JP6894823B2 - Tunnel disaster prevention system - Google Patents

Description

The present invention relates to a tunnel disaster prevention system that monitors abnormalities in a tunnel by connecting terminal devices such as a notification device and a detector installed in the tunnel to a disaster prevention receiver.

Conventionally, emergency facilities have been installed in tunnels such as motorways to protect people and vehicles from fire accidents that occur in the tunnels.

Such emergency facilities include fire detectors, manual notification devices, and emergency telephones for fire monitoring and reporting, fire extinguishing plug devices for extinguishing fires and preventing the spread of fire, and tunnel skeletons. In order to protect the inside of the duct from fire, water spray that sprinkles fire extinguishing water from the water spray head is installed, and a disaster prevention receiver is installed to monitor and control the terminal equipment of these emergency facilities to build a tunnel disaster prevention system. doing.

The tunnel disaster prevention system consisting of a disaster prevention receiver and terminal equipment is roughly divided into an R-type transmission system and a P-type direct delivery system. The R-type transmission method connects a terminal device such as a fire detector whose address is set to a transmission line, and enables individual management in which detection and control are performed for each terminal device by transmission control. In the P-type direct delivery method, a plurality of terminal devices belonging to the same section are connected to a signal line drawn out in a predetermined section unit according to the type of the terminal device, and detection and control are performed for each signal line.

By the way, in the P-type direct delivery type tunnel disaster prevention system, terminal devices such as a manual notification device, a fire extinguisher activation device, and a duct temperature detector have a signal output unit for operation or detection configured as a non-voltage a contact switch. A non-voltage a contact switch is connected to the signal line drawn from the disaster prevention receiver. The non-voltage a-contact switch is normally turned off in the monitoring state, and is turned on by an operation or detection operation to output a non-voltage contact signal.

Specifically, the power supply voltage is applied to one of the signal lines via a pull-up resistor at the line receiver provided in the disaster prevention receiver, and the signal line is in the steady monitoring state when the non-voltage a contact switch is turned off. Almost no current is consumed, and the power supply voltage between the signal lines seen from the disaster prevention receiver is kept at approximately the power supply voltage. When the non-voltage a contact switch is turned on, a current flows through the signal line, the voltage between the signal lines seen from the disaster prevention receiver drops to almost zero volts, and the line receiver of the disaster prevention receiver increases the current consumption of the signal line or Detects a voltage drop between signal lines and outputs a received signal indicating the operation or detection of the terminal device to the control unit.

For example, in the case of a fire signal from a manual notification device, the disaster prevention receiver performs control operations such as fire display, lighting control of the response lamp on the terminal side, and manual notification area display, as well as remote monitoring control equipment, TV monitoring equipment, and variable. A fire alarm signal is sent to external equipment such as road information board equipment, tunnel ventilation equipment, and lighting equipment so that predetermined countermeasure control can be performed.

In addition, if it is a fire hydrant start signal from a fire hydrant starter such as a fire hydrant valve open / close detection switch provided in the fire hydrant device, the disaster prevention receiver sends a pump start signal to the fire hydrant pump equipment to remotely operate the fire hydrant pump equipment. I am trying to start the operation.

Japanese Unexamined Patent Publication No. 2002-246962 Japanese Unexamined Patent Publication No. 11-128381

In such a conventional P-type direct delivery type tunnel disaster prevention system, the insulation deteriorates due to aged deterioration of the signal line (outside line cable) connecting the terminal equipment, and the signal line connecting the terminal equipment. More current than expected in the normal monitoring state flows, and the disaster prevention receiver determines that the signal is received by the operation or detection operation of the terminal equipment and performs an alarm operation, as well as remote monitoring control equipment, TV monitoring equipment, and variable road. Information board equipment, tunnel ventilation equipment, lighting equipment, and other other equipment are often linked to block traffic in tunnels.

In order to solve this problem, a current monitoring device is provided in a housing separate from the disaster prevention receiver, and the current flowing through the signal line connected to the terminal device provided with the non-voltage a contact switch is, for example, once a day. It is measured and recorded at regular intervals, and when the measured current deviates from a predetermined threshold range, an abnormality in the current value of the signal line is determined and an alarm is given.

By the way, in the conventional disaster prevention receiving board, a graphic panel on which a tunnel system diagram is drawn is arranged on the front surface of the board. In the tunnel system diagram of the graphic panel, for example, the fire hydrant device installed in the longitudinal direction of the tunnel is displayed in an array of rectangular symbols, and a plurality of partition indicators corresponding to the sections divided in the longitudinal direction of the tunnel are used as a manual notification device. It is arranged separately for the fire hydrant activation device.

For example, when the disaster prevention receiver receives a fire signal from a manual notification device installed in a fire hydrant device and outputs a fire alarm, the division symbol lamp corresponding to the signal line that received the fire signal is turned on to make a manual notification. It makes it possible to identify the section where the fire was made.

However, even if the section where the manual report was made is known by the lighting of the section indicator light, the fire hydrant device where the manual report was made is unknown, and there is a problem that it cannot be known unless the person goes to the site to check it.

In order to solve this problem, it is better to use the R-type transmission method that knows the address of the terminal device instead of the P-type direct delivery method. It is desired that the P-type direct delivery system can identify and display the operated terminal devices in the section in addition to the section display.

In addition, since the current monitoring device is conventionally provided in a separate housing from the disaster prevention receiver, the transmission function and processing function that send fire information, failure information, etc. from the disaster prevention receiver to the current measurement device and store it together with the measurement history. There is also a problem that the equipment configuration and processing become complicated.

The present invention integrates the functions of the current monitoring device with the disaster prevention receiver to simplify the equipment configuration and processing, and is a working terminal device among a plurality of terminal devices connected to the signal line drawn out in each section. It is an object of the present invention to provide a P-type direct delivery type tunnel prevention system that enables identification display by using a current monitoring function that measures a current value of a signal line and determines an abnormality.

(Tunnel disaster prevention system)
The present invention
Multiple terminal devices that are connected to each signal line drawn from the disaster prevention receiver into the tunnel and output the detection signal by passing the line current when the detection switch is turned on.
A monitoring and control unit installed on the disaster prevention receiver that receives detection signals from signal lines and performs predetermined control processing.
Installed in the disaster prevention receiver, the current value flowing through multiple signal lines is measured at predetermined measurement cycles and stored as a measurement history, and when the measured current value deviates from the predetermined threshold range, the current value abnormality is determined. And a current monitoring unit that outputs a current value abnormality alarm,
In the tunnel disaster prevention system equipped with
Multiple terminal devices connected to the signal line have different resistance values that allow different line currents to flow when the detection switch is turned on. Resistors with different resistance values are connected in series with the detection switch.
When a detection signal is received by a signal line, the monitoring control unit instructs the current monitoring unit to measure the current value flowing through the signal line where the detection signal is received, and outputs the detection signal based on the measured current value. It is characterized in that the terminal device is identified and displayed.

(Identification display of fire alarm device)
The terminal device is a manual notification device provided in a fire hydrant device that outputs a fire signal by turning on the detection switch by a fire notification operation.
When the monitoring control unit receives a fire signal from the signal line, it outputs a fire alarm and instructs the current monitoring unit to measure the current value flowing through the signal line where the fire signal is received, and the measured current. The fire extinguisher device to which the fire signal is output is identified and displayed based on the value.

(Identification display of fire hydrant activation device)
The terminal device is a fire hydrant starter that outputs a fire hydrant start signal by turning on the detection switch by opening the fire hydrant valve open / close lever provided in the fire hydrant device or starting the pump start switch.
When the monitoring control unit receives a fire hydrant start signal from the signal line, it sends a pump start signal to the fire extinguishing pump equipment to start operation, and also instructs the current monitoring unit to receive the fire hydrant start signal. The fire hydrant device to which the fire hydrant start signal is output is identified and displayed based on the measured current value.

(Identification display of fire hydrant device by graphics panel)
On the front of the housing of the disaster prevention receiver, a graphic panel displaying a tunnel system diagram in which multiple fire hydrant indicators are arranged corresponding to the arrangement of the fire hydrant device in the tunnel is arranged.
The monitoring control unit activates the fire hydrant indicator light in the graphic panel corresponding to the fire hydrant device whose output of the fire signal or the fire hydrant start signal is identified.

(Division display by graphics panel)
On the graphic panel, a plurality of compartment indicators are arranged separately for the manual notification device and the fire hydrant activation device corresponding to the compartments divided in the longitudinal direction of the tunnel, and the monitoring control unit receives the fire signal or the fire hydrant activation signal. Activate the line indicator light in the graphic panel corresponding to the signal line.

(Monitoring device in the housing)
A monitor device is placed inside the housing of the disaster prevention receiver.
When the current monitoring unit detects a predetermined measurement history reading operation, the current monitoring unit reads the measurement history and displays it on the screen of the monitoring device.

(Second monitoring device)
A second monitor device was installed in place of the graphic panel on the front of the housing of the disaster prevention receiver.
In the monitoring control unit, a plurality of fire hydrant symbols are arranged in the second monitor device according to the arrangement of the fire hydrant device in the tunnel, and a plurality of manual notification devices or fire hydrant activation device units connected for each signal line. The tunnel system diagram corresponding to the fire hydrant device in which the output of the fire hydrant signal or the fire hydrant activation signal is identified by displaying the tunnel system diagram in which a plurality of section symbols are arranged corresponding to the sections divided in the tunnel is displayed on the screen. The display of the fire hydrant symbol in the above is changed, and the display of the section symbol in the tunnel system diagram corresponding to the signal line in which the fire signal or the fire hydrant activation signal is received is changed.

(Basic effect)
The present invention is provided in a plurality of terminal devices that are connected to each signal line drawn from the disaster prevention receiving board into the tunnel and output a detection signal by passing a line current when the detection switch is turned on, and a signal provided in the disaster prevention receiving board. A monitoring control unit that receives a detection signal from the line and performs a predetermined control process, and a disaster prevention receiver are provided to measure the current value flowing through a plurality of signal lines at a predetermined measurement cycle and store it as a measurement history. In a tunnel disaster prevention system equipped with a current monitoring unit that determines a current value abnormality and outputs a current value abnormality alarm when the measured current value deviates from a predetermined threshold range, a plurality of current values connected to a signal line are provided. When the detection switch is turned on, a resistor with a different resistance value is connected in series with the detection switch, and the monitoring control unit instructs the current monitoring unit when the detection signal is received by the signal line. The current value flowing through the signal line where the detection signal was received was measured, and the terminal device that output the detection signal was identified and displayed based on the measured current value. When any of the detection switches of the terminal device is turned on, a detection signal is output by flowing a line current with a unique value determined by the resistance connected to the detection switch, and the current monitoring unit provided in the disaster prevention receiver board detects it. By measuring the current value of the signal line that received the signal, it is possible to identify which detection switch connected to the same signal line is turned on from the measured current value, even with the P-type direct delivery method. , The terminal device that outputs the detection signal can be easily identified and displayed.

Further, since the current monitoring unit is provided integrally with the disaster prevention receiver, the equipment configuration and processing can be simplified and the installation space can be reduced as compared with the case where the current monitoring device is provided in a separate housing.

(Effect of identification display of fire alarm device)
The terminal device is a manual notification device provided in a fire extinguisher device that outputs a fire signal by turning on the detection switch by a fire notification operation, and the monitoring control unit fires when a fire signal is received from the signal line. Along with outputting an alarm, the current monitoring unit is instructed to measure the current value flowing through the signal line where the fire signal is received, and the fire extinguisher device to which the fire signal is output is identified and displayed based on the measured current value. Therefore, when any of the manual notification devices provided in the plurality of fire extinguishing plug devices connected to the same signal line is operated and a fire signal is output, the current value of the signal line in which the fire signal is received is displayed. By measuring, it is possible to easily identify and display the fire extinguisher device equipped with a manual notification device that outputs a fire signal, and identify the position in the tunnel where the fire report was made without going to the site. To enable appropriate response.

(Effect of identification display of fire hydrant activation device)
The terminal device is a fire hydrant starter that turns on the detection switch and outputs a fire hydrant start signal by opening the fire hydrant valve open / close lever provided in the fire hydrant device or starting the pump start switch. When a fire hydrant start signal is received from the signal line, a pump start signal is sent to the fire hydrant pump equipment to start operation, and the current value is instructed to the current monitoring unit to indicate the current value flowing through the signal line where the fire hydrant start signal is received. Since the fire hydrant device to which the fire hydrant start signal was output is identified and displayed based on the measured current value, the fire hydrant open / close lever is opened by any of the multiple fire hydrant devices connected to the same signal line. When an operation is performed and a fire hydrant start signal is output, the fire hydrant device that opened the fire hydrant open / close lever can be easily identified by measuring the current value of the signal line that received the fire hydrant start signal. It can be displayed, and it is possible to know the fire hydrant device used for fire extinguishing activities without going to the site, and it is possible to appropriately grasp the situation of the fire site in the tunnel.

(Effect of identification display of fire hydrant device by graphics panel)
In addition, a graphic panel displaying a tunnel system diagram in which a plurality of fire hydrant indicator lights are arranged corresponding to the arrangement of the fire hydrant device in the tunnel is arranged on the front of the housing of the disaster prevention receiver, and the monitoring control unit displays a fire signal. Or, because the fire hydrant indicator light in the graphic panel corresponding to the identified fire hydrant device is activated, the fire hydrant indicator light indicating the fire hydrant symbol arranged in the tunnel system diagram of the graphic panel lights up. Alternatively, by blinking, the fire hydrant device operated by the manual notification device and the fire hydrant device operated by the fire hydrant activation device can be easily and easily identified.

(Effect of partition display by graphics panel)
Further, on the graphic panel, a plurality of compartment indicators are arranged separately for the manual notification device and the fire hydrant activation device corresponding to the compartments divided in the longitudinal direction of the tunnel, and the monitoring control unit receives the fire signal or the fire hydrant activation signal. Since the line indicator light in the graphic panel corresponding to the signal line is activated, the division indicator light indicating the division symbol arranged in the graphic panel lights up or blinks, so that a manual notification device or a fire hydrant can be activated. The compartment in which the activation device is operated can be easily and easily identified, and the fire hydrant indicator lights in the compartment arranged corresponding to the lit or blinking compartment indicator lights are lit or blinked in the compartment. The number of fire hydrant devices operated can be easily and easily grasped.

(Effect of monitoring device in the housing)
In addition, a monitor device is arranged in the housing of the disaster prevention receiver, and when the current monitoring unit detects a predetermined measurement history reading operation, the measurement history is read out and displayed on the screen of the monitoring device. By viewing the measurement history of the current value measured to monitor insulation deterioration etc. on the screen of the monitor device, it is possible to appropriately grasp the deterioration state of the signal line, and the signal that received the fire signal or fire extinguisher start signal. Since the measurement history of the current value measured for the line is generated, the history of the fire signal and the fire extinguisher start signal can also be viewed on the monitor device.

(Effect of the second monitoring device)
Further, a second monitoring device is provided on the front surface of the housing of the disaster prevention receiving panel instead of the graphic panel, and the monitoring control unit has a plurality of monitoring control devices corresponding to the arrangement of the fire hydrant device in the tunnel. Along with the arrangement of fire hydrant symbols, a screen display of a tunnel system diagram in which multiple division symbols are arranged corresponding to the divisions in which the inside of the tunnel is divided for each of multiple manual notification devices or fire hydrant activation devices connected for each signal line. Change the display of the fire hydrant symbol in the tunnel system diagram corresponding to the fire hydrant device whose output of the fire hydrant or fire hydrant start signal is identified, and the tunnel corresponding to the signal line where the fire signal or fire hydrant start signal is received. Since the display of the division symbol in the system diagram is changed, when the manual notification device or the fire hydrant activation device is operated, the operated district symbol in the tunnel system diagram displayed on the second monitor screen is operated. By changing the display color of the fire hydrant symbols arranged corresponding to the area symbol and flickering, the operated fire hydrant device or section can be easily and easily identified.

Further, by viewing the measurement history of the current value measured for monitoring the insulation deterioration of the signal line on the screen of the monitor device arranged in the housing, the display of the disaster prevention monitoring by the second monitor device is restricted. It is possible to appropriately grasp the deterioration state of the signal line from the measurement history without having to do so, and since the measurement history of the current value measured for the signal line that received the fire signal and the fire extinguishing plug start signal is also generated, the fire signal and the fire signal The history of the fire extinguisher activation signal can also be viewed on the monitor device.

Explanatory diagram showing the outline of the tunnel disaster prevention system Explanatory drawing showing the appearance of the disaster prevention receiver Explanatory drawing showing the state of opening the panel door of the disaster prevention receiver and looking at the monitor device. Explanatory drawing showing by taking out the graphic panel of FIG. Block diagram showing the outline of the functional configuration of the tunnel disaster prevention system Circuit block diagram showing the circuit configuration of the manual notification device connected to the signal line Explanatory drawing which showed the setting of the threshold value which identifies the current of the signal line which flows by the switch-on of the manual notification device of FIG. Explanatory drawing showing the relationship between the fire hydrant number, the section, and the fire hydrant device identification code in the section. Explanatory diagram showing the measurement recording screen of the monitor device displaying the measurement history by regular cycle measurement Explanatory drawing showing the measurement record narrowing down screen of the monitor device which displays the measurement history extracted by setting the narrowing down condition. Flow chart showing disaster prevention monitoring control by disaster prevention receiver Explanatory drawing which showed other embodiment of disaster prevention receiver

[Overview of tunnel disaster prevention system]
FIG. 1 is an explanatory diagram showing an outline of a tunnel disaster prevention system. As shown in FIG. 1, an up line tunnel 1a and a down line tunnel 1b are constructed as a tunnel for a motorway, and the up line tunnel 1a and the down line tunnel 1b are connected by an evacuation connecting pit 2.

Inside the up line tunnel 1a and the down line tunnel 1b, fire hydrant devices 18 are installed along the wall surface of the observer passage in the longitudinal direction of the tunnel, for example, at intervals of 50 meters.

The fire hydrant device 18 houses a hose with a nozzle inside the fire hydrant door. In the event of a fire, the fire hydrant door is opened to pull out the hose with a nozzle, and when the fire hydrant valve open / close lever is opened, fire hydrant water is discharged and the fire hydrant valve open / close detection is detected. The switch 14 is turned on, and a fire hydrant start signal is output to the disaster prevention receiver 10 to start the fire extinguishing pump.

Further, the fire hydrant device 18 is provided with a notification device door, and the notification device door is provided with a manual notification device (transmitter) 16. As described above, the fire hydrant device 18 is provided with the fire hydrant valve open / close detection switch 14 and the manual notification device 16 as terminal devices, and when the non-voltage a contact switch functioning as the contact means is turned on, the fire hydrant start signal and the fire are generated. A notification signal (fire signal) is output.

The fire hydrant device 18 is provided with a pump start switch used by the fire brigade, but since it is the same switch in terms of the system that outputs the same fire hydrant start signal as the fire hydrant valve open / close detection switch 14, the following This will be described as a fire hydrant valve open / close detection switch (including a pump start switch) 14. Further, the manual notification device 16 is installed in the emergency telephone box in addition to the fire hydrant device 18, but in the following description, the manual notification device provided in the fire hydrant device 18 will be described as a representative.

In addition to the fire hydrant device 18, a fire detector, an automatic valve device, a temperature detector in a duct, and the like are provided as tunnel emergency equipment, but they are not shown.

Fire detectors are installed along the wall surface in the longitudinal direction of the tunnel, for example, at intervals of 25 meters or 50 meters, and monitoring areas are set on both sides, which are 25 meters or 50 meters on the left and right, to detect the flame caused by the fire and notify the fire. ..

The automatic valve device constitutes a water spray facility, and the main valve is opened and driven by remote opening control of the electric valve for operation, and fire extinguishing water is discharged from multiple water spray heads installed in the longitudinal direction at the top of the tunnel wall surface. Protect the tunnel frame from fire.

The temperature detector in the duct is placed in the duct where the pipes and cables are laid inside the observer passage in the longitudinal direction of the tunnel, and detects the temperature rise in the duct due to a cable fire or the like, and functions as a contact means. A temperature detection signal is output when the a-contact switch is turned on.

Disaster prevention receivers 10 are installed in the monitoring centers of the up line tunnel 1a and the down line tunnel 1b. In addition to the disaster prevention monitoring function of the up line tunnel 1a and the down line tunnel 1b, the disaster prevention receiving panel 10 is provided with a current monitoring function for monitoring the current of the P-type signal line to which the terminal device is connected.

From the disaster prevention receiver 10, the P-type signal lines 12-11 to 12-16 are divided into, for example, 6 sections in the up line tunnel 1a and the down line tunnel 1b for each predetermined section divided in the longitudinal direction of the tunnel. 12-21 to 12-26 are pulled out, and in this embodiment, one section is formed by four fire hydrant devices 18, and a plurality of fire hydrant valve open / close detection switches 14 and manual operation are provided for each section. The reporting device 16 is connected to the same signal line.

Similarly, for the in-duct temperature detector installed in the duct, a P-type signal line is pulled out in each section, and a plurality of in-duct temperature detectors provided in each section are connected. However, the illustration is omitted. Further, the signal lines 12-11 to 12-26 may be referred to as a signal line 12 when it is not necessary to distinguish them.

The P-type signal line 12 is composed of a signal line and a common line, and is connected to a non-voltage a contact switch provided in each of the fire extinguisher valve open / close detection switch 14, the manual notification device 16, and the temperature detector in the duct of the fire extinguisher device 18. In this case, by turning on the non-voltage a contact switch and passing the line current by each operation or detection operation, the fire extinguishing plug start signal, fire notification signal (fire signal), and temperature detection signal are sent to the disaster prevention receiver 10. ing.

In addition to the fire extinguishing plug device 18, fire detector and automatic valve device, the emergency facilities for the tunnel include fire extinguishing pump equipment 20, cooling pump equipment for ducts 22, IG slave station equipment 24, ventilation equipment 28, and alarm display board equipment. 30, radio rebroadcasting equipment 32, TV monitoring equipment 34, lighting equipment 36, etc. are provided, and except that the IG slave station equipment 24 is connected by a data transmission line, the other equipment is disaster-prevented by a P-type signal line. It is individually connected to the receiving panel 10. Here, the IG slave station equipment 24 is a communication equipment that connects the disaster prevention receiver 10 and the remote monitoring and control equipment 26, which is a higher-level equipment provided outside, via the network 25.

The ventilation equipment 28 is equipment that gives energy to the air in the tunnel by the high blowing wind speed operated by the jet fan installed on the ceiling side in the tunnel to cause an air flow in the longitudinal direction of the tunnel.

Further, the alarm display board equipment 30 is equipment for displaying an abnormality in the tunnel on an electric display board to notify the user in the tunnel. The radio rebroadcasting facility 32 is a facility for allowing a driver or the like to receive information from a road administrator in a tunnel. The TV monitoring equipment 34 is equipment for confirming the scale and position of a fire, operating a water spraying equipment, and grasping the situation in a tunnel when evacuation guidance is performed. The lighting equipment 36 is equipment for driving and managing the lighting equipment in the tunnel.

[Disaster prevention receiver]
2A and 2B are explanatory views showing the appearance of the disaster prevention receiver, FIG. 2A shows the front side, and FIG. 2B shows the side surface. FIG. 3 is an explanatory diagram showing a state in which the panel door of the disaster prevention receiver is opened to look at the monitor device.

(Front panel and monitoring device in the housing)
As shown in FIG. 2, the disaster prevention receiver 10 is provided with a panel door 64 that can be opened and closed by operating a handle on the front surface of the box-shaped housing 62 opened in the front-rear direction, and also on the back surface of the housing 62. A back door 66 that can be opened and closed by a bundle operation is provided.

On the front side of the panel door 64, a graphic panel 44 in which a section indicator light and a fire hydrant indicator light are arranged in a tunnel system diagram, a display panel 55 in which a plurality of representative lights are arranged, and various operation switches and telephones are arranged. An operation panel 52 is provided.

Inside the housing 62, a monitor device 46 using a liquid crystal display with a touch panel is arranged. As shown in FIG. 3, when the panel door 64 of the disaster prevention receiver 10 is opened, the monitor device 46 arranged on the support frame 68 appears in the housing 62, and the current value of the signal line is measured on the screen of the monitor device 46. It is possible to display the measurement history of the current value including the result and the judgment result.

(Graphic panel)
FIG. 4 is an explanatory view showing the graphic panel of FIG. 2 taken out. As shown in FIG. 4, a fire representative light 100 is provided in the upper center of the graphic panel 44, and following the tunnel name below it, as a tunnel system diagram, an up line tunnel system diagram 102a and a down line tunnel system diagram 102b Is drawn.

The up line tunnel system diagram 102a is divided into three stages: a fire hydrant arrangement unit 104, a manual notification device arrangement unit 106, and a fire hydrant starter arrangement unit 108. In the fire hydrant arrangement unit 104, fire hydrant indicator lights 110 are arranged as rectangular fire hydrant symbols indicating, for example, 22 fire hydrant devices arranged at intervals of 50 meters in the longitudinal direction of the tunnel.

The manual notification device arrangement unit 106 is divided into 6 division symbols corresponding to the P-type signal line, and each division symbol is indicated with a division number of "1 to 6" (corresponding to the line number). In addition, a compartment indicator lamp 112 is provided in each compartment symbol. The section symbols on which the section indicator lights 112 are arranged are arranged corresponding to the four fire hydrant indicator lights 110, but the last section symbol is the fire hydrant number or two fire hydrant indicator lights 21 and 22. It is arranged corresponding to 110.

Similarly, the fire extinguishing starter arrangement unit 108 is also divided into six compartment symbols corresponding to the P-type signal line, and each compartment symbol is indicated with a compartment number of "1 to 6", and each compartment is also divided into six compartment symbols. A line indicator light 114 is provided on the symbol. The fire hydrant arrangement unit 104, the manual notification device arrangement unit 106, and the fire hydrant starter arrangement unit 108 are the same for the down line tunnel system diagram 102b.

The fire hydrant indicator light 110 and the line indicator lights 112 and 114 provided on the graphic panel 44 are turned on when it is determined that a fire or fire hydrant activation is caused by receiving a signal from the corresponding signal line.

[Disaster prevention receiver configuration]
(Outline of disaster prevention receiver)
FIG. 5 is a block diagram showing an outline of the functional configuration of the tunnel disaster prevention system. As shown in FIG. 5, the disaster prevention receiver 10 includes a control unit 40, and the control unit 40 is a function realized by executing a program, for example, and the hardware includes various inputs including a CPU, a memory, and an AD conversion port. Use a computer circuit or the like equipped with an output port or the like.

The control unit 40 is provided with a P-type transmission unit 42 in which various terminal devices installed in the tunnel are connected by a P-type signal line 12, and the control unit 40 is provided with a graphic panel 44 and a monitoring device 46. , An alarm unit 48 equipped with a speaker, a buzzer, an alarm indicator light, etc., a display panel 50 equipped with various indicator lights, an operation panel 52 equipped with various switches, and further, an IG slave station facility 24, a ventilation facility 28, and an alarm. A P-type transmission unit 54 is provided in which the display board equipment 30, the radio rebroadcasting equipment 32, the television monitoring equipment 34, the lighting equipment 36, the fire extinguishing pump equipment 20, and the cooling pump equipment 22 are individually connected by a P-type signal line. ..

The P-type transmission unit 54 is provided with a line reception unit 60 corresponding to the signal lines 12-11 to 12-1n and 12-21 to 12-2n drawn out to the upstream tunnel 1a, and the line reception unit 60 is provided with the line reception unit 60. Is provided with a current detection unit 61 that detects the current flowing through the signal line.

Further, the P-type transmission unit 54 is similarly provided with a line reception unit 60 corresponding to the signal lines 12-11 to 12-1n and 12-21 to 12-2n drawn out to the down line tunnel 1b. The line receiving unit 60 is provided with a current detecting unit 61 for detecting the current flowing through the signal line.

(Configuration of manual notification device)
FIG. 6 is a circuit block diagram showing a circuit configuration of a manual notification device connected to a signal line.

As shown in FIG. 6, for example, the signal line 12-21 pulled out from the line receiving unit 60 of the disaster prevention receiving panel 10 is a manual reporting device 16-1 to 16- provided in the fire hydrant devices 18-1 to 18-4. fourth switch is connected, the resistor R _a having different resistance values to the switches of the manual notification apparatus _{16-1~16-4, R B, R C,} R D are connected in series.

R _A in the present embodiment, R _B, R _C, between _{R D R A <R B <} R C <R D
Relationship is set, the current flowing through the signal line 12-21 by switching on the manual reporting apparatus _{16-1~16-4 I A, I B, I} C, when the I _D,
I _A > I _B > I _C > I _D
Relationship has been obtained.

Also, the end of the signal line 12-21 has flowed disconnection monitoring current I _O is connected to the terminating resistor R _0, the resistance value _{R O <R A <R B} <R C <R D
Therefore, the current value is I _A > I _B > I _C > I _D > I _O.
Relationship has been obtained.

FIG. 7 is an explanatory diagram showing the setting of a threshold value for identifying the current of the signal line flowing by switching on the manual notification device of FIG.

As shown in FIG. 7, the current flowing through the switching-on of the manual reporting apparatus 16-1 to 16-4 flowing in the signal line 12-21 I _A, I _B, relative to I _C, I _D and disconnection monitoring current I _O By setting the current thresholds Is1, Is2, Is3, Is4, and Is5 as shown in the figure, assuming that the identification codes of the manual notification devices 16-1 to 16-4 are A, B, C, and D, the signal line 12- By measuring the current value flowing through 21, the disconnection, monitoring, switch-on of the manual notification device 16-1 of the identification code A, the switch-on of the manual notification device 16-12 of the identification code B, and the manual notification device of the identification code C It is possible to determine whether the switch-on of 16-3 and the switch-on of the manual notification device 16-4 having the identification code D are determined.

FIG. 8 is an explanatory diagram showing the relationship between the fire hydrant number, the section, and the fire hydrant device identification code in the section. For example, the section number 1 corresponding to the first section is identified by receiving the manual communication signal from the manual notification device 16-1 connected to the signal line 12-21 of FIG. 6, and the signal line 12-shown in FIG. 7 identifies the identification code a by measuring the current I _a flowing to 21, such (partition number 1, identification codes a) the combination of 22 units of hydrants are arranged in the tunnel from the relationship shown in FIG. 8 It is possible to identify from the device 18 that a fire reporting operation has been performed by the fire hydrant device having the fire hydrant number 1.

This point also applies to the other automatic notification device 16 connected to the signal line 12-12 to 12-26 and the fire hydrant valve detection switch 14 connected to the signal line 12-11 to 12-16.

Specifically, based on the relationship shown in FIG. 8, the memory provided in the control unit 40 of the disaster prevention control panel 10 stores the table information in which the fire hydrant number is stored using the set of the division number and the identification code as an index. There is.

The control unit 40 is provided with the functions of the monitoring control unit 56 and the current monitoring unit 58 as functions realized by executing the program.

(Monitoring and control unit)
The monitoring control unit 56 detects from terminal devices such as a fire hydrant valve open / close detection switch 14, a manual notification device 16, a fire detector, a temperature detector in a duct, and an automatic valve device provided in the fire hydrant device 18 installed in the tunnel. Performs predetermined monitoring and control based on signals and operation signals.

Further, when the monitoring control unit 56 receives, for example, a fire notification signal (fire signal) operated by the manual notification device 16 provided in the fire hydrant device 18 via the line reception unit 60, the alarm unit 48 sounds the main sound. At the same time, the fire representative light 100 of the graphic panel 44 shown in FIG. 4 is turned on or blinks to display the fire representative, and the division indicator light of the manual notification device arrangement unit 106 corresponding to the signal line that received the fire notification signal. The 112 is turned on to display the manual notification area, and the response signal is transmitted to the fire hydrant device 18 to turn on the response lamp.

Further, the monitoring control unit 56 transmits a fire hydrant start signal by turning on the fire hydrant valve open / close detection switch 14 accompanying the operation of the fire hydrant valve open / close lever provided in the fire hydrant device via the line receiving unit 60, following the reception of the fire notification signal. When the fire hydrant is received, the division indicator 114 of the fire hydrant starter arrangement unit 108 corresponding to the signal line that received the fire hydrant start signal of the graphic panel 44 shown in FIG. 4 is turned on to display the fire hydrant start area, and further, the pump is displayed. A start signal is transmitted to the fire hydrant pump equipment 20 to start the fire hydrant pump.

Further, the monitoring control unit 56 transmits a fire notification signal to the distant monitoring control equipment 26 via the IG slave station equipment 24 to give an alarm as a control for other equipment based on the reception of the fire notification signal, the TV monitoring equipment 34. Control to display the fire report section by, control to display the fire report of the manual report section by the alarm display board equipment 30, control to ventilate the manual report section by the ventilation equipment 28, control to illuminate the manual report section by the lighting equipment 36, etc. I do.

Further, when the temperature inside the duct rises and the temperature inside the duct receives the temperature detection signal inside the duct, the monitoring control unit 56 outputs a pump start signal to the cooling pump equipment 22 from the head installed in the duct. Controls to sprinkle water to cool the inside of the duct.

Further, the monitoring control unit 56 monitors the disconnection failure of the signal line 12, and when it detects the disconnection failure of the signal line to the manual notification device 16, the alarm unit 48 sounds the fault sound and the display shown in FIG. When the manual notification line disconnection lamp on the panel 50 is turned on in yellow, for example, and when a disconnection failure of the signal line 12 with respect to the fire hydrant valve open / close detection switch 14 is detected, the alarm unit 48 sounds a fault sound and the display panel shown in FIG. Control is performed so that the 50 fire hydrant line disconnection lights are turned on, for example, in yellow.

(Current monitoring unit)
The current monitoring unit 58 measures the current value of the signal line 12 connected to the terminal device provided with the non-voltage a contact switch including the fire extinguisher valve open / close detection switch 14 and the manual notification device 16, and the measured current value is a predetermined upper limit. When the value and the lower limit value deviate from the threshold range, the current value abnormality is determined, and the measurement result is stored as a measurement history in a memory using a detachable memory card.

The current value of the signal line 12 is measured by the current monitoring unit 58, for example, the detection voltage of the current detection resistor inserted in the signal line 12 provided in the current detection unit 61 of FIG. 5 is AD-converted and read, and is affected by noise. The average value of the current values measured for a predetermined time is obtained in order to remove the above.

Here, the current value measurement by the current monitoring unit 58 includes a fixed cycle measurement, an automatic measurement, and a manual measurement. The constant cycle measurement of the current monitoring unit 58 sequentially measures the current values of all the signal lines 12 at predetermined cycles, for example, once a day, and when the measured current values deviate from the predetermined threshold range, the current is measured. Control is performed to determine a value abnormality and store the measurement result and the determination result in the memory as a measurement history.

In the automatic measurement of the current value by the current monitoring unit 58, when the automatic measurement operation by the monitoring device 46 is detected, the current values flowing through all the signal lines 12 are sequentially measured, and the measured current value is out of the predetermined threshold range. In that case, the abnormality of the current value is determined, and the measurement result is controlled to be displayed on the screen on the monitor device 46.

In the manual measurement of the current value by the current monitoring unit 58, when a manual measurement operation including the selection of the signal line by the monitoring device 46 is detected, the current value flowing through the selected signal line is measured, and the measured current value is predetermined. When the current value is out of the threshold range of, the current value abnormality is determined, and the measurement result is controlled to be displayed on the screen on the monitor device 46.

Further, when the current monitoring unit 58 detects the measurement history display operation by the monitoring device 46, the current monitoring unit 58 controls the monitoring device 46 to display the measurement history of the current value stored in the memory on the screen.

During the measurement of the constant cycle measurement, the automatic measurement or the manual measurement, the current monitoring unit 58 lights the current monitoring device measuring light in the display panel 50 shown in FIG. 5 in green, and also performs the constant cycle measurement and the automatic measurement. Alternatively, when a current value abnormality is determined by manual measurement, the manual notification current value abnormality lamp or the fire extinguishing plug current value abnormality lamp in the display panel 50 shown in FIG. 5 is turned on in yellow to be representatively displayed.

Further, when the current monitoring unit 58 detects the abnormality history display operation by the monitoring device 46, the current monitoring unit 58 extracts the measurement history in which the current value abnormality is determined from the measurement history of the current value stored in the memory and monitors the monitoring device 46. Controls the screen display in chronological order.

[Identification display of activated terminals based on signal line current value measurement]
(Identification display of manual notification device)
The monitoring control unit 56 provided in the control unit 40 of the disaster prevention receiving panel 10 of FIG. 5 is, for example, any of the four fire hydrant devices 18-1 to 18-4 connected to the signal line 12-21 shown in FIG. When a fire report signal output by switching on by the fire report operation of the manual report devices 16-1 to 16-4 provided in the hydrant is received, the current monitoring unit 58 is instructed to receive the fire report signal. When the current value flowing through the signal line 12-21 is measured and it is determined that the measured current value is within the range of the current thresholds Is2 to Is3 shown in FIG. 7, for example, FIG. It is determined that the signal is a fire notification signal due to the switch-on of the manual notification device 16-1 shown, and the fire hydrant indicator lamp having the fire hydrant number 1 in the fire hydrant arrangement portion 104 of the up line tunnel system diagram 102a of the graphic panel 44 of FIG. 4 is determined. The 110 is turned on or blinks, and the fire hydrant device 18-1 controls to identify and display that a fire alarm operation has been performed.

As described above, when the fire notification signal is received, the disaster prevention receiving panel 10 is provided with the manual notification device 16 that outputs the fire notification signal by measuring the current value of the signal line 12 for which the fire notification signal is received. The fire hydrant device 18 can be easily identified and displayed, and the position in the tunnel where the fire report is made can be specified and an appropriate response can be taken without going to the site.

(Effect of identification display of fire hydrant activation device)
The monitoring control unit 56 provided in the control unit 40 of the disaster prevention receiving panel 10 of FIG. 5 is, for example, a fire hydrant valve opening / closing lever provided in any of the four fire hydrant devices 18 connected to the signal lines 12-11. When the fire hydrant valve open / close detection switch 14 is turned on by the opening operation and the output fire hydrant start signal is received, the current value flowing through the signal line 12-11 in which the fire hydrant start signal is received is instructed to the current monitoring unit 58. When it is measured and it is determined that the measured current value is within the range of the current thresholds Is2 to Is3 shown in FIG. 7, for example, it is a fire hydrant start signal by turning on the fire hydrant valve open / close detection switch 14 corresponding to the identification code A. When this is determined, the fire hydrant indicator light 110 having the fire hydrant number 1 in the fire hydrant arrangement portion 104 in the up line tunnel system diagram 102a of the graphic panel 44 of FIG. 4 is turned on or blinks, and the fire hydrant device 18-1 activates the fire hydrant. Controls to identify and display that the operation has been performed.

Therefore, the disaster prevention receiver 10 is provided with a fire hydrant valve open / close detection switch 14 that outputs a fire hydrant start signal by measuring the current value of the signal line 12 for which the fire hydrant start signal is received when the fire hydrant start signal is received. The fire hydrant device 18 used can be easily identified and displayed, and the fire hydrant device 18 used for fire extinguishing activities can be known without going to the site, and the situation of the fire site in the tunnel can be appropriately grasped. It is possible to do.

(Display of measurement recording screen by monitoring device)
FIG. 9 is an explanatory diagram showing a measurement recording screen of the monitoring device displaying the measurement history by the constant cycle measurement.

As shown in FIG. 9, an automatic measurement selection button 73, a manual measurement selection button 74, a measurement record selection button 75, an abnormality history selection button 76, and a line selection button 77 are arranged on the lower side of the monitor screen 70 by hatching. As shown, when the measurement record selection button 75 is operated, the illustrated measurement record screen 72 is displayed.

On the right side of the measurement recording screen 72, a page display 78, page switching buttons 79 and 80, a file save button 81, and a memory eject button 82 are arranged.

By operating the page switching buttons 79 and 80, the page of the measurement history detailed information 83 can be switched. The file save button 81 instructs the memory storage of the measurement result. The memory eject button 82 is operated when ejecting the memory storing the current value measurement information from the disaster prevention receiving panel 10.

The measurement history detailed information 83 displayed in the center of the measurement recording screen 72 is divided into each item of line number, date and time, item, upper limit value / lower limit value, measurement value and judgment indicated by “No”, and for each signal line. Information is listed in. Here, in the line number 004, since the measured value is 1.25 mA and exceeds the upper limit value of 1.00 mA, it is determined that the current value is abnormal by the display of "NG". Since the measured values of the other line numbers are within the range of the upper limit value and the lower limit value, it is judged to be normal by the display of "OK".

The current monitoring unit 58 stores the measurement history of the current value measured by the measurement cycle once a day, and by operating the measurement record selection button 75, the measurement history detailed information 83 is based on the stored history information. Is displayed on the screen, but it was also measured when the operated fire extinguisher device was identified and displayed by measuring the current value of the signal line that received the fire notification signal or the fire extinguishing plug start signal based on the instruction of the monitoring control unit 56. The current value is stored as a measurement history.

Therefore, when the measurement recording screen 72 is displayed as shown in FIG. 9, the measurement history of the current value measured by receiving the fire notification signal and the fire hydrant start signal can also be viewed, and the fire occurrence time and the fire hydrant start time can be viewed. Etc. can be investigated.

(Narrowed display of measurement history)
By operating the line selection button 77 arranged below the measurement record screen 72 of FIG. 9, the display can be switched to the measurement record narrowing screen 84 shown in FIG.

The measurement record narrowing screen 84 of FIG. 10 includes a system selection unit 85, a device selection unit 86, a division selection unit 87, a confirmation button 88, a release button 89, a page display 90, page switching buttons 91 and 92, and a closing button 93. It is provided.

The system selection unit 85 selects from an up line and a down line. The device selection unit 86 selects from manual notification, fire hydrant, and duct. The section selection unit 87 inputs a section number.

On the measurement record narrowing screen 84, for example, when it is desired to narrow down to the measurement record of "section 01 in the manual notification device for the up line", as shown in the figure, the system selection unit 85 has an "up line" and the device selection unit 86 has "up line". When "manual notification" and "01" are set in the section selection unit 87 and the confirmation button 88 is operated, the corresponding narrowing measurement record 94 is displayed.

When the release button 89 is operated in this state, the narrowing condition and the narrowing measurement record 94 are cleared. Further, when the closing button 93 is operated, the screen returns to the measurement recording screen 72 of FIG.

By using the function of the measurement record narrowing screen 84, the measurement records can be narrowed down and displayed by setting the narrowing conditions in combination with the system, the device, and the section from the huge number of stored measurement records. For example, the current value measured by receiving the fire notification signal or the fire hydrant start signal can be displayed on the screen to easily investigate the fire occurrence time, the fire hydrant start time, and the like.

As the conditions for narrowing down the measurement records, a period may be selected in addition to the system, device, and section.

[Disaster prevention monitoring control]
FIG. 10 is a flowchart showing disaster prevention monitoring control by the disaster prevention receiving board, and is a control operation of the monitoring control unit 56 and the current monitoring unit 58 provided in the disaster prevention receiving board of FIG.

As shown in FIG. 10, when the current monitoring unit 58 determines in step S1 that the measurement cycle of the current value once a day has been reached, the process proceeds to step S2, and the current values of all the signal lines are sequentially measured and the current is measured. The presence or absence of a value abnormality is determined, and the current value measurement control is performed in which the measurement result and the determination result are stored in the memory as the measurement history.

Subsequently, the monitoring control unit 56 monitors the presence or absence of reception of the fire alarm signal in step S3, and when it determines that the fire alarm signal has been received, proceeds to step S4 to perform fire alarm control, and then in step S5 the fire alarm is reported. Identify the area number where there was a fire from the signal line that received the fire alarm signal.

Subsequently, the monitoring control unit 56 proceeds to step S6, instructs the current monitoring unit 58 to measure the current value of the signal line that has received the fire notification signal, and based on the measured current value, the fire hydrant of the reporting source in step S7. Identify the number.

Subsequently, the monitoring control unit 56 proceeds to step S8, turns on the section indicator light 112 and the fire hydrant indicator light 110 of the section in the graphic panel 44 of FIG. 4 where the fire has been reported, and turns on the section and the fire hydrant where the fire has been reported. Display the device.

Subsequently, the monitoring control unit 56 monitors the reception of the fire hydrant start signal in step S9, and when it determines the reception of the fire hydrant start, proceeds to step S10 to perform fire hydrant pump start control, and then in step 11, the fire hydrant is started. The division number is identified from the signal line that received the fire hydrant activation signal.

Subsequently, the monitoring control unit 56 proceeds to step S12, instructs the current monitoring unit 58 to measure the current value of the signal line that has received the fire hydrant start signal, and based on the measured current value, the fire hydrant of the start source is measured in step S13. Identify the number.

Subsequently, the monitoring control unit 56 proceeds to step S14, turns on the section indicator light 114 and the fire hydrant indicator light 110 of the section in the graphic panel 44 of FIG. 4 where the fire hydrant is activated, and sets the section where the fire hydrant is activated. Display the fire hydrant device.

Subsequently, the monitoring control unit 56 proceeds to step S15 to determine whether or not there is a fire recovery, and when the fire in the tunnel is extinguished and the fire recovery is determined, the predetermined recovery process is performed in step S16. , Return to step S1 and perform normal disaster prevention monitoring control.

[Disaster prevention receiver with main monitor device]
12A and 12B are explanatory views showing another embodiment of the disaster prevention receiver, FIG. 12A shows the front side, and FIG. 12B shows the side surface.

As shown in FIG. 12, the disaster prevention receiver 10 of the present embodiment has a panel door 64 provided on the front surface of a box-shaped housing 62 opened in the front-rear direction and which can be opened and closed by operating a handle. A second monitor device 96 using a liquid crystal display with a touch panel is installed in place of the graphic panel 44 provided in the embodiment, and an operation display unit 98 is arranged below the second monitor device 96.

On the screen of the second monitoring device 96, an image corresponding to the tunnel system diagram shown in FIG. 4 drawn on the graphic panel 44 of the disaster prevention receiving panel 10 of FIG. 2 is displayed on the screen, and further, a predetermined image relating to tunnel disaster prevention monitoring is displayed. Information is displayed.

Similar to the embodiment of FIG. 2, a monitor device 46 using a liquid crystal display with a touch panel is arranged inside the housing 64, and the measurement history of the current values shown in FIGS. 9 and 10 is read and displayed. ..

The disaster prevention receiver 10 provided with the second monitor device 96 is different in that the second monitor device 96 is provided in place of the graphic panel 44 shown in FIG. 5, and has other configurations. And the control function will be the same.

Therefore, when the disaster prevention receiver 10 provided with the second monitor device 96 receives the fire report signal or the fire hydrant start signal, the fire report in the tunnel system diagram displayed on the screen of the second monitor device 96. Change or flicker the display color of the fire hydrant symbol for which the operation or fire hydrant start operation is determined, and change the display of the section symbol in the tunnel system diagram corresponding to the signal line where the fire notification signal or fire hydrant start signal is received. By letting or flickering, the operated fire hydrant device or compartment can be easily and easily identified.

Further, by viewing the measurement history of the current value measured for monitoring the insulation deterioration of the signal line on the screen of the monitor device 46, it is possible to appropriately grasp the deterioration state of the signal line, and also the fire alarm signal and the fire alarm signal. Since the measurement history of the current value measured by the reception of the fire extinguishing plug start signal is also stored, the measurement history of the current value of the fire notification signal and the fire extinguishing plug start signal can also be viewed on the monitor device 46.

[Modification of the present invention]
The present invention includes appropriate modifications that do not impair its purpose and advantages, and is not further limited by the numerical values shown in the above embodiments.

1a: Up line tunnel 1b: Down line tunnel 10: Disaster prevention receiver 12, 12-11 to 12-26: Signal line 14: Fire hydrant valve open / close detection switch 16: Manual notification device 18: Fire hydrant device 20: Fire extinguishing pump equipment 22: Cooling pump equipment 24: IG slave station equipment 26: Remote monitoring and control equipment 28: Ventilation equipment 30: Alarm display board equipment 32: Radio rebroadcasting equipment 34: TV monitoring equipment 36: Lighting equipment 40: Control unit 42, 54: P type Transmission unit 44: Graphic panel 46: Monitor device 48: Alarm unit 50: Display panel 52: Operation panel 56: Monitoring control unit 58: Current monitoring unit 60: Line receiving unit 61: Current detection unit 62: Housing 64: Panel door 70: Monitor screen 72: Measurement record screen 84: Measurement record narrowing screen 96: Second monitor device 100: Fire representative light 102a: Up line tunnel system diagram 102b: Down line tunnel system diagram 104: Fire hydrant arrangement unit 106: Manual notification Device placement unit 108: Fire hydrant starter device placement unit 110: Fire hydrant indicator lights 112, 114: Line indicator lights

Claims (7)

Multiple terminal devices that are connected to each signal line drawn from the disaster prevention receiver into the tunnel and output the detection signal by passing the line current when the detection switch is turned on.
A monitoring control unit provided on the disaster prevention receiving panel, which receives the detection signal from the signal line and performs predetermined control processing.
The current value provided in the disaster prevention receiver is measured at predetermined measurement cycles and stored as a measurement history, and when the measured current value deviates from a predetermined threshold range, the current value is measured. A current monitoring unit that determines an abnormality and outputs a current value abnormality alarm,
In the tunnel disaster prevention system equipped with
In the plurality of terminal devices connected to the signal line, resistors having different resistance values for passing different line currents are connected in series with the detection switch when the detection switch is turned on.
When the detection signal is received by the signal line, the monitoring control unit instructs the current monitoring unit to measure the current value flowing through the signal line to which the detection signal is received, and the measured current value. A tunnel disaster prevention system characterized in that the terminal device that outputs the detection signal is identified and displayed based on the above.
In the tunnel disaster prevention system according to claim 1,
The terminal device is a manual notification device provided in a fire hydrant device that turns on the detection switch and outputs a fire signal by a fire notification operation.
When the monitoring control unit receives the fire signal from the signal line, the monitoring control unit outputs a fire alarm and instructs the current monitoring unit to measure the current value flowing through the signal line to which the fire signal is received. A tunnel disaster prevention system characterized in that the fire extinguishing plug device to which the fire signal is output is identified and displayed based on the measured current value.
In the tunnel disaster prevention system according to claim 1,
The terminal device is a fire hydrant starter that turns on the detection switch and outputs a fire hydrant start signal by opening the fire hydrant valve open / close lever provided in the fire hydrant device or starting the pump start switch.
When the monitoring control unit receives the fire hydrant start signal from the signal line, the monitoring control unit transmits a pump start signal to the fire hydrant pump equipment to start the operation, and also instructs the current monitoring unit to send the fire hydrant start signal. A tunnel disaster prevention system characterized in that the received current value flowing through the signal line is measured, and the fire hydrant device to which the fire hydrant start signal is output is identified and displayed based on the measured current value.
In the tunnel disaster prevention system according to claim 2 or 3.
On the front of the housing of the disaster prevention receiver, a graphic panel displaying a tunnel system diagram in which a plurality of fire hydrant indicator lights are arranged corresponding to the arrangement of the fire hydrant device in the tunnel is arranged.
The tunnel disaster prevention system is characterized in that the monitoring control unit operates the fire hydrant indicator light in the graphic panel corresponding to the fire hydrant device whose output of the fire signal or the fire hydrant activation signal is identified.
In the tunnel disaster prevention system according to claim 4.
In the graphic panel, a plurality of compartment indicator lights are arranged separately for the manual notification device and the fire hydrant activation device corresponding to the compartments divided in the longitudinal direction of the tunnel.
The monitoring control unit is a tunnel disaster prevention system characterized by operating a line indicator light in the graphic panel corresponding to the signal line in which the fire signal or the fire hydrant activation signal is received.
In the tunnel disaster prevention system according to claim 4 or 5.
A monitor device is placed inside the housing of the disaster prevention receiver.
The tunnel disaster prevention system is characterized in that, when the current monitoring unit detects a predetermined measurement history reading operation, the current monitoring unit reads the measurement history and displays it on the screen of the monitoring device.
In the tunnel disaster prevention system according to claim 4.
A second monitoring device is provided on the front surface of the housing of the disaster prevention receiver in place of the graphic panel.
In the monitoring control unit, a plurality of fire hydrant symbols are arranged in the second monitoring device according to the arrangement of the fire hydrant device in the tunnel, and a plurality of manual notification devices or fire hydrant activations connected to each signal line are activated. The tunnel corresponding to the fire hydrant device in which the output of the fire signal or the fire hydrant activation signal is identified by displaying the tunnel system diagram in which a plurality of partition symbols are arranged corresponding to the sections divided in the tunnel for each device is displayed on the screen. To change the display of the fire hydrant symbol in the system diagram and to change the display of the section symbol in the tunnel system diagram corresponding to the signal line in which the fire signal or the fire hydrant activation signal is received. A characteristic tunnel disaster prevention system.

Images