JP2014182709A - Alarm system and alarm device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an alarm system using flash light configured to notify a person, including the hearing impaired, about fire breakout to urge evacuation without causing photosensitive epilepsy, and to provide an alarm device.SOLUTION: An alarm system includes a plurality of alarm devices which emit flash light on the basis of a fire signal from an automatic fire alarm system. The alarm devices are grouped by evacuation route. In each group, flash light-emitting operation is repeated along the evacuation route from an alarm device located closest to a fire sensor which has transmitted a fire sensing signal toward an alarm device located at the terminal in sequence with a predetermined phase difference, to evacuate a person toward an emergency exit located at the terminal of the evacuation route.

Description

  The present invention relates to an alarm system and an alarm device that prompts evacuation when an emergency such as a fire occurs, and more particularly to an alarm system and an alarm device that issue an alarm by light.

  Conventionally, automatic fire alarm equipment has been evacuated by sounding an alarm sound device arranged at a predetermined interval at a predetermined volume, or by playing an audio message through an emergency broadcasting facility that has been operated in conjunction, warning the occurrence of a fire. It was something to encourage.

  However, in the case where a person who should evacuate in the event of an emergency such as a fire has a hearing impairment, it is desired to spread an alarm device that works on a sense other than hearing such as light to notify the emergency. An alarm device that emits flash light using an electronic flash typified by a strobe (registered trademark) that emits intense flash light, a large-intensity LED lamp, or the like as a light source has been put into practical use.

Japanese Patent Laid-Open No. 08-161679

http://www.hochiki.co.jp/webcatalog/pdf/hc_ssfa1208.pdf http://www.saxa.co.jp/product/business/pdf/SHW-101.pdf

  Conventionally, an alarm device that is normally turned off and emits flash light in the event of an emergency such as a fire has been controlled by each alarm device itself. When a large number of such alarm devices are installed at predetermined intervals like the alarm sound device of the automatic fire alarm facility and are activated at the same time when a fire occurs, each of the many alarm devices emits light at different timings. It is known that such artificial strong light stimulation may cause photosensitivity seizures such as light-stimulating epilepsy in humans (for example, a private television broadcasting station on December 16, 1997). The case that a viewer of a TV animation with a strong light stimulation scene broadcasted by the company caused a photosensitivity attack was widely reported and well-known.

  It is an object of the present invention to provide an alarm system and an alarm device using a flashlight that can notify a person with hearing impairment to the occurrence of an emergency such as a fire and prompt evacuation without causing a photosensitivity attack. Objective.

(1) The alarm system of the present invention has a unique identifier, fire detection means for transmitting a fire detection signal including the identifier when a fire is detected, and makes a fire determination based on the fire detection signal. When a fire location is identified and a fire is detected, a fire receiving means for sending a fire signal including fire location information and an individual unique identifier are arranged and arranged in groups for each evacuation route. And a plurality of alarm devices having light emitting means for flashing light at a predetermined cycle with a predetermined phase difference in the order from the fire position side to the emergency exit side.
(2) Further, in the alarm system of the present invention, in (1), the alarm device is also disposed in a room outside the evacuation route, the fire detection means disposed in the room is activated, and the fire receiving means When the fire is judged to be a fire room, the alarm device disposed in the fire chamber emits flash simultaneously with the alarm device that first flashes in the group.
(3) Further, in the alarm system of the present invention, in (1) or (2), the fire determination means sends a synchronization signal to the alarm device every time corresponding to an integral multiple of the predetermined period, The alarm device that has received the synchronization signal initializes a timing means for timing the predetermined period for flash emission.

  According to the configuration of the first aspect of the present invention, the plurality of alarm devices emit flash light so as to flow in order toward the emergency exit, and do not emit flash light at disjoint timings, so that the auditory disturbance is not caused without causing a photosensitivity attack. A certain person can be informed of the occurrence of a fire and prompted to evacuate, and the evacuation can be visually induced to move away from the location of the fire toward the emergency exit.

  Further, according to the configuration of claim 2 of the present invention, in addition to the above, a person with hearing impairment can be urged to evacuate from a fire room isolated from the evacuation route. Since the alarm device on the nearest evacuation route and the alarm device in the fire room, which may be visually recognized at the same time when escaping to the fire, simultaneously emit flash light, there is an effect that no photosensitivity attack is caused.

  Further, according to the configuration of the third aspect of the present invention, the timing means for determining the flash emission period is periodically synchronized, so that the timing at which the entire alarm system operates does not step out, and the timing There is an effect that it is not necessary to use a highly accurate and expensive device for the means.

It is a block diagram of the alarm system which concerns on Embodiment 1 of this invention. It is a block diagram of the alarm device which concerns on Embodiment 1 of this invention. It is a figure which shows an example of arrangement | positioning of the alarm system which concerns on Embodiment 1 of this invention. It is a table | surface which shows an example of the 1st table which concerns on Embodiment 1 of this invention. It is an operation | movement flowchart of the alarm system which concerns on Embodiment 1 of this invention. It is a time chart figure of the alarm system which concerns on Embodiment 1 of this invention. It is a table | surface which shows an example of the 2nd table which concerns on Embodiment 1 of this invention. It is a block diagram of the alarm device which concerns on Embodiment 2 of this invention.

[Embodiment 1]
The first embodiment will be described with reference to FIGS.

  First, the configuration of the alarm system according to the present embodiment will be described with reference to FIG.

  A plurality of fire detectors, each of which is a fire detection means, has a unique identifier for each area to be monitored for fire and has a unique identifier. 2 is disposed as appropriate. For convenience of explanation, the fire detector 2-1 and the fire detector 2-2 are distinguished from the fire receiver 1 side, which will be described later, with consecutive numbers, and are collectively referred to as the fire detector 2.

  The unique identifier that each fire detector 2 has is an address represented by, for example, a numerical value of multiple digits, and may be any one that can identify the fire detector 2 that has detected a fire when a fire occurs. . By using such a fire detector 2, it becomes possible to grasp the fire position when a fire occurs.

  The fire detector 2 is connected to the fire receiver 1 which is a fire receiving means via the electric circuit Ls. The automatic fire alarm system constituted by the fire detector 2 and the fire receiver 1 may be a P-type system in which the electric circuit Ls is connected by an individual electric circuit for each system of the fire detector 2, or the electric circuit Ls is detected by fire. It may be an R-type system that is connected to the system of the device 2 through a common electric circuit and performs multiplex transmission.

  The fire receiver 1 receives a fire detection signal D from the fire detector 2 via the electric circuit Ls when a fire occurs, makes a fire determination based on the fire detection signal D, and determines that a fire has occurred. 1 is a fire receiver of a well-known automatic fire alarm facility that performs a fire display and a fire sound alarm by an indicator lamp, an acoustic device, etc. provided in 1 and an alarm by an acoustic device or the like installed in the building. However, the fire receiver 1 in the present embodiment identifies the fire detector 2 that has detected a fire from the identifier of the fire detector 2 included in the fire detection signal D, and the fire detector that has been identified as having detected a fire. The fire position is specified from the place where 2 is arranged. That is, the fire receiver 1 according to the present embodiment determines a fire occurrence and a fire position based on the fire detection signal D.

  When the fire receiver 1 determines that a fire has occurred, a fire signal F including fire position information is sent to the alarm device 3 to be described later via the electric circuit Lf. When the fire signal F is an ON-OFF type signal, the fire position information may be superimposed on the fire signal F by a known modulation method. When the fire signal F is a multiplex transmission signal, the transmission data protocol may be configured to include the fire position information.

  When the fire receiver 1 determines that a fire has occurred, it sends a fire signal F, for example, an ON-OFF type fire signal F, and supplies power to an alarm device 3 to be described later. Power supply from the fire receiver 1 to the alarm device 3 may be performed by a fire signal F sent from the electric circuit Lf, or a power supply (not shown) may be provided separately to supply power to the alarm device 3. May be.

  The warning device 3 emits flash light at a predetermined period T based on the fire signal F sent from the fire receiver 1, and gives a warning that can prompt the hearing impaired to evacuate.

  In the present embodiment, a plurality of alarm devices 3 are grouped for each evacuation route, connected in parallel to the electric circuit Lf, and arranged at intervals. For convenience of explanation, each alarm device 3 is distinguished from the fire receiver 1 in order by attaching a number consecutive to the alarm devices 3-1 to 3-n (n is a natural number). 3 is called. And among the alarm devices 3-1 to 3-n grouped for each evacuation route, the emergency exit is arranged at least in the vicinity of the terminal.

  The alarm device 3 has a unique identifier, for example, an address represented by a numerical value of a plurality of digits, based on a fire signal F including fire position information, in the order from the fire position side to the emergency exit side, Flash emission is performed at a predetermined cycle with a predetermined phase difference. Therefore, it is desirable that the alarm device 3 is arranged so that a plurality of alarm devices 3 can always be seen from the evacuation route so that the order toward the emergency exit can be grasped.

  The fire receiver 1 stores the identifier of the fire detector 2 and the identifier of the alarm device 3 closest to the fire detector 2 in association with each other for each group organized for each evacuation route. Have When the fire receiver 1 determines that a fire has occurred, the identifier of the alarm device 3 corresponding to the identifier from the fire detector 2 that has sent the fire detection signal D is read with reference to the first table, and this is fired. The position information is included in the fire signal F and sent out.

  Here, the first table will be described with reference to FIGS. 3 and 4.

  The first table is a data table registered in a storage unit (not shown) provided in the fire receiver 1. As shown in FIG. 4, for the alarm devices 3 grouped for each evacuation route, the fire detector 2 The identifier and the identifier of the alarm device 3 closest to the fire detector 2 are stored in advance in association with each other, and the identifier of the fire detector 2 disposed in the room of the evacuation route and the identifier of the alarm device 3 are associated with each other. And store it in advance.

  Here, for convenience of explanation, a setting example of the first table shown in FIG. 4 is shown assuming an arrangement example as shown in FIG.

  The evacuation route is assumed to be a corridor in the building having emergency exits E1 and E2 at both ends, and the alarm device 3 is 3-1, 3-2, 3-3 in order from the emergency exit E1 side to the emergency exit E2 side. 3-4 and 3-5, and the alarm devices 3-1 and 3-5 at the end of the evacuation route are arranged near the emergency exits E1 and E2, respectively. Similarly, the fire detector 2 is arranged in order from the emergency exit E1 side to the emergency exit E2 side, for example, 2-1, 2-2, 2-3, 2-4, 2-5, and each is an alarm device. 3-1, 3-2, 3-3, 3-4, and 3-5 are the closest.

  Further, it is assumed that there are three rooms that do not correspond to the evacuation route, and each has a doorway facing the corridor that is the evacuation route. A first chamber, a second chamber, and a third chamber are provided from the emergency exit E1 side to the emergency exit E2 side. Alarm devices 3-6, 3-7, 3-8, fire detector 2- 6, 2-7, 2-8 shall be arranged.

  If the identifiers of the alarm devices 3-1 to 3-8 are sequentially F001 to F008 and the identifiers of the fire detectors 2-1 to 2-8 are respectively D001 to D008, the evacuation route closest to the fire detector 2 is set. For example, the alarm device 3 disposed on the wall surface is determined along the corridor, and the correspondence between the identifiers is determined as shown in FIG. That is, for the identifier of the fire detector 2, D001, D002, D003, D004, D005, D006, D007, D008, respectively, the identifier of the alarm device 3 arranged along the evacuation route, F004, F005, F001, F003, and F005 are determined.

  On the other hand, the fire detectors 2-6 to 2-8 and the alarm devices 3-6 to 3 to 8 are disposed in the first to third chambers that do not correspond to the evacuation route. However, if the entrances and exits of the respective rooms are closed, the alarm devices 3-1 to 3-5 arranged in the corridor that is an evacuation route cannot be visually recognized from the respective rooms. For this reason, when the fire detector 2 in the same room is activated and a fire is judged, it is necessary to activate the alarm device 3 in the corresponding room.

  And when the doorway of a room is opened, there is a possibility that the alarm device 3 in the room and the latest alarm device 3 arranged in the corridor which is an evacuation route may be simultaneously recognized, so as to prevent photosensitivity seizures. In addition, these are made to flash at the same time. Therefore, in the first table, the identifier of the alarm device 3 outside the evacuation route and in the fire room is grouped for each evacuation route as data for flashing the corresponding alarm device 3 in conjunction with the fire. The alarm device 3 is registered separately from the data that associates the identifier of the fire detector with the identifier of the alarm device closest to the fire detector.

  In this way, even when the alarm device 3 on the evacuation route cannot be visually recognized from the fire room, the alarm device 3 in the room informs the person with hearing impairment that the fire has occurred and prompts the evacuation to move from the room to the evacuation route. Even when the latest alarm device 3 and the alarm device 3 in the room arranged on the evacuation route are viewed at the same time when leaving, it is possible to prevent light-sensitive seizures because they flash at the same time.

  Next, the configuration of the alarm device 3 according to the present embodiment will be described with reference to FIG.

  The alarm device 3 includes a fire signal receiving unit 31 that is a receiving unit that receives the fire signal F from the fire receiver 1 through the electric circuit Lf, and includes a connection terminal INf for connecting to the electric circuit Lf.

  The alarm device 3 includes a power supply unit 36 that receives power from the fire receiver 1 and supplies power to a circuit inside the alarm device 3. In FIG. 2, the power supply unit 36 is supplied with power from the fire signal F received via the electric circuit Lf. However, as described above, the power supply unit 36 may receive power via a dedicated power line. It is.

  As the light emitting unit 35 as the light emitting means, an electronic flash represented by a strobe (registered trademark) that emits intense flash light or an LED lamp with a large amount of light can be used. The devices used for the light emitting unit 35 are not limited to these, and any light source that emits visible light that can emit light more than a certain level that can be used for alarming with light and that can be intermittently controlled may be used.

  The light emitting unit 35 may receive power supply via the control unit 34 as shown in FIG. 2 or may receive power supply directly from the power supply unit 32 (not shown) to cause the light emitting unit 35 to emit light. A trigger signal may be received from the control unit 34. In the latter configuration, an electronic flash is used as the light emitting means, and a high voltage that does not lead to the start of discharge is applied in advance from the power supply unit 36, and the electronic flash of the light emitting means is discharged to start light emission. It is suitable for the purpose of sending a trigger signal from the control unit 34.

  The alarm device 3 also has a timer 32 that is a timer that starts timing based on the fire signal F, outputs a time t, and is initialized at a predetermined period T. The timer 32 measures the time t after the fire signal receiver 31 receives the fire signal F from the fire receiver 1, and outputs the value of the timer to the controller 34.

  Further, the alarm device 3 includes a delay time setting unit 33 that is a delay time setting unit that calculates and stores a delay time t0 from when the time measuring unit 32 starts to measure time until the own device emits flash light.

  That is, first, the delay time setting unit 33 obtains the light emission order N in which the own device performs flash emission based on the fire position information included in the fire signal F, and calculates and stores the delay time t0 based on the light emission order N. .

  The alarm device 3 compares the time t with the delay time t0 with reference to the delay time t0 stored in the delay time setting unit 33. When the time t reaches the delay time t0, the alarm unit 3 is turned on. It has the control part 34 which is a control means to perform flash light emission.

  Next, the operation of the alarm system according to the present embodiment will be described with reference to FIGS.

  The alarm system according to the present embodiment is an alarm system in which, in the event of a fire, the alarm device 3 flashes in order to guide the evacuation toward the terminal alarm device 3 disposed near the emergency exit along the evacuation route. is there. That is, in a group organized for each evacuation route, the alarm device 3 closest to the fire detector 2 that has sent the fire detection signal D is set as a starting point, toward the alarm device 3 positioned at the end along the evacuation route. The alarm device 3 flashes in order with a predetermined phase difference ΔT.

  This operation will be described in detail.

<Operation of fire detector 2>
When a fire occurs, one of the fire detectors 2 detects a fire. Here, for simplicity of explanation, the explanation will be made assuming that the fire detector 2-2 senses a fire (see FIGS. 1 and 3).

  The fire detector 2-2 that has detected a fire sends a fire detection signal D to the fire receiver 1. At this time, the fire detection signal D includes, as information, an identifier previously given to the fire detector 2-2. The identifier of the fire detector 2-2 is assumed to be “D002”, for example. That is, when a fire is detected, the fire detector 2-2 is a fire detection means for sending out a fire detection signal D including the identifier “D002”.

<Operation of fire receiver 1>
Next, the fire receiver 1 that has received the fire detection signal D determines the occurrence of a fire and the fire position based on the fire detection signal D (see FIGS. 1, 5, and 6).

  For example, when the fire receiver 1 has a known accumulation function, it is determined that a fire has occurred as a result of the accumulation function. The determination of the occurrence of a fire is not limited to the storage function of the fire receiver 1, but the magnitude and rate of increase of physical quantities caused by fire, the distribution of physical quantities caused by fire detected by a plurality of fire detectors 2, or Any known fire determination function based on a plurality of fire detection principles may be used, and it is selected as appropriate according to which method the fire occurrence is determined.

  When the fire receiver 1 determines that a fire has occurred, it is determined from the identifier “D002” included in the fire detection signal D received by the fire receiver 1 that the fire detector 2-2 has detected a fire. The fire receiver 1 determines that the place where the fire detector 2-2 is disposed is the fire position.

  The fire receiver 1 stores, for each group organized for each evacuation route, a first table in which the identifier of the fire detector 2 and the identifier of the alarm device 3 closest to the fire detector 2 are stored in association with each other. Have. Here, for example, according to the arrangement examples shown in FIGS. 3 and 4, the alarm device 3 closest to the fire detector 2-2 that has detected a fire is the alarm device 3-2 having the unique identifier “F002”. . That is, the identifier “D002” of the fire detector 2-2 included in the fire detection signal D and the identifier of the alarm device 3-2 are associated and stored in the first table (see FIG. 4).

  When the fire receiver 1 determines that a fire has occurred, the identifier “of the alarm device 3-2 corresponding to the identifier“ D002 ”from the fire detector 2-2 that sent the fire detection signal D is referred to by referring to the first table. F002 "is obtained. The identifier “F002” of the alarm device 3-2 is used as fire position information, and a fire signal F including the fire position information is sent to the alarm devices 3-1 to n through the electric circuit Lf (FIGS. 5 and 6). reference).

<Operation of alarm device 3>
The alarm device 3 has a fire signal receiving unit 31 as fire signal receiving means for receiving the fire signal F (see FIG. 2).

  In addition, the alarm device 3 includes a timer 32 as a timer that starts timing and outputs a timer t to a controller 34 described later when the fire signal F is received via the fire signal receiver 31. Note that the timer unit 32 is initialized at the predetermined period T described above, and operates so as to repeat the time period during the predetermined period T while the fire signal F is received. That is, the time measuring unit 32 is a time measuring unit that starts time counting based on the fire signal F, outputs the time measuring time t to the control unit 34, and is initialized at a predetermined period T.

  Further, the alarm device 3 includes a delay time setting unit 33 that is a delay time setting unit that calculates and stores a delay time t0 from when the time measuring unit 32 starts to measure time until the own device emits flash light.

  First, the delay time setting unit 33 obtains the light emission order N in which the own device performs flash emission from the fire position information included in the received fire signal F, that is, the identifier.

  For example, if the alarm device 3 grouped for each evacuation route has a sequential identifier along the evacuation route, the difference between the number part of the identifier as the fire position information and the number part of the identifier of the own aircraft By obtaining the absolute value of the light emission order, the light emission sequence N to be emitted by the own device can be obtained. The identifier of the alarm device 3 is not limited to the serial number as described above, and any code may be given. In that case, it is only necessary to allow the alarm device 3 to correspond to the code representing the identifier and the order along the evacuation route, and the corresponding means may be any known technique or known technique, and is appropriately selected. Is done.

  Here, it is assumed that alarm devices 3-1, 3-2,..., 3-n (n is a natural number) are arranged in the order of the evacuation route, and the identifiers are “F001”, “F002”,. If it is “Fn”, by calculating the difference between the number part of the identifier as the fire position information and the number part of each identifier, the light emission order N of flash emission is [2], [1], ... [| n- "number part of identifier as fire position information" | +1]. That is, a value obtained by adding 1 to the absolute value of the difference between the number part of the identifier of the own device and the identifier as the fire position information is the light emission order N in which flash emission is performed.

  That is, if the alarm device 3-1 and the alarm device 3-n (the alarm device 3-5 in the examples of FIGS. 3 and 4) corresponding to the end of the evacuation route are arranged in the vicinity of the emergency exit, the alarm device 3- From 2 to the alarm device 3-1, and from the alarm device 3-2 to the alarm device 3-n, the flash light is emitted in order toward the emergency exit.

  For example, when the fire detector 2-2 sends a fire detection signal D including its own identifier “D002”, the fire receiver 1 includes the corresponding identifier “F002” with reference to the first table when a fire determination is made. Fire signal F is sent out. Receiving this, the alarm device 3 obtains the light emission order N in which the own device performs flash emission as described above. In this case, the first is the alarm device 2-2, the second is the alarm devices 2-1 and 2-3, the third is the alarm device 2-4, and the fourth is the alarm device 2-5.

  Next, the delay time setting unit 33 calculates and stores the delay time t0 based on the light emission order N.

  The delay time t0 is, for example, such that in a group organized for each evacuation route, a plurality of alarm devices 3 including the own device emit flash light with a predetermined phase difference Δt in the emission order N of the own device. t0 = Δt · (N−1), t0 = Δt · N, etc. are obtained (see FIG. 6).

  In other words, the delay time setting unit 33 obtains the light emission sequence N in which the own device performs flash emission based on the fire position information, and a plurality of devices including the own device have the predetermined phase difference Δt in the light emission sequence N and flash. This is a delay time setting means for calculating and storing a delay time t0 from when the time counting unit 32 starts measuring time based on the light emission order N until the own device emits flash light so as to emit light.

  Then, the control unit 34 of the alarm device 3 compares the measured time t with the delay time t0 with reference to the delay time t0 stored in the delay time setting unit 33, and when the measured time t reaches the delay time t0. Then, the light emitting means 35 is controlled to emit flash light (see FIGS. 5 and 6).

  As described above, the alarm device closest to the fire detector 2 (fire detector 2-2 in the examples of FIGS. 3 and 4) that sent the fire detection signal D in the group organized for each evacuation route when a fire occurs. 3 (alarm device 3-2 in the examples of FIGS. 3 and 4), and the alarm device 3 (alarm devices 3-1 and 3-5 in the examples of FIGS. 3 and 4) located at the end along the evacuation route. ), The alarm device 3 sequentially flashes at a predetermined phase difference Δt. In other words, the alarm device 3 sequentially flashes to the evacuation guide toward the terminal alarm device 3 disposed near the emergency exit along the evacuation route.

  In the event of a fire, if a fire is not located near the alarm device of the group, for example, if a fire occurs in another district or floor, the alarm device 3 farthest from the emergency exit in the group (FIGS. 3 and 7). In the example, the alarm device 3-3) is set as a starting point, and the alarm device 3 (the alarm devices 3-1 and 3-5 in the examples of FIGS. 3 and 7) located at the end of the evacuation route in order What is necessary is just to make flash light emission. For example, the fire receiver 2 is provided with a second table in which the identifier of the alarm device 3 farthest from the emergency exit is stored in advance for each group organized for each evacuation route. When the fire receiver 1 determines that a fire has occurred, the identifier of the alarm device 3 farthest from the emergency exit is read with reference to the second table, and this is included in the fire signal F and sent as fire position information.

  With this configuration, when a fire occurs, in the group organized for each evacuation route, the evacuation route starts from the alarm device 3 (the alarm device 3-3 in the example of FIGS. 3 and 7) farthest from the emergency exit. The alarm device 3 sequentially flashes with a predetermined phase difference Δt toward the alarm device 3 (the alarm devices 3-1 and 3-5 in the example of FIGS. 3 and 7) located at the end of the alarm device 3 along the line.

  When a second table is provided in place of the first table, flash emission is sequentially performed along the evacuation route with the alarm device 3 farthest from the emergency exit as the starting point in all the groups that have received the fire signal F. It becomes like this. However, if a fire breaks out along the evacuation route, it may interfere with the evacuation. Therefore, it is desirable to perform the evacuation guidance described in the first embodiment in the group of evacuation routes to which the fire position belongs. In other words, it is desirable that the fire receiver 1 has a second table in addition to the first table. Then, for the group to which the fire position belongs when a fire occurs, the alarm device 3 closest to the fire detector 2 that has sent the fire detection signal D with reference to the first table is set as the flash emission start point. For the group to which the fire position does not belong, referring to the second table, the alarm device 3 farthest from the emergency exit is set as the flash emission start point. In this way, for each group organized for each evacuation route, the alarm device 3 flashes in order with a predetermined phase difference Δt toward the alarm device 3 located at the end along the evacuation route. good. In other words, when the fire receiver 1 determines that a fire has occurred, it refers to the second table for the group of evacuation routes to which the fire position does not belong, and sends the identifier of the alarm device 3 farthest from the emergency exit as fire position information. . Then, in the group to which the fire position does not belong, the alarm device 3 that is farthest from the emergency exit is used as a start point, and the alarm device is sequentially arranged with a predetermined phase difference Δt toward the alarm device 3 that is positioned at the end along the evacuation route. 3 flashes. The evacuation route group that determines the flash emission start point with reference to the second table is the evacuation route group to which the fire position does not belong on the fire floor, all the floors immediately above the fire floor, and other than the fire floor. It may be at least one of the floors, and is set as appropriate according to the structure of the building and the evacuation route.

  By the way, depending on the fire position, there may be a restriction on the evacuation route on the floor above the fire floor. For example, staircases and elevator shafts close to the fire location may get into a chimney due to the rising airflow generated by the heat of the fire, and may become difficult to evacuate. Therefore, the evacuation route and its direction may be selected on a floor higher than the fire floor, avoiding a route that makes evacuation difficult depending on the fire position. That is, control is performed so as to move away from the emergency exit that makes evacuation difficult for each group organized for each evacuation route. Then, a third table in which the identifier of the alarm device 3 that is the start point of the flash emission is stored in advance in association with the identifier of the fire detector 2 that has detected the fire so as to be such a flash emission start point. You may provide in the receiver 1. FIG.

[Embodiment 2]
The configuration of the second embodiment will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected to the same structure as Embodiment 1, and description is abbreviate | omitted. Further, the reference numerals in FIG. 1 are read based on FIG.

  The configuration of the present embodiment is different from that of the first embodiment. First, the alarm device 3 of the first embodiment further includes a synchronization signal receiving unit 38 as a means for receiving a synchronization signal included in the fire signal F. The alarm device 30 is provided. Secondly, the fire receiver 1 sends out a synchronization signal included in the fire signal F to the alarm device 30 every time corresponding to an integral multiple of the predetermined period T. Third, when the synchronization signal receiver of the alarm device 30 receives the synchronization signal included in the fire signal F, the timer 37 is initialized.

  That is, in the present embodiment, the timer unit 37 of the alarm device 30 is synchronously operated by the synchronization signal from the fire receiver 1.

  The reason for doing this is to maintain the accuracy of the timer 37 included in each alarm device 30. That is, when the timer 37 is operated for a long time, due to the accuracy of the timer 37 itself, the predetermined period T that should be common to each of the alarm devices 30 gradually shifts, and the timer that was performing the same operation all at once. There is a possibility that “step-out” may occur in which the time measurement result of 37 shifts.

  In order to prevent this, first, the accuracy of the timer 37 is increased. For example, a quartz oscillator or the like may be used to operate the timer unit 37 based on high-precision oscillation.

  However, it is not possible to completely synchronize the timing units 37 of the respective alarm devices 30. If the operation is continued for a longer time, step-out occurs. In addition, such a method uses an expensive device, resulting in an increase in cost. Therefore, in this embodiment, the accuracy of the time measuring unit 37 is controlled to perform periodic synchronization in order to minimize the accuracy of the time measuring unit 37 so that it can be realized at a low cost and to prevent step-out. It was made to synchronize periodically according to.

  That is, the fire receiver 1 sends out a synchronization signal to the alarm device 30 every time corresponding to an integral multiple of the predetermined period T, and the alarm device 30 that has received this signal initializes the timer 37.

  By sending the synchronization signal to the alarm device 30 every time corresponding to an integral multiple of the predetermined period T as described above, it is possible to minimize the deviation in the timing of flash emission at the time of initialization. Note that the degree of time corresponding to the integral multiple is appropriately determined according to the accuracy of the timer 37.

  The fire receiver 1 has been described as transmitting a fire signal F including a synchronization signal. However, the present invention is not limited to this, and the fire receiver 1 transmits the fire signal F separately from the fire signal F via a dedicated line (not shown). The apparatus 30 may receive a synchronization signal via a terminal (not shown) that connects the dedicated line.

  In addition, signal exchange between the fire receiver 1 and the alarm device 30 may be performed by multiplex transmission, for example, polling, or multiplex transmission so as to include the synchronization signal.

  Further, when performing multiplex transmission as described above, the alarm device 30 generates the synchronization signal therein based on multiplex transmission, for example, polling, by counting periodically transmitted signals with the alarm device 30. You may make it do.

  Further, the time measuring unit 37 described in the first embodiment may be replaced with a means for counting signals based on multiplex transmission as described above, for example, polling, instead of means for individually timing in the alarm device 3. In this case, the alarm device 3 operates in synchronization with the multiplex transmission signal from the fire receiver 1, and the timer 37 for counting this also operates in synchronization. A synchronization signal is not necessary.

Further, the alarm devices 3 and 30 may be controlled by radio signals via a relay device (not shown) connected to the fire receiver 1. That is,
(1) The repeater that has received the fire signal F from the fire receiver 1 transmits the fire signal F as a radio signal.
(2) The fire signal receiving unit 31 of the alarm device 3 or 30 is replaced with a wireless signal receiving unit that receives the wireless signal.
(3) Further, the power source unit is an internal battery power source, another external power source, or an internal secondary battery power source charged by another external power source.
(4) The alarm device 3 or 30 is controlled to flash by the fire signal F as the radio signal.

  It may be configured and operated as described above.

  Further, the alarm device 3 or 30 may be controlled to be initialized by a synchronization signal superimposed on the radio signal F.

1 Fire receiver 2, 2-1 to n (n is a natural number) Fire detector,
3, 3-1 to n, 30, 30-1 to n (n is a natural number) alarm device,
31 fire signal receiving unit, 32 timing unit, 33 delay time setting unit, 34 control unit,
35 light emitting section, 36 power supply section, 38 synchronization signal receiving section,
INf Fire signal input terminal, Ls, Lf Electric circuit

Claims (3)

A fire detection means having an individual unique identifier and transmitting a fire detection signal including the identifier when a fire is detected;
Fire receiving means for making a fire determination based on the fire detection signal and identifying a fire position, and sending a fire signal including fire position information when the fire is determined;
Each unit has its own unique identifier, arranged in groups for each evacuation route, and has a predetermined phase difference in order from the fire position side to the emergency exit side based on the fire signal, and flash emission at a predetermined cycle A plurality of alarm devices having light emitting means for
An alarm system characterized by comprising: When the alarm device is also disposed in the room outside the evacuation route, the fire detection means disposed in the room is activated, and when the fire receiving means is judged to be a fire and determined to be a fire room,
The alarm system according to claim 1, wherein the alarm device disposed in the fire room emits flash simultaneously with the alarm device that first flashes in the group. The fire determination means sends a synchronization signal to the alarm device every time corresponding to an integral multiple of the predetermined period,
3. The alarm system according to claim 1, wherein the alarm device that has received the synchronization signal initializes timing means for timing the predetermined period of flash emission. 4.

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