JP2955173B2 - Disaster prevention control system, repeater and disaster prevention system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disaster prevention control system, a repeater, and a disaster prevention system used for disaster prevention equipment and the like that are compatible with large-scale and intelligent buildings.

[0002]

2. Description of the Related Art Conventionally, for example, Japanese Patent Application Laid-Open No. 58-172799
There is known a disaster prevention system as disclosed in US Pat. FIG. 4 is a configuration diagram of a conventional disaster prevention system. This disaster prevention system has an R-type (distributed system) system configuration corresponding to the enlargement and intelligentization of buildings, and a plurality of repeaters 2 are connected to a transmission line 5 extending from the receiver 1 in a distributed manner. ing.

A sensor 3 and a control terminal 4 are connected to each repeater 2. A terminal control unit 21 for controlling the control terminal 4 and information from the sensor 3 are provided in each repeater 2. , A receiver abnormality detecting unit 24, a selection switching unit 25, and a repeater transmission control unit 23. In addition, the receiver 1 is provided with a transmission control processing unit 11, an operation unit 13, and a display unit 12.

In this disaster prevention system, when the sensor 3 connected to one of the plurality of repeaters 2 detects, for example, a fire, the repeater 2 connected to the sensor 3 is transmitted to the information receiving unit 22 by the information receiving unit 22. The fire information is received and sent to the receiver 1 via the transmission line 5. When the fire information is sent from the repeater 2 via the transmission line 5, the transmission control processing unit 11 of the receiver 1 displays the fire information on the display unit 12, makes a comprehensive judgment, and outputs a predetermined command signal. The signal is sent to each repeater 2 via the transmission line 5. When the transmission control unit 23 of each repeater 2 receives this command signal, each repeater 2 can control the control terminal 4 according to the command signal. In addition, the control terminal 4 connected to each repeater 2 can be similarly controlled via the transmission line 5 by manually operating the operation unit 13 of the receiver 1.

[0005] By the way, a system such as a case where the receiver 1 has failed, a failure has occurred in the transmission line 5 between the receiver 1 and the repeater 2, or a case where maintenance and inspection of each device have been performed. Even when an emergency (for example, an abnormality such as a fire) occurs at the time of a down, it is necessary to control the control terminals connected to the repeaters 2 in an interlocked manner.

For this reason, in the disaster prevention system of FIG. 4, in addition to the transmission line 5, a direct input monitoring input line 6 and a direct input simultaneous control line 7 are further provided. An automatic / manual changeover switch 15, an alarm indicator operated by a signal from the monitoring input line 6, an alarm output unit thereof (an alarm output unit to the simultaneous control line 7) 14, and a simultaneous control switch 16 are provided. Further, even when the system is down, interlocking control over the repeaters 2 is automatically performed,
Further, in an emergency, the interlocking control can be performed by human judgment.

That is, when the system is down, in each of the repeaters 2, a receiver abnormality is detected by the receiver abnormality detecting section 24 connected to the transmission line 5, so that the selection switching section 25 of each of the repeaters 2 The information receiving unit 22 is connected to the monitoring input line 6
Switch to connect to.

Now, when the system is down,
If the sensor 3 connected to any of the repeaters 2 detects an abnormality such as a fire when the manual changeover switch 15 is set to automatic, this information is transmitted to the sensor 3.
Is sent to the receiver 1 via the connected repeater 2 and the directly-monitored monitoring input line 6, where the receiver 1 displays an alarm on the alarm display section, and outputs a signal directly from the transfer output section. The notification is automatically output to the simultaneous control line 7 of the pulling. Thereby, the control terminal 4 connected to each repeater 2 can be automatically and interlocked.

When the system is down, automatic / auto
If the sensor 3 connected to any of the repeaters 2 detects an abnormality such as a fire when the manual changeover switch 15 is set to manual, this information is similarly transmitted to the monitoring input line 6. Is transmitted to the receiver 1 via the display unit, and the receiver 1 displays an alert on the alert display unit. However, in this case, the transfer is not automatically output. That is, the changeover switch 1
When 5 is set to manual, the operator sees the alarm display and knows that it is an emergency case, and at the discretion of the operator, the simultaneous control switch 16 is operated to activate the simultaneous control line 7. Thus, the control terminal 4 connected to each repeater 2 can be interlocked and controlled.

[0010]

By the way, in a conventional disaster prevention system including a direct lead line, including the disaster prevention system shown in FIG. A centralized system is used for the interlocking control of the control terminal by the lead line. That is, taking the disaster prevention system shown in FIG. 4 as an example, the configuration is such that a plurality of repeaters 2 are connected to one direct simultaneous control line 7 extending from the receiver 1. In this case, generally, a predetermined voltage (for example, 24 V DC) is supplied from the power supply (not shown) of the receiver 1 to the direct drawing simultaneous control line 7. The voltage is monitored, and when the voltage of the direct drawing simultaneous control line 7 is maintained at a predetermined voltage (24 VDC), it is determined that the voltage is normal. When it is determined that there is, the interlocking control for the control terminal 4 is forcibly performed.

Therefore, when the centralized system is adopted, voltage supply to all the repeaters must be performed only by the power supply of the receiver 1, and it is necessary to increase the power supply capacity of the receiver 1. , The number of repeaters connected to the direct pull-out simultaneous control line 7 and the receiver 1
Disadvantage is that the distance between the relay and the repeater is limited. Further, when the direct pulling simultaneous control line 7 is short-circuited, there arises another problem that the fuse of the receiver 1 is blown.

Conventionally, the direct lead line (for example, the direct lead simultaneous control line 7) is not monitored for disconnection or short circuit. When the direct lead line is disconnected or short circuited at the time of system down, disaster prevention is performed. There has been a problem that interlocking control cannot be performed at all in the system.

The present invention solves the above-described problem in the centralized system of interlocking control, and provides an interlocking control system capable of performing interlocking control in a distributed form for each repeater connected to the direct line. An object of the present invention is to provide a disaster prevention control system, a relay device, and a disaster prevention system.

[0014]

In order to achieve the above object, according to the first and seventh aspects of the present invention, a plurality of repeaters are connected to a receiver via a transmission line.
Furthermore, between the receiver and the repeater and between each repeater,
The direct drawing lines are scattered and laid, and each of the repeaters is
Each uses its own power supply to monitor the status of the direct line between the immediately connected receiver or other repeater,
As a result of monitoring, when it is detected that the terminal is in an abnormal state, the terminal connected to the terminal is controlled to a predetermined state, and a direct line between the terminal and a subsequent repeater is set to an abnormal state. I have. Thereby, when an abnormal state is detected in a certain repeater, the abnormal state is sequentially propagated to the repeaters subsequent to this repeater via a direct drawing line, and the interlocking control can be performed. In this case, according to the present invention, since each repeater monitors and controls the state of the direct drawing line using its own power supply, the power supply capacity of the receiver does not need to be large, and the number of connected repeaters, The restriction on the distance between the receiver and the repeater can be eliminated.

[0015] In particular, according to the second aspect of the present invention, the repeater immediately after the receiver monitors whether or not the state of the direct line with the receiver is based on the abnormality detection from the receiver. ,
If it is based on abnormality detection, this can be detected as an abnormal state, and interlocking control can be performed. Furthermore, in the invention according to claim 3, each repeater monitors whether the state of the direct lead between the receiver or the other repeater connected immediately before is broken or short-circuited, and Even when a short circuit occurs, this can be detected as an abnormal state and interlocking control can be performed.

According to a fourth aspect of the present invention, in the third aspect of the present invention, each of the repeaters has a disconnection state between a directly connected receiver and another repeater. Alternatively, when an abnormal state due to a short circuit is detected, the fact is sent to the receiver via a transmission line. Thereby, the operator on the receiver side can know that the direct drawing line is disconnected or short-circuited.

According to the fifth, sixth, and eighth aspects of the present invention, when a predetermined factor occurs, each repeater is connected to a receiver or another repeater connected immediately before. The direct drawing line between them is directly connected to the direct drawing line between the subsequent repeater. As a result, even when a certain repeater is not functioning, the interlocking control can be performed without being affected by this.

[0018]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a configuration diagram of one embodiment of a disaster prevention system according to the present invention. Referring to FIG. 1, this disaster prevention system
A plurality of repeaters 52-1 to 52-n are connected to the receiver 51 via a transmission line 55.
A sensor 53 and a control terminal 54 are respectively connected to -52-n. In this disaster prevention system,
In addition to the transmission line 55, a direct input line 56 and a direct control line 57 are provided. Here, the direct input line 5
The direct drawing control line 57 corresponds to the direct drawing monitoring input line 6 and the simultaneous control line 7 of the disaster prevention system shown in FIG. 4, respectively.
Is not based on a centralized system like the simultaneous control line 7 of the disaster prevention system shown in FIG. 4, but is based on a distributed system.

That is, in FIG.
7 is a section between the receiver 51 and the repeater 52-1;
-1 and the repeater 52-2,..., The repeater 52- (n-
They are laid in a distributed manner, such as between 1) and the repeaters 52-n. In addition, the direct input line 56 may be laid like the monitoring input line 6 of the disaster prevention system shown in FIG. 4, or, like the direct input control line 57, is based on a distributed system. May be.

FIG. 2 is a diagram showing a configuration example of the receiver and the repeater in the disaster prevention system of FIG. 1, particularly a configuration example related to the direct control line 57. Referring to FIG. 2, the receiver 5
In order to enable control of the control terminal 54 by the direct drawing control line 57 laid between the relay terminal 5 and the relay 52-1,
The receiver 51 is provided with a state switching unit 62 for switching the state of the direct drawing control line 57, and the repeater 52-1 applies a predetermined voltage to the direct drawing control line 57 to the receiver 51. A power supply 65 to be supplied, a connection control unit 63 that controls connection of the direct drawing control line 57, a state monitoring unit 64 that monitors the state of the direct drawing control line 57 between the receiver 51, and a direct drawing control line 57. And a terminal control section 67 for controlling the control terminal 54 connected thereto according to the result of the state monitoring.

The control terminal 5 is connected by a direct control line 57 laid between the repeaters 52-1 and 52-2.
In order to enable the control of the relay unit 52-1, the repeater 52-1 is further provided with a state switching unit 66 for switching the state of the direct control line 57, similarly to the receiver 51.
Includes a power supply 65 for supplying a predetermined voltage to the direct pull control line 57 between the relay 52-1 and the relay 52-1, like the relay 52-1.
A connection control unit 63 that controls connection of the direct drawing control line 57,
A state monitoring unit 64 that monitors the state of the direct drawing control line 57;
A terminal control section 67 for controlling the control terminal 54 connected to itself according to the result of monitoring the state of the direct control line 57 is provided.

In the same manner, in the same manner, the direct connection between the repeaters 52-2 and 52-3,..., Between the repeaters 52- (n-1) and 52-n is performed. Pull control line 5
7 also applies to the repeaters 52-1 and 52-2.
Is the same as the direct drawing control line 57 laid between them.

That is, each of the repeaters 52-1 through 52-n
Have the same configuration with respect to the control by the direct drawing control line 57, and include a connection control unit 63, a state monitoring unit 64, a terminal control unit 67, a power supply 65, and a state switching unit 66, respectively. ing. Although not shown in FIG. 2, each of the repeaters 52-1 to 52-n has an information receiving unit for receiving information from the sensor 3 and a receiving unit, similarly to the respective repeaters of the disaster prevention system of FIG. A receiver abnormality detecting unit for detecting an abnormality of the device 51, a selection switching unit, and the like may be further provided.

Here, the power supply 65 of the repeater 52-i includes:
The one that supplies a voltage of, for example, DC 24 V to the direct pulling control line 57 between the preceding stage of the repeater 52-i is used.

When the system is down, the status switching unit 62 of the receiver 51 is connected to the repeater 52.
Any of the sensors 5 connected to -1 to 52-n
In step 3, an abnormality such as a fire is detected.
Is notified to the receiver 51 via, or that an abnormality such as a fire has occurred is notified to the receiver 51 side,
On the receiver 51 side, for example, when a switch such as the simultaneous control switch 16 provided in the receiver of the disaster prevention system of FIG. The state is switched from the normal state to the abnormality detection state.

The connection control unit 63 of the repeater 52-i (1 ≦ i ≦ n) is connected to the receiver 51 or the repeater 52-i of the preceding stage.
The direct control line 57 from (i-1) is connected to the repeater 52-i.
Connected to the state monitoring unit 64 of
(i + 1) to control whether to directly connect to the direct drawing control line 57.
It is determined whether the power supply 65 of i is normal or down. When the power supply 65 is normal, the direct drawing control line 57 from the preceding stage is connected to the state monitoring unit 64 of the repeater 52-i. Is down, the repeater 52-
i is apparently not present, that is, the repeater 52-
i is substantially passed through, and the direct drawing control line 57 from the preceding stage is connected to the direct drawing control line 57 between the subsequent stage repeater 52- (i + 1).
It is designed to connect directly to

The status monitor 64 of the repeater 52-i
Monitors whether the state of the direct control line 57 from the receiver 51 or the repeater 52- (i-1) at the preceding stage is normal or abnormal. Here, the state monitoring unit 64 sets the abnormal state of the direct-pull control line 57 as not only the state in which an abnormality such as a fire is detected (that is, the abnormality detection state), but also the disconnection state and short-circuit state of the direct-pull control line 57 Is also monitored.

The state switching unit 66 of the repeater 52-i
Has a function of interlocking control of the control terminals 54 of the repeaters 52- (i + 1) to 52-n at the subsequent stage of the repeater 52-i, and is monitored by the status monitor 64 of the repeater 52-i. result
In accordance with the (state of the preceding direct drawing control line 57), the state of the direct drawing control line 57 laid between the relay unit 52- (i + 1) at the subsequent stage is automatically switched and controlled. I have.

Next, the operation of the disaster prevention system having such a configuration, particularly, the interlocking control operation by the direct control line 57 will be described. If the receiver 51 breaks down, or
When a system failure occurs, such as when a failure occurs in the transmission line 5 between the receiver 51 and the repeaters 52-1 to 52-n or when a maintenance check of each device is performed. , Any of the sensors 53 connected to the repeaters 52-1 to 52-n (for example, the repeaters 52-1 to 52-n).
When an abnormality such as a fire is detected by the sensor 53) connected to −j and is notified to the receiver 51 via the repeater 52-j and the direct input line 56, or an abnormality such as a fire is detected. Is reported to the receiver 51 side, and a switch such as the simultaneous control switch 16 provided in the receiver 1 of the illustrated disaster prevention system is operated by the operator on the receiver 51 side. At this time, the state switching unit 62 of the receiver 51 switches the direct drawing control line 57 between the receiver 51 and the repeater 52-1 from the normal state to the abnormality detection state.

For example, if the power supplies 65 of the repeaters 52-1 to 52-n are all normal and the repeaters 52-1 to 5
2-n connection control unit 63 is a direct drawing control line 57 from the preceding stage.
Is connected to its own state monitoring unit 64, when the state of the direct drawing control line 57 is switched from the normal state to the abnormality detection state by the state switching unit 62 of the receiver 51, the repeater 52-1 is connected.
The state monitoring unit 64 detects that the direct drawing control line 57 is in the abnormality detection state. Thereby, the repeater 52-1
Of the control terminal 5 connected thereto
4 is controlled in a predetermined manner. For example, the control terminal 54
Is a fireproof shutter, it can be closed in conjunction with it.

When the status monitoring unit 64 of the repeater 52-1 detects that an abnormal state is detected, the status switching unit 66 of the repeater 52-1 causes the subsequent direct control line 57 to be connected.
Is switched from the normal state to the abnormal state. As a result, the state monitoring unit 64 of the repeater 52-2 detects that the direct control line 57 is in an abnormal state, and the terminal control unit 67 of the repeater 52-2 determines the control terminal connected thereto. Predetermined control is performed at 54.

As described above, the state switching unit 62 of the receiver 51
When the state of the direct drawing control line 57 connected to the receiver 51 is switched to the abnormality detection state, the abnormality detection state is sequentially transmitted to the direct drawing control line 57 between the repeaters 52-1 to 52-n. In each of the repeaters 52-1 to 52-n, the control terminal 54 is controlled by the terminal control unit 67 to a state corresponding to the occurrence of an abnormality (for example, when the control terminal 54 is a fireproof shutter, To close it), thereby enabling interlocking control. That is, each of the repeaters 52-1 to 52-n can set the control terminal 54 connected thereto to an interlocked state.

In the conventional disaster prevention system shown in FIG. 4, the control terminals set in the respective repeaters can be set in an interlocking state, but in the present embodiment, each of the repeaters 52-1 through 52-n is set. Uses its own power supply 65 to supply power to the distributed direct drawing control line 57, to control the direct drawing control line 57, and to perform interlocking control. No power supply of the receiver 51 is required, and therefore the power capacity of the receiver 51 is not increased, and the number n of the repeaters 52 and the receiver 51 and the repeater 5 are not required.
Can completely remove the restriction on the distance between the two
Conventional problems can be solved.

In this embodiment, each repeater 52
The status monitoring units 64 of -1 to 52-n are connected to the direct control line 57 regardless of whether a system down occurs.
As an abnormal state, a disconnection state and a short-circuit state of the direct drawing control line 57 are also monitored. Now, for example, the state monitoring unit 64 of the repeater 52-i sets the receiver 51 or the repeater 52-
When it is detected that the direct drawing control line 57 between (i-1) is disconnected or short-circuited, this repeater 52-i
Notifies the receiver 51 to that effect via the transmission line 55. In this case, the receiver 51 informs the operator of the direct drawing control line 57 by, for example, displaying that the disconnection or short circuit has occurred. In addition, at this time, considering that the transmission line 55 may be disconnected or short-circuited, the terminal control unit 67 of the repeater 52-i performs
As in the case of detecting the abnormality detection state, predetermined control is performed on the control terminal 54 connected to the repeater 52-i. Further, the state switching unit 66 of the repeater 52-i switches the subsequent direct drawing control line 57 to an abnormal state.

As described above, the status monitor 64 of a certain repeater 52-i is connected to the receiver 51 or the repeater 52- (i-1) at the preceding stage of the repeater 52-i. When detecting that the disconnection state or the short-circuit state is detected at 57, the abnormal state is sequentially transmitted to the direct drawing control lines 57 between the repeaters 52- (i + 1) to 52-n subsequent to the repeater 52-i. , So that each repeater 52
In -i to 52-n, the terminal control unit 67 can perform predetermined control on the control terminal 54. That is, when a disconnection or short circuit occurs in the direct drawing control line 57 immediately before the repeater 52-i, the control terminal 54 connected to each of the subsequent repeaters 52-i to 52-n is provided for fail-safe operation. Can be set in an interlocked state. Note that, in this case, the receiver 51, the preceding stage of the repeater 52-i in which the disconnection or short circuit does not occur in the direct drawing control line 57,
As described above, the interlocking control is performed between the repeaters 52-1 to 52- (i-1) when the direct drawing control line 57 is in the abnormality detection state by the receiver 51.

In the present embodiment, for example, when the power supply 65 of a certain repeater 52-i is down (stopped), the connection control unit 63 of this repeater 52-i is connected to the receiver at the preceding stage. 51 or the repeater 52- (i-1) is connected to the direct control line 57 by the repeater 52-i.
Is controlled so as to be directly connected to the direct drawing control line 57 connected to the repeater 52- (i + 1) at the subsequent stage.

Thus, the direct drawing control line 57 from the preceding stage
Is substantially passed through the repeater 52-i in which the power supply 65 is down, and passes through the connection control unit 6 of the subsequent repeater 52- (i + 1).
3 and directly connected to the repeaters 52- (i-1) and 52- (i-1).
i, the status monitoring unit 64 of the repeater 52- (i + 1) can monitor the status of the direct control line 57 between the repeaters 52- (i + 1). That is, for example, a certain repeater 52-
Even if the power supply 65 of i is down due to maintenance and inspection of the repeater 52-i, it is not affected by this and the repeater 52-i is not affected.
, The control terminals 54 of the repeaters 52-1 to 52-n can be set in an interlocked state by the direct control line 57.

FIG. 3 is a diagram showing a more specific configuration example of the disaster prevention system according to the present invention. Referring to FIG. 3, the receiver 51 is provided with a switch (for example, a fire confirmation switch) SW for switching the state of the direct drawing control line 57. Resistors 71 and 72 (resistors R ₁ and R ₂ , respectively) for changing the state of the direct control line 57 in accordance with turning off are provided. A voltage of 24 V DC is supplied to the direct pull control line 57 from the power supply 65 of the repeater 52-1. However, in FIG. 3, a voltage supply portion to the direct pull control line 57 is omitted for simplicity. ing. Further, in FIG. 3, for simplicity of description, it is assumed that the interlocking control is performed only by operating the switch SW. Therefore, the direct input line 56 and its related parts are not shown.

Further, the repeater 52-1, the relay switch RY ₂ for controlling the connection of the straight pull control line 57 connected between the preceding stage of the receiver 51, the front of the receiver 51 An input unit 73 that captures the state of the direct drawing control line 57 connected between the input unit 73 and a processor (CPU) 74 that performs predetermined control based on information captured by the input unit 73;
An output unit 75 for outputting a state switching signal from the processor 74 based on the information captured by the input unit 73, and an output unit 75
Depending on the state switching signal from the repeater 52-1 and the relay switch RY ₁ for switching the state of the straight pull control line 57 which is connected between the repeater 52-2 is provided, furthermore, The direct control line 57 connected between the repeaters 52-1 and 52-2 is also connected to the direct control line 57 connected between the receiver 51 and the repeater 52-1.
Resistors 77 and 78 having the same function as (respectively, resistance values R ₁ ,
R ₂ ) are provided.

The processor 74 is connected to the repeater 52
-1 for controlling the whole, and the direct control line 5
In addition to performing state monitoring and state switching of the control unit 7, control on the transmission line 55 and control on the direct input line 56 are also performed. Further, the processor 74 includes:
It is assumed that a function as the terminal control unit 67 shown in FIG. 1 is also provided. Also, in FIG. 3, the repeaters 52-2 through 52-
Although n is not shown, it is assumed that the repeaters 52-2 to 52-n have the same configuration as the repeater 52-1.

Next, the operation of the disaster prevention system having the configuration shown in FIG. 3 will be described. Normally, in a disaster prevention system of this type, when the system is not down, the control terminal 54 connected to each of the repeaters 52-1 to 52-n is controlled by the transmission line 55. That is, in the receiver 51, switches S ₁ to Sn to set controlling each control terminal 54 connected to the respective repeaters 52-1 to 52-n in a predetermined state (not shown) is provided and which, when the receiver 51 is polled sequentially circulate through each repeater 52-1 to 52-n through the transmission line 55, corresponding to information of each switches S ₁ to Sn, which is set in a predetermined state To the processor 74 of the repeater. Thereby, the processor 7 of each of the repeaters 52-1 to 52-n
4 can control its own control terminal 54 according to the switch information set at the time of polling.

At this time, if a switch (for example, a fire confirmation switch) SW is operated, the receiver 51 gives priority to the information indicating that the switch SW has been operated, and the transmission line 5.
5 to each of the repeaters 52-1 through 52-n. Thereby, the processor 7 of each of the repeaters 52-1 to 52-n
4 judges that an abnormality such as a fire has occurred,
The control terminals 54 connected to -1 to 52-n can be interlocked and controlled according to the abnormality control routine RT. As described above, when the system is not down, the interlocking control can be performed via the transmission line 55 by operating the switch SW.

On the other hand, when the system is down, the processor 74 of each of the repeaters 52-1 to 52-n draws the control target from the transmission line 55 directly to the control line 57.
Switch to. Now, it is assumed that the power supply 65 of the repeater 52-1 is not down and is normal. In this case, in FIG. 3, the input unit 73 of the repeater 52-1 and the processor 7
4 indicates that when the switch SW is not operated and the direct control line 57 with the receiver 51 has no disconnection or short circuit,
It is detected that the resistance value of the direct drawing control line 57 is (R ₁ + R ₂ ). Further, when the switch SW is operated, the resistance of the straight pull control line 57 detects that the R _1. When a disconnection or a short circuit occurs, the resistance values of the direct pull control line 57 are “∞” and “0”, respectively.
Is detected. That is, the processor 74
A first state in which the switch SW has not been operated and the disconnection / short circuit of the direct-pull control line 57 with the receiver 51 has not occurred, a second state in which the switch SW has been operated, and a direct-pull control. The third state in which the wire 57 is disconnected or short-circuited can be detected in a distinguishable manner.

When the processor 74 detects that the direct drawing control line 57 with the receiver 51 is in the first state, the processor 74 causes the output section 75 to output a state switching signal indicating that the state is normal. Thereby, the relay switch RY
₁ is held in an open state as shown in FIG. In this case, the repeater 52-2, disconnection straight pull control line 57 which is connected between the repeater 52-1, when there is no short circuit, the resistance of the straight pull control line 57 is (R ₁ + R ₂₎ So that
It is detected that the direct drawing control line 57 is in the first state.
In this way, in the receiver 1, when the switch SW is not operated and each of the direct control lines 57 is not disconnected or short-circuited, the resistance value of each direct control line 57 becomes (R ₁
+ R ₂ ), and all the repeaters 52-1 to 52-n
Can be detected as normal. In this case, the control of the control terminal 54 is not performed in each of the repeaters 52-1 to 52-n.

On the other hand, when it is detected that the direct drawing control line 57 with the receiver 51 is in the second state, the processor 74 of the repeater 52-1 is connected to the repeater 52-1. The control terminal 54 is controlled according to the abnormality control routine RT. For example, if the control terminal 54 is a fire shutter and the abnormality control routine RT is a program for closing the fire shutter in conjunction with a fire signal, the processor 74 can close the fire shutter in a linked manner. I do. Further, the processor 74 of the repeater 52-1 causes the output unit 75 to output a state switching signal indicating that there is an abnormality. Thereby, the relay switch RY
₁ is closed. In this case, the repeater 52-2, the resistance of the straight pull control line 57 which is connected becomes R ₁ between the repeaters 52-1, the straight pull control line 57 is in a second state And the processor 74 of the repeater 52-2 controls the control terminal 54 connected to the repeater 52-2 according to the abnormality control routine RT. Further, the output unit 75, by outputting the state switching signal indicating that the abnormality, the relay switch RY ₁ repeater 52-2 to a closed state.

Further, a direct drawing control line 5 between the receiver 51
7 is detected to be in the third state, the repeater 52
The -1 processor 74 sends the notification to the receiver 51 via the transmission line 55 to notify the operator of the receiver 51. At this time, since the transmission line 55 may be broken, etc.
The -1 processor 74 controls the control terminal 54 connected to the repeater 52-1 according to the abnormality control routine RT. For example, if the control terminal 54 is a fire shutter and the abnormality control routine RT is a program for closing the fire shutter in conjunction with a fire signal, the processor 74
Allows the fireproof shutter to be closed in conjunction with it.
Further, the processor 74 of the repeater 52-1 outputs the output unit 7
From step 5, a state switching signal indicating that the state is abnormal is output. As a result, the relay switch RY ₁ is a closed state.
In this case, the repeater 52-2, the resistance of the straight pull control line 57 which is connected becomes R ₁ between the repeaters 52-1, the straight pull control line 57 is in a second state Is detected, and the processor 74 of the repeater 52-2
The control terminal 54 connected to 2-2 is controlled according to the abnormality control routine RT. Also, the output unit 75 outputs a state switching signal indicating that there is an abnormality, and
It is of the relay switch RY ₁ in the closed state.

As described above, when the switch SW of the receiver 51 is operated, or when the direct control line 57 connected between the receiver 1 and the repeater 52-1 is disconnected or short-circuited, The information indicating the abnormal state can be sequentially propagated from the repeater 52-1 to the repeater 52-n via the direct drawing control line 57. In each of the repeaters 52-1 to 52-n, the abnormality control is performed. The interlocking control of the control terminal 54 can be performed according to the routine RT.

In the above example, the receiver 1 and the repeater 5
Although the case where there is a disconnection and a short circuit in the direct drawing control line 57 connected to the 2-1 is described, the direct drawing control line 57 between the receiver 1 and the repeater 52-1 has a disconnection and a short circuit. There is no short circuit and, for example, the repeaters 52- (i-1) and 52- (i-1)
If there is a disconnection or short circuit in the direct control line 57 connected to the relay device 52-i, the repeaters 52- (i-1) and 52
-I becomes the third state, and the repeater 52-i sends the fact to the receiver 51 via the transmission line 55, and furthermore, By transmitting the information indicating the abnormal state to the repeater, each repeater after the repeater 52-i performs the interlocking control of the control terminal 54 in accordance with the abnormality control routine RT. At this time, the repeaters 52-1 to 52- (i
When there is no disconnection or short circuit in the direct drawing control line 57 during -1), the repeaters 52-1 to 52- (i-1) at the preceding stage are linked and controlled by the switch SW of the receiver 1.

Further, for example, the voltage 65 of the repeater 52-1
When but down, straight pull control line 57 from relay switch RY ₂ is turned off, the receiver 51, the repeater 5
2-1 is passed through to repeaters 52-1 and 52-2.
Is connected to the direct drawing control line 57 between the two. In this case, disconnection and short circuit of the direct control line 57 between the receiver 51 and the repeaters 52-1 to 52-2 are monitored by the repeater 52-2.

In the above-described embodiment, the connection control section 63 of the repeater switches the connection of the direct drawing control line 57 when the power supply 65 of the repeater itself goes down (stops).
The switching of the connection of the direct drawing control line 57 may be controlled by another factor other than when the own power supply 65 goes down.

In the above embodiment, the repeater 52-1 is used.
Each of the repeaters 52-1 to 52-n is a main repeater and the main repeater is a main repeater. The present invention can be similarly applied to a configuration in which a sensor, a control terminal, and a repeater are connected to each of the devices 52-1 to 52-n.

In the above embodiment, the direct control line 5
Although the monitoring and control of the disconnection and short-circuit of 7 have been described, the monitoring and control method of such disconnection and short-circuit
In the case where 6 is laid in a distributed manner similarly to the direct drawing control line 57, it can also be used for monitoring and controlling disconnection and short circuit of the direct drawing input line 56.

Further, in the above-described embodiment, power is supplied to the direct drawing control line 57 between the receiver 51 and the repeater 52-1 by the power supply 65 of the repeater 52-1.
Direct control line 5 between 2-i and repeater 52- (i + 1)
7 is supplied by the power supply 65 of the repeater 52- (i + 1). Instead, the power supply to the direct drawing control line 57 between the receiver 51 and the repeater 52-1 is received. It is also possible to supply power to the direct control line 57 between the repeaters 52-i and 52- (i + 1) using the power supply of the repeater 52-i. However, in this case, since it is necessary to use the power supply of the receiver 51, from the viewpoint of further saving the power supply of the receiver 51, as in the above-described embodiment, without using the power supply of the receiver 51 at all, It is preferable to supply power to the direct control line 57 only with the power supply 65 of the repeaters 52-1 to 52-n.

In the above-described embodiment, one repeater 5
In 2-i, although the relation between the sensor 53 and the terminal 54 connected to the repeater 52-i is not specifically mentioned, the repeater 52-i is abnormally connected to the preceding direct drawing control line 57. When the state is detected, the terminal 54 connected to the self is controlled in conjunction with the fire signal only when the sensor 53 connected to the self detects an abnormality (when a fire signal is generated). May be like this, or
Regardless of whether or not the sensor 53 has detected an abnormality,
The terminal 54 connected to itself may be controlled when an abnormal state is detected from the direct drawing control line 57 in the preceding stage.

[0055]

As described above, according to the first and seventh aspects of the present invention, a plurality of repeaters are connected to a receiver via a transmission line. Between the relays and between the repeaters, direct lead wires are laid in a distributed manner, and each of the repeaters uses its own power supply, and receives the receiver or other connected immediately before. The status of the direct line between the relay and the relay device is monitored, and when the status is detected as an abnormal condition as a result of the monitoring, the terminal connected to the relay device is controlled to a predetermined status, and the relay device at the subsequent stage is connected to the terminal device. Since the direct lead between them is set to an abnormal state, when an abnormal state is detected in a certain repeater, the abnormal states are sequentially transmitted to the repeaters subsequent to this repeater via the direct lead. Propagation allows interlocking control. In this case, according to the present invention, since each repeater monitors and controls the state of the direct drawing line using its own power supply, the power supply capacity of the receiver does not need to be large, and the number of connected repeaters, The restriction on the distance between the receiver and the repeater can be eliminated.

In particular, according to the second aspect of the present invention, the repeater immediately after the receiver monitors whether the state of the direct line with the receiver is based on the detection of an abnormality from the receiver. ,
If it is based on abnormality detection, this can be detected as an abnormal state, and interlocking control can be performed. Furthermore, in the invention according to claim 3, each repeater monitors whether the state of the direct lead between the receiver or the other repeater connected immediately before is broken or short-circuited, and Even when a short circuit occurs, this can be detected as an abnormal state and interlocking control can be performed.

According to a fourth aspect of the present invention, in the third aspect of the present invention, each repeater is in a state of a direct line between a receiver or another repeater connected immediately before. Is detected as an abnormal state due to disconnection or short circuit, the fact is transmitted to the receiver via the transmission line, so that the operator on the receiver side can know that the direct drawing line is disconnected or short circuited.

According to the fifth, sixth, and eighth aspects of the present invention, when a predetermined factor occurs, each of the repeaters is connected to a receiver or another repeater connected immediately before. Is connected directly to the direct line between the subsequent repeater, so even if one repeater is not functioning, it is not affected by this Can be performed.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of one embodiment of a disaster prevention system according to the present invention.

FIG. 2 is a diagram illustrating a configuration example of a receiver and a repeater in the disaster prevention system illustrated in FIG. 1;

FIG. 3 is a diagram showing a more specific configuration example of the disaster prevention system according to the present invention.

FIG. 4 is a configuration diagram of a conventional disaster prevention system.

[Explanation of symbols]

 REFERENCE SIGNS LIST 51 receivers 52-1 to 52-n repeater 53 sensor 54 control terminal 55 transmission line 56 direct drawing input line 57 direct drawing control line 62 state switching unit 63 connection control unit 64 state monitoring unit 65 power supply 66 state switching unit 67 Terminal control unit

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-58-172775 (JP, A) JP-A-5-129896 (JP, A) JP-A-2-66698 (JP, A) (58) Field (Int.Cl. ⁶ , DB name) G08B 23/00-31/00 G08B 17/00

Claims (9)

(57) [Claims] 1. A plurality of repeaters are connected to a receiver via a transmission line, and further, a direct drawing line is scattered between the receiver and the repeaters and between the repeaters. Each of the repeaters, using its own power supply, monitors the state of a direct line between the immediately connected receiver and another repeater, and as a result of the monitoring, the state is abnormal. Is detected, the terminal connected to itself is controlled to a predetermined state,
Also, a disaster prevention control method characterized in that the state of a direct drawing line with a repeater at a subsequent stage is set to an abnormal state. 2. The disaster prevention control method according to claim 1, wherein
The repeater immediately after the receiver monitors whether the state of the direct line between the receiver and the receiver is based on abnormality detection from the receiver. Disaster prevention control method characterized by detecting as a state. 3. The disaster prevention control method according to claim 1,
Each of the repeaters monitors whether the state of the direct lead between the receiver or another repeater connected immediately before is a disconnection or a short circuit, and when the state is a disconnection or a short circuit, this is regarded as an abnormal state. Disaster prevention control method characterized by detection. 4. The disaster prevention control method according to claim 3,
Each of the repeaters, when the state of the direct lead between the receiver or another repeater connected immediately before is detected as an abnormal state due to disconnection or short circuit, that effect is transmitted via the transmission line. Disaster prevention control method characterized by sending to the receiver. 5. The disaster prevention control system according to claim 1, wherein
Each of the repeaters, when a predetermined factor occurs, directly connects a direct lead between the immediately connected receiver or another repeater to a direct lead between the subsequent repeater. Disaster prevention control method characterized by the following. 6. The disaster prevention control method according to claim 5,
Each of the repeaters, when its own power supply is stopped, directly connects a direct lead between the immediately connected receiver or another repeater to a direct lead between the subsequent repeater. Disaster prevention control method characterized by the following. 7. Status monitoring means for monitoring the status of a direct line between a receiver or another repeater connected immediately before, and
A terminal control means for controlling a terminal connected thereto to a predetermined state when the monitoring result is in an abnormal state, and a direct lead line between a subsequent repeater when the monitoring result is in an abnormal state And a state setting means for setting an abnormal state. 8. The repeater according to claim 7, further comprising, when a predetermined factor occurs, a direct line between the receiver and another repeater connected immediately before the repeater. A connection control means for performing control so as to directly connect to a direct line between the relay device and the relay device. 9. A disaster prevention system using the repeater according to claim 7 to perform disaster prevention monitoring.