JP7407991B2 - Fire hydrant equipment and fire hydrant equipment - Google Patents

Description

The present invention relates to a fire hydrant device in which a fire hose is housed, and a fire hydrant facility in which the fire hydrant device is installed.

Conventionally, fire hydrant devices have been installed as tunnel emergency equipment in tunnels such as expressways and motorways.The fire hydrant device is equipped with a fire hydrant door that can be opened freely, and a hose with a nozzle attached to the tip and a fire hydrant valve. Contains valves, including valves.

Fire hydrant devices are generally installed embedded in the tunnel wall surface at intervals of, for example, 50 meters along the tunnel side wall. In the event of a vehicle accident involving a fire, in tunnels with a lifeguard passageway, road users such as the driver of the accident vehicle should climb onto the lifeguard passageway using steps installed on the side of the lifeguard passageway and climb up the tunnel. The fire hydrant door of the fire hydrant device installed on the wall is opened forward and a hose with a nozzle is taken out to extinguish the fire.

The observer passageway is built as a sidewall passageway raised above the road surface, making it possible to safely inspect various equipment installed inside the tunnel, including fire hydrant systems, without interfering with vehicle traffic inside the tunnel. .

In addition, in tunnels without lifeguard passageways, users such as the driver of the accident vehicle should approach the fire hydrant device installed on the tunnel wall, open the fire hydrant door forward, and install the hose with a nozzle. We are trying to take out the fire and extinguish the fire.

Japanese Patent Application Publication No. 2006-181057 Japanese Patent Application Publication No. 2008-055024 JP2009-285126A

By the way, urban tunnels made using the shield method etc. have a structure that does not allow the installation of a fire hydrant device embedded in the tunnel wall, and it is necessary to install the fire hydrant device embedded in the side (wall surface) of the lifeguard passage.

However, when a fire hydrant device with a door that opens forward like a conventional fire hydrant is installed in a lifeguard passageway, there is a problem that when the fire hydrant door opens, the fire hydrant exceeds the building limit and protrudes onto the road.

To solve this problem, we installed a fire hydrant storage box embedded in the lifeguard passage, installed a front door that slides open and close facing the road, and installed an upper door that opens and closes upward on the lifeguard passage. A fire hydrant storage box has been proposed.

According to the fire hydrant storage box embedded in the lifeguard passage, in the event of a fire caused by a vehicle accident, users can easily and easily remove the nozzle from the hose storage area by opening the front door facing the road. You can extinguish a fire by pulling out the attached hose. In addition, if a vehicle is stopped in front of a fire hydrant system and operation from the front door is not possible, by opening the upper door of the lifeguard passage, the hose with a nozzle can be pulled out to extinguish the fire without being obstructed by the stopped vehicle. It can be carried out.

By the way, the width of the fire hydrant storage box installed embedded in the lifeguard passage is about 0.7 meters, and the width of the fire hydrant storage box is narrow, for example, about 0.35 meters, half of the lifeguard passage. The fire hydrant storage box stores about 30 meters of hose wrapped horizontally inside.

Further, as shown in the schematic diagrams of FIGS. 23(A) and 23(B), a foam nozzle 204 attached to the tip of a hose 202 stored in a fire hydrant storage box 200 is installed horizontally on the back surface of an upper door 206. A structure in which the nozzle holder 208 is fitted horizontally and removably locked is being considered.

However, when the fire hydrant storage box 200 is installed embedded in the lifeguard passage, it is assumed that it will be operated from the road side or from the road side of the lifeguard passage, and the position of the user who operates it and the exposed The positional relationship with the position of the foam nozzle 204 latched to the nozzle holder 208 differs depending on the operating position, and the position from which the foam nozzle 204 can be easily taken out differs depending on the user's position. Therefore, depending on the position where the foam nozzle 204 is locked, it may take time to take out the foam nozzle 204 from the operating position.

The present invention provides a fire hydrant device that makes it easy and stable to store a fire hose and allows the fire hose to be easily and easily taken out from the road side and the road side of a lifeguard passage, and a fire hydrant equipped with the fire hydrant device. The purpose is to provide facilities.

(Fire hydrant device)
The present invention provides a fire hydrant device in which a fire hose is housed,
A guide member is provided extending in the vertical direction of the fire hydrant device at a predetermined interval from the front side to the rear side inside the fire hydrant device,
When the fire hose is stored, the fire hose is wound so that its periphery is stacked upward from the bottom of the fire hydrant device, and a part of the front side of the fire hydrant device on the outer periphery is stacked against the guide member from the rear side. It is characterized in that it is housed inside the fire hydrant device so as to form a recessed portion with respect to the front surface of the fire hydrant device by coming into contact with the fire hydrant device.

(Second guide member)
A second guide member is provided on the front side of the interior of the fire hydrant device and extends in the vertical direction of the fire hydrant device,
The fire hose is housed so as to come into contact with the second guide member from the rear side.

(Multiple guide members provided)
A plurality of guide members and second guide members are provided.

(upper door)
A nozzle is attached to the end of the fire hose,
An upper door is provided in the opening formed at the top of the fire hydrant device located above the stored fire hose,
The upper door can be opened so that the nozzle is operably exposed from the outside of the hydrant device on the front side.

(hose guide)
A hose guide is provided in an opening formed above the housed fire hose in the front of the fire hydrant device to support and guide the fire hose from below when the fire hose is pulled out from the opening.

(Fire hydrant equipment)
The present invention is a fire hydrant equipment comprising a fire hydrant embedded part that is an internal space under the road surface of a lifeguard passage along a tunnel wall surface in a tunnel,
The above-described fire hydrant device is characterized in that the fire hydrant device is embedded in the fire hydrant embedding part so that the upper surface is exposed to the road side of the lifeguard passage and the front surface is exposed to the road side.

(basic effect)
The present invention provides a fire hydrant device in which a fire hose is housed, in which a guide member extends in the vertical direction of the fire hydrant device at a predetermined interval from the front side to the rear side of the inside of the fire hydrant device. When the fire hose is stored, the fire hose is wound so that the periphery is stacked upward from the bottom of the fire hydrant device, and a part of the outer peripheral part of the front side of the fire hydrant device is attached to the guide member. On the other hand, by coming into contact with the fire hydrant from the rear side, the fire hose is stored inside the fire hydrant system so as to form a recess against the front surface of the fire hydrant system, so the fire hose stored inside the fire hydrant system has no tendency to spread outward. A repulsive force is generated to prevent the stacked storage state from collapsing.

(Effect of upper door)
In addition, a nozzle is attached to the tip of the fire hose, and an upper door is provided in the opening formed at the top of the fire hydrant device located above the stored fire hose. Since the fire hydrant device can be opened so that it can be operated from outside, the nozzle appears right in front of the user when operating from the front side of the fire hydrant device, and the nozzle can be easily and easily taken out and removed from the fire hose. It is possible to bring out the

(Effect of hose guide)
In addition, a hose guide is provided in the opening formed above the stored fire hose in the front of the fire hydrant device to support and guide the fire hose from below when the fire hose is pulled out from the opening. This makes it possible to simply and easily pull out the fire hose with the assistance of the hose guide.

An explanatory diagram showing tunnel emergency equipment, including fire hydrant equipment, installed inside a tunnel on a motorway. An explanatory diagram showing the appearance of the fire hydrant storage box during normal times An explanatory diagram showing the external appearance of the fire hydrant storage box in Figure 2 from the front and from the top. An explanatory diagram showing the external appearance of the fire hydrant storage box in Figure 2 from the side. Explanatory diagram showing the front-opening handle part of a fire hydrant storage box equipped with a front-opening mechanism An explanatory diagram showing the mechanical structure of the front-opening mechanism that opens the second upper door forward and slides it open when the front door falls. Explanatory diagram showing the internal structure of a fire hydrant storage box Explanatory diagram showing the opening operation of the front door and second upper door when operating from the road side Explanatory diagram showing the opening operation of the first upper door when operating from the observer passage side An explanatory diagram showing the first embodiment of the nozzle holder with the upper door closed. An explanatory diagram showing the suspended state of the foam nozzle by the nozzle holder of the first embodiment when the second upper door is opened in the front and the first upper door is opened in the rear. Explanatory diagram showing a second embodiment of the nozzle holder Explanatory diagram showing a third embodiment of the nozzle holder An explanatory diagram showing the suspended state of the foam nozzle by the nozzle holder of the third embodiment when the second upper door is in the front-opening state and the first upper door is in the backward-opening state. Explanatory diagram showing the nozzle holder of the third embodiment viewed from the front An explanatory diagram showing the nozzle holder of the third embodiment viewed from the side An explanatory diagram showing the nozzle holder of the third embodiment viewed from the side with some of the holder members rotated around the vertical axis An explanatory diagram showing the nozzle holder of the fourth embodiment viewed from the front An explanatory diagram showing the nozzle holder of the fourth embodiment viewed from the side Explanatory diagram showing another embodiment of the door structure in the fire hydrant storage box An explanatory diagram showing the opening operation of the front door and upper door when operating the fire hydrant storage box of Fig. 13 from the road side. An explanatory diagram showing the opening operation of the upper door when operating the fire hydrant device in Figure 13 from the lifeguard passage side. Explanatory diagram showing the nozzle holder being considered

[Overview of tunnel emergency equipment]
FIG. 1 is an explanatory diagram showing tunnel emergency equipment including fire hydrant equipment installed in a tunnel of a motorway. As shown in FIG. 1, the inside of a tunnel 10 constructed by the shield construction method is covered with a cylindrical tunnel wall surface 12 and partitioned by a floor slab 18 to provide a road 15. In this example, Road 15 has two lanes in each direction.

A lifeguard passageway 14 is provided along the tunnel wall surface 12 on the left side of the road 15 divided by a floor slab 18, and the internal space below the lifeguard passageway 14 is used as a duct 22, in which electrical conduits and the like are laid. . The lifeguard passageway 14 has dimensions of, for example, 90 centimeters in height and 70 centimeters in width.

The lower side of the floor slab 18 on which the road 15 is formed is partitioned into a plurality of sections in the tunnel lateral direction. For example, the section located below the lifeguard passage 14 is used as a management passage 20, and The management passage 20 is used as an emergency evacuation passage when a fire breaks out in the tunnel. A water supply main pipe 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 equipment 16 is installed separately into a fire hydrant storage box 30 in which a hose is stored and a water discharge control mechanism storage part 26. .

The fire hydrant storage box 30 is arranged in a fire hydrant embedded part hollowed out in a box shape over the road surface of the lifeguard passageway 14 and the wall surface on the road 15 side. The water discharge control mechanism storage section 260 is disposed in the management passage 20 below the fire hydrant storage box 30, into which a branch pipe 24a branched from the water supply main pipe 24 is drawn, and also supplies fire extinguishing water to the fire hydrant storage box 30. A water supply pipe 25 has been set up.

[Fire hydrant equipment]
Figure 2 is an explanatory diagram showing the external appearance of the fire hydrant storage box in normal conditions, Figure 3 is an explanatory diagram showing the external appearance of the fire hydrant storage box in Figure 2 from the front and plane, and Figure 4 is an explanatory diagram showing the external appearance of the fire hydrant storage box in Figure 2. It is an explanatory view shown from the side.

(External structure of fire hydrant storage box)
As shown in FIGS. 2 to 4, the fire hydrant storage box 30 of the fire hydrant equipment 16 is embedded in an internal space under the road surface of the lifeguard passageway 14. The fire hydrant storage box 30 has a front door 32 disposed in a front door opening 33 formed above the front center of a housing 31 so as to be slidable in the vertical direction.

Further, a first upper door 34 having the same width as the front door 32 is disposed in a first upper door opening 35 formed at the center of the upper surface of the fire hydrant storage box 30 facing the road surface of the lifeguard passageway 14. Furthermore, a second upper door opening 37 is formed at the center of the front side of the first upper door 34, and a second upper door 36 is disposed therein.

The first upper door 34 is pivotally supported on both sides of the door front edge by hinges 46 arranged at the front edge corners of the upper part of the housing 31. As shown in the first upper door 34a in FIG. It is designed to open at the back, opening upwards with the center at the center.

The rear edge of the second upper door 36 is pivotally supported on the second upper door opening 37 of the first upper door 34 by a hinge 42, and as shown in the second upper door 36a in FIG. The front opening opens upwards.

A front-opening handle 38 is pivotally supported on the front edge of the second upper door 36 by a hinge 44, and a front-opening mechanism provided on the handle body of the front-opening handle 38 allows the second upper door 36 to be opened in the closed state. When the front door 32 is locked in the closed state shown in the figure and the user operates it from the road 15 side, when the front opening handle 38 is opened, the front door 32 is locked to the second upper door 36. When released, the front door 32 falls to the back side of the housing 31 due to its own weight, opening the front door opening 33, and by opening the second upper door 36 forward, the second upper door opening of the fire hydrant storage box 30 is opened. 37 is opened.

Here, the hinge 46 that pivotally supports the first upper door 34 on the front edge corner of the casing 31 and the hinge 44 that pivotally supports the front opening handle 38 on the front edge of the second upper door 36 are arranged so that their axes are centered. The front-opening handle 38, which is arranged so that the lines are coaxial and locks the housing 31 and the front door 32 in the closed position, is the fixed side, and the hinges 44 and 46 are used to open the first door together with the second upper door 36. The upper door 34 is pivotally supported so that it can be opened rearward.

A notification device panel 48 is provided on the upper left front side of the fire hydrant storage box 30. The reporting device panel 48 is provided with a red indicator light 50, a transmitter 52, a response lamp 54, and a telephone jack 55. The red indicator light 50 is always on, so that the installation location of the fire hydrant equipment can be seen from a distance. In the event of a fire, when the transmitter 52 is pressed and the push button switch is turned on, the outgoing signal is sent to the disaster prevention receiver installed in the monitoring center of the monitoring room and a fire alarm is issued. , the response lamp 54 is lit, and the red indicator lamp 50 is blinked.

[Front opening mechanism]
FIG. 5 is an explanatory diagram showing the front-opening handle portion of a fire hydrant storage box equipped with a front-opening mechanism, with FIG. 5(A) showing the front and FIG. 5(B) The side view seen from XX is shown. FIG. 6 is an explanatory diagram showing the mechanical structure of the front-opening mechanism that opens the second upper door and slides it open when the front door falls. FIG. 6(A) shows the closed state, and FIG. 6(B) indicates the state in which the front opening handle is opened.

As shown in FIG. 5, on both sides of the handle body 38a of the front-opening handle 38, which is pivotally supported by a hinge 44 at the tip of the second upper door 36 disposed on the top surface of the fire hydrant storage box 30, there are shafts of the front-opening mechanism. The member 56 has been taken out, and when the second upper door 36 is closed, the tip of the shaft member 56 is inserted into the shaft hole of the bearing member 58 arranged on the back side of the front door 32, so that the second upper door 36 is closed. The front door 32 is locked to 36 and held in the closed position.

When the front-opening handle 38 is lifted up, the shaft member 56 is pulled inward, and by coming out of the shaft hole of the bearing member 58, the locking of the front door 32 is released, and the front door 32 slides and falls due to its own weight. to open the front door opening 33.

As shown in FIG. 6(A), the front opening mechanism 60 has one end of a pair of bent links 62 connected at a movable fulcrum 64 in the handle body 38a, and the bent position of the link 62 serves as a rotation fulcrum 66 for the handle. The link 62 is fixed to the main body 38a side, and the other end of the link 62 is connected to a fulcrum 68 at the end of the shaft member 56 as a slide fulcrum 70, and the movable fulcrum 64 is biased upward as shown in the figure by a spring 72. ing.

When the front-opening handle 38 is not operated, the link 62 rotates outward under the force of the spring 72, fitting the shaft member 56 into the shaft hole 58a of the bearing member 58, and opening the second upper door 36. The front door 32 is locked in place.

When the front-opening handle 38 is lifted up, the moving fulcrum 64 moves downward against the spring 72 via a link mechanism (not shown), as shown in FIG. 6(B), and the link 62 rotates inward. By moving and pulling the shaft member 56 inward, the tip of the shaft member 56 is removed from the shaft hole 58a of the bearing member 58, the front door 32 is unlocked, and the front door 32 slides and falls due to its own weight. to open the front door opening 33.

Note that the front opening mechanism 60 is not limited to the link mechanism shown in FIG. 6, but includes any appropriate link mechanism that draws the shaft member 56 inward and pulls it out from the shaft hole 58a of the bearing member 58 by lifting up the front opening handle 38. .

[Internal structure of fire hydrant storage box]
FIG. 7 is an explanatory diagram showing the internal structure of the fire hydrant storage box, with FIG. 7(A) showing the front and FIG. 7(B) showing a plane seen from the YY cross section of FIG. 7(A).

As shown in FIG. 7, the inside lower side of the casing 31 in the fire hydrant storage box 30 is a hose storage section 74, in which hoses 76 having a shape-retaining structure are horizontally stacked and wound inward.

The rectangle seen from the plane of the housing 31 has a width of about 1.4 meters and a depth of about 0.35 meters. The shape is a rounded rectangle consisting of two parallel lines and two semicircles, and the length of one turn of the hose 76 wound inside the planar rectangular housing 31 is approximately 3.5 meters. Since the length is required to be 30 meters or more, the hose 76 may be wound inward by overlapping nine turns or more.

Here, the hose 76 wound inside the housing 31 into a rectangular shape with rounded corners is shown as parallel hose portions 76a, 76c and semicircular hose portions 76b, 76d.

A hose guide structure 80 is provided on the central front side of the casing 31 for deforming inward the parallel line hose portion 76a on the front side of the hose 76 wound inside the casing 31 into a rounded rectangle.

The hose guide structure 80 has four guide pipes 80a, 80b, 80c, and 80d made of metal pipes erected on a bottom plate 81, and the guide pipes 80a and 80d at both ends are erected along the inner surface of the housing 31. The central guide pipes 80b and 80c are separated inward by a predetermined length and stand upright, and the hose 76 is wound inward along the guide pipes 80a, 80b, 80c, and 80d of the hose guide structure 80, so that the front side of the hose 76 is The parallel line hose portion 76a is deformed inwardly into a shape close to a gourd shape, and due to this deformation, a repulsive force is generated in the deformed parallel line hose portion 76a of the hose 76, which tends to spread outward.

By providing such a hose guide structure 80, the hose 76 that is overlapped and wound internally within the housing 31 has a rounded oval parallel line hose portion 76a that is deformed inward by the hose guide structure 80. As a result, a repulsive force that tries to spread outward is generated, and a force that presses against the inner wall of the housing 31 is generated, so that even if the parallel hose portions 76a and 76c of the overlapping inwardly wound hose 76 become longer, To surely prevent collapse inward.

Here, the hose guide structure 80 deforms the parallel hose portion 76a on the front side of the hose 76 inward, and the parallel hose portion 76c on the back side is not deformed inward, but deforms inside the parallel hose portion 76a. This increases the force of the hose 76 as a whole to spread outward, and it is possible to reliably prevent the parallel hose portion 76c on the back side that has not been deformed inward from collapsing inward.

In addition, when the front door 32 and the second upper door 36 or the first upper door 34 are opened and the hose 76 is pulled out, a force trying to push out the hose due to deformation of the radial hose portions 76b and 76d of the hose 76 is generated. In addition, the parallel line hose portion 76a of the hose 76 is also deformed inward by the hose guide structure 80, generating a force that tries to push out the hose 76, making it possible to reduce the force with which the hose 76 is pulled out.

At the upper part of the hose guide structure 80, guide pipes 82a to 82d and guide pipes are provided so as to surround the inside of the front door opening 33, the first top door opening 35, and the second top door opening 37 shown in FIGS. 1 and 2. 84a and 84b are arranged, and when the hose 76 is pulled out, the hose 76 is brought into sliding contact with the guide pipes 82a to 82c or the guide pipes 84a and 84b, thereby preventing wear and tear on the hose 76 and reducing the force with which the hose is pulled out.

Further, a foam nozzle 78 connected to the tip of the hose 76 is detachably latched to the back surface of the second upper door 36 by a nozzle holder 86. The nozzle holder 86 of this embodiment has a suspension structure in which the foam nozzle 78 is pivotally supported on the back surface of the second upper door 36 and suspended in a suspended state, and the twelfth upper door 36 is fixed to the upper door in FIG. 36a, or when the first upper door 34 and the second upper door 36 are integrally opened from the rear as shown in the first upper door 34a of FIG. A nozzle holder 86 holds a foam nozzle 78 in a suspended state on the back side of the door.

Therefore, when the second upper door 36 is opened forward or the first upper door 34 is opened backward together with the second upper door 36, the foam nozzle 78 held in a suspended state on the back side of the door appears at the top of the fire hydrant storage box 30. become.

When the second upper door 36 opens forward, the foam nozzle 78 held on the back side of the door appears in a range of approximately 0.9 to 1.3 meters from the road 15; This corresponds to the range from the waist to the shoulders of the user, and since the foam nozzle 78 appears in front of the user, the foam nozzle 78 can be easily taken out.

Furthermore, when the first upper door 34 opens backward, the foam nozzle 78 held on the back side of the door appears at a position within a range of approximately 0.2 to 0.4 meters from the road surface of the lifeguard passageway 14. The foam nozzle 78 appears in front of the user who is bending over the lifeguard passageway 14 and operating the rear-opening handle 40, and the user can easily take out the foam nozzle 78 from the lifeguard passageway 14 side. .

Further, an operation box is disposed inside the right side of the top opening of the housing 31, and a fire hydrant valve opening/closing lever is provided on the operation box, and a manual pilot valve provided inside the operation box is opened/closed. However, illustration is omitted. When the fire hydrant valve opening/closing lever is opened, the manual pilot valve is opened, and the fire hydrant valve separately arranged in the water discharge control mechanism housing 26 shown in FIG. 1 can be opened remotely.

Further, one or more of the operation box, manual pilot valve, and fire hydrant opening/closing lever may be arranged in the empty space secured by the hose guide structure 80. Further, a connecting member between the manual pilot valve and the fire hydrant opening/closing lever or a part of the piping from the manual pilot valve to the fire hydrant valve may be arranged in an empty space.

By arranging appropriate members in the empty space as described above, it is possible to effectively utilize the space of the fire hydrant storage box arranged in the lifeguard passage where space is limited.

[Operation to open the second upper door and front door from the road side]
FIG. 8 is an explanatory diagram showing the opening operation of the front door and the second upper door when operated from the road side.

As shown in FIG. 8, when the user operates the fire hydrant storage box 30 from the road side, when the user lifts up the front opening handle 38, the front door 32 is unlocked and the front door 32 slides under its own weight. It falls, and the front door opening 33 is opened.

Subsequently, when the user performs a forward opening operation to open the second upper door 36 in the depth direction, the shaft members 56 disposed on both sides of the handle body 38a open as shown in FIGS. is pulled out from the bearing member 58 on the back side of the front door 32, the second upper door 36 is opened forward about the hinge 42, and the second upper door opening 37 is opened.

At this time, as shown in FIG. 7(A), the nozzle holder 86 arranged on the back side of the second upper door 36 is located in front of the user on the road and is locked to the nozzle holder 86. The foam nozzle 78 appears in front of the user, and the user can easily take out the foam nozzle 78 and pull out the hose 76.

[Operation to open the upper door from the lifeguard passage side]
FIG. 9 is an explanatory diagram showing the opening operation of the first upper door when operated from the observer passage side.

As shown in FIG. 9, when the user operates the fire hydrant storage box 30 from the lifeguard passage side, when the user bends down from the lifeguard passage and lifts up the rear opening handle 40, the first upper door opens. 34 is released from being locked to the housing 31 side, the first upper door 34 is opened backward around the hinge 46 at the front edge corner, and the first upper door opening 35 is opened.

At this time, the second upper door 36 is also opened rearward about the hinge 44 together with the first upper door 34, and the front opening handle 38 supported by the hinge 44 does not move. The tip of the shaft member 56 of the front-opening mechanism 60 shown in FIG. The second upper door 36 is rearwardly opened integrally with the first upper door 34 while retaining the lock.

When the first upper door opening 35 is opened by the rear opening of the first upper door 34, the nozzle holder 86 disposed on the back side of the second upper door 36 is locked, as shown in FIG. 6(A). The foam nozzle 78 that has been removed appears in front of the user who is bending down in the lifeguard passage, and can easily take out the foam nozzle 78 and pull out the hose 76.

[First embodiment of nozzle holder]
FIG. 10 is an explanatory diagram showing the first embodiment of the nozzle holder with the upper door closed, with FIG. 10(A) showing the front and FIG. 10(B) showing the side. Further, FIG. 11 shows the suspension of the foam nozzle by the nozzle holder of the first embodiment when the second upper door is in the front-opening state (FIG. 11(A)) and the first upper door is in the backward-opening state (FIG. 11(B)). It is an explanatory diagram showing extracted states.

As shown in FIG. 10, the nozzle holder 86A of this embodiment has a support member 88 disposed on the back surface of the second upper door 36, and a hinge 42 that supports the axis of the second upper door 36, as shown in FIG. A holder body 90 is swingably provided by an axis pin 94 with an axis line 96 parallel to the core line, and a bent portion is provided at the tip of the holder body 90 to detachably grip the inverted tapered tip 78a of the foam nozzle 78. A chuck portion 92 is provided in which chuck claws 92a using a plurality of leaf springs are arranged radially.

A nozzle 78 is detachably suspended from the back side of the second upper door 36 in the closed state by a nozzle holder 86A, and is connected to the rear end of the foam nozzle 78 as shown in FIG. 7(A). The hose 76 facing downward toward the hose storage section 74 is oriented downward toward the hose storage section 74, and as shown in FIG. 7(B), no matter what position the horizontally wound hose 76 ends, The large hose 76 is not deformed, and the second upper door 36 can be smoothly opened and closed by opening forward, and the first upper door 34 integrated with the second upper door 34 can be opened and closed backward.

FIG. 11(A) shows a state in which the second upper door 36 is opened forward by the user's operation from the road side, and at this time, the front door 32 is released and slides open. . When the second upper door 36 is opened forward to the position shown in the figure, the holder supported pivotally by a shaft pin 94 prevents the movement of the support member 88 of the nozzle holder 86A fixed to the rear surface of the door as the second upper door 36 opens. The main body 90 maintains a suspended position in which it is suspended downward by receiving the weight of the foam nozzle 78 and the hose 76 that are suspended by being engaged with the chuck claws 92a of the chuck part 92. The nozzle 78 is pulled upward and the foam nozzle 78 appears in front of the user who is operating it from the road side, and the foam nozzle 78 can be easily taken out with the second upper door 36 open. is possible.

To remove the foam nozzle 78 from the nozzle holder 86A, the foam nozzle 78 can be pulled out from the chuck claw 92a of the chuck portion 92 by pulling the foam nozzle 78 downward. In addition, at the time of restoration after using the fire hydrant, the tip of the foam nozzle 78 can be locked by pushing it from below into the chuck claw 92a of the chuck part 92 of the nozzle holder 86A.

FIG. 11B shows a state in which the first upper door 34 is opened backwards with the second upper door 36 integrated by the user's operation from the observer passage side. When the first upper door 34 is opened backwards to the illustrated position, the holder, which is pivotally supported by a shaft pin 94, resists the movement of the support member 88 of the nozzle holder 86A fixed to the rear surface of the door as the second upper door 36 is opened. The main body 90 maintains a suspended position in which it is suspended downward by receiving the weight of the foam nozzle 78 and the hose 76 that are suspended by being engaged with the chuck claws 92a of the chuck part 92. The nozzle 78 is pulled upward, and the foam nozzle 78 appears in front of the user who is bending over and operating it from the observer's passage. This allows for easy removal.

As shown in FIGS. 7 and 11, it is preferable that the handle of the foam nozzle 78 is suspended sideways. By suspending the handle of the foam nozzle 78 so that it faces sideways, the handle of the foam nozzle 78 can be prevented from going to the back side no matter which direction the door is opened. In order to ensure that the handle of the foam nozzle 78 is hung sideways, a message indicating the suspension method is displayed on the back of the upper door, a mark is placed on the tip of the nozzle, or when the handle of the nozzle is placed sideways. A mechanism may be provided to lock only the lock.

Further, a mechanism for locking the upper door when it is opened may be provided. By locking the door, it is possible to prevent the upper door from closing due to the force of pulling down the foam nozzle 78 when the foam nozzle 78 is taken out.

Further, the force with which the foam nozzle 78 is held by the chuck claw 92a of the chuck portion 92 of the nozzle holder 86A is sufficient to withstand the weight of the foam nozzle 78 and the portion of the hose 76 that floats when the upper door is opened.

Further, the holding can be released by the sum of the weight of the foam nozzle 78 and the portion of the hose 76 that floats when the upper door is opened, and the pulling down force for removing the foam nozzle 78.

Further, a mechanism may be provided in which a switch is provided in the chuck claw 92a of the chuck portion 92 that is turned on when the foam nozzle 78 is pushed in from below, and the gripping force of the nozzle is released by releasing the switch.

[Second embodiment of nozzle holder]
FIG. 12 is an explanatory diagram showing a second embodiment of the nozzle holder, in which FIG. 12(A) shows the front, FIG. 12(B) shows the side, and FIG. 12(C) shows a box-frame-shaped nozzle grip. A plane view of the section from below is shown.

As shown in FIG. 12, the nozzle holder 86B of this embodiment has a support member 88 disposed on the back surface of the second upper door 36, and a hinge 42 that supports the axis of the second upper door 36, as shown in FIG. The point that the holder body 90 is swingably provided by an axis pin 94 with an axis 96 parallel to the core line is the same as the embodiment shown in FIG. A nozzle grip part 98 is provided.

The nozzle gripping part 98 has openings formed on the left and right sides for inserting and removing the inverted tapered tip 78a of the foam nozzle 78, and a lower opening 98a having a width that allows the base side of the inverted tapered tip 78a to pass through in the lower lateral direction. An arc-shaped notch 98b is formed in the center of the lower opening 98a, into which the reversely tapered tip 78a of the foam nozzle 78 received from the side is fitted and held.

According to the nozzle holder 86B of this embodiment, the holder main body 90 is supported by the shaft pin 94 on the support member 88 on the back side of the door, so that the foam nozzle is always supported regardless of the open/closed position of the first upper door 34. 78 can be kept constant, and the first upper door 34 integrated with the second upper door 36 can be opened and closed smoothly by opening backward.

In addition, the inverted tapered tip 78a of the foam nozzle 78 can be fitted into the box-frame-shaped nozzle gripping portion 98 disposed at the tip of the holder body 90 from either the left or right side to be locked in a suspended state. Further, when the first upper door 34 is opened, the foam nozzle 78 suspended from the nozzle gripping part 98 can be easily taken out by pulling it off in either the left or right direction.

The reverse tapered tip portion 78a has a structure in which the diameter of the tip is wider than that of the base. The arcuate notch 98b has a structure that is wider than the base side of the inverted tapered tip portion 78a and narrower than the tip of the inverted tapered tip portion 78a. In addition, since the lower opening 98a has a width that allows the base of the inverted tapered tip 78a to pass through, the user can insert the inverted tapered tip 78a from the lower opening 98a to the notch 98b, and then release the foam nozzle 78. By releasing the nozzle, the nozzle falls to a place where the diameters of the notch 98b and the reversely tapered tip 78a are equal, and the nozzle is fitted and held. This restricts horizontal and downward movement, and upward movement is also restricted by the weight of the nozzle itself.

When taking out the foam nozzle 78, the foam nozzle 78 is removed from the lower opening 98a by shifting the foam nozzle 78 upward and lifting the foam nozzle 78 to a height where the reverse taper tip 78a is smaller than the width of the lower opening 98a. can be taken out. Furthermore, the inverted tapered tip may be shaped like a gourd, which has a concave shape in the middle in the height direction. In this case, the lower opening 98a may have a width that allows it to pass through the concave portion of the inverted tapered tip portion 78a.

As shown in FIG. 12, it is preferable that the handle of the foam nozzle 78 is suspended horizontally. By suspending the handle of the foam nozzle 78 so that it faces sideways, the handle of the foam nozzle 78 can be prevented from going to the back side no matter which direction the door is opened. In order to suspend the foam nozzle 78 so that the handle faces sideways, a message indicating the suspension method may be displayed on the back of the upper door, or a mark may be placed on the tip of the nozzle. Further, in the nozzle gripping portion 98, a guide having a length approximately equal to the height from the reverse tapered tip portion 78a to the handle may be provided downward from the periphery of the notch 98b.

[Third embodiment of nozzle holder]
FIG. 13 is an explanatory diagram showing the third embodiment of the nozzle holder, in which FIG. 13(A) shows the front of the interior with the front of the casing and a part of the front door cut away, and FIG. 13(B) shows the side view. A cross section viewed from the direction is shown. Furthermore, FIG. 14 shows the suspended state of the foam nozzle by the nozzle holder when the second upper door is opened forward (FIG. 14(A)) and when the first upper door is opened backward (FIG. 14(B)). FIG. Further, FIG. 15 is an explanatory diagram showing the third embodiment of the nozzle holder viewed from the front with the upper door open, and FIG. 16 is an explanatory diagram showing the nozzle holder of the third embodiment viewed from the side. 17 is an explanatory view showing the nozzle holder of the third embodiment in a state where some of the holder members are rotated around a vertical axis, as seen from the lateral direction.

(Configuration of nozzle holder with 3-axis degrees of freedom)
As shown in FIGS. 15 to 17, the nozzle holder 86C of this embodiment includes a support member 120, a first holder member 124, a second holder member 128, a third holder member 132, and a chuck portion 138.

The support member 120 has two support arms 120a extending in front of a mounting portion 120b, and the mounting portion 120b is fastened and fixed to the back surface of the second upper door 36 with bolts 121 and nuts 122.

A first holder member 124 is rotatably supported around a first axis 140 by a shaft pin 126 in a shaft hole on the distal end side of the support arm 120a. The first holder member 124 is an upwardly open U-shaped member in cross section. Here, the first axis 140 of the shaft pin 126 is parallel to the axis of the second upper door 36 formed by the hinge 42 shown in FIG.

Below the first holder member 124 , a second holder member 128 is rotatably supported around a second axis 142 by a bolt shaft 130 and a nut 131 . The second holder member 128 is a U-shaped member in cross section that opens downward, and the second axis 142 is perpendicular to the first axis 140.

Below the second holder member 128, a third holder member 132 is rotatably supported around a third axis 144 by a shaft pin 134. The second holder member 128 is a U-shaped member in cross section that opens downward, and the third axis 144 is orthogonal to the second axis 142.

A chuck portion 138 is fixed to the lower side of the third holder member 132 by a rivet 136. In the check part 138, check claws 138a made of four leaf springs formed in a substantially "F" shape are arranged radially, and a reverse tapered tip 78a of the foam nozzle 78 is connected from below to the check claws 138a. By fitting, the foam nozzle 78 is removably locked in a suspended state.

In the nozzle holder 86C of this embodiment, the chuck portion 138 is attached to the shaft pin 126 via the first holder member 124, the second holder member 128, and the third holder member 132 with respect to the support member 120 on the fixed side. , are rotatably connected around three axes by first to third axes 140, 142, and 144 by a bolt shaft 130 and a shaft pin 134. That is, in the nozzle holder 86C of this embodiment, the chuck part 138, in which the foam nozzle 78 is locked, is freely suspended from the back surface of the second upper door 36, which is the fixed side, with three axial degrees of freedom. .

In addition, the chuck part 138 is freely suspended from the support member 120 on the fixed side via the first holder member 124, the second holder member 128, and the third holder member 132, which have three degrees of freedom. Therefore, the chuck part 138 freely moves around three axes in accordance with the movement of the foam nozzle 78 to which the hose 76 is connected when the door is opened and closed, and the plurality of chuck claws 138a gripping the reverse tapered tip 78a at the tip of the nozzle. The locking is performed uniformly and in a well-balanced manner, and the foam nozzle 78 can be reliably locked in a suspended state without increasing the locking force of the four chuck claws 138a on the foam nozzle 78.

In addition, since the foam nozzle 78 can be reliably locked in a detachable manner without increasing the locking force of the foam nozzle 78 by the chuck claw 138a, the foam nozzle 78 locked on the nozzle holder 86C can be pulled out with a light force. It is possible to improve operability.

(Upper door closed)
As shown in FIG. 13, in the normal state where the second upper door 36 is closed, the support member 120 fixed to the back surface of the closed second upper door 36 has its support arm 120a facing downward. A chuck part 138 is suspended below it via a first holder member 124, a second holder member 128, and a third holder member 132, which are connected with three axes of freedom. The reverse tapered tip 78a of the foam nozzle 78 is fitted into the check claw 138a, and is held in a suspended state under the weight of the foam nozzle 78 and the hose 76.

In this state where the foam nozzle 78 is removably suspended by the nozzle holder 86C on the back surface of the second upper door 36 in the closed state, the rear end of the foam nozzle 78 is suspended as shown in FIG. 7(A). The hose 76 connected to the hose 76 faces downward toward the hose storage part 74, and as shown in FIG. Even if the second upper door 36 is opened forward, the second upper door 36 can be opened and closed smoothly, and the first upper door 34 integrated with the second upper door 34 can be opened and closed backward, without causing a large deformation of the hose 76.

(Upper door open)
FIG. 14A shows a state in which the second upper door 36 is opened forward by the user's operation from the road side, and at this time, the front door slides down and opens as the lock is released. When the second upper door 36 is opened forward to the illustrated position, the first holder, which has three-axis degrees of freedom, responds to the movement of the support member 120 of the nozzle holder 86C fixed to the back surface of the door as the second upper door 36 opens. The foam nozzle 78 that is locked to the chuck part 138 that is supported in a free state via the member 124, the second holder member 128, and the third holder member 132 is pulled upward, and the user operating it from the road side The foam nozzle 78 appears in front of the user, making it possible to easily take out the foam nozzle 78 with the second upper door 36 open.

The foam nozzle 78 can be easily removed from the nozzle holder 86C by pulling the foam nozzle 78 downward from the front, since the chuck part 138 is freely suspended from the supporting member 120, which is the fixed side. It can be removed from the chuck claw 138a of the chuck portion 138. In addition, at the time of restoration after using the fire hydrant, the foam nozzle 78 can be easily locked by pushing the tip of the foam nozzle 78 from below into the chuck part 138 of the nozzle holder 86C.

FIG. 14(B) shows a state in which the first upper door 34 is opened backward with the second upper door 36 integrated by the user's operation from the observer passage side. When the first upper door 34 is opened backward to the illustrated position, the first holder member 124 has three-axis degrees of freedom with respect to the movement of the support member 120 of the nozzle holder 86C fixed to the back surface of the second upper door 36; The foam nozzle 78, which is locked to the chuck part 138 which is supported in a free state via the second holder member 128 and the third holder member 132, is pulled up and operated from the lifeguard passage side by bending down. The foam nozzle 78 appears in front of the user, and the foam nozzle 78 can be easily taken out with the first upper door 34 open.

Here, the arrangement of the nozzle holder 86C with respect to the back surface of the second upper door 36 is such that the support member 120 is fixed at a position on the depth side from the front and rear center position of the second upper door 36. 14(B), when the first upper door 34 is opened backward with the second upper door 36 integrated, it is at a higher position than when it is opened from the front as shown in FIG. The nozzle holder 86C is pulled up, making it easy to take out the foam nozzle from the observer passage side.

Further, as shown in FIG. 14(B), the position of at least a portion of the foam nozzle 78 when the first upper door 34 is opened backward is different from that when the second upper door 36 is opened forward as shown in FIG. 14(A). By being configured to be higher than at least a part of the foam nozzle 78 at the time, the operator can easily take out the foam nozzle 78 from the observer passage side.

Further, in the first embodiment shown in FIG. 11, the support member 88 is provided at the center of the back surface of the second upper door 36, but the support member 88 is provided on the back surface of the second upper door 36 similarly to the third embodiment shown in FIG. By providing the foam nozzle 78 on the depth side, the position of at least a portion of the foam nozzle 78 when the first upper door 34 is opened backward is the same as the position of at least a portion of the foam nozzle 78 when the second upper door 36 is opened forward. This makes it easier for the operator to take out the foam nozzle 78 from the observer's passage.

Furthermore, by arranging the back side of the second upper door 36 of the nozzle holder 86C at the center position in the door front-rear direction, similar to the first embodiment shown in FIG. 11, when the second upper door 36 is opened forward, The nozzle holder 86C may be pulled up to the same height when the first upper door 34 is opened backward with the second upper door 36 integrated.

Further, the chuck portion 138 of the third embodiment shown in FIGS. 14 to 17 may be replaced with the nozzle gripping portion 98 of the second embodiment shown in FIG. 12.

[Fourth embodiment of nozzle holder]
FIG. 18 is an explanatory view of a nozzle holder according to a fourth embodiment of the nozzle holder viewed from the front, and FIG. 19 is an explanatory view of a nozzle holder of a fourth embodiment of the nozzle holder viewed from the side.

(Configuration of nozzle holder with two-axis degrees of freedom)
As shown in FIGS. 18 and 19, the nozzle holder 86D of this embodiment includes a support member 120, a first holder member 124, a second holder member 146, and a chuck portion 138.

In the support member 120, two support arms 120a extend in front of a mounting portion 120b, and the mounting portion 120b is fastened and fixed to the back surface of the second upper door 36 with bolts 121 and nuts 122.

A first holder member 124 is rotatably supported around a first axis 140 by a shaft pin 126 in a shaft hole on the distal end side of the support arm 120a. The first holder member 124 is parallel to the axis of the second upper door 36 formed by the hinge 42 shown in FIG.

A second holder member 146 is rotatably supported below the first holder member 124 by a bolt shaft 130 and a nut 131 about a second axis 142 in the vertical direction. The second holder member 146 is a member that is open laterally and has a rectangular cross section, and the second axis 142 is perpendicular to the first axis 140.

A chuck portion 138 is fixed to the lower side of the second holder member 146 by a rivet 136. The check part 138 has check claws 138a made of four leaf springs arranged radially, and the foam nozzle 78 is suspended by fitting the reverse tapered tip 78a of the foam nozzle 78 into the check claws 138a from below. It is removably locked in the lowered position.

In the nozzle holder 86D of this embodiment, the chuck part 138 is connected to the support member 120 on the fixed side through the first holder member 124 and the second holder member 146, and is connected to the shaft pin 126 and the bolt shaft 130. It is rotatably connected around two axes defined by first and second axes 140 and 142. That is, in the nozzle holder 86D of this embodiment, the chuck part 138 that locks the foam nozzle 78 is suspended from the back surface of the second upper door 36, which is the fixed side, with two-axis degrees of freedom.

In addition, since the chuck part 138 is freely suspended around two axes via the first holder member 124 and the second holder member 146, which have two degrees of freedom, with respect to the support member 120 on the fixed side. The chuck part 138 moves freely around two axes in response to the movement of the foam nozzle 78 to which the hose 76 is connected as the door opens and closes, and is engaged by the plurality of chuck claws 138a that grip the reversely tapered tip 78a at the nozzle tip. The locking is performed uniformly and in a well-balanced manner, and the foam nozzle 78 can be reliably locked in a suspended state without increasing the locking force of the four chuck claws 138a on the foam nozzle 78.

Moreover, since the foam nozzle 78 can be reliably locked in a detachable manner without increasing the locking force of the foam nozzle 78 by the chuck claw 138a, the foam nozzle 78 locked on the nozzle holder 86D can be pulled out with a light force. It is possible to improve operability.

When the user opens the second upper door 36 forward by operating from the road side, two The foam nozzle 78, which is locked to the chuck part 138 that is supported in a free state via the first holder member 124 and the second holder member 146, which have axial degrees of freedom, is pulled upward and is operated from the road side. The foam nozzle 78 appears in front of the user, making it possible to easily take out the foam nozzle 78 with the second upper door 36 open.

In addition, when the first upper door 34 is opened backward with the second upper door 36 integrated by the user's operation from the lifeguard passage side, it is fixed to the back side of the door as the second upper door 36 is opened. With respect to the movement of the support member 120 of the nozzle holder 86D, the bubbles are stopped by the chuck part 138, which is supported in a free state via the first holder member 124 and the second holder member 146, which have two degrees of freedom. The nozzle 78 is pulled upward, and the foam nozzle 78 appears in front of the user who is bending over and operating it from the observer's passage. This allows for easy removal.

Furthermore, the chuck portion 138 of the third embodiment shown in FIGS. 18 and 19 may be replaced with the nozzle gripping portion 98 of the second embodiment shown in FIG.

[Other embodiments of door opening/closing structure]
FIG. 20 is an explanatory diagram showing another embodiment of the door structure of the fire hydrant storage box, and FIG. 21 is an explanatory diagram showing the opening operation of the front door and upper door when the fire hydrant storage box of FIG. 20 is operated from the road side. , FIG. 22 is an explanatory diagram showing the opening operation of the upper door when the fire hydrant storage box of FIG. 20 is operated from the lifeguard passage side.

(Front-opening structure of upper door)
The door opening/closing structure of the present embodiment shown in FIG. 20 is different from the embodiment in which the upper door is divided into the first upper door 34 and the second upper door 36 in FIG. It is characterized by being pivoted so that it can be opened forward and backward.

When the user operates the door from the road side, when the user operates the front-opening handle 38, the front door 32 is unlocked, slides down, and is opened as shown in FIG. 21.

Further, the upper door 100 is opened by holding the front opening handle 38 and opening it upward, and at this time, the nozzle holder 86 arranged on the back surface of the upper door 100 appears in front of the user's eyes. Note that the foam nozzle locked to the nozzle holder 86 is not shown.

The engagement of the front door 32 with the upper door 100 is the same as that shown in FIGS. 5 and 6, and when the user operates it from the road side, when the front opening handle 38 is operated, the front door 32 is engaged with the upper door 100 on both sides of the handle body 38a. When the shaft member 56 that has been taken out is pulled in and comes out of the shaft hole of the bearing member 58 arranged on the back side of the front door 32, the lock with the front door 32 is released, and the front door 32 is opened by sliding and falling. The upper door 100 can be opened.

As shown in FIG. 21, the structure of the rear edge portion for front opening the upper door 100 is such that shaft members 104 are taken out from both sides of the handle body 102a of the rear opening handle 102 of the upper door 100, and the tip of the shaft member 104 is is fitted into the shaft hole of the bearing member 106 fixed to the housing 31. This structure is the same opening/closing structure as the front opening handle 38 side shown in FIGS. 5 and 6.

For this reason, the upper door 100 is opened and closed in the vertical direction centering on the axes of the two by fitting the shaft member 104 of the rear-opening handle 102 into the bearing member 106 on the side of the housing 31 for pivotal support.

(Upper door opens backwards)
When a user operates the fire hydrant storage box 30 shown in FIG. 20 from the lifeguard passage side, when the user operates the rear opening handle 102, the lock with the housing 31 side is released, and the upper door 100 opens as shown in FIG. It can be opened later. At this time, the nozzle holder 86 arranged on the back surface of the upper door 100 appears in front of the user who is bending down.

As shown in FIG. 21, the opening/closing structure for opening the upper door 100 backwards is such that a shaft member 110 is supported on the back side on both sides of the front edge of the upper door 100, and the upper door opening of the casing 31 is supported correspondingly. A semi-cylindrical bearing member 108 with an upward opening is fixedly arranged on both sides of the front edge of the upper door 112, and with the shaft member 110 of the upper door 100 fitted into the bearing member 108, , the upper door 100 is pivotally supported so that it can be opened from behind.

Further, the front opening operation handle 38 provided at the center of the front edge of the upper door 100 can close the front door 32 by inserting the tip of the shaft member 56 into the shaft member 58 inside the front door 32. The upper door 100 can be opened backwards while being locked.

In the fire hydrant storage box 30 with the door opening/closing structure shown in FIGS. 20 to 22, the foam nozzle is suspended from the back of the door by the nozzle holder 86 when the upper door 100 is closed. Even when the upper door 100 is opened forward and backward, the foam nozzle remains suspended by the nozzle holder 86 and is pulled up as the upper door 100 is opened. To easily take out a nozzle with an upper door 100 open without changing the posture of the nozzle.

[Modification of the present invention]
(nozzle holder)
The claw portion or box frame-shaped nozzle gripping portion that removably locks the foam nozzle with the nozzle holder shown in the above embodiment is an example, and the structure that removably locks the foam nozzle in a suspended state on the back of the door. Any suitable structure may be used.

(Nozzle holder with 2-axis degree of freedom or 3-axis degree of freedom)
In the above embodiment, the chuck part has two or three axes of freedom by multi-stage connection of the shaft pin and the U-shaped holder member to the support member fixed to the back surface of the upper door, but is limited to this. However, for example, the chuck part may be swingably connected to a support member fixed to the back surface of the upper door via a ball joint, thereby achieving two or three axes of freedom. .

(Foam fire hydrant equipment)
Although the above embodiment takes as an example a foam fire hydrant equipment that discharges fire extinguishing foam, the present invention is not limited to this, and may be a fire hydrant equipment that discharges fire extinguishing water.

(others)
Although the above embodiment takes as an example a fire hydrant facility having a front door, the present invention is not limited to this, and may have a structure without a front door.

Moreover, although the above embodiment takes a tunnel fire hydrant as an example, it may also be used for a fire hydrant embedded in a general road. Alternatively, the fire hydrant storage box may be exposed without being embedded. When used in an exposed type fire hydrant storage box, it is preferable that the top door be at a height of about 1 meter in order to make it easy to open the top door and take out the nozzle. In addition, the fire hydrant storage box of the present invention can be installed on two aisle surfaces of different heights, or on surfaces with different heights that people can walk on, such as on and below the podium of a gymnasium or stage, and on a wall that touches that surface. May be applied.

Furthermore, the present invention includes appropriate modifications without impairing its objects and advantages, and is not limited by the numerical values shown in the above embodiments.

10: Tunnel 12: Tunnel wall 14: Observer passage 15: Road 16: Fire hydrant equipment 18: Floor slab 20: Management passage 22: Duct 24: Main water supply pipe 24a: Branch pipe 25: Water supply pipe 26: Water discharge control mechanism storage Part 30: Fire hydrant storage box 31: Housing 32: Front door 33: Front door opening 34: First upper door 35: First upper door opening 36: Second upper door 37: Second upper door opening 38: Front opening handle 40, 102: Rear opening handle 42, 44, 46: Hinge 48: Notifying device panel 56, 104: Shaft member 58, 106: Bearing member 58a: Shaft hole 60: Front opening mechanism 74: Hose storage section 76: Hose 78: Foam nozzle 78a: Reverse tapered tip 80: Hose guides 80a to 80d, 82a to 82c, 84a, 84b: Guide pipes 86, 86A, 86B, 86C, 86D: Nozzle holder 88, 120: Support member 90: Holder body 92, 138: Chuck parts 92a, 138a: Chuck claw 94: Shaft pin 98: Nozzle gripping part 100: Upper door 124: First holder member 126, 134: Shaft pin 128, 146: Second holder member 130: Bolt shaft 132: No. 3 holder member 140: first axis 142: second axis 144: third axis

Claims (6)

In a fire hydrant device with a fire hose stored inside,
A guide member is provided inside the fire hydrant device at a position with a predetermined interval from the front side to the rear side, extending in the vertical direction of the fire hydrant device,
When the fire hose is stored, the fire hose is wound so that its periphery is stacked upward from the bottom of the fire hydrant device, and a portion of the outer peripheral portion on the front side of the fire hydrant device is attached to the guide member. A fire hydrant device, characterized in that the fire hydrant device is housed inside the fire hydrant device so as to form a recess with respect to the front surface of the fire hydrant device by coming into contact with the fire hydrant device from the rear side.
In the fire hydrant device according to claim 1,
A second guide member is provided on the front side of the interior of the fire hydrant device and extends in the vertical direction of the fire hydrant device,
The fire hydrant device is characterized in that the fire hose is housed so as to come into contact with the second guide member from the rear side.
In the fire hydrant device according to claim 1 or 2,
A fire hydrant device characterized in that a plurality of the guide members and the second guide member are provided.
In the fire hydrant device according to any one of claims 1 to 3,
A nozzle is attached to the tip of the fire hose,
An upper door is provided in an opening formed in the upper part of the fire hydrant device located above the stored fire hose,
The fire hydrant device, wherein the upper door is openable so that the nozzle is operably exposed from the outside of the fire hydrant device on the front side.
In the fire hydrant device according to any one of claims 1 to 4,
A hose guide is provided in an opening formed above the stored fire hose on the front side of the fire hydrant device to support and guide the fire hose from below when the fire hose is pulled out from the opening. A fire hydrant device characterized by being provided.
A fire hydrant facility comprising a fire hydrant embedded part that is an internal space under the road surface of a lifeguard passage along a tunnel wall in a tunnel,
The fire hydrant device according to any one of claims 1 to 5 is embedded in the fire hydrant embedded part so that the upper surface is exposed to the road side of the lifeguard passage and the front surface is exposed to the road side. fire hydrant equipment.

Images