-type receiver 100 detects a fire, It is the extent to which the receiver 100 is informed that a fire has occurred on the earth where it is installed. For example, in the case of an apartment, one P-type receiver 100 is installed in one P-type receiver 100, so that it is only possible to confirm whether or not a fire has occurred through the P-type receiver 100, Can not be confirmed. Therefore, an apparatus for monitoring a fire according to an embodiment of the present invention adds a fire signal repeater 200 to a conventional P-type receiver 100 to provide accurate fire occurrence location information.

The fire signal repeater 200 will now be described in more detail with reference to FIG. As shown in FIG. 3, the fire signal repeater 200 includes an interface module 210, a communication module 220, and a control module 230.

The interface module 210 is an interface for transmitting / receiving signals or data to / from the sensor unit 300. The communication module 220 is an interface for transmitting / receiving various kinds of signals or data to / from the control server 400.

The control module 230 sends and receives signals to and from the sensor unit 300 through the interface module 210 and identifies the fire detection sensor 310 that senses the occurrence of a fire, And informs the control server 400 of the occurrence. Further, the control module 230 receives the announcement item according to the fire occurrence position and transmits the received announcement item to the beacon 320 of the sensor unit 300.

Next, the control server 400 according to the embodiment of the present invention will be described. 4 is a block diagram illustrating a configuration of a control server according to an embodiment of the present invention. Referring to FIG. 4, the control server 400 according to the embodiment of the present invention includes a communication unit 410, a storage unit 420, and a control unit 430.

The communication unit 410 is for communication, and can communicate using a broadband mobile communication or a wireless local area communication scheme. The communication unit 410 is implemented as a single module in which both the broadband mobile communication and the wireless local area communication connection mode communication functions are implemented, so that at least one of the above two functions is selected and operated. However, the communication unit 410 may be implemented by a plurality of modules separately performing communication functions of the broadband mobile communication and the wireless local area communication connection method. Broadband mobile communication may exemplify a communication method of accessing a network through a base station according to standards such as WCDMA, LTE and LTE-A, and the wireless local area communication may be a wireless local area network (WLAN) using a wireless fidelity ) Method, it is possible to exemplify communication for accessing a network through an access point (AP). The communication unit 410 may include an RF transmitter for up-converting and amplifying the frequency of a transmitted signal, and an RF receiver for low-noise amplifying the received signal and down-converting the frequency of the received signal. In addition, the communication unit 410 may receive a radio signal including data via a wireless channel, and may transmit the radio signal to the controller 430. In addition, the data received from the control unit 430 may be converted into a wireless signal and transmitted through a wireless channel.

The storage unit 420 stores programs and data necessary for the operation of the control server 400, and can be divided into a program area and a data area. The program area may store a program for controlling overall operation of the control server 400, an operating system (OS) for booting the control server 400, an application program, and the like. The data area is an area in which data generated according to use of the control server 400 is stored. In addition, the storage unit 420 may store various kinds of data generated according to the operation of the control server 400. [

The control unit 430 may control the overall operation of the control server 400 and the signal flow between the internal blocks of the control server 400 and may perform a data processing function for processing data. The controller 430 may be a central processing unit (CPU), an application processor, a graphic processing unit (GPU), or the like. The detailed operation of the control unit 430 will be described below.

A method for remotely monitoring a fire according to an embodiment of the present invention will now be described in more detail. FIG. 5 is a flowchart for explaining a method for monitoring a fire according to an embodiment of the present invention, and FIG. 6 is a timing diagram for explaining a method for determining whether a fire occurs according to an embodiment of the present invention.

5, the sensor unit 300 includes a plurality of fire detection sensors 310. In step S110, the fire signal repeater 200 detects a fire detection signal from at least one of the plurality of fire detection sensors 310 . At this time, the control module 230 of the fire signal repeater 200 receives the fire detection signal through the interface module 210. The interface module 210 is provided with a line connected to a line through which the fire detection sensor 310 transmits a fire detection signal to the P type receiver 100. The interface module 210 can receive a fire detection signal of the fire detection sensor 310 have. When the control module 230 receives the fire detection signal from the at least one fire detection sensor 310 through the interface module 210, the control module 230 initializes the fire detection sensor 310 by transmitting a signal in step S120. At this time, an initialization relay signal may be used as a transmitted signal. If it is not a failure, the fire detection sensor 310 will transmit a fire detection signal again in step S130. Accordingly, the control module 230 determines that the corresponding fire detection sensor 310 senses an actual fire in step S140. More specifically, the determination of the occurrence of a fire in steps S110 to S140 will be described with reference to FIG. When a fire detection signal is generated (HIGH), the control module 230 reads the fire detection signal and accordingly generates an initialization relay signal. Then, according to the initialization relay signal, the fire detection sensor 310 is initialized and the fire detection signal is initialized (LOW). Despite initialization, in the event of a real fire, the fire detection signal will again be high (HIGH). Accordingly, when the fire detection signal is again HIGH, the control module 230 determines that an actual fire has occurred. On the other hand, it is shown that one fire signal is detected and one initialization is performed. However, according to the alternative embodiment, it is determined that a fire detection signal is generated when a plurality of fire detection signals are generated in order to determine whether or not the fire detection signal is generated according to the chattering signal. For example, when the control module 230 performs sampling (signal reading) 16 times at 10 msec intervals to continuously detect a fire detection signal, it is determined that a fire detection signal is generated, not by a chattering signal. The control module 230 drives the relay for a predetermined period of time (200 msec or more), transmits the initialization relay signal at a predetermined cycle, and initializes the state of the fire detection sensor 310 through a process of disconnecting the line with the fire detection sensor 310. If the control module 230 still generates a fire detection signal after maintaining a predetermined period (or time) initialization state, it can be determined that a fire has finally occurred. Accordingly, the control module 230 of the fire signal repeater 200 transmits a fire signal to the control server 200 through the communication module 220 in step S150. Here, the fire signal includes the identification information of the fire detection sensor 310 that transmits the fire monitoring signal again. Since each fire detection sensor 310 and the interface module 210 of the fire signal repeater 200 are connected by separate lines, the control module 230 can identify the fire detection sensor 310 that transmitted the fire detection signal And the identification information of the fire detection sensor 310 can be derived.

The control server 400 maps and stores the identification information of each fire detection sensor 310 and the location where each fire detection sensor 310 is installed. Accordingly, the control server 400 having received the identification information of the fire detection sensor 310 can derive the location of the fire from the identification information of the fire detection sensor 310 in step S160.

On the other hand, it has been described that the fire position reading through the initialization is performed in the fire signal repeater 200 itself. However, according to an alternative embodiment, the control server 400 may directly specify the fire signal repeater 200 that generated the fire detection signal. That is, when the fire signal repeater 200 transmits a fire detection signal to the control server 400, the control server 400 transmits an initialization signal (initialization relay signal) to the fire detection sensor 310 through the fire signal repeater 200, To perform initialization. The control server 400 may receive the fire detection signal of the fire signal repeater 200 generated again through the fire signal repeater 200 and directly specify the fire signal repeater 200 that generated the fire detection signal . Accordingly, the control server 400 can derive the fire occurrence position.

Next, as described above, the present invention provides an indication of the evacuation direction in correspondence with the fire occurrence position as it derives the accurate fire occurrence position. These announcements are transmitted to the user equipment 600 carried by people through beacons 320 installed at different positions of the building, and the user equipment 600 outputs announcement messages. Typically, the user device 600 is a handheld device that can communicate with the beacon 320 in a Bluetooth manner. Preferably, the user device 600 may be a smart phone. The method of providing such announcement will be described in more detail.

FIG. 7 is a flowchart for explaining a method for providing a notification according to an embodiment of the present invention, FIG. 8 is a view for explaining a notification according to an embodiment of the present invention, and FIG. Fig. 6 is a view for explaining a method of providing a guide ment according to an embodiment.

When the control server 400 derives the fire occurrence location in step S160 according to the method described above with reference to FIG. 5, the control server 400 can know the fire occurrence location. Accordingly, the control server 400 derives the evacuation route, and generates the announcement guidance guiding the evacuation route derived in step S210.

The announcement item according to the embodiment of the present invention is a notification of the evacuation direction from the reference object within a predetermined distance from the position where the beacon 320 is installed. Such an announcement may optionally further include a warning notice. The reference object may be the object that the user who listens to the announcement within the predetermined distance of the beacon 320 is the easiest to identify. These reference objects are predetermined for each beacon 320. The evacuation direction indicates the direction along the evacuation path derived from the reference object. And the warning guide is a message to warn the user in particular, and is a guideline for prohibiting entry to the reference object.

More specifically, with reference to FIG. 8, such a mentor will be described. 8 shows a cross-sectional view of an eight-story corridor apartment. Assuming that the right side is east and the left side is west, there are stairs in the east and west, and a corridor between the stairs. Assuming that a fire has occurred on the fifth floor of the apartment, if any floor is evacuated to the east staircase, it can be very dangerous due to smoke. The evacuation route of the 6th floor is derived as shown by the arrow. The announcements according to the positions of the first to sixth beacons 321 to 326 may be generated as shown in Table 2 according to Table 1 below.

Beacon Reference target Evacuation direction Warning Guide First beacon Stairs / hallway Down stairs N / A Second beacon Stairs / hallway / number 601 West stairway direction N / A Third beacon Corridor / 601/602 Direction 601 N / A Fourth beacon Corridor / 602/603 Direction 602 Do not enter the east stairs Fifth Beacon Corridor / Room 602 / Stairs Direction 602 Do not enter the east stairs 6th beacon Stairs / hallway Corridor direction Evacuate from the east stairway

Beacon Announcement First beacon Evacuate down the stairs Second beacon Evacuate to the western staircase Third beacon Evacuate in direction 601 Fourth beacon Evacuate in direction 602. Do not enter the east stairs Fifth Beacon Evacuate in direction 602. Do not enter the east stairs 6th beacon Evacuate in the hallway direction. Evacuate out of the east stairs.

In this way, the control server 400 derives the evacuation route according to the location of the fire occurrence, and generates announcements according to the derived evacuation route and the position of each beacon 320. Since the beacon 320 is installed in a pair with the fire detection sensor 310, the beacon 320 has the same position information as that of the fire detection sensor 310, and the control server 400 has the same information as the fire detection sensor 310 Stores the location of the beacon 320 in advance. When generating the announcement message, the control server 400 transmits the announcement for each beacon 320 to the fire signal repeater 200 in step S220, and the fire signal repeater 200 transmits a plurality of beacons 320 to the respective beacons 320 of the sensor unit 300. The beacons 320 of the sensor unit 300 are connected to the beacons 320 of the sensor unit 300, Accordingly, each of the plurality of beacons 320 can store its own announcement. Each of the plurality of beacons 320 of the sensor unit 300 transmits the announcement to the user device 600 when the user device 600 enters the communication range of the beacon 320 in its own communication range in step S240. Then, the user device 600 outputs the corresponding announcement, and the user can safely evacuate according to the announcement. More specifically, as shown in FIG. 9, the beacon 320 can detect that the user apparatus 600 enters the communication coverage. Accordingly, the beacon 320 transmits the announcement to the user apparatus 600 when the user apparatus 600 enters the communication coverage. Then, the user device 600 outputs the announcement item through the speaker.

As described with reference to FIG. 8, Table 1 and Table 2, the announcement provides different announcements for each of a plurality of beacons 320 installed at different positions. For example, when a user who has heard an emergency bell due to a fire occurs and attempts to evacuate in the direction of the stairs, the fifth beacon 325 enters the communication range of the fifth beacon 325, Evacuate in the direction of the announcement '602. East step entrance prohibition 'to the user device 600, and the user device 600 outputs it. The user who listened to this announcement will evacuate in direction 602 and sequentially communicate with the fourth beacon 324, the third beacon 323, the second beacon 322 and the first beacon 321 . Accordingly, the user device 600 will continuously output the announcements received from the fourth beacon 324, the third beacon 323, the second beacon 322, and the first beacon 321. Accordingly, the user evacuates in direction '602'. The user can safely evacuate according to the evacuation route derived by the control server 400 while listening to the "Prohibition of entrance to the east stairway", "Escape to the direction of 601", "Escape to the western staircase" .

Hereinafter, an apparatus for remotely monitoring a fire according to a further embodiment of the present invention will be described. The fire monitoring system according to a further embodiment further includes a plurality of smoke diffusion delay devices 500 in addition to the P-type receiver 100, the fire signal repeater 200, the sensor unit 300, and the control server 400. The smoke diffusion delay device 500 will be described below. 10 and 11 are views for explaining a smoke diffusion delay device 500 according to an embodiment of the present invention.

According to a further embodiment of the present invention, the interior of the building can be divided into a plurality of zones. Fig. 10 shows a plurality of zones A01 to A18 viewed from a plan view of any one layer of the building. Each of these zones may have a virtual hexahedron shape having a different size as shown in Fig. At least one sensor unit 300 and a smoke diffusion delay device 500 are installed in each of the plurality of zones A01 to A18.

The smoke spread delay device 500 of each zone can communicate with the control server 400 through the P-type receiver 100 and the fire signal repeater 200, like the sensor unit 300. The smoke diffusion delay apparatus 500 according to the embodiment of the present invention includes an exhaust unit 510, an intake unit 520, and a diffusion delay unit 530. The exhaust unit 510, the intake unit 520, and the diffusion delay unit 530 are installed in the ceiling C of each zone.

The vent portion 510 is for discharging the smoke out of the building according to the embodiment of the present invention. The exhaust part 510 basically comprises an exhaust duct. The exhaust duct is preferably of a cross shape as shown, but is not limited thereto. In the exhaust duct, an exhaust duct inlet (D) for sucking smoke is installed downward from the ceiling. The exhaust duct of the exhaust section 510 of one of the zones is connected to the exhaust duct of the exhaust section 510 of the other zone in the four corners of the cuboid. That is, the exhaust duct of the exhaust unit 510 has exhaust connection portions N, S, E, and W connected to the exhaust ducts of the other zones from any one of the four sides. The exhaust connection portions N, S, E, and W of the exhaust connection portions N, S, E, and W corresponding to the rim of the building are connected to the exhaust ducts It can be an exit. The exhaust duct inlet D and the connecting portions N, S, E and W are provided with an exhaust fan and an exhaust window. The exhaust window selectively opens or closes the exhaust duct inlet D and the connecting portions N, S, E, W so that the smoke is discharged along the smoke exhaust path when the smoke exhaust path is designated according to the embodiment of the present invention. When the exhaust fan is designated as the exhaust path, the fan is operated to ensure smooth exhaust of the smoke.

The intake unit 520 is for supplying outside air into the building according to an embodiment of the present invention. The intake unit 520 basically comprises an intake duct. The intake duct is preferably of a cross shape as shown, but is not limited thereto. In the intake duct, an intake duct outlet (D) for supplying outside air is installed downward from the ceiling. The intake ducts of the intake portions 520 of one of the zones are connected to the intake ducts of the intake portions 520 of the other zones in the four corners of the cuboid. That is, the intake duct of the intake unit 520 has intake connections N, S, E, and W connected to the intake ducts of the other zones from all four sides of one zone. The intake connection portions N, S, E and W of the intake connection portions N, S, E and W corresponding to the rims of the building are connected to the intake ducts It can be an entrance. The intake duct D and the intake connections N, S, E, and W are provided with an intake fan and an intake window. The intake window is configured such that, when the ventilation path is designated according to the embodiment of the present invention, air is smoothly supplied along the ventilation path and the intake duct inlet D and the intake connections N, S, E, W are selectively opened , It closes. The suction fan is operated so that the air is smoothly supplied when the ventilation path is designated.

The diffusion delay unit 530 includes a driver that selectively allows the screen and the screen to be housed in the ceiling or moved down the ceiling. As shown in the figure, the diffusion delay unit 530 is not installed on all four sides of each zone, but may be installed so that smoke does not spread to the passage when the boundary of the zone is a passage. The screen of the diffusion delay unit 530 is moved downward from the ceiling by the driver, when the zone is designated as the delay zone according to the embodiment of the present invention, as shown in Fig. 11, Stop.

Next, a method for monitoring a fire according to another embodiment of the present invention will be described. 12 and 13 are flowcharts for explaining a method for monitoring a fire according to another embodiment of the present invention. 14 is a view for explaining a method for monitoring a fire according to another embodiment of the present invention.

Referring to FIG. 12, the sensor unit 300 includes a plurality of fire detection sensors 310. The fire detection sensor 310 is a pair of a heat detection sensor and a smoke detection sensor. The heat sensing sensor according to the embodiment of the present invention senses the temperature, and the smoke sensing sensor can sense the amount of smoke. Accordingly, the fire detection sensor 310 transmits a fire detection signal when it detects a smoke exceeding a predetermined temperature or a predetermined amount. The fire detection sensors 310 are installed at predetermined intervals in each of the zones A01 to A17.

The fire signal repeater 200 may receive a fire detection signal from at least one of the plurality of fire detection sensors 310 in step S310. At this time, the control module 230 of the fire signal repeater 200 receives the fire detection signal through the interface module 210. The interface module 210 is provided with a line connected to a line through which the fire detection sensor 310 transmits a fire detection signal to the P type receiver 100. The interface module 210 can receive a fire detection signal of the fire detection sensor 310 have. When the control module 230 receives the fire detection signal from the at least one fire detection sensor 310 through the interface module 210, the control module 230 transmits a signal in step S320 to initialize the fire detection sensor 310. [ At this time, an initialization relay signal may be used as a transmitted signal. If it is not a failure, the fire detection sensor 310 will send a fire detection signal again in step S330. Accordingly, the control module 230 determines that the corresponding fire detection sensor 310 senses an actual fire in step S340. Steps S310 to S340 are the same as steps S110 to S140. In addition, the sensor unit 300 transmits the sensor information together with the fire detection signal to the fire signal repeater 200 in step S330. The sensor information according to the embodiment of the present invention transmits the fire detection signal again at S330 when the temperature and the smoke amount sensed by the fire detection sensor 310 are transmitted when the fire detection signal is first transmitted at S310 (first time) (Second time) includes the temperature and the amount of smoke detected by the fire detection sensor 310.

The control module 230 of the fire signal repeater 200 transmits a fire signal to the control server 200 through the communication module 220 in step S350. The fire signal includes identification information (ID) of the fire detection sensor 310 that transmitted the sensor information and the fire monitoring signal. Since each fire detection sensor 310 and the interface module 210 of the fire signal repeater 200 are connected by separate lines, the control module 230 can identify the fire detection sensor 310 that transmitted the fire detection signal And the identification information of the fire detection sensor 310 can be derived. The control server 400 maps the identification information of each fire detection sensor 310 and the location of each fire detection sensor 310 in the storage unit 420 and stores the information in advance. When the control unit 430 of the control server 400 receives the identification information ID of the fire detection sensor 310 through the communication unit 410, Position can be derived. On the other hand, the sensor information includes the temperature and the amount of smoke sensed at a second time, which is the time and temperature after the first time and the amount of smoke and the temperature sensed at the first time. Although the sensor information is transmitted through the above-described fire signal, the present invention is not limited thereto. The sensor information may be transmitted separately from the fire signal. The first time is the time for step S310, However, when sensor information is transmitted separately from the fire signal, the first time and the second time may be different, and the time period between the first time and the second time may be different.

Next, the control unit 430 of the control server 400 calculates the escape time at step S370. The escape time according to the embodiment of the present invention is such that after the fire alarm occurs, that is, after the control unit 430 receives the fire signal, the person in the building who is farthest from the exit of the building escapes to the exit of the building Is an estimate of the amount of time it takes. The storage unit 420 stores building information. The building information includes a position of the furthest away from the exit of the building and a person moving from the position to the exit of the building. The distance Ds, the distance Dp of the hallway, and the number of doors Cd. Accordingly, the controller 430 derives the escape time Te according to the following equation (1).

Dp is the distance of the corridor, and Vp is the speed at which a person walks the corridor. Vp is the value obtained through simulated training, and it is possible to use the average speed of people moving in a corridor during simulation training. Ds is the distance of the stairs, and Vs is the speed at which a person walks the stairs. Vs is the value obtained through simulated training, and it is possible to use the average speed of people moving through the stairs during simulation training. Cd is the number of doors and Td is the time it takes for people to open and close the door. Td is the value obtained through simulated training. Td can use the average value of the time it takes for people to open and close the door during mock training. The escape time for a plurality of outlets and the escape time for a plurality of copper lines for each of the plurality of outlets can be obtained through the expression (1). According to the embodiment of the present invention, the longest time out of the plurality of escape times obtained through Equation (1) can be used or an average can be used.

If the escape time is calculated, the controller 430 derives the delayed area in step S380. The delay zone is the minimum zone for delaying the spread of smoke during the escape time. In other words, the delay zone is the minimum zone that can estimate the amount of smoke that can occur in a fire during the calculated escape time and accommodate the smoke to the outside according to the estimated amount of smoke. The storage unit 420 stores the amount of smoke generated in accordance with the physical properties of the material including the wall, the ceiling, and the floor and the area of the material to be burnt (combustion area) based on the physical properties of the material. That is, the storage unit 420 stores the amount of smoke generated according to the combustion area for each material.

On the other hand, as described above, the sensor information includes the temperature of the first time and the amount of the smoke and the amount of the temperature and the smoke of the second time. The control unit 430 derives the temperature increase rate and the smoke amount increase rate based on the temperature and the amount of smoke in the first time of the sensor information and the amount of the temperature and smoke in the second time which is a time after a predetermined period has elapsed from the first time . Then, the control unit 430 estimates the combustion area, which is the area of the material that can be burned during the escape time calculated according to the derived temperature increase rate and the smoke amount increase rate. This combustion area may vary depending on the material properties of the material.

Therefore, according to the present invention, the combustion area of the material can be obtained through simulation and simulation using the temperature increase rate and the smoke amount increase rate for a predetermined time as input parameters for each material. Moreover, such simulations and simulations can be repeated to obtain the statistics of the combustion area, and the average value of the statistics can be used as the combustion area used in the embodiment of the present invention. The storage unit 420 may store the combustion area according to the temperature increase rate and the smoke amount increase rate for each material.

Then, based on the physical properties of the material stored in the storage unit 420, the amount of smoke that can occur during the escape time is estimated based on the amount of smoke generated according to the area of the material to be burned. Then, the control unit 430 designates the minimum area that can accommodate the smoke so as not to diffuse to the outside according to the amount of smoke that may occur during the estimated escape time.

The storage unit 420 stores the smoke capacity per hour in advance for each zone. The hourly smoke capacity includes the amount of smoke per hour that can be discharged through the exhaust section 510 of the zone and the base smoke capacity of that zone. The basic smoke capacity of the zone depends on the volume taking into consideration the length from the ceiling of each zone to the screen of the diffusion delay unit 530. In the case of smoke, the mechanism of smoke movement is as follows: (1) after smoke occurs, (2) it reaches the ceiling by buoyancy, (3) . If the generation of smoke continues, it will diffuse out of the zone if it falls below the screen of the diffusion delay unit 530 after falling down from the ceiling. Therefore, each zone can have a predetermined basic capacity of smoke even when the exhaust unit 510 is not operated. This default smoke capacity is the volume multiplied by the length and floor or ceiling area from the ceiling of each zone to the screen of the diffusion delay unit 530.

Thus, the control unit 430 derives a delay zone based on the smoke capacity per hour of each zone, at least one zone capable of accommodating the amount of smoke that may occur during the escape time estimated based on the zone where the fire occurred. For example, FIG. 14 assumes a situation where a fire has occurred at the boundaries of zones A07 and A08. Accordingly, the controller 430 can calculate the escape time and estimate the amount of smoke that may occur during the escape time. If the amount of smoke is estimated, the control unit 430 calculates the minimum area that can accommodate the estimated amount of smoke during the escape time, including zones A07 and A08 based on the smoke capacity per hour of each zone. At this time, it is assumed that the zones A07, A08, and A11 are selected as delay zones, as shown.

Then, the controller 430 generates a delay command in step S390. The delay command may be transmitted to the smoke diffusion delay device 500 through the fire signal repeater 200 in steps S400 and S410. The delay command causes the smoke of the zone selected as the delay zone to be discharged to the outside through the shortest smoke exhaust path and the screen of the diffusion delay section 530 is blocked by the driver from below the ceiling As shown in FIG. Optionally, the delay command may further comprise a control signal to cause the intake portion 520 of the remaining zone not selected as the retarded zone to supply air into the building through the shortest ventilation path, without interfering with the exhaust path have.

As shown, zones A08, A07, and A11 are designated as delay zones in accordance with the delay command, and the dashed lines in FIG. 14 represent the exhaust ducts of the exhaust unit 510 or the exhaust unit 510 interconnected by each zone . According to the delay command, the smoke generated in the zone A08 is designated as a smoking course to be discharged outside the building through the exhaust part 510 of the zones A08, A07 and A06, and the smoke generated in the zone A07 is divided into zones A07 and A06 And the smoke generated in the area A11 may be designated to be discharged to the outside of the building through the exhaust part 510 of the areas A11 and A06 have. Then, the exhaust fan of the corresponding zone can be operated according to the designated smoking course, and the exhaust window can be opened. Also, the screen of the diffusion delay unit 530 in the delay zone will move down from the ceiling by the driver.

As described above, the present invention specifies a delay zone. This delay zone will prevent the smoke from spreading out of the delay zone during the escape time. Therefore, the control unit 430 of the control server 400 derives the shortest escape route having the shortest distance while bypassing the delay zone in step S420, and generates the announcement according to the derived shortest escape route.

The generated announcement message is transmitted to the sensor unit 300 through the fire signal relay in steps S430 and S440. These announcements are transmitted to the user equipment 600 carried by people through beacons 320 installed at different positions of the building, and the user equipment 600 outputs announcement messages. Typically, the user device 600 is a handheld device that can communicate with the beacon 320 in a Bluetooth manner. Preferably, the user device 600 may be a smart phone. This method of providing guidance is as described above with reference to FIGS. 7 to 8, except that it is to guide the shortest evacuation route having the shortest distance while bypassing the delay zone.

Meanwhile, the method according to the embodiment of the present invention may be implemented in a form of a program readable by various computer means and recorded in a computer-readable recording medium. Here, the recording medium may include program commands, data files, data structures, and the like, alone or in combination. Program instructions to be recorded on a recording medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. For example, the recording medium may be a magnetic medium such as a hard disk, a floppy disk and a magnetic tape, an optical medium such as a CD-ROM or a DVD, a magneto-optical medium such as a floppy disk magneto-optical media, and hardware devices that are specially configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions may include machine language wires such as those produced by a compiler, as well as high-level language wires that may be executed by a computer using an interpreter or the like. Such a hardware device may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

According to the present invention as described above, the fire signal repeater can be installed in the P-type repeater to accurately detect the location of the fire. Furthermore, since the evacuation route is derived based on the position where the fire occurs, and the derived evacuation route is guided through the beacon, the user can safely evacuate along the evacuation route. In particular, since the announcement message according to the embodiment of the present invention guides the evacuation direction from the reference target identified within a predetermined distance from the beacon, the evacuating user can understand the announcement message more intuitively and can easily grasp the evacuation path .

While the present invention has been described with reference to several preferred embodiments, these embodiments are illustrative and not restrictive. It will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit of the invention and the scope of the appended claims.

100: P type receiver
200: fire signal repeater
300:
310: Fire sensor
320: Beacon
400: control server
500: Smoke diffusion delay device
600: User device

Claims (8)

An apparatus for monitoring a fire,
A smoke spread delay device installed in each zone for dividing into multiple zones of a building;
A plurality of fire detection sensors for detecting fire through the amount of temperature and smoke;
A P-type receiver for receiving a fire detection signal transmitted from a fire detection sensor detecting a fire among the plurality of fire detection sensors;
A fire signal repeater for determining whether a fire has occurred according to a fire detection signal received by the P-type receiver, and for transmitting a fire signal including identification information and sensor information of the fire detection sensor when it is determined that a fire has occurred; And
The fire detection unit identifies a fire occurrence location based on the identification information of the fire detection sensor, sets a part of the plurality of zones of the building as a delay zone based on the fire occurrence position, and the smoke diffusion delay unit of the delay zone Wherein the control server transmits a delay command to the fire control server. The method according to claim 1,
The control server
A communication unit for receiving the fire signal;
A storage unit for storing physical quantities of materials including walls, ceilings, and floors, a combustion area according to a temperature increase rate and a smoke amount increase rate for each material, and an amount of smoke generated according to a combustion area for each material; And
After the fire signal is received, an escape time, which is an estimate of the time it takes for a person in the building to escape to the exit of the building to the farthest person from the exit of the building, is calculated, Estimating the amount of smoke generated according to the estimated combustion area, calculating the amount of smoke generated according to the amount of the derived smoke, And a control unit for selecting a delay zone, which is at least one zone in which at least one zone can be detected. 3. The method of claim 2,
The control unit
Equation

To calculate the escape time,
Te is the escape time,
Dp is the distance of the corridor,
Vp is the speed at which a person walks the corridor,
Ds is the distance of the step,
Vs is the speed at which a person walks the stairs,
Cd is the number of doors,
And Td is the time taken by the person to open and close the door. 3. The method of claim 2,
The control unit
And a delay command including a smoke exhaust path for causing the smoke diffusion delay device in the delay zone to discharge smoke, through the communication unit. A method for monitoring a fire,
Receiving a fire detection signal transmitted from a fire detection sensor detecting a fire among a plurality of fire detection sensors to a P-type receiver;
Transmitting a fire signal including identification information and sensor information of the fire detection sensor which transmitted the fire detection signal to the control server;
The control server identifies a fire occurrence location based on the identification information of the fire detection sensor, selects a part of the plurality of zones of the building as a delay zone based on the fire occurrence location, And sending a delay command to cause the smoke to be discharged. ≪ Desc / Clms Page number 24 > 6. The method of claim 5,
The step of transmitting the delay command
Calculating an escape time, which is an estimate of the time taken from the person in the building to the exit of the building to the exit of the building, after the control server receives the fire signal;
Estimating a combustion area, which is an area of a material that can be burned during the escape time, by the control server;
Deriving an amount of smoke generated according to the estimated combustion area; And
And selecting a delay zone, which is at least one zone that can accommodate the smoke out of the plurality of zones during the escape time according to the amount of the derived smoke. Methods for monitoring. The method according to claim 6,
The step of calculating the escape time
The control server
Equation

To calculate the escape time,
Te is the escape time,
Dp is the distance of the corridor,
Vp is the speed at which a person walks the corridor,
Ds is the distance of the step,
Vs is the speed at which a person walks the stairs,
Cd is the number of doors,
Wherein said Td is the time it takes for a person to open and close the door. 6. The method of claim 5,
The step of transmitting the delay command
And sending a delay command to the control server, wherein the control server includes a smoke exhaust path for causing the smoke diffusion delay device in the delay zone to discharge smoke.

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