JP7009601B2 - Fire hydrant equipment and fire hydrant equipment in the tunnel - Google Patents

Description

The present invention relates to an in-tunnel fire hydrant facility and a fire hydrant device that raise the hose storage portion to enable the hose to be taken out.

Conventionally, a fire hydrant device has been provided as a tunnel emergency facility installed in a tunnel such as a highway or a motorway, and the fire hydrant device is a fire extinguisher storage part of a housing equipped with an openable fire hydrant door and a nozzle at the tip. A hose and valves equipped with a fire extinguisher are stored, and for example, two fire extinguishers are stored in a fire extinguisher storage unit equipped with a fire extinguisher door that can be opened and closed.

Such fire hydrant devices are installed, for example, at intervals of 50 meters along the side wall facing the guard passage provided in the tunnel. The observer passage is provided as a side wall passage that is about 1 meter higher than the road surface, and it is necessary to inspect various equipment including the fire hydrant device installed in the tunnel safely without obstructing the passage of vehicles in the tunnel. It is possible.

In the event of a vehicle accident involving a fire, users such as the driver of the accident vehicle open the fire hydrant door of the fire hydrant device, pull out the hose with a nozzle, and operate the fire hydrant valve open / close lever to operate the fire extinguishing pump equipment. Fire extinguishing work can be done by starting up and discharging water.

Japanese Unexamined Patent Publication No. 2008-055024 Japanese Unexamined Patent Publication No. 2009-285126

However, in the case of the fire hydrant device installed in such a conventional tunnel, since it is installed along the side wall of the tunnel facing the observer passage, the user can observe from the road surface when a fire occurs due to a vehicle accident. It is necessary to reach for the fire hydrant device installed on the side wall of the tunnel beyond the passage, open the fire hydrant door, pull out the hose to extinguish the fire, and the fire hydrant device is installed at a high position away from the road surface. Depending on the person, it may be necessary to go up to the observer passage and operate it out of reach, and some observer passages are provided with handrails, which interfere with fire extinguishing work and are difficult to handle. There was a case.

In order to solve this problem, the applicant of the present application proposes an elevating type fire hydrant facility that can be easily and easily handled from the road side and the guard passage side. In the elevating type fire hydrant equipment, the hose storage part where the hose with the nozzle is stored is arranged in the observer passage so that it can be elevated and lowered by the elevating mechanism. Then, the hose storage part is raised and held in the exposed position on the observer passage by the operation of the elevating mechanism, and the hose storage part exposed on the observer passage does not need to open the fire hydrant door. The hose with a nozzle can be pulled out easily and easily to extinguish the fire.

By the way, in such an elevating type fire hydrant facility, the hose accommodating portion provided in the observer passage is moved by the elevating mechanism, so that the hose accommodating portion is connected to the water supply pipe on the fixed side. A structure that can supply fire extinguishing water even when moving is required, and a flexible hose connects the water supply pipe on the fixed side and the hose storage portion on the moving side.

However, the flexible hose that connects the water supply pipe on the fixed side and the hose storage on the moving side needs a sufficient hose length to allow the hose storage to move, and the connecting hose becomes long. As a result, the connecting hose bends significantly in a steady state in which the hose storage portion is stored in the observer passage, and therefore it is necessary to secure a space that does not hinder the bending of the hose, which causes a problem that the equipment becomes large.

An object of the present invention is to provide an in-tunnel fire hydrant facility and a fire hydrant device capable of reducing the installation space and miniaturization by connecting a hose storage portion moved by an elevating mechanism and a fixed side pipe at the shortest distance. ..

(Fire hydrant equipment in the tunnel)
The present invention
A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When using a fire hydrant, an elevating mechanism that raises the hose storage and holds it in a predetermined exposed position on the road surface of the guard passage,
A water discharge control mechanism that is installed separately from the hose storage and supplies fire extinguishing water to the hose of the hose storage to discharge water.
In the fire hydrant equipment in the tunnel equipped with
A part of the pipe extending from the water discharge control mechanism to the hose storage part of the elevating mechanism to the predetermined position on the hose storage part side of the elevating mechanism is fixed to the elevating mechanism, and the upper end of the pipe on the hose storage part side and the hose storage It is characterized in that it is connected to the portion by a flexible connecting hose.

(Piston cylinder elevating mechanism)
The elevating mechanism is a piston cylinder elevating mechanism that elevates and lowers the hose storage unit by controlling the supply and discharge of hydraulic pressure.
A part of the pipe is fixed to the outside of the cylinder in the piston cylinder elevating mechanism.

(Hose length of connecting hose)
The connecting hose has a predetermined hose length that allows the hose compartment to be raised to an exposed position on the observer passage.

(Universal joint)
A universal joint is provided at the hose connection portion between the connecting hose and the hose storage portion and / or at the connecting portion between the connecting hose and the pipe.

(Pantograph elevating mechanism 1)
In another embodiment of the invention,
A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When using a fire hydrant, an elevating mechanism that raises the hose storage and holds it in a predetermined exposed position on the road surface of the guard passage,
A water discharge control mechanism that is installed separately from the hose storage and supplies fire extinguishing water to the hose of the hose storage to discharge water.
In the fire hydrant equipment in the tunnel equipped with
The elevating mechanism is a pantograph elevating mechanism that expands and contracts in the vertical direction, which is the elevating direction by the drive mechanism.
Piping is fixed along the link arm from the lower end of the link arm located at the bottom of the pantograph elevating mechanism to the upper end of the link arm located at the top of the pantograph elevating mechanism.
The feature is that the pipe extending from the water discharge control mechanism toward the lower end of the link arm located at the bottom and the lower end of the pipe fixed to the link arm located at the bottom are connected by a flexible connecting hose. And.

(Pantograph elevating mechanism 2)
The fixing of the piping to the predetermined link arm is divided and fixed for each link arm.
A flexible connecting hose connects the upper end of the pipe fixed to the link arm located at the lower part and the lower end of the pipe fixed to the link arm located at the upper part.

(Drive mechanism of pantograph elevating mechanism)
The drive mechanism of the pantograph elevating mechanism is a piston cylinder mechanism that expands and contracts the pantograph up and down by controlling the supply and discharge of hydraulic pressure, or a screw shaft drive mechanism that expands and contracts the pantograph up and down by the rotation of the screw shaft by a motor.

(Fire hydrant device in tunnel)
The present invention
A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When the hose storage unit uses a fire hydrant in the installed state, an elevating mechanism that raises the hose storage unit and holds it in a predetermined exposed position on the road surface of the watchman's passage.
A water discharge control mechanism that is installed separately from the hose storage and supplies fire extinguishing water to the hose of the hose storage to discharge water.
In a tunnel fire hydrant device equipped with
In the installed state, a part of the pipe extending from the water discharge control mechanism toward the hose storage part toward the hose storage part side of the elevating mechanism to the predetermined position on the upper part is fixed to the elevating mechanism, and the pipe is connected to the hose storage part side. It is characterized in that the upper end thereof and the hose housing portion are connected by a flexible connecting hose.

Since the other features of the in-tunnel fire hydrant device of the present invention are basically the same as those of the above-mentioned in-tunnel fire hydrant equipment, the description thereof will be omitted.

(Basic effect)
The present invention is a hose storage unit that is installed up and down inside an observer passage provided along the wall surface of a tunnel and in which a hose with a nozzle is retractably stored, and a hose storage unit when a fire extinguisher is used. A water discharge control mechanism that is installed separately from the hose storage part and supplies fire extinguishing water to the hose of the hose storage part. In the fire extinguishing plug equipment in the tunnel equipped with, a part of the pipe extending from the water discharge control mechanism toward the hose storage part to the predetermined position on the upper part on the hose storage part side of the elevating mechanism is fixed to the elevating mechanism. Since the upper end of the pipe on the hose storage side and the hose storage part are connected by a flexible connecting hose, the water supply pipe set up in the conventional observer passage and the hose storage part are connected by a connecting hose. By fixing a part of the pipe to the elevating mechanism, piping to the upper part of the elevating mechanism, and connecting the connecting hose to the upper end of the pipe, the height of the connecting pipe fixed to the elevating mechanism can be increased. The length of the connecting hose can be shortened by a considerable amount, and by shortening the connecting hose, the bending of the connecting hose when the hose storage part is stored in the observer passage is reduced, and the inside of the observer passage is reduced. It is possible to reduce the size of the fire extinguishing plug equipment by reducing the space required for arranging the connecting hoses.

(Effect of piston cylinder elevating mechanism)
In addition, the elevating mechanism is a piston cylinder elevating mechanism that elevates and lowers the hose storage part by controlling the supply and discharge of hydraulic pressure. By fixing the connecting pipe to the outside, the upper end of the connecting pipe is located sufficiently close to the hose storage portion, which makes it possible to shorten the connecting hose to the required hose length.

(Effect of hose length of connecting hose)
In addition, since the connecting hose has a predetermined hose length that allows the hose storage section to rise to an exposed position on the observer passage, a part of the piping is fixed to the elevating mechanism to connect to the hose storage section. Even if the hose is shortened, the hose housing can be reliably moved to the exposed position on the observer passage.

(Effect of universal joint)
In addition, since a universal joint is provided at the hose connection part between the connecting hose and the hose storage part, or at the connection part between the connecting hose and the pipe, the lateral movement of the connecting hose connected to the hose storage part and the pipe can be performed. It is absorbed by the universal joint, and the raising and lowering of the hose storage part by the raising and lowering mechanism can be smoothly moved without being hindered by the connecting hose and piping.

(Effect when using the pantograph elevating mechanism)
In another embodiment of the present invention, a hose storage unit, which is installed up and down inside an observer passage provided along the wall surface of the tunnel and in which a hose with a nozzle is retractably stored, and a fire extinguisher are used. In this case, the elevating mechanism that raises the hose storage part and holds it in a predetermined exposed position on the road surface of the observer passage and the hose storage part are installed separately and supply fire extinguishing water to the hose of the hose storage part. In the in-tunnel fire extinguisher equipment equipped with a water discharge control mechanism that discharges water, the elevating mechanism is a pantograph elevating mechanism that expands and contracts in the vertical direction, which is the elevating direction by the drive mechanism, and is located below the pantograph elevating mechanism. A pipe is fixed along the link arm from the lower end of the link arm to the upper end of the link arm located at the upper part of the pantograph elevating mechanism, and the pipe and the lower part extend from the water discharge control mechanism toward the lower end of the link arm located at the lower part. A flexible connecting hose connects the lower ends of the pipes fixed to the link arm located at the bottom, so a connecting hose is used to connect to the lower ends of the pipe fixed to the link arm located at the bottom. The part where the connecting hose is used remains almost unchanged with respect to the movement of the pantograph elevating mechanism, the connecting hose can be shortened, the placement space can be significantly reduced, and the fire extinguisher equipment can be miniaturized. Further, the fixing of the pipe to the predetermined link arm is divided and fixed for each link arm, and the upper end of the pipe fixed to the link arm located at the lower part and the lower end of the pipe fixed to the link arm located at the upper part. Even when the space is connected by a flexible connecting hose, the pipe moves integrally with the link arm in the pantograph elevating mechanism, and the distance between the pipe fixed to the link arm and the hose storage part is changed. Has hardly changed, the pantograph elevating mechanism and piping are integrated, and the connecting hose connecting the water discharge control mechanism and the hose storage part that moves to the upper limit is virtually unnecessary, the placement space is greatly reduced, and the fire extinguisher is plugged. Equipment can be miniaturized.

(Effect of the drive mechanism of the pantograph elevating mechanism)
In addition, the drive mechanism of the pantograph elevating mechanism is a piston cylinder mechanism that expands and contracts the pantograph up and down by controlling the supply and discharge of hydraulic pressure, or a screw shaft drive mechanism that expands and contracts the pantograph up and down by the rotation of the screw shaft by the motor. Even if the connecting pipe is fixed to the link arm of the pantograph elevating mechanism, it is possible to reliably elevate and drive the pantograph elevating mechanism.

Since the effect of the in-tunnel fire hydrant device of the present invention is the same as that of the above-mentioned in-tunnel fire hydrant equipment, the description thereof will be omitted.

Explanatory drawing showing tunnel emergency equipment including fire hydrant equipment installed in a shield tunnel Explanatory drawing showing the fire hydrant storage box for storing the hose from the front, the plane, and the side. Explanatory drawing showing the embodiment in which the connecting pipe is fixed to the piston cylinder elevating mechanism in the cross section seen from the road side. An explanatory view showing a state in which the hose storage portion of FIG. 3 is raised by an elevating mechanism and exposed on the observer passage in a cross section seen from the road surface side. Explanatory drawing showing an embodiment in which a connecting pipe is fixed to a pantograph elevating mechanism in a cross section seen from the road side. An explanatory view showing a state in which the hose storage portion of FIG. 5 is raised by an elevating mechanism and exposed on the observer passage in a cross section seen from the road surface side. Explanatory drawing showing another embodiment in which the connecting pipe is fixed to the pantograph elevating mechanism in a cross section seen from the road side.

[Overview of emergency tunnel equipment]
FIG. 1 is an explanatory diagram showing tunnel emergency equipment including a fire hydrant equipment installed in a tunnel of a motorway. 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, and in this example, the road 15 is provided. Road 15 has two lanes in one direction.

An observer passage 14 is provided along the tunnel wall surface 12 on the left side of the road 15 partitioned by the deck 18, and the internal space below the observer passage 14 is used as a duct 22 and conduits and the like are laid. ..

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

Fire hydrant equipment 16 is installed every 50 meters in the longitudinal direction of the tunnel 10, and the fire hydrant device of the fire hydrant equipment 16 is separately installed in the fire hydrant storage box 25 in which the hose is stored and the control mechanism storage unit 45.

The fire hydrant storage box 25 is arranged in a fire hydrant embedding portion that is hollowed out in a box shape over the road surface of the observer passage 14 and the wall surface on the road 15 side. The control mechanism storage unit 45 is arranged in a management passage 20 below the fire hydrant storage box 25, and a branch pipe branched from the water supply main 24 is drawn in, and water supply for supplying fire extinguishing water to the fire hydrant storage box 25. The plumbing has been set up.

The fire hydrant storage box 25 of the fire hydrant equipment 16 is provided with a hose storage unit in which a hose with a nozzle is stored and an elevating mechanism thereof. The hose compartment is raised and exposed, enabling fire extinguishing work by pulling out a hose with a nozzle.

[Fire hydrant equipment]
FIG. 2 is an explanatory view showing a fire hydrant storage box for storing a hose from the front, a plane, and a side surface. As shown in FIG. 2, the fire hydrant storage box 25 of the fire hydrant equipment 16 is embedded and installed in the internal space under the floor surface of the observer passage 14. In the fire hydrant storage box 25, a hose storage portion that is raised and lowered by the hydraulic cylinder of the raising and lowering mechanism is arranged.

The fire hydrant storage box 25 has an opening 27 formed on the front surface of the housing, and the opening 27 is provided with an inspection door 26 and a notification device panel 28, and the screw can be removed and removed at the time of inspection.

The reporting device panel 28 is provided with a red indicator lamp 30, a transmitter 32, and a response lamp 34. The red indicator light 30 is constantly lit so that the installation location of the fire hydrant equipment 16 can be seen from a distance. In the event of a fire, when the transmitter 32 is pressed and the push button switch is turned on, a fire alarm signal is sent to the disaster prevention receiver in the monitoring room to issue a fire alarm, and a response signal is sent from the disaster prevention receiver to respond. The lamp 34 is turned on and the red indicator lamp 30 is blinked.

Further, the notification device panel 28 is provided with an ascending switch 36a and a descending switch 36b for raising and lowering the hose accommodating portion of the fire hydrant equipment 16 arranged in the observer passage 14.

Further, the handrail 40 is not provided in the portion of the observer passage 14 in which the fire hydrant equipment 16 is installed, which interferes with the operation of the hose storage portion that rises from the inside and is exposed on the road surface of the observer passage 14. I try not to be.

[Fire hydrant equipment using a piston cylinder elevating mechanism]
FIG. 3 is an explanatory view showing an embodiment in which the connecting pipe is fixed to the piston cylinder elevating mechanism in a cross section seen from the road side, and FIG. 4 shows the hose storage portion of FIG. It is explanatory drawing which showed the exposed state in the cross section seen from the road surface side.

As shown in FIG. 3, a rectangular fire hydrant elevating port 42 is opened at a position on the road surface side of the fire hydrant storage box 25 installed in the observer passage. A hose storage portion 44 is arranged so as to be able to move up and down below the fire hydrant elevating port 42. The hose storage portion 44 includes a box-shaped housing 48 opened on the front surface and the back surface, and four frame pipes 52 are arranged in the openings on the front surface and the back surface of the housing 48, and a hose outlet 55 is formed between them. ing.

Inside the hose storage portion 44, the hose 54 having the nozzle 56 attached to the tip thereof is stored in an inwardly wound state, and the nozzle 56 attached to the tip of the hose is arranged in the central portion of the internally wound hose 54. The nozzle 56 can be taken out from either the front surface or the back surface of the hose.

Further, in the hose storage unit 44, the water discharge switch 38a for opening the electric valve by operating the water discharge control mechanism provided in the control mechanism storage unit 45 arranged in the management passage 20 and the electric valve are closed. A water discharge stop switch 38b is provided.

As the elevating mechanism of the hose accommodating portion 44, the piston cylinder elevating mechanism 46a is provided. In the piston cylinder elevating mechanism 46a, the hydraulic cylinder 60 is arranged upright in the center of the rectangular bottom of the hose storage portion 44, and the hydraulic cylinder 60 has a piston rod 63 connected to a piston 61 slidably provided in the cylinder. It is taken out upward, and the tip of the piston rod 63 is fixed to the bottom of the hose storage portion 44.

A control mechanism storage unit 45 is arranged in the management passage 20 below the fire hydrant storage box 25, and in the control mechanism storage unit 45, valves that supply fire extinguishing water to the hose 54 of the hose storage unit 44 and discharge the water. A water discharge control mechanism is provided, and an elevating control mechanism including valves for elevating and driving the piston cylinder elevating mechanism 46a is provided.

A branch pipe 24a branched from the water supply main 24 that functions as a water pressure source is connected to the control mechanism storage unit 45, and fire extinguishing water supplied from the fire extinguishing pump equipment to the water supply main 24 is introduced.

The water supply pipe 58 raised inside the fire hydrant storage box 25 from the water discharge control mechanism built in the control mechanism storage unit 45 is connected via the pipe 80 by a fixing member 82 on the outside of the hydraulic cylinder 60 in the vertical direction. It is connected to the pipe 64.

A universal joint 90 is provided on the upper end side of the connecting pipe 64 fixed to the hydraulic cylinder 60 via the pipe 86, and is flexible between the universal joint 92 provided at the hose connection port of the hose storage portion 44. It is connected by the connecting hose 88 of.

The connecting hose 88 has a predetermined hose length required to move the hose accommodating portion 44 to the exposed position by the piston cylinder elevating mechanism 46a, whereby the hose accommodating portion 44 moves up and down with respect to the connecting pipe 64 on the fixed side. Even so, the hose storage portion 44 can be moved without disconnecting the connecting hose 88.

Further, the connecting hose 88 is not directly connected to the water supply pipe 58 raised in the fire extinguishing plug storage box 25, and the water supply pipe 58 is connected to the connecting pipe 64 fixed to the outside of the cylinder 60 via the pipe 80. By connecting the connecting hose 88 to the upper end side of the connecting pipe 64, the shortest hose length is a predetermined hose length required to move the hose storage portion 44 to the exposed position.

Further, the lateral movement of the connecting hose 88 caused by the elevating operation is absorbed by the movements of the universal joints 90 and 92, the extreme bending of the connecting hose 88 is suppressed, and the elevating operation of the hose storage portion 44 is not hindered. I have to.

A pipe 59 for supplying and draining fire extinguishing water is connected to the hydraulic cylinder 60 of the piston cylinder elevating mechanism 46a from the elevating control mechanism built in the control mechanism accommodating portion 45.

Here, the number of hydraulic cylinders 60 provided in the piston cylinder elevating mechanism 46a can be appropriately set, for example, four hydraulic cylinders are arranged at the corners of the bottom of the hose storage portion 44. May be.

The piston cylinder elevating mechanism 46a is hydraulically driven, but is not limited to this, and may be hydraulically driven.

[Operation of piston cylinder elevating mechanism fire hydrant equipment]
(During normal monitoring)
During normal monitoring when a vehicle is passing through the road of the tunnel 10 shown in FIG. 1, as shown in FIG. 3, the hose storage portion 44 of the fire hydrant storage box 25 is provided with water discharge in the control mechanism storage portion 45. Since the supply of fire extinguishing water from the control mechanism is stopped, the hydraulic cylinder 60 of the piston cylinder elevating mechanism 46a positions the piston 61 at the lowest point, whereby the piston cylinder elevating mechanism 46a puts the hose accommodating portion 44 into a fire hydrant. Even if the fire hydrant entrance 42 is closed by the road surface plate 50 on the upper surface of the housing 48 and the fire hydrant equipment 16 is installed in the observer passage 14, the observer passage 14 is stored in the storage box 25. It does not obstruct or pose a danger to passers-by.

(In case of fire)
On the other hand, when a vehicle accident accompanied by a fire occurs in the tunnel 10, the user goes to the fire hydrant facility 16 near the place where the fire occurred and pushes the transmitter 32 of the reporting device panel 28 to fire the disaster prevention receiving panel of the monitoring center. A notification signal is transmitted, a confirmation response signal is received from the disaster prevention receiving panel, the response lamp 34 is turned on, and the red indicator lamp 30 is blinked to confirm the completion of the notification to the monitoring center side.

Subsequently, in order to extinguish the fire, when the ascending switch 36a provided on the notification device panel 28 is pressed and turned on, fire extinguishing water is sent from the control mechanism storage unit 45 to the hydraulic cylinder 60 of the piston cylinder elevating mechanism 46a and into the cylinder. The supplied fire extinguishing water raises the piston 61 and pushes up the hose storage portion 44 supported via the piston rod 63.

Therefore, the road surface plate 50 closing the fire hydrant elevating port 42 of the fire hydrant storage box 25 is lifted, the hose storage portion 44 stored inside slowly appears from the road surface, rises to the exposed position shown in FIG. 4, and stops. , Hold this exposed position.

At this time, as the hose storage portion 44 rises, the distance from the connecting pipe 64 fixed to the outside of the cylinder 60 to which the connecting hose 88 is connected becomes longer, but the connecting hose 88 is held in the exposed position. Since the hose has a predetermined hose length that is equal to or longer than the distance from the lower surface of the 44 to the upper end of the connecting pipe 64, a connected state with some slack is obtained, and the connection between the connecting pipe 64 and the hose 54 is reliably maintained.

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

Subsequently, when the user presses the water discharge switch 38a provided in the exposed hose storage unit 44 to turn it on, a water discharge start signal is output to the water discharge control mechanism of the control mechanism storage unit 45, and the fire extinguishing water is connected to the water supply pipe 58. It is supplied to the hose 54 via the hose 88, and the fire can be extinguished by discharging water from the nozzle 56.

On the other hand, when the user extinguishes a fire from the observer passage 14 side, the nozzle 56 can be easily taken out from the back opening of the housing 48 in the hose storage portion 44 exposed and held on the observer passage 14. The hose 54 can be easily pulled out to extinguish the fire.

When the fire is extinguished and the fire extinguishing work is completed, the water discharge stop switch 38b provided in the hose storage unit 44 is pressed to turn it on, and a water discharge stop signal is output to the water discharge control mechanism of the control mechanism storage unit 45, and the nozzle 56 Water discharge from is stopped.

Further, in the restoration work after the fire extinguishing work is completed, after draining the hose 54, the hose 54 is stored in the hose storage portion 44 exposed and held on the observer passage 14 in an inwardly wound state. .. Subsequently, by turning on the lowering switch 36b provided on the notification device panel 28, the hose storage portion 44 is lowered by the piston cylinder elevating mechanism 46a, and the road surface plate 50 is lowered to the position where the fire hydrant elevating port 42 is closed. Then, the hose storage unit 44 is stored in the fire hydrant storage box 25.

[Fire hydrant equipment using pantograph elevating mechanism]
FIG. 5 is an explanatory view showing an embodiment in which the connecting pipe is fixed to the pantograph elevating mechanism in a cross section seen from the road side, and FIG. 6 shows the hose storage portion of FIG. 5 being raised by the elevating mechanism and exposed on the observer passage. It is explanatory drawing which showed the state in which it was made in the cross section seen from the road surface side.

As shown in FIG. 5, in the present embodiment, the pantograph elevating mechanism 46b is provided as the elevating mechanism.

The pantograph elevating mechanism 46b is composed of four link arms 74a to 74d. The link arms 74a to 74d are schematically shown.

The left end of the link arm 74a is rotatably supported by the fulcrum 76a on the base 75a, and the right end of the link arm 74b is slidably supported along the base 75a by the slider 78b. It is crossed at and connected rotatably at the fulcrum 76c.

The left end of the link arm 74c is rotatably connected to the right end of the link arm 74a by the fulcrum 76c, and the right end of the link arm 74d is rotatably connected to the left end of the link arm 74b by the fulcrum 76c. 74c and 74d are crossed at the center and rotatably connected at the fulcrum 76c.

Further, the right end of the link arm 74c is slidably connected to the mounting base 75b by the slider 78a, and the left end of the link arm 74d is rotatably supported along the mounting base 75b by the fulcrum 76b.

As a drive mechanism for the pantograph elevating mechanism 46b, a piston cylinder mechanism is provided, the lower end of the cylinder 60 is rotatably connected to the link arm 74b by a fulcrum 82a, and the piston 61 slidably provided in the cylinder 60. The tip of the connected piston rod 63 is rotatably connected to the link arm 74c by a fulcrum 82b.

The connecting pipe 64a divided along the link arm 74a is fixed to the pantograph elevating mechanism 46b, and the connecting pipe 64b divided along the link arm 74c is fixed to the pantograph elevating mechanism 46b.

The water supply pipe 58 raised from the control mechanism accommodating portion 45 is connected to the left end of the connecting pipe 64a fixed to the link arm at the lower end by the flexible connecting hose 66. Further, the right end of the connecting pipe 64a and the right end of the connecting pipe 64b are also connected by a flexible connecting hose 68. Further, a hose 54 stored in the hose storage portion 44 is connected to the left end of the connecting pipe 64b.

As described above, in the present embodiment, the connecting hose 66 is flexible for connecting the inlets of the connecting pipes 64a and 64b which are divided and fixed to the link arms 74a and 74d of the pantograph elevating mechanism 46b and the connecting portion. , 68 is only used, the connection interval of the connecting hoses 66 and 68 hardly changes with respect to the movement of the pantograph elevating mechanism 46b, and the connecting hoses 66 and 68 used can be minimized.

Since the other configurations and functions are the same as those of the embodiment of FIG. 3, the description thereof will be omitted.

[Operation of fire hydrant equipment using pantograph elevating mechanism]
(During normal monitoring)
During normal monitoring when a vehicle is passing through the road of the tunnel 10 shown in FIG. 1, as shown in FIG. 5, the hose storage unit 44 of the fire hydrant equipment 16 is provided with a water discharge control unit in the control mechanism storage unit 45. Since the supply of fire extinguishing water from the mechanism is stopped, the hydraulic cylinder 60 of the pantograph elevating mechanism 46b positions the piston 61 at the lowest point, whereby the pantograph elevating mechanism 46b descends by folding the link arms 74a to 74d. At the position, the hose storage unit 44 is housed in the internal space of the observer passage 14, the fire hydrant elevating port 42 is closed by the road surface plate 50 on the upper surface of the housing 48, and the fire hydrant equipment 16 is installed in the observer passage 14. Even if it is installed, it does not obstruct or pose a danger to people passing through the observer passage 14.

(In case of fire)
On the other hand, when a vehicle accident accompanied by a fire occurs in the tunnel 10, the ascending switch 36a provided on the reporting device panel 28 is pressed in order to extinguish the fire after performing a fire reporting operation to the monitoring center side. When turned on, fire extinguishing water is sent from the control mechanism storage unit 45 to the hydraulic cylinder 60 of the pantograph elevating mechanism 46b, the piston 61 is raised by the fire extinguishing water supplied into the cylinder, and is linked to the link arm 74b via the piston rod 63. The distance between the arms 74c is widened.

When the distance between the link arms 74b and 74c is widened, the angles of the link arms 74b and 74c widen around the fulcrum 76c, and in conjunction with this, the angles of the link arms 74a and 74d also widen around the fulcrum 76d. The sliders 78b and 78a at the left ends of the 74b and 74c slide to the left, and the hose storage portion 44 mounted on the mounting base 75b is pushed up.

For this reason, the road surface plate 50 closing the fire hydrant elevating port 42 of the observer passage 14 is lifted, the hose storage portion 44 stored inside slowly appears from the road surface, rises to the exposed position shown in FIG. 6, and stops. , Hold this exposed position.

With the ascending drive of the hose storage portion 44 by the pantograph elevating mechanism 46b, the connecting pipes 64a and 64b fixed to the link arms 74a and 74d also maintain the connection between the water supply pipe 58 and the hose storage portion 44. Will be moved.

When the hose storage portion 44 is held on the observer passage 14 in an exposed state, the user can easily and easily pull out the hose 54 by taking out the nozzle 56 from the road side through the front opening of the housing 48. You can extinguish the fire.

In the restoration work after the fire is extinguished and the fire extinguishing work is completed, after draining the hose 54, the hose 54 is wound inward in the hose storage portion 44 exposed and maintained on the observer passage 14. To store. Subsequently, by turning on the lowering switch 36b provided on the notification device panel 28, the hose storage portion 44 is lowered by the pantograph elevating mechanism 46b, and the road surface plate 50 is lowered to the position where the fire hydrant elevating port 42 is closed. The hose storage unit 44 is stored in the internal space of the observer passage 14.

[Other embodiments of fire hydrant equipment using a pantograph elevating mechanism]
FIG. 7 is an explanatory view showing another embodiment in which the connecting pipe is fixed to the pantograph elevating mechanism in a cross section seen from the road side.

As shown in FIG. 7, in the present embodiment, the connecting pipe 64 is fixed from the link arm 74a on the lower end side of the pantograph elevating mechanism 46b to the link arm 74c on the upper end side, and is raised from the control mechanism storage unit 45. The water supply pipe 58 is connected to the left end of the connecting pipe 64 fixed to the link arm 74a at the lower end by the flexible connecting hose 66. Further, a hose 54 stored in the hose storage portion 44 is connected to the right end of the connecting pipe 64.

As described above, in the present embodiment, only the flexible connecting hose 66 is used for connecting the inlet of the connecting pipe 64 fixed to the link arm 74a of the pantograph elevating mechanism 46b, and the connecting hose 66 is used. The connection interval of the pantograph elevating mechanism 46b hardly changes with respect to the movement of the pantograph elevating mechanism 46b, and the connecting hose 66 to be used can be minimized.

Since the other configurations and functions are the same as those of the embodiment of FIG. 5, the description thereof will be omitted.

[Modified example of the present invention]
(Drive mechanism)
The above embodiment uses, but is not limited to, a hydraulic cylinder driven by hydraulic pressure or hydraulic pressure as the drive mechanism of the pantograph elevating mechanism 46b. For example, a screw shaft rotated by a motor is screwed by providing a screw hole in a member connecting a slider 78b provided at the right end of the link arm 74b, and the slider 78b is slid to the left by the rotation of the screw shaft. The pantograph elevating mechanism 46b may be driven to extend upward, or the slider 78b may be slid to the right by the reverse rotation of the screw shaft to drive the pantograph elevating mechanism 46b to contract downward.

(Fire hydrant equipment)
The hoses of the fire hydrant equipment, valves such as the fire hydrant valve, the configuration and arrangement of the notification device, and other configurations shown in the above embodiment are arbitrary, and an appropriate configuration may be adopted.

(others)
Further, 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.

10: Tunnel 12: Tunnel wall surface 14: Observer passage 15: Road 16: Fire hydrant equipment 18: Floor slab 20: Management passage 22: Duct 24: Water supply main 24a: Branch pipe 25: Fire hydrant storage box 26: Inspection door 30 : Red indicator 32: Transmitter 34: Response lamp 36a: Up switch 36b: Down switch 42: Fire hydrant elevating port 44: Hose storage unit 45: Control mechanism storage unit 46a: Piston cylinder elevating mechanism 46b: Pantograph elevating mechanism 48: Body 50: Road surface plate 54: Hose 55: Hose outlet 56: Nozzle 60: Hydraulic cylinder 66, 68, 88: Connecting hoses 64, 64a, 64b: Connecting pipes 74a to 74d: Link arm 75a: Base 75b: Mounting base 76a-76c, 82a, 82b: fulcrum 78a, 78b: slider

Claims (14)

A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When using a fire hydrant, an elevating mechanism that raises the hose storage unit and holds it in a predetermined exposed position on the road surface of the observer passage.
A water discharge control mechanism that is installed separately from the hose storage unit and supplies fire extinguishing water to the hose of the hose storage unit to discharge water.
In the fire hydrant equipment in the tunnel equipped with
A part of the pipe extending from the water discharge control mechanism toward the hose storage portion to a predetermined position on the upper part of the elevating mechanism on the hose storage portion side is fixed to the elevating mechanism, and is fixed to the hose storage portion side of the pipe. A fire hydrant facility in a tunnel, characterized in that an upper end thereof and the hose storage portion are connected by a flexible connecting hose.
In the fire hydrant equipment in the tunnel according to claim 1.
The elevating mechanism is a piston cylinder elevating mechanism that elevates and elevates the hose storage portion by controlling the supply and discharge of hydraulic pressure.
A fire hydrant facility in a tunnel, characterized in that a part of the pipe is fixed to the outside of the cylinder in the piston cylinder elevating mechanism.
In the in-tunnel fire hydrant equipment according to claim 1 or 2.
The connecting hose is a fire hydrant facility in a tunnel, characterized in that the hose accommodating portion has a predetermined hose length capable of rising to the exposed position.
In the fire hydrant equipment in the tunnel according to any one of claims 1 to 3.
A tunnel fire hydrant facility characterized in that a universal joint is provided at a connection portion between the connecting hose and the hose of the hose storage portion, or at a connection portion between the connecting hose and the pipe.
A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When using a fire hydrant, an elevating mechanism that raises the hose storage unit and holds it in a predetermined exposed position on the road surface of the observer passage.
A water discharge control mechanism that is installed separately from the hose storage unit and supplies fire extinguishing water to the hose of the hose storage unit to discharge water.
In the fire hydrant equipment in the tunnel equipped with
The elevating mechanism is a pantograph elevating mechanism that is expanded and contracted in the vertical direction, which is the elevating direction by the drive mechanism.
Piping is fixed along a predetermined link arm from the lower end of the link arm located at the lower part of the pantograph elevating mechanism to the upper end of the link arm located at the upper part of the pantograph elevating mechanism.
A flexible connecting hose was connected between the pipe extending from the water discharge control mechanism toward the lower end of the link arm located at the lower portion and the lower end of the pipe fixed to the link arm located at the lower portion. Fire hydrant equipment in the tunnel, which is characterized by this.
In the fire hydrant equipment in the tunnel according to claim 5.
The fixing of the pipe to the predetermined link arm is divided and fixed for each link arm.
An in-tunnel fire hydrant characterized in that the upper end of a pipe fixed to a link arm located at the lower portion and the lower end of a pipe fixed to a link arm located at the upper portion are connected by a flexible connecting hose. Facility.
In the in-tunnel fire hydrant equipment according to claim 5 or 6.
The drive mechanism of the pantograph elevating mechanism shall be a piston cylinder mechanism that expands and contracts the pantograph up and down by controlling the supply and discharge of hydraulic pressure, or a screw shaft drive mechanism that expands and contracts the pantograph up and down by the rotation of the screw shaft by the motor. Fire extinguishing equipment in the tunnel featuring.
A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When the hose storage unit uses a fire hydrant in the installed state, an elevating mechanism that raises the hose storage unit and holds it at a predetermined exposed position on the road surface of the observer passage.
A water discharge control mechanism that is installed separately from the hose storage unit and supplies fire extinguishing water to the hose of the hose storage unit to discharge water.
In a tunnel fire hydrant device equipped with
In the installed state, a part of the pipe extending from the water discharge control mechanism toward the hose storage portion to a predetermined position on the upper part of the elevating mechanism on the hose storage portion side is fixed to the elevating mechanism. A fire hydrant device in a tunnel, characterized in that an upper end on the hose storage portion side and the hose storage portion are connected by a flexible connecting hose.
In the tunnel fire hydrant device described in claim 8,
The elevating mechanism is a piston cylinder elevating mechanism that elevates and elevates the hose storage portion by controlling the supply and discharge of hydraulic pressure.
A fire hydrant device in a tunnel, characterized in that a part of the pipe is fixed to the outside of the cylinder in the piston cylinder elevating mechanism.
In the in-tunnel fire hydrant device according to claim 8 or 9.
The connecting hose is a fire hydrant device in a tunnel, wherein the hose accommodating portion has a predetermined hose length capable of rising to the exposed position in the installed state.
In the in-tunnel fire hydrant device according to any one of claims 8 to 10.
A tunnel fire hydrant device characterized in that a universal joint is provided at a connection portion between the connecting hose and the hose of the hose storage portion, or at a connection portion between the connecting hose and the pipe.
A hose storage unit that is installed up and down inside the guard passage provided along the tunnel wall surface and that allows the hose with a nozzle to be pulled out and stored.
When the hose storage unit uses a fire hydrant in the installed state, an elevating mechanism that raises the hose storage unit and holds it at a predetermined exposed position on the road surface of the observer passage.
A water discharge control mechanism that is installed separately from the hose storage unit and supplies fire extinguishing water to the hose of the hose storage unit to discharge water.
In a tunnel fire hydrant device equipped with
The elevating mechanism is a pantograph elevating mechanism that is expanded and contracted in the vertical direction, which is the elevating direction by the drive mechanism.
Piping is fixed along a predetermined link arm from the lower end of the link arm located at the lower part of the pantograph elevating mechanism to the upper end of the link arm located at the upper part of the pantograph elevating mechanism.
In the installed state, a flexible connection is made between the pipe extending from the water discharge control mechanism toward the lower end of the link arm located at the lower portion and the lower end of the pipe fixed to the link arm located at the lower portion. An in-tunnel fire hydrant device characterized by being connected by a hose.
In the in-tunnel fire hydrant device according to claim 12,
The fixing of the pipe to the predetermined link arm is divided and fixed for each link arm.
An in-tunnel fire hydrant characterized in that the upper end of a pipe fixed to a link arm located at the lower portion and the lower end of a pipe fixed to a link arm located at the upper portion are connected by a flexible connecting hose. Device.
In the in-tunnel fire hydrant device according to claim 12 or 13.
The drive mechanism of the pantograph elevating mechanism shall be a piston cylinder mechanism that expands and contracts the pantograph up and down by controlling the supply and discharge of hydraulic pressure, or a screw shaft drive mechanism that expands and contracts the pantograph up and down by the rotation of the screw shaft by the motor. A fire hydrant device in a tunnel featuring.

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