JP6842909B2 - Firefighting equipment and fire hoses - Google Patents

Description

The present invention relates to a fire-fighting equipment in which a nozzle is connected to one end of a fire-fighting hose and the other end of the fire-fighting hose is connected to a water source, and a fire-fighting hose used therein.

In recent years, photovoltaic power generation systems that utilize solar heat, which is one of the renewable energies, have rapidly become widespread in ordinary houses, and are being introduced in fields other than housing, such as industrial fields and public facilities. In this photovoltaic power generation system, light energy is converted into electrical energy by a solar cell module (solar panel), so that power generation cannot be cut off from the outside. Therefore, when a fire breaks out in a solar power generation system or a building equipped with it, fire extinguishing activities using water are carried out. At this time, "(1) of" 5.2 Dangers of firefighting activities "in Non-Patent Document 1 ) In "Danger of electric shock", if the water is not atomized by the rod-shaped water discharge and hangs on the building, etc., the fire extinguishing activist (firefighter, building user (facility manager, security officer, etc.) ) May get an electric shock.

As a measure to prevent electric shock during firefighting activities, the surface of the solar cell module is covered with a nonflammable light-shielding sheet to block light, the output voltage of the solar cell module is lowered, and then the fire extinguishing activity is started. A possible countermeasure is to physically destroy the solar cell module and then start fire extinguishing activities.

16th Fire and Disaster Prevention Research Lecture Material (February 2013) "Fires in houses with photovoltaic power generation systems and problems with firefighting activities" Firefighting Research Center

However, the former countermeasure has the disadvantage that the fire progresses before the surface of the solar cell module is covered with the light-shielding sheet, and the safety of the fire extinguishing activist during the covering work with the light-shielding sheet cannot be ensured.
Further, in the latter countermeasure plan, there is a risk of electric shock when the solar cell module or the like is destroyed, and there is a disadvantage that the fire progresses by the time the destruction of the solar cell module or the like is completed. Further, there is a problem that the cost burden increases due to the re-installation of the photovoltaic power generation system including the solar cell module after the fire is extinguished.

Therefore, as current measures, measures such as keeping a distance at the time of water discharge, spraying water, and using gloves with high insulation are taken, but all measures are taken when water is discharged to the solar cell module. The risk of getting an electric shock remains.
In addition, the above-mentioned problem of electric shock during firefighting activities may occur even when water is discharged from a fire extinguishing area equipped with an electric facility other than a photovoltaic power generation system, an electric vehicle, a fuel cell vehicle, or the like. ..

In view of this situation, a main object of the present invention is to provide firefighting equipment capable of preventing electric shock of a fire extinguishing activist who holds a pipe including a nozzle, and a useful fire hose used for the fire extinguishing equipment.

The first characteristic configuration according to the present invention is a fire-fighting equipment in which a nozzle is connected to one end of a fire-fighting hose and the other end of the fire-fighting hose is connected to a water source.
The point is that the firefighting equipment is provided with a first grounding means for electrically grounding the nozzle.

According to the above configuration, when water is discharged to the fire extinguishing target area, the active wire portion of the electrical equipment or the like existing in the fire extinguishing target area and the nozzle are electrically connected via the rod-shaped water discharge, and the active wire portion is used. Leakage current may flow through the nozzle through the rod-shaped water discharge. At this time, since the leakage current flowing through the nozzle can be smoothly discharged to the ground by the first grounding means, it is possible to prevent an electric shock of a fire extinguishing activist who holds the pipe including the nozzle.

The second characteristic configuration of the present invention is that the second grounding means for electrically grounding the closing portion provided in the water supply passage between the water source and the fire hose is provided.

According to the above configuration, there is a possibility that a leakage current may flow through the opening / closing portion provided in the water supply channel between the fire hose and the water source during the fire extinguishing activity. At this time, since the leakage current flowing through the opening / closing portion can be smoothly discharged to the ground by the second grounding means, it is possible to prevent an electric shock of a fire extinguishing activist who is opening / closing the opening / closing portion.

The third characteristic configuration according to the present invention is that the fire hose has a ground wire that electrically connects the nozzle and the opening / closing portion in a state of forming a part of the grounding conductive path of the first grounding means. Arranged,
The remainder of the ground conductive path of the first grounding means is that is configured with a ground conductive path of the second grounding means.

According to the above configuration, when the water is discharged to the fire extinguishing target area, the leakage current flowing through the nozzle is discharged to the ground wire arranged in the fire hose so as to form a part of the ground conductive path of the first grounding means. It can be discharged to the ground via the opening / closing part and the conductive path for grounding of the second grounding means. Therefore, it is possible to prevent electric shock of fire extinguishing activists as compared with the case where the first grounding means for electrically grounding the nozzle and the second grounding means for electrically grounding the opening / closing part are independently configured in separate systems. It is possible to construct firefighting equipment that can be used in terms of structure and cost.

The fourth feature configuration according to the present invention is the fire hose used in the firefighting equipment according to any one of the first feature configuration to the third feature configuration.
A fire hose in which a ground wire forming a part of a conductive path for grounding of the first grounding means is arranged on the outer surface side, the inner surface side, or between layers of a plurality of hose constituent layers formed in layers in the hose radial direction. It is in the point that it is .

According to the above configuration, the ground wire can be appropriately arranged by utilizing the outer surface side or the inner surface side of the fire hose composed of a plurality of hose constituent layers or the layers of the hose constituent layers.

In the fifth characteristic configuration according to the present invention, the plurality of hose constituent layers include a hose main body and a protective layer formed by covering the outer or inner surface of the hose body in close contact with the hose body.
The point is that the ground wire is arranged between the hose body and the protective layer.

According to the above configuration, the ground wire can be protected at the same time by the protective layer that protects the outer surface or the inner surface of the hose body in a close contact state, so that the coating structure of the ground wire can be simplified and the protective layer can be simplified. The ground wire can be reliably held in place by the close contact force of.

In the sixth characteristic configuration according to the present invention, the plurality of hose constituent layers include an inner hose body and an outer hose body cloaked therein.
The point is that the ground wire is arranged between the inner hose body and the outer hose body.

According to the above configuration, the ground wire can be protected by the outer hose body for enhancing the wear resistance of the fire hose, and the ground wire is arranged when the outer hose body is cloaked on the inner hose body. Can be completed .

Explanatory drawing which shows 1st Embodiment of firefighting equipment Enlarged view of the main part showing the first embodiment of the firefighting equipment Enlarged sectional view of the main part along the line III-III in FIG. Explanatory drawing which shows the 2nd Embodiment of a firefighting equipment Explanatory drawing which shows 3rd Embodiment of firefighting equipment Enlarged sectional view showing each of the 4th embodiment (a) to the 8th embodiment (e) of the firefighting equipment. Perspective view showing a ninth embodiment of firefighting equipment

[First Embodiment]
FIG. 1 is an explanatory diagram of a fire-fighting equipment 100 of the present invention assuming a fire of a solar cell module (solar panel) 201 of a photovoltaic power generation system 200, which is an example of a live wire portion of an electric equipment or the like. In the firefighting equipment 100 of the present embodiment, the fire hydrant 20 installed in the fire hydrant built-in storage box 1 is used as a water source, and the water supply pipe 21 of the fire hydrant 20 is not shown in the drawing installed in the basement of a building or the like. A metal on-off valve 22 is provided as an opening / closing part for opening / closing the water supply path from the fire-prevention water tank or the water pipe buried in the ground to the water supply port of the fire hydrant 20.
A base end portion of a flexible fire hose 30 composed of a plurality of hose constituent layers is connected to the water supply port of the on-off valve 22, and a nozzle 42 is provided at the tip end portion of the fire hose 30. A metal (aluminum alloy, copper alloy, etc.) pipe hose 40 is connected.

Then, in the firefighting equipment 100 of the present embodiment, as shown in FIGS. 1 and 2, the first grounding means 50 for electrically grounding the pipe 40 including the nozzle 42 and the on-off valve 22 of the fire hydrant 20 are electrically connected. A second grounding means 60 for grounding is provided. The fire hose 30 is provided with a ground wire 70 that electrically connects the pipe 40 including the nozzle 42 and the on-off valve 22 in a state of forming a part of the grounding conductive path 51 of the first grounding means 50. The remaining portion of the grounding conductive path 51 of the first grounding means 50 is composed of the grounding conductive path 61 of the second grounding means 60.

Therefore, when the water is discharged to the fire extinguishing target area, the solar cell module 201 of the photovoltaic power generation system 200 existing in the fire extinguishing target area and the nozzle 42 of the pipe 40 are electrically connected via the rod-shaped water discharge. Even when a leakage current flows from the solar cell module 201 side to the nozzle 42 of the pipe 40 via rod-shaped water discharge, the leakage current flowing through the nozzle 42 of the pipe 40 is passed through the grounding conductive path 51 of the first grounding means 50. It is possible to smoothly discharge to the ground via the route, and it is possible to prevent an electric shock of a fire extinguishing activist holding the pipe 40.
Further, even when a leakage current flows through the on-off valve 22 during fire extinguishing activity, the leakage current flowing through the on-off valve 22 can be smoothly discharged to the ground via the grounding conductive path 61 of the second grounding means 60. This makes it possible to prevent an electric shock from a fire extinguishing activist who is opening and closing the on-off valve 22.

Moreover, the ground wire 70 and the on-off valve 22 are arranged in the fire hose 30 in a state where the leakage current flowing through the nozzle 42 of the pipe 40 forms a part of the grounding conductive path 51 of the first grounding means 50. , It is possible to discharge to the ground via the grounding conductive path 61 of the second grounding means 60. Therefore, the firefighting equipment 100, which can prevent the fire extinguishing activist from getting an electric shock, is provided with the first grounding means 50 for electrically grounding the pipe 40 including the nozzle 42 and the second grounding means for electrically grounding the on-off valve 22. Compared with the case where 60 and 60 are independently configured in separate systems, the configuration can be advantageous in terms of structure and cost.

As shown in FIG. 2, the pipe hook 40 is formed by fitting and connecting a metal pipe hook main body 41 formed in a tapered tapered pipe shape and a tip portion of the pipe hook main body 41 in a watertight state. A metal nozzle 42 and a metal cylindrical receiving metal fitting 45 fitted and fixed to the base end of the pipe main body 41 in a watertight state are provided as a main configuration.
Each of the fitting connection portion between the nozzle 42 and the tip end portion of the tube spear body 41 and the fitting and fixing portion between the base end portion of the tube spear body 41 and the receiving metal fitting 45 are configured in a conductive connection state in which electricity can be applied. There is. Therefore, the leakage current flowing through the nozzle 42 of the pipe spear 40 flows along the nozzle 42 → the fitting connection portion → the pipe spear main body 41 → the fitting fixing portion → the receiving metal fitting 45.

A first insulating coating layer 43 made of an electrically insulating material such as a string or rubber having a non-slip function is formed on the outer peripheral surface of the pipe main body 41 which is a gripping part of the pipe 40 during fire extinguishing activity. At the same time, a second insulating coating layer 44 made of an electrically insulating material such as rubber, which also has a non-slip function, is formed on the maximum outer diameter portion of the outer peripheral surface of the receiving metal fitting 45.
Further, a third insulating coating layer 24 made of an electrically insulating material such as rubber having a non-slip function is also formed on the grip portion of the operation handle 22A for opening and closing the on-off valve 22 of the fire hydrant 20.

Then, as shown in FIGS. 1 and 2, a metal cylindrical receiving metal fitting 31 is provided at one end of the fire hose 30, and a metal cylindrical receiving metal fitting 31 is provided at the other end of the fire hose 30. A metal fitting 32 is provided.
As shown in FIG. 2, the metal fitting 32 at the other end of the fire hose 30 is detachably plugged and connected to the metal fitting 45 at the rear end of the pipe spear 40. The metal fitting 32 of the hose 30 and the metal fitting 45 of the pipe spear 40 are configured in a conductively connected state in which electricity can be applied. With the metal fitting 32 of the fire hose 30 and the metal fitting 45 of the pipe hook 40 in this conductive connection state, the hose tip coupling side conductive path portion 51A as a part of the grounding conductive path 51 of the first grounding means 50 It is configured.

As shown in FIG. 2, the receiving metal fitting 31 at one end of the fire hose 30 is detachably inserted and connected to the metal cylindrical insertion metal fitting 23 provided at the water supply port of the on-off valve 22 of the fire hydrant 20. In this plug-in coupling state, the receiving metal fitting 31 of the fire hose 30 and the metal fitting 23 of the on-off valve 22 are configured in a conductive connection state in which electricity can be energized. With the receiving metal fitting 31 of the fire hose 30 and the metal fitting 23 of the on-off valve 22 in this conductively connected state, the hose base end coupling side conductive path portion 51B as a part of the grounding conductive path 51 of the first grounding means 50. Is configured.

When the fire hose 30 is added, the receiving metal fitting 31 of one fire hose 30 to be connected is detachably plugged and connected to the plug 32 of the other fire hose 30. In the state, the receiving metal fitting 31 of one fire-fighting hose 30 and the metal fitting 32 of the other fire-fighting hose 30 are configured in a conductively connected state in which electricity can be supplied. The hose intermediate coupling side as a part of the grounding conductive path 51 of the first grounding means 50 by holding the receiving metal fitting 31 of one fire-fighting hose 30 and the metal fitting 32 of the other fire-fighting hose 30 in this conductive connection state. The conductive path portion 51C is configured.

The fire hose 30 targeted by the present invention is classified into a flat hose for fire, a wet hose for fire, and a shape-retaining hose for fire. Further, the flat hose for fire fighting is classified into a flat hose, an outer coating hose, a double jacket hose, and an outer covering hose. In the fire-fighting equipment 100 of the present invention, any of the above-mentioned fire-fighting hoses 30 can be preferably used, but in the present embodiment, a flat hose is used as the fire-fighting hose 30.

As shown in FIG. 3, the hose body of this flat hose is composed of a tubular jacket (cylindrical woven fabric) 30A in which threads such as cotton and synthetic fibers are mixed (plain weave) with warp threads 30a and weft threads 30b. There is. An example of a protective layer that is coated and formed on the inner surface of the jacket 30A in a state of close contact, a tubular lining layer 30B made of rubber, synthetic resin, or the like for preventing water leakage during water supply is formed in close contact with an adhesive or the like. Has been done. Further, on the outer surface of the jacket 30A, a coating layer (or covering layer) 30C formed by applying a wear-resistant resin is closely formed as an example of a protective layer that is coated and formed on the outer surface in a close contact state.
Therefore, in the above-mentioned flat hose, the coating layer 30C, the jacket 30A constituting the hose body, and the lining layer 30B are composed of a hose constituent layer having a three-layer structure in which the coating layer 30C, the jacket 30A and the lining layer 30B are arranged in order from the outer surface side to the inner surface side.

Then, as shown in FIGS. 2 and 3, between the outer surface of the jacket 30A and the coating layer 30C, a ground wire 70 forming a part of the grounding conductive path 51 of the first grounding means 50 is used for fire fighting. It is arranged over the entire length of the hose 30, and both ends of the ground wire 70 are electrically conductively connected to the metal fittings 32 and the metal fittings 31 at both ends of the fire hose 30.
Therefore, the hose-side conductive path portion 51D, which is a part of the ground conductive path 51 of the first grounding means 50, is configured by the ground wire 70 arranged over the entire length of the fire hose 30.
Further, with the above configuration, the ground wire 70 can be protected at the same time by the wear-resistant coating layer 30C that protects the outer surface of the jacket 30A in a close contact state, so that the coating structure of the ground wire 70 can be simplified. it can.

In the present embodiment, the ground wire 70 is arranged between the outer surface of the jacket 30A and the coating layer 30C. The ground wire 70 is placed on the outer surface of the coating layer 30C of the fire hose 30 with an adhesive, a band, or the like. It may be arranged with.

Then, as shown in FIG. 2, a part of the first grounding means 50 up to the on-off valve 22 of the fire hydrant 20 in the grounding conductive path 51 is the pipe hook 40, the metal fitting 32 in the fire hose 30 on the downstream side, and the ground. It is composed of a wire 70, a receiving metal fitting 31, a metal fitting 32 for the fire hose 30 on the upstream side, a ground wire 70, and a metal fitting 31, and the metal fitting 31 for the fire hose 30 on the upstream side is a metal fitting 23 for the on-off valve 22. It is plugged into the hose in a conductively connected state.
Therefore, the remaining portion of the grounding conductive path 51 of the first grounding means 50 is also configured with the grounding conductive path 61 of the second grounding means 60.
The grounding conductive path 61 of the second grounding means 60 is electrically connected to the first grounding wire 62 conductively connected to the on-off valve 22 and the grounding electrode 63 buried at a predetermined depth in the ground. It is configured by electrically connecting the ground wire 64 to the terminal box 65 so that it can be energized.

In FIG. 1, 202 is a junction box of the photovoltaic power generation system 200, and 203 is a power conditioner of the photovoltaic power generation system 200.

Further, in the above-described embodiment, a part of the grounding conductive path 51 of the first grounding means 50 is also configured by the grounding conductive path 61 of the second grounding means 60, but the pipe 40 including the nozzle 42 is electrically operated. Even if the grounding conductive path 51 of the first grounding means 50 for grounding and the grounding conductive path 61 of the second grounding means 60 for electrically grounding the on-off valve 22 are independently configured in separate systems. Good.

Further, when the grounding conductive path 51 of the first grounding means 50 is independently configured, the insertion fitting 32 of the upstream fire hose 30 and the receiving metal 31 of the downstream fire hose 30 are plugged and connected. The hose intermediate coupling side conductive path portion 51C configured by the above may be electrically connected to the ground electrode 63 embedded at a predetermined depth in the ground so as to be electrically conductive.

Further, the fire hydrant built-in type storage box 1 of the above-described embodiment may be either an indoor fire hydrant or an outdoor fire hydrant. Further, instead of the fire hydrant built-in type storage box 1, a above-ground fire hydrant, an underground fire hydrant, or the like may be used.

[Second Embodiment]
FIG. 4 shows the firefighting equipment 100 of another embodiment. In this firefighting equipment 100, as a water source, a metal underground fire hydrant 20 connected to a water pipe 10 buried in the ground and arranged in a manhole 11 is used. The fire hydrant 20 is provided with a metal on-off valve 22 as an opening / closing portion for opening / closing the water supply path from the water pipe 10 to the water supply port of the fire hydrant 20.
A third ground wire 66, which is electrically connected to a ground electrode 63 buried at a predetermined depth in the ground, is electrically connected to the fire hydrant 20 so as to be energized.

Further, the water supply port 301 of the fire pump vehicle 300 and the water supply port of the on-off valve 22 of the fire hydrant 20 are connected by a fire hose 30 provided with the ground wire 70 described in the first embodiment, and the fire pump vehicle 300 is released. Two fire-fighting hoses 30 having a ground wire 70 (the number of hoses may be one or a plurality of three or more) are connected to the water port 302. Among them, a metal pipe spear 40 provided with a nozzle 42 is connected to the tip of the fire hose 30 on the downstream side.
The ground wire 70 of the fire hose 30 on the water supply side and the ground wire 70 of the fire hose 30 on the upstream side on the water discharge side can be energized via a conductive connection (not shown) on the fire pump vehicle 300 side. It is electrically connected, and is also electrically connected to the ground wire 70 of the fire hose 30 on the water supply side and the fire hydrant 20 so as to be energized.

Then, the grounding conductive path 51 of the first grounding means 50 for electrically grounding the pipe 40 including the nozzle 42 is the pipe 40, the metal fitting 32 in the fire hose 30 on the downstream side on the water discharge side, and the ground wire. 70, receiving metal fitting 31, metal fitting 32 in the fire hose 30 on the upstream side which is also on the water discharge side, ground wire 70, conductive connection part (not shown) on the fire pump vehicle 300 side, fire hose 30 on the water supply side. The main part is composed of the ground wire 70.
Further, the grounding conductive path 61 of the second grounding means 60 that electrically grounds the on-off valve 22 of the fire hydrant 20 is mainly composed of the fire hydrant 20, the third grounding wire 66, and the grounding electrode 63.
Also in this second embodiment, the remaining portion of the grounding conductive path 51 of the first grounding means 50 is also configured by the grounding conductive path 61 of the second grounding means 60.
Since the other configurations are the same as the configurations described in the first embodiment, the same numbers as those in the first embodiment are added to the same configuration parts, and the description thereof will be omitted.
Further, a fire engine with a water tank may be used instead of the fire pump vehicle 300.

[Third Embodiment]
FIG. 5 shows the firefighting equipment 100 of another embodiment. In this firefighting equipment 100, a fire prevention water tank 80 buried underground is used as a water source.
The base end of the fire hose 30 provided with the ground wire 70 described in the first embodiment is connected to the water supply port 301 of the fire pump vehicle 300, and is connected to the metal fitting 32 on the tip side of the fire hose 30. Is connected to a receiving metal fitting 31 provided at the base end of a normal fire hose 35 not provided with a ground wire 70. Among them, the water supply port 35A of the normal fire hose 35 is inserted into the water in the tank from the water intake 80A of the fire prevention water tank 80.
Further, at a predetermined portion around the intake port 80A of the fire prevention water tank 80, a terminal box electrically connected to a ground electrode 63 buried at a predetermined depth in the ground via a fourth ground wire 67 so as to be electrically connected. 65 is provided, and the metal fitting 32 of the fire hose 30 provided with the ground wire 70 on the water supply side is electrically connected to the terminal box 65 so as to be energized.

Two fire-fighting hoses 30 (the number of hoses may be one or three or more) equipped with a ground wire 70 are connected to the water discharge port 302 of the fire-fighting pump vehicle 300, of which downstream. A metal pump 40 having a nozzle 42 is connected to the tip of the fire hose 30 on the side.
The ground wire 70 of the fire hose 30 on the water supply side and the ground wire 70 of the fire hose 30 on the upstream side on the water discharge side can be energized via a conductive connection (not shown) on the fire pump vehicle 300 side. Further, the metal fitting 32 of the fire hose 30 provided with the ground wire 70 on the water supply side and the terminal box 65 are electrically connected so as to be energized.

Then, the grounding conductive path 51 of the first grounding means 50 for electrically grounding the pipe 40 including the nozzle 42 is the pipe 40, the metal fitting 32 in the fire hose 30 on the downstream side on the water discharge side, and the ground wire. 70, receiving metal fitting 31, metal fitting 32 in the fire hose 30 on the upstream side which is also the water discharge side, the ground wire 70, the conductive connection portion (not shown) on the fire pump vehicle 300 side, and the fire hose 30 on the water supply side. The main part is composed of a ground wire 70, a metal fitting 32, a fourth ground wire 67, and a ground electrode 63.

The firefighting equipment 100 of the third embodiment described above presents an embodiment in which only the first grounding means 50 for electrically grounding the pipe spear 40 including the nozzle 42 is provided.
Since the other configurations are the same as the configurations described in the first embodiment, the same numbers as those in the first embodiment are added to the same configuration parts, and the description thereof will be omitted.

[Other Embodiments]
(1) FIG. 6 shows another embodiment in which the arrangement of the ground wire 70 with respect to the fire hose 30 is changed.
In the fourth embodiment shown in FIG. 6A, the ground wire 70 forming a part of the grounding conductive path 51 of the first grounding means 50 is attached to the lining layer 30B that protects the inner surface of the jacket 30A with an adhesive or the like. It is stuck.
In the fifth embodiment shown in FIG. 6B, the ground wire 70 forming a part of the grounding conductive path 51 of the first grounding means 50 is inserted and arranged in the internal space 30D of the fire hose 30.
In the sixth embodiment shown in FIG. 6C, a ground wire 70 forming a part of the grounding conductive path 51 of the first grounding means 50 is arranged between the inner surface of the jacket 30A and the lining layer 30B. There is.
In the case of this embodiment, the ground wire 70 can be protected at the same time by the lining layer 30B that protects the inner surface of the jacket 30A in a close contact state, so that the coating structure of the ground wire 70 can be simplified.
In the seventh embodiment shown in FIG. 6D, one or a plurality of warp threads 30a constituting the jacket 30A of the fire hose 30 form a part of the grounding conductive path 51 of the first grounding means 50. It is cross-woven (plain weave) by replacing it with the ground wire 70.
In the case of this embodiment, the arrangement of the ground wire 70 is completed at the same time as the knitting of the jacket 30A.
In the eighth embodiment shown in FIG. 6E, the jacket 30A of the fire hose 30 has a plurality of warp threads 30a arranged in an annular shape and one or a plurality of warp threads 30a woven spirally into the warp threads 30a. It is composed of a tubular woven fabric composed of a book weft 30b, and one or more of the wefts 30b of the tubular woven fabric are connected to a ground wire 70 forming a part of a conductive path 51 for grounding of the first grounding means 50. It is replaced and woven.
Also in the case of this embodiment, the arrangement of the ground wire 70 is completed at the same time as the knitting of the jacket 30A.

(2) FIG. 7 shows a ninth embodiment in which a double jacket hose is used as the fire hose 30. In this embodiment, a plurality of hose constituent layers constituting the fire hose 30 are composed of an inner jacket 30E which is an example of an inner hose body and an outer jacket 30F which is an example of an outer hose body cloaked therein. An earth wire 70 forming a part of the earthing conductive path 51 of the first grounding means 50 is arranged between the inner jacket 30E and the outer jacket 30F.
In the case of this embodiment, the ground wire 70 can be protected by the outer jacket 30F for increasing the wear resistance of the fire hose 30, and the ground wire 70 is used when the outer jacket 30F is cloaked on the inner jacket 30E. The arrangement can be completed.

(3) In each of the above-described embodiments, the fire hydrant 20 and the fire prevention water tank 80 are taken as examples as water sources, but other artificial water sources such as pools may be used, and nature such as rivers, ponds, swamps, and the sea may be used. It may be irrigation.

(4) In each of the above-described embodiments, the case where the ground electrode 63 is pre-embedded in the ground on the water source side is illustrated, but when the ground circuit equipment provided with the ground electrode 63 does not exist, the water source side At the site, the ground electrode 63 is embedded at a predetermined depth in the ground, and the ground plug derived from the ground electrode 63 is connected to the ground wire 70 on the fire hose 30 side.

(5) In each of the above-described embodiments, a part of the grounding conductive path 51 of the first grounding means 50 is composed of a grounding wire 70 provided on the fire hose 30, but the grounding wire 70 is not usually provided. In the case of the fire hose 35 of the above, it is preferable to directly electrically connect the pipe 40 provided with the nozzle 42 and the ground electrode 63 with a ground wire.

(6) In each of the above-described embodiments, the photovoltaic power generation system 200 is exemplified as a fire extinguishing target provided with a live wire portion, but the fire fighting equipment 100 of the present invention includes electrical equipment other than the photovoltaic power generation system 200, an electric vehicle, and the like. It is also effective for fires in fuel cell vehicles.

20 Water source (fire hydrant)
22 Opening / closing part (opening / closing valve)
30 Fire hose 30A Hose constituent layer (hose body, jacket)
30B hose constituent layer (protective layer, lining layer)
30C hose constituent layer (protective layer, coating layer)
30E inner hose body (inner jacket)
30F outer hose body (outer jacket)
42 Nozzle 50 1st grounding means 51 Conductive path for grounding 60 2nd grounding means 61 Conductive path for grounding 70 Grounding wire 80 Water source (fireproof water tank)

Claims (3)

Is connected Kan鎗having a hose end to the nozzle and the tube鎗本body for fire-fighting, the other end of the fire hose is a fire fighting equipment to be connected to the on-off valve at the tip of the water supply path extending from the water source ,
The fire hose has a ground wire that electrically connects the on-off valve and the pipe spear, which are electrically grounded.
A first insulating coating layer having a non-slip function is coated on the outer peripheral surface of the pipe spear body .
The pipe hook is provided with a receiving metal fitting to which the metal fitting of the fire hose is detachably inserted and connected, and a second insulation having a non-slip function is provided on the maximum outer diameter portion of the outer peripheral surface of the receiving metal fitting. Firefighting equipment with a coating layer. A fire-fighting facility in which a pipe having a nozzle and a pipe body is connected to one end of a fire-fighting hose, and the other end of the fire-fighting hose is connected to an on-off valve at the tip of a water supply channel extending from a water source. ,
The fire hose has a ground wire that electrically connects the on-off valve and the pipe spear, which are electrically grounded.
A first insulating coating layer having a non-slip function is coated on the outer peripheral surface of the pipe spear body.
Firefighting equipment in which a third insulating coating layer having a non-slip function is coated on the grip portion of the operation handle of the on-off valve. A pipe having a nozzle and a pipe body is connected to one end of the fire hose, and the other end of the fire hose is connected to an on-off valve at the tip of a water supply channel extending from a water source.
The fire hose has a ground wire that electrically connects the on-off valve and the pipe spear, which are electrically grounded.
A fire-fighting hose used in fire-fighting equipment in which a first insulating coating layer having a non-slip function is coated on the outer peripheral surface of the pipe body.
The jacket of the fire hose is composed of a tubular woven fabric composed of a plurality of warp threads arranged in a ring shape and one or a plurality of weft threads woven into the warp threads in a spiral shape. A fire hose in which one or more weft threads of a woven fabric are woven in place of the ground wire, and a protective layer made of resin is coated on the outer surface of the jacket in a state of close contact.

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