JP4363798B2 - Disaster prevention system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a disaster prevention system capable of setting linked / non-linked for each group of terminals.
[0002]
[Prior art]
Conventionally, in a disaster prevention system, a central processing unit such as a receiver is connected to a large number of terminals such as detectors and smoke-proof terminals via a line, and a system that monitors and informs a fire while transmitting and receiving them. Adopted.
An example of a conventional disaster prevention system is shown in FIG. In the disaster prevention system 1 shown in FIG. 7, the smoke prevention terminal 3 to the smoke prevention terminal 7 are connected to the receiver 2, and these perform an output operation in conjunction with a sensor (not shown). The receiver 2 stores interlocking data related to the interlocking relationship between terminals.
The smoke prevention terminals 3 to 7 are divided into several groups, and each terminal is given a group address of the group to which the terminal belongs. In FIG. 7, smoke prevention terminal 3, smoke prevention terminal 5 belongs to group 1, smoke prevention terminal 4 belongs to group 2 and group 3, and smoke prevention terminal 6 belongs to group 4. The receiver 2 stores the group address of each group, sends an ON / OFF signal for each group, and changes the linked / non-linked setting. For example, in the disaster prevention system 1 shown in FIG. 7, since the smoke prevention terminal 3 to the smoke prevention terminal 7 are classified into four groups, the receiver 2 stores four addresses.
[0003]
[Problems to be solved by the invention]
However, since the number of addresses that can be set in the address table in the memory of the receiver 2 is finite, as described above, when the same number of addresses as the number of groups is required, the number of installed terminals is large and large. In the system, the number of groups is large, and the address table on the receiver 2 side may be insufficient. In addition, when there are many terminals, the number of communication packets increases and the line is congested.
This is true not only for smoke prevention terminals in the disaster prevention system but also for other terminals that are linked / non-linked controlled.
[0004]
An object of the present invention is to prevent consumption of an address table of a central processing unit and the like and prevent congestion of a communication line even if the scale of the system becomes large and there are many terminals such as smoke prevention terminals in a disaster prevention system. .
[0005]
[Means for Solving the Problems]
  In order to solve the above problems, the invention described in claim 1 is, for example, as shown in FIGS.
  A plurality of interlocking source terminals (sensors 11 and 12), a plurality of interlocking destination terminals (smoke prevention terminals 13, 14, 15, 16, and 17) that perform a predetermined operation in conjunction with the interlocking source terminal, and a synchronization destination terminal In a disaster prevention system (10) comprising interlocking / non-interlocking instruction means (receiver 9) for transmitting a interlocking / non-interlocking signal for instructing to maintain or cancel the interlocking relationship to
  The plurality of linkage destination terminals are divided into a predetermined number of groups, and in each linkage destination terminal, which group belongs is set,
  The interlock / non-link signal consists of the same number of bits as the number of groups, and each bit corresponds to one different group and indicates either link or non-link.
The group setting in the link destination terminal is performed by associating each bit of data having the same number of bits as the number of groups with one group for each bit and setting whether or not the group belongs to the group.It is a disaster prevention system characterized by this.
[0006]
  According to the invention described in claim 1, in the disaster prevention system, the plurality of interlocking destination terminals that are interlocked with the interlocking source terminal are divided into a predetermined number of groups, and the interlocking destination terminal itself belongs to which group. Or is set. The interlock / non-link signal transmitted by the link / non-link instruction means is composed of n bits, for example, when the link destination terminals are classified into n groups, and each bit corresponds to one group. Therefore, the interlock / non-link instruction means can give a link / non-link instruction to all link destination terminals for each group with a single link / non-link signal. Since only one address addressed to the link destination terminal is required and only one communication packet is required, congestion of the communication line can be prevented.
According to the first aspect of the present invention, the group setting in the interlocking destination terminal includes n bits when the interlocking destination terminal is classified into n groups, and each bit corresponds to one group. . In this way, since each bit and group correspond one-to-one, for example, it is possible to set one interlocking destination terminal to belong to a plurality of groups.
  Here, the “link source terminal” includes various fire detectors and transmitters, the “link destination terminal” is a smoke prevention terminal, and the “link / non-link instruction means” is a receiver or host computer. Etc.
[0007]
In the disaster prevention system according to claim 1, as in the invention according to claim 2, the interlocking source terminal, the interlocking destination terminal, and the interlocking / non-interlocking instruction means are connected to the intelligent distributed control network (N). It may be configured.
Here, as the intelligent distributed control network, for example, a LONWORKS network (developed by Echelon, USA) can be cited.
[0010]
  The invention according to claim 3 is the invention according to claim 1 or 2.In the described disaster prevention system, the interlocking destination terminal is a smoke prevention terminal.
  Here, the smoke prevention terminal operates to prevent the spread of fire, such as a fire door and a smoke outlet, prevent smoke, or eliminate it in a predetermined direction.
[0011]
The invention according to claim 4 is the invention according to claim 3.In the disaster prevention system described in
  A repeater (20, 30) comprising a control circuit (21, 31) for outputting a control signal for operating the smoke-proof terminal;
  A temperature sensor (24) connected to the control circuit and detecting that a predetermined temperature has been reached;
  When the temperature sensor detects that the temperature reaches a predetermined temperature, a control signal is output from the control circuit.
[0012]
  Claim 4When the temperature sensor detects that the temperature reaches the predetermined temperature, the control signal is output from the control circuit. Therefore, even if the CPU or driver in the control circuit does not operate normally due to high temperatures, the control signal is forcibly output from the control circuit and the smoke prevention terminal is activated, so that the safety of the disaster prevention system is improved. Can do.
[0013]
  Claim 5The invention described inClaim 4In the disaster prevention system described in
  The control circuit includes a switch unit (S) that outputs a control signal to the smoke prevention terminal by switching the ON / OFF state, and a relay switch that includes a signal output instruction unit (relay unit R) that outputs the control signal to the switch unit. (25)
  When the temperature sensor detects that the temperature reaches a predetermined temperature, a control signal is output from the switch unit via the signal output instruction unit.
[0014]
  Claim 5According to the invention, when the temperature sensor provided in the repeater detects that the predetermined temperature has been reached, the control signal is output from the switch unit via the signal output instruction unit, so that the smoke prevention terminal is securely connected. Can be controlled.
[0015]
  Claim 6The invention described inClaim 4In the disaster prevention system described in
  The control circuit includes a switch unit (S) that outputs a control signal to the smoke prevention terminal by switching the ON / OFF state, and a relay switch that includes a signal output instruction unit (relay unit R) that outputs the control signal to the switch unit. (25)
  When the temperature sensor detects that the temperature reaches a predetermined temperature, a control signal is output from the switch unit regardless of the signal output instruction unit.
[0016]
  Claim 6According to the invention, when it is detected by the temperature sensor that the predetermined temperature is reached, a control signal is output from the switch unit to the smoke prevention terminal irrespective of the signal output instruction unit provided in the relay switch. . Therefore, for example, even when the signal output instruction unit cannot be operated due to high temperature, the smoke-proof terminal can be controlled and safety is higher.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS. FIG. 1 is a diagram showing an outline of a disaster prevention system 10 as an example of the present invention. The disaster prevention system 10 includes a receiver 9 and a large number of terminals connected to the receiver 9. In FIG. 1, the sensors 11 and 12 and the smoke prevention terminals 13 and 14 are illustrated.
In FIG. 1, the sensor 11 and the smoke prevention terminal 13 and the sensor 12 and the smoke prevention terminal 14 are set in an interlocking relationship. In the disaster prevention system 10, such an interlocking relationship is set also in other terminal devices not shown in FIG. Linkage / non-linkage will be described later.
[0018]
The disaster prevention system 10 is composed of an intelligent distributed control network N, and the receiver 9, the detectors 11 and 12, and the smoke prevention terminals 13 and 14 respectively have hardware nodes 9a, 11a, 12a, 13a, and 14a. The nodes 9a and 11a to 14a are connected to the network N. Each of the nodes 9a and 11a to 14a includes a neuron chip (not shown) that is a dedicated microcomputer for network construction, a transceiver (not shown) for physically connecting the neuron chip to the network N, and the like. The neuron chip includes a CPU (Central Processing Unit) and various memories. A predetermined setting is made for each neuron chip, whereby the receiver 9, the sensors 11, 12 and the smoke-proof terminals 13, 14 have intelligence and can communicate with each other so that they can communicate with each other. N is built.
FIG. 1 shows a part of the disaster prevention system 10. A large number of various terminals are connected to the network N, and nodes are mounted on these terminals.
[0019]
In the disaster prevention system 10, the receiver 9 is connected to all terminals, but does not control all terminals. The receiver 9 plays a role of grasping the situation of the entire system, and the receiver 9 and each terminal are in an almost equal relationship.
[0020]
The receiver 9 is connected to each terminal, grasps the current situation in the disaster prevention system 10, displays the situation, and gives a fire notification by an alarm. Furthermore, an operation unit (not shown) including a switch or the like is provided, and various settings and setting cancellations can be performed via the operation unit, and a predetermined signal is transmitted to each terminal according to the settings. Specifically, for example, an interlocking / non-interlocking signal is transmitted, that is, here, the receiver 9 becomes the interlocking / non-interlocking instruction means of the present invention.
Examples of the detectors 11 and 12 that are interlocking source terminals include smoke detectors, heat detectors, flame detectors, and the like, which detect a fire, output an alarm signal, and transmit it to the receiver 9 and the like. is there.
Examples of the smoke evacuation terminals 13 and 14 that are linked terminals include a fire door and a smoke evacuation port.
[0021]
The neuron chip of the receiver 9 and each terminal (node) constituting the disaster prevention system 10 has a self-address memory area and an address table memory area, as illustrated in FIG. The destination addresses of the address table (15 in this embodiment) can be stored. In FIG. 2, the smoke prevention terminal 14 and the sensor 12 in the disaster prevention system 10 are omitted, and the receiver 9, the sensor 11, and the smoke prevention terminal 13 are shown in detail.
Specifically, the receiver 9 has its own address, and the sensor 11 and the smoke prevention terminal 13 each have its own address and its own broadcast address (hereinafter referred to as “self broadcast address”).
In the disaster prevention system 10, as described above, a large number of smoke prevention terminals are installed, and these smoke prevention terminals are grouped, for example, by type such as fire doors or disaster prevention areas such as floors.
The broadcast address is, for example, a common address used when the receiver 9 transmits a signal having the same content to all smoke prevention terminals belonging to the transmission destination (all groups).
[0022]
Further, as the transmission destination address, for example, the receiver 9 stores the address of the smoke prevention terminal 13 and the broadcast address, and the sensor 11 has the address of the receiver 9 and the address of the smoke prevention terminal 13. The smoke prevention terminal 13 stores the address of the receiver 9 and the like.
Each of the receiver 9, the sensor 11, and the smoke prevention terminal 13 checks the destination address of the signal sent via the network N, and if it is a self address or a self broadcast address, A specific CPU in the neuron chip is taken in and processed.
[0023]
The outline of the operation at the time of fire detection in the disaster prevention system 10 will be described with reference to FIG.
For example, the sensor 11 detects a fire and transmits a notification signal to the receiver 9 and the smoke prevention terminal 13. The receiver 9 receives the notification signal and performs predetermined various alarm operations. On the other hand, the smoke prevention terminal 13 receives an alarm signal from the sensor 11 and performs an output operation (for example, an operation for closing a fire door), and outputs a response signal indicating that the output operation has been performed to the receiver 9. It is supposed to be. Further, after the output operation according to the alarm signal, the smoke-proof / exhaust terminal 13 performs an output operation so as to return, for example, by a control signal from the receiver 11 when a predetermined time elapses.
Here, a command signal for controlling and driving the smoke prevention terminal such as an alarm signal from the sensor 11 is referred to as a control signal.
[0024]
In the disaster prevention system 10, as described above, smoke prevention terminals are divided into groups, and one smoke prevention terminal may belong to a plurality of groups. Then, the interlocking relationship between the smoke prevention terminal and the sensor can be switched to non-interlocking in units of groups by the interlocking / non-interlocking signal from the receiver 9. Based on FIG. 3 and FIG. 4, the switching between interlocking / non-interlocking will be described.
[0025]
FIG. 3 shows smoke prevention terminals 15 to 17 in addition to the smoke prevention terminals 13 and 14 as smoke prevention terminals.
Here, the smoke prevention terminal 13 belongs to the group 1, the smoke prevention terminal 14 belongs to the groups 2 and 3, the smoke prevention terminal 15 belongs to the group 1, and the smoke prevention terminal 16 belongs to the group 4. The smoke prevention terminal 17 does not belong to any group.
In the memory in the neuron chip, the smoke prevention terminal 13 to the smoke prevention terminal 17 store their own groups with a number sequence, and store them in an n-bit number sequence Am when classifying them into n types of groups. In order to classify into four groups as shown in FIG.₁x₂x_Threex_Four(X = 0 or 1). Of the 4-bit sequence Am, x₁Is in group 1, x₂Is in group 2, x_ThreeIs in group 3, x_FourCorresponds to group 4 and the group to which it belongs₁~ X_FourIs set to “1”, and “0” is set for a group to which the user does not belong.
That is, as shown in FIG. 3, when classifying the smoke prevention terminal 13 into the group 1, “1” is set first such as “1000”. When classifying the smoke prevention terminals 14 into the groups 2 and 3, “1” is set to the second and third as “0110”. Similarly, the smoke prevention terminal 15 is set to “1000”, the smoke prevention terminal 16 is set to “0001”, and the smoke prevention terminal 17 is set to “0000”. FIG. 4A shows the classification of this group in a table. This setting is performed for each terminal by a management tool (such as a personal computer) connected to the network N when the disaster prevention system 10 is started up.
[0026]
On the other hand, the receiver 9 stores linked / unlinked data to be transmitted as a linked / unlinked signal. The linked / unlinked data is stored in an n-bit sequence Bm “y” when smoke-proof terminals connected to the receiver 9 are classified into n groups.₁y₂y_Three... y_n"(Y = 0 or 1).
Among the n-bit sequence Bm, y₁Is in group 1, y₂Is in group 2, y_ThreeFor groups that each column corresponds to each group and you want to maintain the interlocking relationship, such as “Group 3”, set the setting of each column to “0”, cancel the interlocking relationship, Is set to “1”. Each smoke evacuation terminal is switched to a non-linked state when a linked / unlinked signal in which “1” is set for a group to which the smoke control terminal belongs is transmitted. That is, x_n= Y_nWhen there is n where = 1, each smoke prevention terminal is switched to an unlinked state.
For example, when the smoke prevention terminal 13 to the smoke prevention terminal 17 are divided into four groups and the receiver 9 transmits the sequence Bm “1000” as the interlock / non-link signal, the y of the sequence Bm₁Is 1. Since smoke prevention terminals 13 and 15 are set to group 1, x₁= 1 and x_n= Y_nSince n which becomes = 1 exists (n = 1), the smoke prevention terminals 13 and 15 are switched to the non-interlocking state. However, smoke prevention terminals 14, 16, 17 are x₁= 0 and x_n= Y_nSince n which becomes = 1 does not exist, the interlocking / non-interlocking signal is ignored and the interlocking relationship is maintained.
[0027]
FIG. 4B shows a transmission example of the receiver 9 in a table.
Since the transmission example a is “0000”, there is no group that is not set to be interlocked. Since the transmission example b is “1000”, the smoke prevention terminal 13 and the smoke prevention terminal 15 classified into the group 1 are switched to the unlinked operation. Since the transmission example c is “0100”, the smoke prevention terminal 14 classified in the group 2 operates in an unlinked manner. Since the transmission example d is “0011”, the group 3 and the group 4 are set to be unlinked, and the smoke prevention terminal 14 and the smoke prevention terminal 16 are operated in an unlinked manner. Since the transmission example e is “1111”, all groups are set to be unlinked. Therefore, all smoke control terminals 13 to 16 operate in a non-interlocking manner.
[0028]
The contents of the sequence Bm in the receiver 9 can be freely switched by the operator at the time of maintenance and inspection.
The receiver 9 then sends the broadcast address to all connected smoke-proof / smoke-proof terminals 13 to 17 as heartbeat signals that are periodically transmitted at regular intervals. To send as a broadcast signal.
The smoke prevention terminal 13 to the smoke prevention terminal 17 are configured to switch their own interlocking / non-interlocking state according to the latest interlocking / non-interlocking signal.
[0029]
The operation flow of the interlock / non-interlock switching process of the smoke prevention terminal 13 to the smoke prevention terminal 17 will be described with reference to FIG. First, in step S1 of FIG. 5, an event of receiving a linked / unlinked signal from the receiver 9 occurs. In step S2, each smoke prevention terminal 13-smoke prevention terminal 17 is x_n= Y_nIt is determined whether or not n satisfying = 1 exists. If it exists, a process of switching to the non-interlocking operation is performed in step S3. If not, a process of maintaining the interlocking operation is performed in step S4. Finish.
[0030]
By the way, the smoke prevention terminal 13-the smoke prevention terminal 17 are provided with the repeater which controls and drives this, and the said node is mounted in the repeater.
6A and 6B show control circuits 21 and 31 in the repeaters 20 and 30 as examples of repeaters provided in the smoke prevention terminal 13 to the smoke prevention terminal 17. The control circuits 21 and 31 include a CPU 22 that controls them, a drive circuit 23, a relay switch 25, a temperature sensor 24 that operates when a predetermined temperature is reached, and the like. The relay switch 25 is switched ON / OFF when the contact point contacts / separates. When the relay switch 25 is turned ON, the switch unit S that outputs a control signal to the smoke-proofing terminal and the switch unit S by a predetermined signal from the drive circuit 23 It consists of a relay part R (signal output instruction part) that turns on and outputs a control signal.
Normally, when an alarm signal is transmitted from the sensor or the like to the repeaters 20 and 30, a signal is sent from the CPU 22 to the relay unit R in the relay switch 25 via the drive circuit 23, and the switch unit S is in the ON state. The switch unit S outputs a control signal to the smoke prevention terminal. As a result, the smoke evacuation terminal performs an output operation.
[0031]
By the way, electronic devices such as the CPU 22 and the drive circuit 23 may not operate normally when the ambient temperature rises due to the occurrence of a fire or the like, and the control signal cannot be transmitted to the smoke prevention terminal.
In such a case, the control circuit 21 shown in FIG. 6A transmits a predetermined signal to the relay unit R when it is detected that the predetermined temperature is reached by the temperature sensor 24 mounted in the repeater 20. Then, the switch unit S is switched to the ON state. Accordingly, the switch unit S forcibly outputs a control signal to the smoke prevention terminal regardless of the CPU 22 or the like.
Further, in the control circuit 31 shown in FIG. 6B, when the temperature sensor 24 detects that the predetermined temperature has been reached, a predetermined signal is transmitted to the switch unit S to switch to the ON state, and smoke prevention A control signal is output to the terminal. In the control circuit 31, regardless of the relay unit R, a control signal is forcibly output to the smoke prevention terminal. Therefore, even when the relay part R does not operate normally, a control signal can be output to the smoke prevention terminal.
[0032]
According to the disaster prevention system 10 described above, for example, when the smoke prevention terminal 13 to the smoke prevention terminal 17 are divided into four types of groups, the 4-bit sequence Am “x” indicates which group it belongs to.₁x₂x_Threex_Four" A linked / unlinked signal transmitted by the receiver 9 is a 4-bit sequence Bm “y₁y₂y_Threey_FourAs with the numerical sequence Am, each column of each bit corresponds to one group. For a group that is to be non-linked, the corresponding column setting is set to “1”, and the smoke-proof / smoke-proof terminal 13 to the smoke-proof / smoke-terminal 17 x_n= Y_nWhen n is set to = 1, the setting is switched to the non-linked setting, and when n does not exist, the signal is ignored.
That is, since the receiver 9 can give an instruction of interlocking / non-interlocking for each group to all the smoke prevention terminals 13 to 17 with a single interlocking / non-interlocking signal. The address to the smoke prevention terminal 13 to the smoke prevention terminal 17 in the terminal 9 is only one broadcast address, and the number of communication packets is only one, so that the consumption of the address table can be saved and the communication line is congested. Can be prevented.
[0033]
Further, as shown in FIG. 6, for example, even when the ambient temperature rises and the control circuits 21 and 31 do not operate normally, the temperature sensor 24 provided in the smoke prevention repeaters 20 and 30 has a predetermined temperature. When it is detected that the control signal is reached, the switch unit S is forced to output a control signal, so that the smoke prevention terminal is reliably controlled and driven. In particular, since the temperature sensor 24 and the relay unit R are not directly connected to the control circuit 31 shown in FIG. 6B, the smoke-proof terminal can be controlled even if the relay unit does not operate normally.
[0034]
Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate.
As for the interlocking relationship, it is not limited to the sensor and the smoke prevention terminal, and it is possible to set the interlocking relationship between all terminals installed in the disaster prevention system. Two or more terminals can be set in various combinations such as smoke exhaust terminals or smoke prevention terminals. The present invention can also be applied to these interlocking relationships.
In addition, the relay switch in the above embodiment is a contact type that can be switched ON / OFF by direct mechanical contact, but may be a contactless type that uses a semiconductor element such as a MOSFET or a thyristor as a switch.
[0035]
【The invention's effect】
  According to the invention described in claim 1, in the disaster prevention system, the plurality of interlocking destination terminals that are interlocked with the interlocking source terminal are divided into a predetermined number of groups, and the interlocking destination terminal itself belongs to which group. Or is set. The interlock / non-link signal transmitted by the link / non-link instruction means is composed of n bits, for example, when the link destination terminals are classified into n groups, and each bit corresponds to one group. Therefore, the interlock / non-link instruction means can give a link / non-link instruction to all link destination terminals for each group with a single link / non-link signal. Since only one address is required for the link destination terminal and only one communication packet is required, consumption of the address table can be saved and congestion of the communication line can be prevented.
  Further claim 1According to the invention described in the above, the group setting in the interlocking destination terminal consists of n bits when classified into n groups, and each bit corresponds to one group. In this way, since each bit and group have a one-to-one correspondence, it is possible to set, for example, one linked terminal to belong to a plurality of groups, and different classifications such as type and building floor number. It is also effective when combining methods.
[0036]
  Claim 1According to the invention described in the above, the group setting in the interlocking destination terminal consists of n bits when classified into n groups, and each bit corresponds to one group. In this way, since each bit and group have a one-to-one correspondence, it is possible to set, for example, one linked terminal to belong to a plurality of groups, and different classifications such as type and building floor number. It is also effective when combining methods.
[0037]
  Claim 4When the temperature sensor detects that the temperature reaches the predetermined temperature, the control signal is output from the control circuit. Therefore, even if the CPU or driver in the control circuit does not operate normally due to high temperatures, the control signal is forcibly output from the control circuit and the smoke prevention terminal is activated, so that the safety of the disaster prevention system is improved. Can do.
[0038]
  Claim 5When the temperature sensor provided in the repeater detects that the predetermined temperature has been reached, the control signal is output from the switch unit via the signal output instruction unit, so that smoke prevention is ensured. You can control the terminal.
[0039]
  Claim 6According to the invention, when it is detected by the temperature sensor that the predetermined temperature is reached, a control signal is output from the switch unit to the smoke prevention terminal irrespective of the signal output instruction unit provided in the relay switch. . Therefore, for example, even when the signal output instruction unit cannot be operated due to high temperature, the smoke-proof terminal can be controlled and safety is higher.
[Brief description of the drawings]
FIG. 1 is a diagram showing a schematic configuration of a disaster prevention system of the present invention.
FIG. 2 is a diagram showing details of a partial configuration of the disaster prevention system of FIG. 1;
FIG. 3 is a diagram for explaining in detail a relationship between a receiver and a smoke prevention terminal;
FIG. 4A is a diagram showing to which group each smoke prevention terminal belongs, and FIG. 4B is a transmission example of a signal sent from the receiver to each smoke prevention terminal.
FIG. 5 is a flowchart showing the operation of the smoke prevention terminal.
FIG. 6 is a diagram showing a control circuit of a repeater of a smoke prevention terminal.
FIG. 7 is a diagram for explaining a relationship between a receiver and a smoke prevention terminal in a conventional disaster prevention system.
[Explanation of symbols]
9 Receiver (Linked / non-linked instruction means)
10 Disaster prevention system
13, 14, 15, 16, 17 Smoke prevention terminal (linked terminal)
20, 30 repeater
21, 31 Control circuit
22 CPU
23 Drive circuit
24 Temperature sensor
25 Relay switch
N Intelligent decentralized control network
R relay part (signal output instruction part)
S Switch part

Claims (6)

A plurality of linkage source terminals, a plurality of linkage destination terminals that perform a predetermined operation in conjunction with the linkage source terminal, and a linkage / non-linkage signal that instructs the linkage destination terminal to maintain or release the linkage relationship / In disaster prevention system equipped with non-linked instruction means,
The plurality of linkage destination terminals are divided into a predetermined number of groups, and in each linkage destination terminal, which group belongs is set,
The interlock / non-link signal consists of the same number of bits as the number of groups, and each bit corresponds to one different group and indicates either link or non-link.
The group setting in the link destination terminal is performed by associating each bit of data having the same number of bits as the number of groups with one group for each bit and setting whether or not the group belongs to the group. Disaster prevention system.   2. The disaster prevention system according to claim 1, wherein the link source terminal, the link destination terminal, and the link / non-link instruction means are connected to an intelligent distributed control network. The disaster prevention system according to claim 1 or 2 , wherein the interlocking destination terminal is a smoke prevention terminal. A repeater including a control circuit that outputs a control signal for operating the smoke-proof terminal;
A temperature sensor connected to the control circuit and detecting that a predetermined temperature has been reached;
The disaster prevention system according to claim 3 , wherein when the temperature sensor detects that the temperature reaches a predetermined temperature, a control signal is output from the control circuit. The control circuit includes a relay unit including a switch unit that outputs a control signal to the smoke prevention terminal by switching the ON / OFF state, and a signal output instruction unit that outputs the control signal to the switch unit,
The disaster prevention system according to claim 4 , wherein when the temperature sensor detects that a predetermined temperature is reached, a control signal is output from the switch unit via the signal output instruction unit. The control circuit includes a relay unit including a switch unit that outputs a control signal to the smoke prevention terminal by switching the ON / OFF state, and a signal output instruction unit that outputs the control signal to the switch unit,
The disaster prevention system according to claim 4 , wherein when the temperature sensor detects that the temperature reaches a predetermined temperature, a control signal is output from the switch unit regardless of the signal output instruction unit.

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