JP2018000333A - Emergency facilities for tunnel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To maintain an elevating type fire hydrant facility capable of lifting a hose storage part and allowing extraction of a hose, in such a manner as to reliably operate.SOLUTION: Each of fire hydrant facilities 16 installed at prescribed intervals apart in a tunnel longitudinal direction includes a hose storage part 44 for storing a hose with a nozzle, liftably/lowerably supported in a watchman's passage 14 by a lifting mechanism and, when a fire hydrant is used, and lifts the hose storage part 44 to an exposure position on the watchman's passage 14 by operation of the lifting mechanism so as to enable extraction of the hose. A disaster-prevention receiver board 100 of a disaster prevention center includes an inspection part that instructs a hydrant control device 140 of the fire hydrant facility 16 to periodically lift/lower the lifting mechanism provided in the hose storage part 44.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a tunnel emergency facility provided with a fire hydrant facility that allows a hose to be taken out by raising a hose storage portion.

  Conventionally, fire hydrant equipment has been provided as emergency equipment for tunnels installed in tunnels such as expressways and motorway roads, and the fire hydrant device has a nozzle at the tip of the fire hydrant storage part of the housing with an openable fire hydrant door. For example, two fire extinguishers are housed in a fire extinguisher housing section having a fire extinguisher door that can be freely opened and closed.

  Such a fire hydrant installation is installed at intervals of, for example, 50 meters along the side wall facing the observer passage provided in the tunnel. The supervisor passage is provided as a side wall passage that is about 1 meter higher than the road surface, and it is possible to inspect various devices including fire hydrants installed safely in the tunnel without hindering vehicle traffic in the tunnel. It is said.

  When a vehicle accident involving a fire occurs, users such as the driver of the accident vehicle open the fire hydrant door of the fire hydrant equipment, pull out the hose with a nozzle, and operate the fire hydrant valve opening / closing lever to operate the fire pump equipment. Fire extinguishing work can be performed by starting and discharging water.

JP 2008-055024 A JP 2009-285126 A

  However, in such a conventional hydrant installation installed in the tunnel, it was installed along the tunnel side wall facing the observer passage. It is necessary to reach out to the fire hydrant equipment installed on the side wall of the tunnel beyond the passage, open the fire hydrant door, pull out the hose to perform fire extinguishing work, and the fire hydrant equipment is installed at a high position away from the road surface Some people may have to go up and operate the guard passage without reaching their hands, and some guard passages are equipped with handrails that interfere with fire fighting operations and are difficult to handle. There was a case.

  In order to solve this problem, the present applicant has proposed a lift-type fire hydrant facility that can be easily and easily handled from the road side and the supervisor passage side. The elevating type fire hydrant equipment has a hose housing part in which a hose with a nozzle is housed so that it can be moved up and down by an elevating mechanism in the surveillance passage. When a vehicle accident involving a fire occurs in the tunnel, a predetermined switch When the operation is performed, the hose storage part is lifted and held at the exposed position on the supervisor passage by the operation of the lifting mechanism, and the hose storage part exposed on the supervisor passage is not required to open the fire hydrant door. The fire can be extinguished simply and easily by pulling out the hose with a nozzle.

  By the way, the tunnel emergency equipment is regularly inspected once every six months or once a year, and for the lift-type fire hydrant equipment, the elevating operation of the hose storage portion by the elevating mechanism is confirmed at the time of the periodic inspection. However, if the period of use becomes long, there is a possibility that there is a problem with the operation of the lifting mechanism before the periodic inspection. There is a risk of hindering fire extinguishing work without being raised to the exposed position on the observer passage.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a tunnel emergency facility capable of maintaining and operating a lift-type fire hydrant facility that raises a hose storage portion and enables a hose to be removed.

(Tunnel emergency equipment)
The present invention relates to a tunnel emergency facility,
Fire hydrant equipment that is installed at predetermined intervals in the tunnel longitudinal direction and that holds the hose with a nozzle housed in the supervisor's passage ascends to an exposed position on the supervisor's passage when the fire hydrant is used by operating the lifting mechanism When,
A fire hydrant control unit that is arranged in the fire hydrant facility and controls the operation of the lifting device,
An inspection unit that is placed on the disaster prevention reception panel and periodically operates the lifting mechanism of the fire hydrant equipment installed in the tunnel,
Is provided.

(Confirmation of lift completion and descent completion by the inspection department)
When the inspection unit determines the predetermined inspection timing, it sends a rising control signal to the fire hydrant control unit to drive the lifting mechanism up and confirms the completion of the lifting when the rising position detection signal is obtained from the fire hydrant control unit. And
After confirming completion of the ascent, a descent control signal is transmitted to drive the elevating mechanism to descend, and when a descent position detection signal is obtained from the fire hydrant control unit, the end of descent is confirmed and the inspection is terminated.

(Confirmation of rising start and falling start by the inspection department)
When the inspection unit determines a predetermined inspection timing, the inspection unit transmits a rising control signal to the fire hydrant control unit to drive the lifting mechanism upward, and starts rising when the lowering position detection signal from the fire hydrant control unit is cut off. Check
After confirming the completion of the ascent, a descent control signal is transmitted to drive the elevating mechanism to descend, and when the ascending position detection signal from the fire hydrant control unit is interrupted, confirm the descent start,
When the descending position detection signal is obtained from the fire hydrant control unit, the end of the descending is confirmed and the inspection is terminated.

(Error judgment and recovery processing)
The fire hydrant control unit determines that there is an error when the lowering position detection signal is not interrupted even after a predetermined time has elapsed since the elevating mechanism is driven up by receiving the ascending control signal from the inspection unit, and the elevating mechanism is driven downward. And an error recovery operation in which the ascending drive is alternately repeated a predetermined number of times.

(Awareness warning sound when moving up and down)
The fire hydrant equipment includes an audio alarm unit that outputs an alarm sound and / or an alarm message,
The inspection unit instructs the fire hydrant control unit to output an alarm sound or an alarm message from the voice alarm unit during the inspection of the fire hydrant equipment.

(Warning display when moving up and down)
Fire hydrant equipment is equipped with a warning indicator light that blinks, blinks, or is lit.
The inspection unit instructs the fire hydrant control unit to blink, blink, or turn on the fire hydrant control unit during inspection of the hydrant facility.

(Cancellation of inspection in case of fire)
If the inspection department receives a fire signal from a fire detector installed in the tunnel or a fire report signal from a transmitter installed in the fire hydrant equipment during the inspection of the fire hydrant equipment, the fire hydrant equipment Stop the inspection.

(Basic effect)
In the emergency equipment for tunnels, the hose with a nozzle installed at predetermined intervals in the longitudinal direction of the tunnel and housed in the supervisor passage is operated by a lifting mechanism when a fire hydrant is used. The fire hydrant equipment that is raised and held at the upper exposed position, the fire hydrant control part that is disposed in the fire hydrant equipment and controls the operation of the lifting device, and the fire hydrant equipment that is disposed in the disaster prevention reception panel and installed in the tunnel. Since there is an inspection section that periodically and sequentially operates the elevating mechanism, for example, a hose by an elevating mechanism provided in a fire hydrant facility installed in the tunnel once a week or once a month The storage unit is moved up and down to the exposed position on the surveillance passage, and then lowered and returned to the original storage position. If there is a problem with the lifting operation, repair or replacement is recommended. Even if the so-called elevating type fire hydrant equipment is used for a long time, the elevating mechanism ensures that the hose storage part is exposed to the position on the supervisor passage even when a fire occurs due to a vehicle accident. As a result, the reliability of the liftable fire hydrant equipment can be ensured.

(Effects of checking the completion of ascent and descent by the inspection department)
In addition, when the inspection unit determines the predetermined inspection timing, the inspection unit transmits a rising control signal to the fire hydrant control unit to drive the lifting mechanism upward, and when the rising position detection signal is obtained from the fire hydrant control unit, the lifting is completed. After confirming the completion of the ascent, the descent control signal is transmitted to drive the elevating mechanism to descend, and when the descent position detection signal is obtained from the fire hydrant control unit, the end of descent is confirmed and the inspection is terminated. A series of raising and lowering operations such as completion of raising and lowering of the hose storage part by the raising and lowering mechanism is performed by an instruction by a control signal from the inspection part, and it is confirmed in cooperation with the detection state of the lowering position and the rising position from the fire hydrant equipment side. In the unlikely event that a problem occurs during the lifting / lowering operation, the inspection side grasps at which stage the problem has occurred and enables appropriate countermeasures.

(Effects of confirming the start of ascent and descent by the inspection department)
In addition, when the inspection unit determines a predetermined inspection timing, the inspection unit transmits an ascent control signal to the fire hydrant control unit to drive the elevating mechanism upward, and the lowering position detection signal from the fire hydrant control unit is interrupted. After confirming the start of ascent, sending the descending control signal after confirming the completion of the ascent to drive the ascending / descending mechanism to descend, confirming the descending start when the ascending position detection signal from the fire hydrant controller is cut off, When the descent position detection signal is obtained, the end of descent is confirmed and the inspection is terminated.Therefore, a series of elevating operations such as start of raising the hose storage part by the elevating mechanism, completion of rise, start of descent, completion of descent, It can be operated by checking with the control signal from the inspection section and checking it in cooperation with the detection status of the lowered position and raised position from the fire hydrant equipment side. If that occurred, if the problem occurs in any mode of operation stage to grasp at the inspection side to allow the appropriate action.

(Effects of error judgment and recovery processing)
In addition, the fire hydrant control unit determines that an error occurs when the lowering position detection signal is not interrupted even after a predetermined time elapses after the elevating mechanism is driven to rise by receiving the elevating control signal from the inspection unit, and the elevating mechanism Since the error recovery operation that repeats the descending drive and the ascending drive alternately alternately for a predetermined number of times is performed, when the hose storage part is lowered and stored in the supervisor passage by the elevating mechanism, the opening of the supervisor passage is set to the hose storage part. If the dust attached to the closed road surface plate is moistened and fixed, the hose storage part is lifted by the lifting mechanism when the dust is adhered to the closed road surface plate. Even if you try to make it move, it is possible that it will not move, but this error is judged, and by repeating the ascending and descending drive of the lifting mechanism, vibration is applied to the hose housing part, and the road surface plate that is fixed By moving, to enable error recovery.

(Effects of warning sound when moving up and down)
In addition, the fire hydrant equipment includes a sound alarm unit that outputs an alarm sound and / or a warning message, and the inspection unit instructs the fire hydrant control unit to instruct the sound hydrant control unit before and during the inspection operation of the fire hydrant facility. Because the alarm sound or warning message is output from the inspection section, the hoist storage part of the fire hydrant equipment is moved up and down by the inspection section in an unattended state. Before starting the operation, alert the surrounding people by outputting an alarm sound or warning message to inform that the inspection operation will be started, and in a state where people are on the road surface plate of the hose storage section Suddenly, it is possible to avoid a situation in which the road surface plate starts to lift.

(Effects of warning display when moving up and down)
In addition, the fire hydrant equipment is equipped with a warning indicator light that blinks, flickers, or is lit, and the inspection unit instructs the fire hydrant control part to blink the warning indicator light before starting the inspection operation of the fire hydrant equipment and during the inspection operation. As with warning sounds or warning messages, the warning indicator light blinks, for example, before the inspection operation is started, so that the inspection operation is performed with the attention of the people around. It is possible to avoid the situation that the road surface plate suddenly starts to lift in a state where a person is on the road surface plate of the hose storage section. In addition, the blinking, blinking, or lighting of the warning indicator light can be confirmed from a remote location. It is also possible to see and confirm.

(Cancellation of inspection in case of fire)
In addition, when the inspection unit receives a fire signal from a fire detector installed in the tunnel or a fire notification signal from a transmitter provided in the fire hydrant equipment during the inspection of the fire hydrant equipment, Since the inspection of the fire hydrant equipment has been stopped, if a fire due to a vehicle accident occurs during the inspection to raise or lower the hose storage part of the fire hydrant equipment by the lifting mechanism, the inspection is stopped at that point and a fire is caused. Along with this, priority is given to the operation of exposing the hose storage part of the fire hydrant equipment actually used on the supervisor passage to enable quick and appropriate fire fighting activities using the fire hydrant equipment.

Explanatory drawing showing fire hydrant equipment installed in a shield tunnel Explanatory drawing showing the outline of emergency equipment for tunnels that checks fire hydrant equipment with the disaster prevention reception board Explanatory drawing showing fire hydrant equipment in the tunnel from the road side Explanatory drawing showing the internal structure of the fire hydrant facility in the tunnel as seen from the road surface side Explanatory drawing which showed embodiment of the water discharge control mechanism and the raising / lowering control mechanism provided in the control-mechanism storage part installed in the supervisor passage Explanatory drawing which showed the state which raised the hose accommodating part by the raising / lowering mechanism, and was exposed on the supervisor path | route seen from the road surface side The block diagram which showed the functional composition of the disaster prevention reception board and fire hydrant control device of Figure 2 Time chart showing inspection control of fire hydrant equipment by disaster prevention reception board Time chart showing inspection control of fire hydrant equipment by disaster prevention reception panel following FIG. The flowchart which showed the detail of the error processing in step S9 of FIG.

[Outline of fire extinguishing equipment in the tunnel]
FIG. 1 is an explanatory view showing a fire hydrant facility installed in a tunnel of an automobile exclusive road. As shown in FIG. 1, the inside of the tunnel 10 constructed by the shield method is covered with a cylindrical tunnel wall surface 12, and a road 15 is provided by being partitioned by a floor slab 18. In this example, The road 15 has two lanes in one direction.

  A supervisor passage 14 is provided along the tunnel wall 12 on the left side of the road 15 partitioned by the floor slab 18, and the internal space below the supervisor passage 14 is used as a duct 22, and a conduit 23 and the like are laid. The

  The lower side of the floor slab 18 on which the road 15 is formed is divided into a plurality of sections in the tunnel lateral direction. For example, the section located under the supervisor passage 14 is used as a management passage 20, and The management passage 20 is used as an emergency evacuation passage when a fire occurs in the tunnel. A water supply main 24 is laid in the management passage 20.

  Fire hydrant equipment 16 is installed at intervals of 50 meters in the longitudinal direction of the tunnel 10, and the fire hydrant equipment 16 is separated into a hose storage part 44 and a control mechanism storage part 45. A fire extinguisher box 17 containing a fire extinguisher is provided adjacent to the fire hydrant facility 16.

  The hose storage portion 44 is disposed in a fire hydrant embedding portion having an attachment port opened on the road surface of the monitoring member passage 14. The control mechanism storage unit 45 is disposed in the management passage 20 below the hose storage unit 44, a branch pipe branched from the water supply main pipe 20 is drawn in, and water supply for supplying fire-extinguishing water to the hose storage unit 44 is provided. Piping is set up.

  The hose storage portion 44 of the fire hydrant facility 16 supports a hose with a nozzle that can be moved up and down by an elevating mechanism in the supervisor passage 14, and when a predetermined ascending operation is performed, an exposed position on the supervisor passage 14 by the elevating mechanism. The fire is extinguished by pulling out the hose with a nozzle.

[Outline of tunnel disaster prevention equipment]
FIG. 2 is an explanatory diagram showing an outline of a tunnel emergency facility for inspecting a fire hydrant facility by a disaster prevention reception panel.

  As shown in FIG. 2, fire hydrant equipment 16 in which a hose storage portion 44 and a control mechanism storage portion 45 are separately arranged is installed in the tunnel 10 in the longitudinal direction of the tunnel at intervals of 50 meters. A fire hydrant control unit 140 is provided for the hose storage unit 44 and the control mechanism storage unit 45.

  In addition, in the tunnel 10, fire detectors are provided at intervals of 25 meters or 50 meters for detecting fire flames as emergency facilities other than the fire hydrant facility 16, and manual notification devices and emergency telephones are provided for fire notifications. A fire hydrant is installed to prevent fires and spread fire, and a water spray to spray fire water from the water spray head is installed to protect the tunnel housing and duct from fire. The illustration is omitted.

  On the other hand, a disaster prevention receiving board 100 is installed at a monitoring center, and the transmission path 102 is drawn from the disaster prevention receiving board 100 to the tunnel 10, and the fire hydrant control unit 140 of the fire hydrant equipment 16 installed in the tunnel 10 is provided. It is connected. As the transmission line 102, an optical fiber transmission line such as FTTH or a coaxial transmission line is used. For example, digital transmission using an IP packet or the like is performed.

  In addition, for the disaster prevention receiver 100, the fire pump system 104, the duct cooling pump system 106, the ventilation system 108, the alarm display panel system 110, the radio rebroadcasting system 112, the television monitoring system 114, the lighting system 116 and the IG A slave station facility 118 and the like are provided, and the other facilities are individually connected to the disaster prevention receiving board 100 through a P-type signal line except that the IG slave station facility 118 is connected by a data transmission line.

  Here, the ventilation facility 108 is a facility that energizes the air in the tunnel by a high blown air speed by the operation of a jet fan installed on the ceiling side in the tunnel and causes a flow of ventilation in the longitudinal direction of the tunnel.

  The alarm display board facility 110 is a facility for informing the user in the tunnel of the abnormality in the tunnel by displaying it on the electric display board. The radio rebroadcasting facility 112 is a facility that allows a driver or the like to receive information from a road manager in the tunnel. The television monitoring facility 114 is a facility for checking the scale and position of the fire, grasping the situation in the tunnel when the water spray facility is operated, and evacuation guidance is performed.

  The lighting equipment 116 is equipment for driving and managing lighting equipment in the tunnel. Furthermore, the IG slave station equipment 118 is a communication equipment that connects the disaster prevention receiving board 100 and a remote monitoring control equipment 120 that is a higher-level equipment provided outside via the network 122.

[Fire hydrant installation structure]
FIG. 3 is an explanatory view showing the fire hydrant equipment in the tunnel from the road side, and FIG. 4 is an explanatory view showing the internal structure of the fire hydrant equipment in the tunnel in a cross section as seen from the road surface side.

(Appearance structure of fire hydrant equipment)
As shown in FIG. 3, the main part of the fire hydrant facility 16 is installed in an internal space below the floor of the supervisor passage 14 provided with the handrail 40, and the supervisor passage 14 serving as the installation location of the fire hydrant facility 16. A fire hydrant door 26 and an informing device panel 28 having an operation box on the inner side are installed on the upper part of the front wall 14a facing the road.

  The fire hydrant door 26 is mounted so that it can be opened and closed downward about the lower hinge 26a. By pulling the handle 27 toward the front, the lock can be released and opened. Inside the operation box 35 closed by the fire hydrant door 26, as shown by a dotted line, a water faucet 90 having a hose connection port and a pump start switch 92 are provided. For this reason, when a vehicle accident involving a fire occurs, the fire brigade opens the fire hydrant door 26 and connects the fire hose to the water faucet 90 so that the fire extinguishing pump is activated by operating the pump start switch so that the fire extinguishing activity can be performed. ing.

  The notification device panel 28 is provided with a red indicator lamp 30, a transmitter 32 and a response lamp 34. The red indicator lamp 30 is always turned on so that the installation location of the fire hydrant facility 16 can be seen from a distance. In the event of a fire, when the push button switch is turned on by pressing the transmitter 32, a transmission signal is transmitted to the fire receiver in the monitoring room, a fire alarm is issued, and a response signal is sent from the fire receiver accordingly, and a response lamp 34 is turned on.

  In addition, the notification device panel 28 is provided with an ascending switch 36 a and a descending switch 36 b for raising and lowering the hose storage portion of the fire hydrant facility 16 disposed in the supervisor passage 14.

  Furthermore, the handrail 40 is not provided in the part of the supervisor passage 14 where the fire hydrant facility 16 is installed, and this hinders the operation of the hose storage portion that is exposed from rising from the inside on the road surface of the supervisor passage 14. I do not want to be.

  It should be noted that the panel portion of the notification device panel 28 on which the ascending switch 36a and the descending switch 36b are arranged can be operated from both the road 15 side and the supervisor passage 14, so that it is oblique to the shoulder portion of the supervisor passage 14. You may arrange | position so that it may be located in.

(Structure of fire hydrant equipment installed in the interior space)
As shown in FIG. 4, a rectangular fire hydrant elevator opening 42 is opened on the road surface corresponding to the installation location of the fire hydrant equipment 16 in the supervisor passage 14, and a step portion is provided above the opening edge of the fire hydrant elevator opening 42. 42a is formed.

  A hose storage portion 44 of the fire hydrant facility 16 is disposed so as to be movable up and down with respect to the fire hydrant elevator 44. The hose storage section 44 includes a box-shaped casing 48 that opens to the front and the back, and four frame pipes 52 are arranged at the front and back openings of the casing 48 to form a hose outlet 55 therebetween. ing.

  Inside the hose storage portion 44, the hose 54 with the nozzle 56 attached to the tip is housed in an internally wound state, and the nozzle 56 attached to the tip of the hose 54 is disposed at the center of the internally wound hose 54, and a housing 48 is provided. The nozzle 56 can be taken out from either the front surface or the back surface.

  Further, in the hose storage portion 44, a water discharge switch 38a and a water discharge stop switch 38b for opening and closing a remote fire hydrant valve using an electric valve provided in the control mechanism storage portion 45 disposed in the management passage 20 are provided. Is provided.

  The hose storage portion 44 is supported by an elevating mechanism 46 so as to be movable up and down. The elevating mechanism 46 is provided with standing hydraulic actuators 60 at four positions corresponding to the corners of the rectangular bottom of the hose storage portion 44. The hydraulic actuators 60 are pistons connected to pistons slidably provided in the cylinder cylinder. The rod is taken out upward, and the tip of the piston rod is fixed to the bottom of the hose housing 44.

  A control mechanism storage section 45 is disposed in the management passage 20 below the internal space in which the elevating mechanism 46 is disposed. The control mechanism storage section 45 is supplied with fire-extinguishing water to the hose 54 of the hose storage section 44. A water discharge control mechanism for discharging water and a lift control mechanism for driving the lift mechanism 46 to move up and down are provided.

  A branch pipe 24a branched from the water supply main pipe 24 is connected to the control mechanism storage section 45, and water for fire extinguishing supplied to the water supply main pipe 24 from the fire pump system is introduced. Further, the branch pipe 24a is branched to the upper part and connected to the water tap 90 shown in FIG.

  The piping from the water discharge control mechanism built in the control mechanism storage unit 45 is connected to a flexible joint 63 serving as a hose connection port of the hose storage unit 44 via a connection hose 62. The connecting hose 62 has a hose length having a margin necessary for connection when the hose storage portion 44 is pushed up from the fire hydrant elevator opening 42 of the monitoring person passage 14 by the lifting mechanism 46 and held at the exposed position. As a result, even if the hose storage portion 44 is moved up and down with respect to the pipe on the fixed side, the hose storage portion 44 can move without the connecting hose 62 being pulled out. Further, the movement of the connecting hose 62 caused by the raising / lowering operation is absorbed by the movement of the flexible joint 63.

  In addition, a pipe for supplying and discharging fire extinguishing water is connected to the hydraulic actuator 60 of the lifting mechanism 46 from the lifting control mechanism built in the control mechanism housing 45.

  The number of hydraulic actuators 60 provided in the elevating mechanism 46 can be an appropriate number as required. For example, a hydraulic actuator having a predetermined diameter having a lifting force corresponding to the weight of the hose storage portion 44 is 1 in the center. Alternatively, the three hydraulic actuators 60 having a total pushing force corresponding to the weight of the hose storage portion 44 may be arranged in a triangle.

  Further, the connection between the hose storage 44 and the control mechanism storage 45 is made by connecting the inside of the supervisor passage with the connection hose 62 and the management passage 20 side with a pipe. The space may be directly connected by a connecting hose. Also in this case, the connection of the connection hose with respect to the hose storage part 44 side and the control mechanism storage part 45 is connected by a flexible joint.

  A lowering position detection switch 94 is provided on the upper left side of the casing 48 of the hose storage portion 44, and an upper position detection switch 96 is provided on the lower left side. The descending position detection switch 94 is turned on by detecting the illustrated descending position in which the hose accommodating portion 44 is accommodated in the supervisor passage 14, and when the ascent and descent mechanism 46 starts to rise, the descending position detection switch 94 is turned off.

  Further, the lift position detection switch 96 is turned off at the storage position of the illustrated hose storage section 44 and is turned on when the hose storage section 44 shown in FIG. .

  As the lowering position detection switch 94 and the rising position detection switch 96, for example, both the lowering position detection switch 94 and the rising position detection switch 96 are configured as reed switches, and are disposed in the vicinity of the supervisor passage in the hose storage portion 44. A permanent magnet for operating the switch is disposed in the horizontal direction in the vicinity of the hydrant opening / closing opening of the monitoring member passage in the vicinity of the lowering position detection switch 94 and the rising position detection switch 96, and the hose storage portion 44 is stored in the monitoring member passage 14. The lowering position detection switch 94 is turned on by the magnetic force of the magnet, and the rising position detection switch 94 is turned on by the magnetic force of the magnet when the hose storage portion 44 is exposed.

  Further, as the descending position detection switch 94 and the ascending position detection switch 96, a mechanical switch such as a limit switch may be used, or a magnetic or optical non-contact switch may be used. Note that the descending position detection switch 94 and the ascending position detection switch 96 may be provided in the supervisor passage on the fixed side.

(Water discharge control mechanism)
FIG. 5 is an explanatory view showing an embodiment of a water discharge control mechanism and a lift control mechanism provided in a control mechanism storage section installed in the supervisor passage.

  As shown in FIG. 5, the water discharge control mechanism 64 is connected to a remote fire hydrant valve 70 using an electric valve by drawing a branch pipe 24 a from a water supply main, and a manual fire hydrant valve 72 is connected in parallel with the remote fire hydrant valve 70. Has been. A pressure adjustment valve 74 is connected to the remote fire hydrant valve 70, and the secondary side of the pressure adjustment valve 74 is connected to the hose 54 via the connection hose 62 as shown in FIG. Further, an automatic drain valve 76 is connected to the secondary side of the pressure regulating valve 74.

  The remote fire hydrant valve 70 is controlled to open when a water discharge switch 38a provided in the hose storage section 44 shown in FIG. 3 is operated, and fire-extinguishing water is supplied to the hose storage section 44 side. When the water discharge stop switch 38b provided in the hose storage unit 44 shown in FIG. 3 is operated during the water discharge operation, the closing control is performed, and the supply of fire-extinguishing water to the hose storage unit 44 is stopped.

  The remote hydrant valve 70 may not be an electric valve, but a hydrant valve opening / closing lever may be provided in the hose housing 44 and connected by a link wire, and the fire hydrant valve may be opened / closed by remote operation by operating the fire hydrant valve opening / closing lever. .

(Elevation control mechanism)
As shown in FIG. 5, the elevation control mechanism 66 is connected to a remote control valve 78 using an electric valve by drawing a branch pipe 24 a from the water supply main, and a manual control valve 80 is connected in parallel with the remote control valve 78. Has been. The secondary side of the remote control valve 78 is connected to the hydraulic actuator 60 shown in FIG. 4 via a piping via an automatic pressure regulating valve 81, a check valve 82 and an orifice 83. A remote drain valve 84 is connected to the primary side of the orifice 83.

  The automatic pressure regulating valve 82 can adjust the set pressure by adjusting the spring load, and the rising speed of the hose accommodating portion 44 by the hydraulic actuator 60 can be adjusted by changing the set pressure.

  In the normal monitoring state, the remote control valve 78, the manual control valve 80, and the remote drain valve 82 are closed, and fire water is not supplied to the hydraulic actuator 60 of FIG. The hose storage portion 44 is stored in the internal space of the supervisor passage 14, and the fire hydrant elevator 42 is closed by the road surface plate 50 of the hose storage portion 44.

  In the event of a fire due to a vehicle accident in the tunnel, the remote control valve 78 is controlled to open by operating the ascending switch 36a of the notification device panel 28 shown in FIG. 3, and water for fire extinguishing is supplied to the hydraulic actuator 60 via the orifice 83. It is supplied, pushes up the piston in the cylinder, and raises the hose storage portion 44 via the piston rod.

  In this case, since the amount of fire extinguishing water squeezed by the orifice 84 is supplied to the hydraulic actuator 60, the hose storage portion 44 is pushed up at a slow predetermined speed determined by the adjustment pressure of the automatic pressure regulating valve 81 and the orifice 84. It is exposed on the supervisor passage 14 and stopped and held at the full stroke position.

  When the hose storage portion 44 exposed and held on the supervisor passage 14 is stored, the remote control valve 78 is closed by operating the lowering switch 36b of the hose storage portion 44 shown in FIG. Supply of fire-extinguishing water to 60 is stopped. In this state, the remote drain valve 84 is controlled to open, fire-extinguishing water is drained from the water pressure actuator 60, and the water pressure actuator 60 of the lifting mechanism 46 receiving the weight of the hose storage 44 is at a slow predetermined speed determined by the orifice 83. The hose storage unit 44 is stored in the fire hydrant elevator 42.

[Operation of fire hydrant equipment]
FIG. 6 is an explanatory view showing a state in which the hose storage portion is lifted by the elevating mechanism and is exposed on the supervisor passage as seen from the road side.

(Normal monitoring)
During normal monitoring when the vehicle is traveling on the road of the tunnel 10 shown in FIG. 1, the hose storage portion 44 of the fire hydrant equipment 16 is supplied with fire-extinguishing water from the elevation control mechanism 66 as shown in FIG. 3. By being stopped, the hydraulic actuator 60 of the elevating mechanism 46 positions the piston at the lowest point, so that the elevating mechanism 46 stores the hose storage portion 44 in the internal space of the supervisor passage 14 and The road surface plate 50 on the upper surface is pressed against and supported by the step portion 42a of the fire hydrant elevator 42, and even if the fire hydrant equipment 16 is installed in the supervisor passage 14, the passage of people through the supervisor passage 14 may be hindered. , Do not pose a danger. At this time, the lowering position detection switch 94 provided in the hose storage portion 44 is turned on, and the rising position detection switch is turned off.

(When a fire breaks out)
On the other hand, when a vehicle accident involving a fire occurs in the tunnel 10, the user goes to the hydrant facility 16 near the fire occurrence place and pushes the transmitter 32 of the notification device panel 28 shown in FIG. The response lamp 34 is turned on to confirm the completion of the report to the monitoring room side.

  Subsequently, in order to perform a fire extinguishing operation, the raising switch 36a provided on the reporting device panel 28 is pressed and turned on. When the ascent switch 36 is turned on, an open control signal is sent to the remote control valve 78 of the lift control mechanism 66, and the remote control valve 78 is controlled to open, so that fire-fighting water from the branch pipe 24a is sent from the remote control valve 78. The piston is raised by the fire-extinguishing water supplied to the hydraulic actuator 60 of the elevating mechanism 46 through the orifice 84 and supplied into the cylinder, and pushes up the hose housing portion 44 supported through the piston rod.

  For this reason, the road surface plate 50 which closes the fire hydrant raising / lowering opening 42 of the monitoring person passage 14 is lifted, and the hose storage portion 44 stored inside slowly appears from the road surface and rises to the exposed position shown in FIG. 6 and stops. , Hold this exposed position. Here, when the hose storage unit 44 starts to rise by the elevating mechanism 46, the lowering position detection switch 94 is turned off. When the hose storage unit 44 is raised to the exposure position and stopped, the rising position detection switch 96 is turned on.

  When the hose storage portion 44 is held in an exposed state on the supervisor passage 14 in this way, the user takes out the nozzle 56 from the road side through the front opening of the housing 48, so that the hose can be easily and easily obtained. 54 can be pulled out.

  Subsequently, when the user presses and turns on the water discharge switch 38a provided in the exposed hose storage portion 44, an open control signal is output to the remote fire hydrant valve 70 of the water discharge control mechanism 64, and the remote fire hydrant valve 70 is opened. The water for extinguishing fire at the specified pressure adjusted by the pressure regulating valve 74 is supplied to the hose 54 via the connecting hose 62, and fire extinguishing activity can be performed by discharging water from the nozzle 56.

  On the other hand, when a user performs a fire extinguishing work from the side of the supervisor passage 14, the nozzle 56 can be easily and easily removed by removing the nozzle 56 from the rear opening of the casing 48 in the hose storage portion 44 exposed and held on the supervisor passage 14. The hose 54 can be easily pulled out and fire extinguishing work can be performed.

  When the fire is extinguished and the fire extinguishing operation is completed, when the water discharge stop switch 38b provided in the hose housing portion 44 is pressed and turned on, a close control signal is output to the remote fire hydrant valve 70 of the water discharge control mechanism 64, and the remote fire hydrant The valve 70 is closed, and water discharge from the nozzle 56 can be stopped.

  Further, in the restoration work after the fire extinguishing work is finished, the hose 56 is drained, and then the hose 54 is housed in an internally wound state in the hose housing part 44 exposed and held on the supervisor passage 14. .

  Subsequently, by turning on the lowering switch 36b provided on the reporting device panel 28, a close control signal is sent to the remote control valve 78 of the lift control mechanism 66 to close it, and then the remote drain valve 84 is controlled to open. The water for fire extinguishing is drained from the hydraulic actuator 60, the elevating mechanism 46 descends in response to the weight of the hose storage portion 44, the road surface plate 50 descends to a position where it contacts the step 42a of the fire hydrant elevating port 42, and stops. The storage unit 44 is stored in the internal space of the supervisor passage 14.

  Here, when the hose storage unit 44 starts to descend by the elevating mechanism 46, the ascending position detection switch 96 switches from on to off, and when the hose storage unit 44 descends to the storage position and stops, the descending position detection switch 94 is activated. Turn on.

  If the hose storage portion 44 is not exposed on the supervisor passage 14 even if the raising switch 36a is operated due to a failure of the lifting mechanism 46 or the like, the fire hydrant door 26 is opened, the nozzle 56 is taken out, and the hose 54 is drawn out. It is possible to ensure high fail-safety.

(On-site inspection of fire hydrant equipment)
When the fire hydrant facility 16 is inspected on site, an attendant may perform an operation necessary for the inspection from the supervisor passage 14 side. The inspection of the lifting mechanism 46 is performed by an attendant opening the inspection door provided on the road surface of the supervisor passage 14 and entering the inside, and the inspection of the control mechanism storage unit 45 is performed by the attendant through the management passage 20. Enter and do.

  The inspection work of the fire hydrant equipment 16 does not open the fire hydrant door on the road 15 side or operate from the road side. Therefore, it is not necessary to restrict the passage of the vehicle by the inspection of the fire hydrant equipment. Inspection work can be done safely even without it.

[Automatic inspection of fire hydrant equipment]
(Disaster prevention reception board)
FIG. 7 is a block diagram showing a functional configuration of the disaster prevention reception board and the fire hydrant control device of FIG. As shown in FIG. 7, the disaster prevention receiving board 100 includes a board control unit 124. The board control unit 124 is a function realized by executing a program, for example, as a hardware, a CPU, a memory, various input / output ports, etc. Use a computer circuit equipped with

  A transmission unit 126 is provided for the panel control unit 124, and a fire hydrant control unit 140 of the fire hydrant facility 16 installed in the tunnel 10 at intervals of 50 meters is connected to the transmission path 102 drawn from the transmission unit 126.

  In addition, an alarm unit 128 provided with a speaker, an alarm indicator light, etc. for the panel control unit 124, a display unit 130 provided with a liquid crystal display, a printer, etc., an operation unit 132 provided with various switches, etc., an IG that communicates with external monitoring equipment A modem 134 for connecting the slave station equipment 118 is provided. Further, the fire extinguishing pump equipment 104, the cooling pump equipment 106, the ventilation equipment 108, the alarm display board equipment 110, the radio rebroadcast equipment 112, the television monitoring equipment 114, and the like shown in FIG. An IO unit 136 to which the lighting equipment 116 is connected is provided.

  The board control unit 124 instructs the transmission unit 126 to repeatedly transmit a calling signal including a polling command that sequentially designates the addresses of the fire detectors installed in the tunnel, and the fire detector matches the self address. When a call signal is received, a response signal including self status information such as fire detection is returned. In addition, the panel control unit 124 of the disaster prevention receiving panel 100 outputs a fire alarm by the alarm unit 128 when the fire is detected by receiving the response signal from the fire detector 12, and linked control of other equipment via the IO unit 136. Control is performed to instruct.

  The panel control unit 124 is provided with the function of the inspection unit 125. The inspection unit 125 transmits a control signal instructing inspection by sequentially specifying the IP address of the fire hydrant equipment 16 installed in the tunnel at a predetermined inspection cycle, for example, one week or one month. An elevating mechanism 46 provided in the facility 16 is operated to perform an inspection operation for raising and lowering the hose storage portion 44.

  The inspection control of the fire hydrant equipment 16 by the inspection unit 125 is performed by transmitting a rising control signal to the fire hydrant control device 140 to drive the lifting mechanism 46 to be lifted and detected by the fire hydrant control device 140 when a predetermined inspection timing is determined. When the rising position detection signal is cut off, the rising start is confirmed, and when the rising position detection signal is obtained from the fire hydrant control device 140 within a predetermined time, the rising completion is confirmed. Is transmitted to drive the elevating mechanism 46 downward, and when a lowering position detection signal is obtained from the fire hydrant control device 140 within a predetermined time, control is performed to confirm the end of lowering and end the inspection.

(Fire hydrant control device)
As shown in FIG. 7, the fire hydrant equipment 16 is provided with a fire hydrant control device 140. The fire hydrant control device 140 includes a fire hydrant control unit 142 and a transmission unit 144. The fire hydrant control unit 142 is a function realized, for example, by executing a program, and uses hardware such as a computer circuit including a CPU, a memory, and various input / output ports.

  Connected to the fire hydrant control unit 142 are a reporting device unit 146, a remote fire hydrant valve 70, a raised position detection switch 96, a lowered position detection switch 94, a voice alarm unit 148, and an alarm indicator lamp 150 provided in the hose storage unit 44. Is done. The fire hydrant controller 142 is connected to a remote control valve 78 and a remote drain valve 84 provided in the control mechanism storage unit 45.

  The notification device unit 146 includes a red indicator lamp 30, a transmitter 32, a response lamp 34, an up switch 36a, and a down switch 36b provided on the notification device panel 28 of FIG.

  The raised position detection switch 96 outputs a raised position detection signal when the hose storage portion 44 shown in FIG. 6 detects and turns on a predetermined raised position exposed on the supervisor passage 14, and at other positions. It turns off and the output of the rising position detection signal is stopped.

  The lowered position detection switch 94 outputs a lowered position detection signal when the hose accommodating portion 44 shown in FIG. 4 detects and turns on a predetermined lowered position accommodated in the supervisor passage 14, and other positions are output. Then, the output is turned off and the output of the descending position detection signal is stopped.

  When the hose storage unit 44 is raised by the elevating mechanism 46, the voice alarm unit 148 outputs a predetermined alarm sound or alarm message in response to an instruction from the fire hydrant control unit 142, and urges people in the vicinity to pay attention.

  The alarm indicator lamp 150 blinks, blinks, or lights in response to an instruction from the fire hydrant control unit 142 when the elevating mechanism 46 moves up the hose storage unit 44, and urges people in the vicinity to pay attention. For example, the warning indicator lamp 150 is disposed below the road surface plate 50 in the hose storage portion 44 shown in FIGS. 3 and 4, and blinks or blinks at the closed position of the road surface plate 50, thereby providing a clearance around the road surface plate 50. Attention is given by emitting light from the light source. Further, while the hose storage portion 44 is raised, it flashes, blinks or lights on the lower side of the road surface plate 50 to emit light to the surroundings for attention.

  Further, when the hose storage unit 44 is raised, if the hose storage unit 44 does not turn on within a predetermined time due to some abnormality, it is assumed that a failure has occurred. An alarm may be given, or a failure detection signal of the fire hydrant facility 16 may be transmitted to the disaster prevention reception panel 100.

(Checking and controlling fire hydrant equipment)
FIG. 8 is a time chart showing inspection control of the fire hydrant equipment by the disaster prevention reception board, and FIG. 9 is a time chart showing inspection control of the fire hydrant equipment by the disaster prevention reception board following FIG.

  As shown in FIG. 8, when the inspection unit 125 of the disaster prevention reception panel 100 determines that the predetermined inspection timing has been reached in step S <b> 1, the IP address of the first initially set fire hydrant facility 16 among the plurality of hydrant facilities. With this setting, an inspection alarm signal is transmitted to the fire hydrant control unit 142 of the fire hydrant facility 16 in step S2. The fire hydrant control unit 142 of the fire hydrant facility 16 that has received this inspection alarm signal instructs the acoustic alarm unit 148 to start outputting a predetermined alarm sound in step S3 and starts blinking or blinking of the alarm indicator lamp 150. A warning sound and a warning display from the fire hydrant facility 16 installed in the tunnel are informed of the start of the operation of the fire hydrant facility 16.

  Subsequently, the inspection unit 125 of the disaster prevention reception panel 100 determines a time-out for a predetermined time in step S4, and then transmits a rising control signal to the fire hydrant control unit 142 of the fire hydrant facility 16 in step S5, and receives the received fire hydrant control. In step S <b> 6, the unit 142 controls the opening of the remote control valve 78 of the control mechanism storage unit 78, supplies fire-extinguishing water to the hydraulic actuator 60 of the elevating mechanism 46, and starts raising the hose storage unit 44.

  When the hose storage unit 44 starts to rise normally by the elevating mechanism 46, the lowering position detection switch 94 is turned off and the lowering position detection signal stops, and the fire hydrant control unit 142 turns off the lowering position detection switch 94 in step S7. It discriminate | determines and progresses to step S10, transmits the raise start detection signal to the disaster prevention receiving board 100, and the check part 125 of the disaster prevention receiving board 100 which received this confirms the rise start of the fire hydrant equipment 16 at step S11.

  If it is not determined in step S7 that the descending position detection switch 94 is off, the turning-off of the descending position detection switch 94 is monitored until a predetermined time out in step S8. If a timeout is determined in step S8, an error in step S9 is detected. Proceed to processing 1.

  Subsequently, when the fire hydrant controller 142 determines in step S12 that the raised position detection switch 96 is turned on when the hose storage 44 is raised to a predetermined exposure position on the supervisor passage 14 and stopped, the process proceeds to step S15. The inspecting unit 125 of the disaster prevention receiving panel 100 that has transmitted the rising completion signal to the receiving panel 100 and has received this signal confirms the completion of the rising of the fire hydrant facility 16 in step S16.

  If it is not determined in step S12 that the ascending position detection switch 96 is on, the on position of the ascending position detection switch 96 is monitored until a predetermined time out in step S13. If a timeout is determined in step S13, an error in step S14 is detected. Proceed to processing 2.

  Subsequently, when the inspection unit 125 of the disaster prevention reception panel 100 determines a predetermined time-out in step S17, the inspection unit 125 proceeds to step S18, transmits a descent control signal to the hydrant control unit 142 of the hydrant facility 16, and receives the received hydrant control. 9 closes the remote control valve 78 of the control mechanism storage unit 78 and opens the remote drain valve 84 in step S19 of FIG. 9, and discharges fire-extinguishing water from the hydraulic actuator 60 of the elevating mechanism 46 to provide a hose storage unit. 44 descent drive is started.

  When the hose storage unit 44 starts to descend normally by the elevating mechanism 46, the ascending position detection switch 96 is turned off, and the fire hydrant control unit 142 determines that the ascending position detection switch 96 is turned off at step S20, and proceeds to step S23. The inspecting unit 125 of the disaster prevention receiving panel 100 that has transmitted the descending start detection signal to the receiving panel 100 and has received the signal confirms the descending start of the fire hydrant facility 16 in step S24.

  If it is not determined in step S20 that the ascending position detection switch 96 is off, the turning off of the ascending position detection switch 96 is monitored until a time-out of a predetermined time in step S21. If a timeout is determined in step S21, an error in step S22 is detected. Proceed to processing 3.

  Subsequently, when the fire hydrant control unit 142 determines in step S25 that the lowering position detection switch 94 is turned on when the hose storage unit 44 descends into the supervisor passage 14 and stops and stops, the process proceeds to step S28, and the disaster prevention reception board The inspection completion part 125 of the disaster prevention receiving board 100 which transmitted the descent completion signal to 100, and received this confirms completion of the descent of the fire hydrant equipment 16 in step S29.

  If it is not determined in step S25 that the descending position detection switch 94 is ON, the ON of the descending position detection switch 94 is monitored until a predetermined time out in step S26. If the timeout is determined in step S26, an error in step S27 is detected. Proceed to processing 4.

  Thus, when the completion of the descent is confirmed in step S29, since a series of raising and lowering operations by the inspection of the hose storage portion 44 of the fire hydrant equipment 16 has been normally completed, the inspection unit 125 of the disaster prevention receiving panel 100 is normal in step S30. The completed inspection result is stored, and in step S31, the process proceeds to the inspection control of the next hydrant facility, and the same inspection control is repeated up to the last hydrant facility.

(Error determination and error recovery)
If it is not determined in step S7 that the lowering position detection switch 94 is turned off even if the elevating mechanism 46 starts to raise the hose housing portion 44 in step S6 in FIG. 8, a timeout of a predetermined time is determined in step S8. If time-out is determined in step S8, the process proceeds to step S9, where it is determined that the hose storage portion 44 does not start to rise even if water for fire extinguishing is supplied to the hydraulic actuator 60 of the lifting device 46, and predetermined error processing 1 I do.

  The error that the hose storage unit 44 does not move even when the lifting mechanism 46 is driven to rise is not limited to the failure of the lifting mechanism 46 or the lifting control mechanism 66, for example, a road surface plate disposed on the upper portion of the hose storage unit 44. 50 and the stepped portion 42a of the fire hydrant opening / closing port 42 formed in the supervisor passage 14 are assumed to be dusty and fixed due to the adhesion of moisture, or when the periphery of the road surface plate 50 is frozen in winter. The

  FIG. 10 is a flowchart showing details of error processing 1 in step S9 of FIG.

  As shown in FIG. 10, the fire hydrant control unit 142 of the fire hydrant control device 140 first performs error processing 1 in the case of determining an error that does not move even when the hose storage unit 44 is driven up by the lifting mechanism 46 in step S41. After the elevating mechanism 46 is switched from the ascending drive to the descending drive, a time-out for a predetermined time is determined at step S42, the elevating mechanism 46 is switched to the ascending drive at step S43, and the hose storage unit 44 is lowered at step S44. It is determined whether or not the position detection switch 94 is turned off. If not turned off, the ascending drive switched in step S43 is continued until a predetermined time-out is determined in step S45.

  In this state, when the time-out is determined in step S45, it is determined in step S46 whether or not N times as the predetermined number of retries has been reached, and if it is less than N times, the process returns to step S41 to drive the lifting mechanism 46 downward. Switch to.

  In this way, by repeatedly and repeatedly switching the elevating mechanism 46 between ascending drive and descending drive until the number of retries reaches N times, a vertical force is repeatedly applied to the hose accommodating portion 44 by the drive mechanism 44 on the hose accommodating portion 44. It is done.

  As a result, when the road surface plate 50 of the hose storage portion 44 is stuck and does not move, the fixed state is loosened by repeatedly applying a vertical force to the road surface plate 50, and the hose storage portion before reaching the N times of retry. 44 is moved, and it is determined in step S44 that the lowering position detection switch 94 is turned off. In step S47, normal activation is performed, and the process returns to the main routine of FIG.

  When the number of retries reaches N times in step S46, recovery is impossible and the error ends, and a failure detection signal of the fire hydrant facility 16 is transmitted to the disaster prevention reception panel 100.

  8 is control on the fire hydrant control unit 142 side, the descent control signal and the up control signal may be transmitted from the inspection unit 125 of the disaster prevention reception panel 100 to be operated.

  Further, since the error processes 2 to 4 shown in steps S14, S22, and S27 of FIGS. 8 and 9 are caused by the failure of the elevating mechanism 44 and / or the elevating control mechanism 66, the recovery process as shown in FIG. The failure detection signal of the fire hydrant facility 16 is transmitted to the disaster prevention reception panel 100 as an error end. In this case, the inspection unit 100 of the disaster prevention receiving panel 100 determines which stage of the inspection control the failure detection signal has been received by, for example, a failure during ascending drive, a failure during descending drive, etc. Information for identifying the contents can be generated and provided to the user.

  Further, the fire hydrant facility 16 that has an error in raising and lowering the hose storage unit 44 may display the fact on the fire hydrant facility 16 or the disaster prevention reception panel 100 until it is confirmed that the error has been solved.

  In addition, if there is an error in raising and lowering the fire hydrant equipment in the immediate vicinity of the fire, in a cooperative environment between the fire hydrant equipment and the disaster prevention system, where the fire hydrant equipment rises due to the fire detection by the fire detector As an alternative to the hydrant facility, the hydrant facility closer to the location of the fire among the hydrant facilities adjacent to the hydrant facility may be raised.

  In addition, when receiving the fire signal from the fire detector or the fire report signal from the transmitter during the inspection, the disaster prevention receiving panel 100 determines that a fire has occurred and transmits an inspection stop signal to the hydrant facility 16 under inspection. To do. The fire hydrant facility 16 that has received the inspection stop signal closes the remote control valve 78 and stops the lifting mechanism 46.

  After the remote control valve 78 is closed, the fire hydrant facility 16 transmits a remote control valve closing completion signal to the disaster prevention receiving panel 100. After receiving the remote control valve closing completion signal, the disaster prevention receiving board 100 sends an elevating control signal of the elevating mechanism 46 to the fire hydrant equipment 16 corresponding to the place where the fire occurred, and raises the hose storage portion 44.

  If the disaster prevention reception panel 100 does not receive the remote control close completion signal within a certain time after sending the inspection stop signal, it will time out and send the rising control signal to the fire hydrant equipment 16 corresponding to the place where the fire occurred. To do.

  In addition, the fire hydrant facility 16 that has received the inspection stop signal may notify the inspection stop by a display or sound indicating that the inspection is being stopped.

[Modification of the present invention]
(Fire hydrant storage part)
The above-mentioned fire hydrant equipment supports the hose storage part so that it can be raised and lowered by the lifting mechanism, but also when a fire extinguisher storage part is provided integrally with the hose storage part to store a fire extinguisher, You may make it raise a fire extinguisher accommodating part to the exposure position on a monitoring person channel | path integrally with a hose accommodating part by a raising / lowering mechanism.

(Elevating mechanism)
In the above embodiment, an elevating mechanism that elevates and lowers the hose storage portion directly by a hydraulic cylinder is taken as an example. However, another mechanism such as a hydraulic cylinder, an electric elevating device, or a pantograph type elevating mechanism may be used.
(Fire hydrant equipment)
The hoses and hydrant valves of the fire hydrant equipment shown in the above embodiment, the configuration and arrangement of the notification device, and other configurations are arbitrary, and an appropriate configuration may be adopted.

(Other)
The present invention includes appropriate modifications that do not impair the object and advantages thereof, and is not limited by the numerical values shown in the above embodiments.

10: Tunnel 12: Tunnel wall 14: Monitor passage 15: Road 16: Fire hydrant equipment 17: Fire extinguisher box 18: Floor slab 20: Management passage 22: Duct 24: Water supply main 24a: Branch pipe 25: Box opening 26: Fire hydrant door 28: Notification device panel 36a: Raising switch 36b: Lowering switch 38a: Water discharge switch 38b: Water discharge stop switch 42: Fire hydrant elevator 44: Hose storage 45: Control mechanism storage 46: Elevating mechanism 48: Housing 50: Road surface plate 54: Hose 55: Hose outlet 56: Nozzle 60: Water pressure actuator 62: Connection hose 63: Flexible joint 64: Water discharge control mechanism 66: Lift control mechanism 70: Remote fire hydrant valve 78: Remote control valve 80: Manual Control valve 81: Automatic pressure regulating valve 82: Check valve 83: Orifice 84: Remote drain valve 94: Lowering position detection switch 96 Raised position detecting switch 100: disaster received Release 102: transmission path 124: panel control unit 125: inspection unit 126,144: Transmission unit 140: fire hydrant controller 142: hydrants controller 148: audio alarm section 150: Alarm indicator

Claims (7)

Fire hydrant equipment that is installed at predetermined intervals in the tunnel longitudinal direction and that holds the hose with a nozzle housed in the supervisor's passage ascends to an exposed position on the supervisor's passage when the fire hydrant is used by operating the lifting mechanism When,
A fire hydrant controller that is disposed in the fire hydrant facility and controls the operation of the lifting device;
An inspection unit that is arranged in a disaster prevention receiving panel and periodically operates the lifting mechanism of the fire hydrant equipment installed in a tunnel,
A tunnel emergency facility characterized by the provision of
In the tunnel emergency facility according to claim 1,
The inspection unit
When a predetermined inspection timing is determined, an elevating control signal is transmitted to the fire hydrant control unit to drive the elevating mechanism to elevate, and when the elevating position detection signal is obtained from the fire hydrant control unit, the elevating completion is confirmed. ,
A tunnel emergency characterized by transmitting a lowering control signal after confirming the completion of the ascent to drive the elevating mechanism downward, and confirming the end of the lowering when the lowering position detection signal is obtained from the fire hydrant control unit and terminating the inspection. Equipment.
In the tunnel emergency facility according to claim 1,
The inspection unit
When a predetermined inspection timing is determined, an elevating control signal is transmitted to the hydrant control unit to drive the elevating mechanism to elevate, and the elevating start is started when the lowered position detection signal from the hydrant control unit is interrupted. Confirmed,
After confirming the completion of the ascent, the lowering control signal is transmitted to drive the elevating mechanism downward, and when the ascending position detection signal from the fire hydrant control unit is interrupted, confirm the start of lowering,
A tunnel emergency facility characterized in that when a descending position detection signal is obtained from the fire hydrant control unit, the end of the descending is confirmed and the inspection is terminated.
In the tunnel emergency facility according to claim 3,
The fire hydrant control unit determines an error when the lowered position detection signal is not interrupted even after a predetermined time has elapsed since the raising and lowering mechanism is driven to rise by receiving the elevation control signal from the inspection unit, A tunnel emergency facility that performs an error recovery operation that alternately repeats a descent drive and a lift drive of a lifting mechanism a predetermined number of times.
In the tunnel emergency facility according to claim 1,
The fire hydrant equipment includes a sound alarm unit that outputs an alarm sound and / or an alarm message,
The tunnel emergency facility, wherein the inspection unit instructs the fire hydrant control unit to output an alarm sound or an alarm message from the voice alarm unit during the inspection of the fire hydrant facility.
In the tunnel emergency facility according to claim 1,
The fire hydrant facility is provided with a warning indicator light that blinks, blinks or is lit,
The tunnel emergency facility, wherein the inspection unit instructs the fire hydrant control unit to blink, blink, or turn on the fire hydrant control unit during the inspection of the hydrant facility.
In the tunnel emergency facility according to claim 1,
When the inspection unit receives a fire signal from a fire detector installed in a tunnel or a fire notification signal from a transmitter provided in the fire hydrant facility during the inspection of the fire hydrant facility A tunnel emergency facility, characterized in that inspection of the fire hydrant facility is stopped.

Images