KR20220036817A - Multipurpose firefighting system for being laid underground - Google Patents

Abstract

The present invention relates to an underground multi-purpose firefighting system, comprising: a buried box buried underground; a door module that covers or exposes an open part of an upper surface of the buried box; a water supply pipe installed inside the buried box to receive fire extinguishing water from the outside of the buried box; a plurality of agent storages arranged inside the buried box to store a plurality of types of agents including fire extinguishing agents used for extinguishing purposes and heterogeneous agents used for purposes other than extinguishing purposes; a valve module for allowing at least one kind of agent to flow into the water supply pipe according to a user operation; and a hose for dispensing a mixture of at least one kind of agent and fire extinguishing water. The underground multi-purpose firefighting system can be used for various purposes such as fire suppression, prevention, snow removal, and cleaning around an area without being limited by an installation space.

Description

{Multipurpose firefighting system for being laid underground}

It relates to a firefighting system buried underground.

Roads in downtown attractions, traditional markets, and residential areas are usually narrow enough for a small car to pass through. As a fire engine cannot enter the road in these areas, there is a problem in that it is difficult to extinguish the fire in case of a fire in these areas. Accordingly, outdoor emergency fire extinguishing devices are being installed in these areas. These outdoor emergency fire extinguishers frequently suffer from freezing in winter due to outdoor installation, impairing the aesthetics of the city, and frequent complaints about inconvenience caused by the installation. In order to solve this problem, Korean Patent No. 10-2007127, "Underground Fire Box System" and Korean Patent No. 10-2015231 "Underground Fire Box System" propose a fire fighting system buried underground. .

The above-described conventional underground fire-fighting system can be used to suppress fires around the installation site, but cannot be used for other purposes such as prevention, snow removal, and cleaning. Fires in downtown attractions, traditional markets, and residential areas generate various toxic gases or substances harmful to the human body. As a result, even if the fire suppression is completed quickly, it is difficult or difficult to disinfect or clean. The cleaning operation took a significant amount of time. In addition, there was a problem that other operations such as snow removal in these areas are not easy.

It is to provide an underground buried multi-purpose fire hydrant system that can be used for various purposes, such as fire suppression, prevention, snow removal, and cleaning, without being restricted by the installation space by being installed underground. It is not limited to the technical problem as described above, and another technical problem may be derived from the following description.

An underground buried multipurpose firefighting system according to the present invention includes: a buried box in which the side and lower surfaces of the omnidirectional are sealed, and a part of the upper surface is buried underground in the form of an open manhole; a door module covering or exposing an open portion of the upper surface of the buried box; a water supply pipe installed inside the buried box to receive fire extinguishing water from the outside of the buried box; a plurality of drug reservoirs installed inside the buried box to store a plurality of kinds of drugs including a fire extinguishing agent used for fire extinguishing purposes and a different kind of drug used for a purpose different from the fire extinguishing purpose; a valve module for allowing at least one kind of drug to be introduced into the water supply pipe from at least one drug reservoir among the plurality of drug reservoirs according to a user operation; and a hose for spraying a mixture of at least one kind of drug introduced into the water supply pipe and fire extinguishing water supplied through the water supply pipe.

When the door module is closed, the open portion of the upper surface of the buried box is sealed by the door module, and as the door module is opened, the hose moves from the inside of the buried box through the upper surface open portion of the buried box. It is moved to the ground above the buried box.

The valve module includes a plurality of drug valves installed between the plurality of drug reservoirs and the water supply pipe, and each drug valve is opened or blocked according to a user operation, thereby allowing drug inflow from the respective drug reservoirs to the water supply pipe. Or cut off, the at least one kind of drug may be introduced into the water supply pipe by the opening of at least one of the plurality of drug valves and the blocking of the remaining drug valves.

The valve module may further include a mixer for mixing a portion of the fire extinguishing water supplied through the water supply pipe and at least one kind of drug that has passed through the at least one drug valve.

The valve module may include a first branch pipe for supplying a portion of the fire extinguishing water flowing through the water supply pipe to the mixer as a pipe branched from the water supply pipe; and a second branch pipe for discharging the mixture generated in the mixer to the inside of the water supply pipe by the hydraulic pressure of the fire extinguishing water flowing into the mixer through the first branch pipe to a pipe branched from the water supply pipe to the inside of the water supply pipe can

The underground buried multi-purpose fire fighting system is installed in the water supply pipe line between the first branch pipe and the second branch pipe and is opened or shielded according to a user's operation to allow the supply of fire extinguishing water from the outside of the buried box to the water supply pipe, or It may further include a main valve to block.

In a state in which the main valve and the plurality of chemical valves are all blocked, the inside of the mixer is kept filled with fire extinguishing water introduced through the first branch pipe, and the main valve and the at least one chemical valve are closed. When opened, the extinguishing water filled in the mixer and at least one kind of medicine passing through the at least one medicine valve are mixed, and the mixture generated in the mixer by the hydraulic pressure of the extinguishing water flowing into the mixer is produced in the water supply pipe. It can be discharged inside.

Inside the mixer, a partition pipe of a form in which the second branch pipe extends to the inside of the mixer is formed, and the outlet of the plurality of drug valves is located below the partition inlet, so that the at least one drug valve At least one kind of drug that has passed may flow back after flowing out from the outlet of the at least one drug valve, pass through the partition pipe and the second branch pipe in turn, and be introduced into the water supply pipe.

The conduit of the water supply pipe gradually narrows from the branched position of the first branch to the branched position of the second branch, and gradually widens as the distance from the branched position of the second branch is increased. formed, and in proportion to the difference between the water pressure of fire extinguishing water in the water supply pipe at the branching position of the first branch pipe and the fire water water pressure in the water supply pipe at the branching position of the second branch pipe, the mixture inside the mixer into the water supply pipe A sucking force is generated, and the medicament in the at least one drug reservoir may be sucked into the mixer by the suction force.

In the portion where the branch hole of the water supply pipe formed at the branching position of the second branch pipe and the pipe of the shape that gradually widens as the distance from the branching position of the second branch pipe meets, the wall surface of the branch hole of the water supply pipe is recessed of the vortex groove is formed, and the mixture passing through the branch hole of the water supply pipe is moved to the vortex groove side while colliding with the fire extinguishing water flowing in the water supply pipe, and the mixture moved to the vortex groove side collides with the wall surface of the vortex groove and retreats In the process of generating a vortex in the space of the vortex groove, the mixture moved to the vortex groove may be mixed with the extinguishing water flowing in the water supply pipe while temporarily stagnating in the vortex groove space due to the vortex.

The underground buried multi-purpose firefighting system according to the present invention is a buried box buried underground, a door module that covers or exposes an open part of the upper surface of the buried box, and is installed inside the buried box to receive fire extinguishing water from the outside of the buried box a plurality of drug storages for storing a plurality of types of drugs, including a fire extinguishing agent used for fire extinguishing purposes and a different kind of drug used for purposes other than the extinguishing purpose, disposed inside the buried box; It includes a valve module for allowing one kind of drug to flow into the water supply pipe, and a hose for spraying a mixture of at least one kind of drug and fire extinguishing water. As it can be moved from the inside of the box to the ground above the buried box, it can be used for various purposes, such as fire suppression, prevention, snow removal, and cleaning, without being restricted by the installation space.

Roads in downtown attractions, traditional markets, and densely populated areas are often narrow, so fire trucks and quarantine vehicles cannot enter, so there were difficulties in fire suppression, prevention, snow removal, and cleaning in these areas. It took a considerable amount of time to complete the work. The underground buried multi-purpose firefighting system according to the present invention is installed in the basement of a narrow road or alley where it is difficult to enter a fire engine, a quarantine vehicle, a snow removal vehicle, a washing vehicle, etc. You can get it done quickly.

The valve module includes a plurality of drug reservoirs and a plurality of drug valves installed between the water supply pipe, a mixer for mixing some of the extinguishing water supplied through the water supply pipe, and at least one drug that has passed through at least one drug valve, and a water supply pipe to the mixer By including a first branch pipe for supplying a portion of the fire extinguishing water flowing through, and a second branch pipe for discharging the mixture generated in the mixer by the water pressure of the fire water to the inside of the water supply pipe, the drug and the fire water can be sufficiently mixed, The mixture of the drug and fire extinguishing water can be smoothly introduced into the branch pipe. It is not limited to the above-described effects, and another technical effect may be derived from the following description.

1 and 2 are perspective views of an underground buried multi-purpose fire fighting system according to an embodiment of the present invention.
3 is a plan view of the underground buried multi-purpose fire fighting system shown in FIG.
4 is a cross-sectional view of the underground multi-purpose fire fighting system shown in FIG.
FIG. 5 is a cross-sectional view of the door module 3 shown in FIG. 1 .
6 is a longitudinal cross-sectional view of the valve module 6 shown in FIG.
7 is an enlarged view of the inner section of the water supply pipe 4 shown in FIG.
8 is a cross-sectional view of an underground buried multi-purpose fire fighting system according to another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. The embodiment described below relates to an underground buried multi-purpose fire fighting system that can be used for various purposes, such as fire suppression, prevention, snow removal, and cleaning, without being restricted by an installation space by being installed underground. Hereinafter, such an underground multi-purpose fire-fighting system may be briefly referred to as "underground multi-purpose fire-fighting system".

1 and 2 are perspective views of an underground multi-purpose fire-fighting system according to an embodiment of the present invention, FIG. 3 is a plan view of the underground multi-purpose fire-fighting system shown in FIG. 1, and FIG. 4 is the underground shown in FIG. It is a cross-sectional view of a buried multi-purpose firefighting system. 1 to 4, the underground buried multi-purpose fire fighting system according to this embodiment is a buried box (1), a box holder (2), a door module (3), a water supply pipe (4), a plurality of drug storage (5) , the valve module (6), the reel (7), and the hose (8) are the main components. 1, 3 and 4 show an underground multi-purpose fire fighting system with the door module 3 open, and FIG. 2 shows an underground multi-purpose fire fighting system with the door module 3 closed. In particular, FIG. 4 shows a cross-section of an underground buried multi-purpose firefighting system in a state buried underground. In order to reduce the complexity of FIG. 4 , a portion protruding from the ground as the door module 3 is opened is omitted. The underground buried type multi-purpose firefighting system according to this embodiment may further include other additional components in addition to the above-described components.

The buried box (1) is the outermost part in the lateral direction and the downward direction of the underground buried multi-purpose fire fighting system according to this embodiment, and the side and lower surfaces of the general direction are sealed, and a part of the upper surface is in the form of an open manhole. buried underground The side and lower surfaces of the buried box 1 are buried underground, and in order for the upper surface of the door module 3 to be level with the ground, the upper surface of the buried box 1 is longer than the ground surface by the length of the side of the box holder 2 installed to go down. However, the upper surface of the buried box 1 may be installed higher than or parallel to the ground surface depending on the installation environment of the buried box 1 or the intention of the installer. In particular, the buried box 1 is preferably made of a material excellent in waterproofing and durability, such as concrete, so as to prevent erosion of the electrical equipment therein by underground moisture, water, microorganisms, etc. However, those of ordinary skill in the art to which this embodiment pertains can understand that it may be made of other materials than the above-mentioned materials. In addition, when the work of burying the buried box (1) underground, it is preferable to compact the ground where the buried box (1) is to be installed so that the buried box (1) is not submerged.

The box holder 2 is a rectangular horizontal frame 21 of the same shape as the top surface of the buried box 1 covering the top surface of the buried box 1, and is bent upward from the inner edge of the horizontal frame 21 at a right angle It consists of an inner vertical frame 22 that rises, and an outer vertical frame 23 that is bent at right angles upward from the outer rim of the horizontal frame. Since the horizontal frame 21 of the box holder 2 has the same shape as the upper surface of the buried box 1 to cover the upper surface of the buried box 1, it has a rectangular shape corresponding to the upper surface open portion of the buried box 1 It has an open area. The hose (8) and the reel (7) are moved to the ground or into the buried box (1) through this opening. The horizontal frame 21 of the box holder 2 provides a space for coupling with the door module 3 , and the inner vertical frame 22 is closely coupled with the waterproof band 35 attached to the door module 3 . Provides an edge for the, and the external vertical frame 23 provides an edge for fixing the door module (3).

Nut-shaped grooves are formed on the upper surface of the buried box 1 , and holes corresponding to the grooves of the buried box 1 are formed in the horizontal frame 21 of the box holder 2 . The buried box 1 and the box holder 2 may be coupled to each other by inserting bolts into the grooves of the upper surface of the buried box 1 through the holes of the horizontal frame 21 of the box holder 2 . The horizontal frame 21 of the box holder 2 may be coupled to the upper surface of the buried box 1 in a sealed state by filling the joint portion between the buried box 1 and the box holder 2 with a waterproofing agent such as silicone. The box holder 2 is preferably made of a hard material that does not deform under any conditions, for example, a metal material. Four rings 203 are coupled to the outer edge of the box holder (2). For the construction of the underground buried multi-purpose fire fighting system according to this embodiment, the buried box 1 needs to be moved. Since the buried box 1 is very heavy, the buried box 1 can be moved using a fork crane after tying the rope to the ring 203 .

The door module 3 is rotatably hinged to the box holder 2 to cover or expose an open portion of the upper surface of the buried box 1 according to its opening/closing operation. FIG. 5 is a cross-sectional view of the door module 3 shown in FIG. 1 . 1 to 5 , the door module 3 includes an upper plate 31 , an auxiliary door 32 , a lower plate 33 , a plurality of dehumidifying pads 34 , and a waterproof band 35 . In order to withstand the ground load applied to the underground multi-purpose firefighting system as people or vehicles can pass thereon, the upper plate 31, auxiliary door 32, and lower plate 33 of the door module 3 are It is made of a metal material whose shape is not easily deformed, and in particular, it is preferably made of an aluminum material that is light and does not easily rust.

The upper plate 31 and the auxiliary door 32 are the outermost parts in the upward direction of the underground buried multi-purpose fire fighting system when the door module 3 is closed, and are exposed to the ground to contact the upper outdoor air. The upper plate 31 is formed in the form of a square panel, and one side of the upper surface is depressed. The auxiliary door 32 is formed in the form of a square plate to fit the recessed portion of the upper surface of the upper plate 31, and is hinged to be rotatably coupled to the step of the recessed portion of the upper surface of the upper plate 31 according to its opening and closing operation. ) to cover or expose the depression of the upper surface. The upper surface of the door module 3, that is, the upper surface of the upper plate 31 and the auxiliary door 32, serves as a sidewalk or a roadway when the door module 3 is closed. According to the present embodiment, as the handle of the top plate 31 can be hidden under the auxiliary door 32, the upper surface of the door module 3 is a flat surface that does not interfere with the movement of vehicles, objects, or people's walking. can be provided as

The two locking devices 310 are installed between the top plate 31 and the box holder 2 to lock the top plate 31 so that the top plate 31 is not opened when the top plate 31 is closed. Each locking device 310 is composed of a pair of levers and hooks. When the lever is lowered, the lever and the hook are engaged, and when the lever is lowered, the lever and the hook are separated. The levers of the left and right locking devices 310 are installed on the left and right sides of the recessed portion of the upper surface of the upper plate 31 , and the hooks are installed on the upper surface of the horizontal frame 21 of the box holder 2 . The user can open the door module 3 in the following order. First, the user opens the auxiliary door 32 by holding the handle of the auxiliary door 32 , lifting the auxiliary door 32 , and then tilting it back. Accordingly, the two levers installed in the recessed portion of the upper surface of the upper plate 31 are exposed. Then, the user raises the two levers to unlock each locking device 310 . Then, the user can open the door module 3 by holding the handle of the upper plate 31 , lifting the upper plate 31 , and then tilting it back.

5, on the lower surface of the upper plate 31 of the door module 3, the upper plate 31 along the upper periphery of the inner vertical frame 22 of the box holder 2 in the closed state ) A gap in the form of going round the circumference of the lower surface is provided, and the waterproof band 35 is inserted and adhered to the gap. The waterproof band 35 may be made of a material having elasticity, such as rubber or silicone. In a state where the door module 3 is closed, the waterproof band 35 attached to the lower surface of the upper plate 31 is pressed by the upper end of the inner vertical frame 22 of the box holder 2, and the box by such pressing The close coupling between the inner vertical frame of the holder 2 and the waterproof band 35 seals the gap between the inner vertical frame of the box holder 2 and the upper plate 31 . In this way, when the door module 3 is closed, the open portion of the upper surface of the buried box 1 is covered and sealed by the door module 3 . Accordingly, when the door module 3 is closed, even if it rains or the sewage on the road flows through the door module 3 , water cannot flow into the buried box 1 .

The lower plate 33 is formed in the form of a square plate, and is attached to the lower surface of the upper plate 31 using bolts to form a dehumidifying and insulating space 30 between the upper plate 31 and the upper plate 31 . The dehumidification insulation space 30 communicates with the inner space of the buried box 1 through the gap between the upper plate 31 and the lower plate 33 .

1 and 2 , a plurality of drain holes 201 are formed on the edge of the bottom surface of the box holder 2 . When the door module 3 is closed, even if it rains or the sewage on the road flows through the door module 3, water cannot flow into the buried box 1 as described above, but the door module 3 and Water flows into the gap between the box holders (2). In this way, when the door module 3 is closed, the water introduced into the gap between the door module 3 and the box holder 2 flows to the surroundings through the drain hole 201 of the box holder 2 .

The clapboard 202 is installed on the outside of the drain hole 201 of the box holder 2 in the form of a square flat plate so that water leaked from the drain hole 201 of the box holder 2 flows down vertically. When the work of burying the buried box (1) underground, the buried box (1) is installed on it after compacting the ground where the buried box (1) is to be installed and then the buried box (1) is installed thereon and the surrounding is filled with soil. When the water leaked from the drain hole 201 of the box holder 2 flows around the buried box 1, the soil filled in this way may be lost.

The water supply pipe (4) is installed inside the buried box (1) and is a pipe made of a metal material for receiving fire extinguishing water from the outside of the buried box (1). The inlet of the water supply pipe 4 is exposed to the outside of the buried box 1 and is connected to a water pipe (not shown), and the outlet is connected to the hose 8 through the elbow storage 48 .

The main valve 45 is installed in the inlet conduit of the water supply pipe 4 to allow or block the supply of fire extinguishing water from the outside of the buried box 1 to the water supply pipe 4 according to a user operation. According to the lever operation of the main valve 45 by the user, the inlet pipe of the water supply pipe 4 is opened or blocked. More specifically, the main valve 45 is installed in the water supply pipe (4) pipe between the first branch pipe (63) and the second branch pipe (64) to be opened or shielded according to a user's operation, whereby the buried box (1) Allows or blocks the supply of fire extinguishing water from the outside of the first branch pipe 63 to the water supply pipe 4 part of the rear side.

A plurality of drug storage (5) is installed in the interior of the buried box (1) for storing a plurality of types of drugs including a drug for fire extinguishing used for fire extinguishing purposes and different kinds of drugs used for purposes other than the purpose of fire extinguishing It is a storage container in the form of a dog bottle. A nut-type screw thread is formed on the spout on the outlet side of each drug reservoir (5). For example, among the four drug reservoirs 5, the first drug reservoir 51 stores a digestive drug, the second drug reservoir 52 stores a disinfectant drug, and the third drug reservoir 53 ) is stored in the snow-removing agent, the fourth chemical storage 52 may be stored in the cleaning agent. Fires can be classified into several types such as general fires (type A) and oil fires (type B), and the extinguishing agent used is different depending on the type. Accordingly, different types of extinguishing agents may be stored in different drug repositories.

The valve module (6) is installed between the water supply pipe (4) and the plurality of drug reservoirs (5) so that any one kind of drug is supplied from any one drug reservoir (5) of the plurality of drug reservoirs (5) according to the user's operation. (4) It plays a role to flow into the inside. For example, according to the user's manipulation of the valve module 6, the extinguishing agent may be introduced into the water supply pipe 4 from the first drug reservoir 51, and the disinfecting drug may be supplied from the second drug reservoir 52 to the water supply pipe. (4) may be introduced into, the snow removal medicament from the third drug reservoir 53 may be introduced into the water supply pipe 4, and the cleaning medicament from the fourth drug reservoir 52 will be introduced into the water supply pipe 4 may be

In addition, the valve module 6 may allow two types of medicaments to be introduced into the water supply pipe 4 from the two medicament reservoirs 5 among the plurality of medicament reservoirs 5 according to a user operation. For example, when it is necessary to disinfect a ground target such as a building in which a fire has occurred, the extinguishing agent and the disinfecting agent from the first chemical storage 51 and the second chemical storage 52 are simultaneously in the water supply pipe (4). By allowing inflow, fire suppression and disinfection of ground targets can be carried out at the same time. Conventionally, it takes a long time because the disinfection is carried out after the fire is extinguished. However, since the fire suppression and the disinfection are carried out at the same time, the required time can be significantly reduced.

6 is a longitudinal cross-sectional view of the valve module 6 shown in FIG. Referring to FIG. 6 , the valve module 6 includes a plurality of chemical valves 61 , a mixer 62 , a first branch pipe 63 , and a second branch pipe 64 . A plurality of chemical valves 61 are installed between the plurality of chemical reservoirs (5) and the water supply pipe (4). Each drug valve 61 is opened or shielded according to the user's operation to allow or block the inflow of the drug from each drug reservoir (5) to the water supply pipe (4). Each drug valve 61 is a kind of ball valve (ball valve) is composed of a straight valve pipe, a ball located in the valve pipe, and a lever for rotating the ball. A through-path is formed in the ball center of each chemical|medical agent valve 61. The ball rotates according to the user's operation of the lever, and the straight valve tube is opened or shielded according to the rotation of the ball.

In Figure 6, each chemical valve 61 is implemented as a ball valve of a very simple structure, the first chemical valve 611 is opened, the remaining chemical valves 612 to 614 is shown an example that is shielded. Each drug valve 61 may be implemented as a valve of a different structure. In this way, any one type of drug can be introduced into the water supply pipe (4) by the opening of any one of the chemical valves of the plurality of chemical valves (61) and the blocking of the remaining chemical valves. Two types of drugs may be introduced into the water supply pipe (4) at the same time by the opening of the two drug valves and the blocking of the remaining drug valves among the plurality of drug valves (61).

The mixer 62 mixes some of the fire extinguishing water supplied through the water supply pipe 4 and any one type of drug that has passed through any one valve, thereby mixing some of the fire extinguishing water supplied through the water supply pipe 4 and any one valve Produces a drug mixture of any one type that has passed through The mixer 62 may mix some of the fire extinguishing water supplied through the water supply pipe 4 and two types of drugs that have passed through the two valves. The mixer 62 is formed in the form of a hexagonal chamber in which the entire surface is closed except for the inlet hole, the water outlet hole, and the plurality of valve holes. Based on the example shown in FIG. 6 , a water inlet hole is formed on the left side of the mixer 62 , a water outlet hole is formed on the lower surface, and four valve holes are formed on the upper surface.

The perimeter of each valve hole of the mixer 62 protrudes in the form of a cylindrical tube, and a bolt-type thread is formed in the protruding portion of the periphery of each valve hole. By screwing the spout on the outlet side of each drug reservoir 5 to the protruding part around each valve hole of the mixer 62, each drug reservoir 5 may be fixedly positioned on the mixer 62 outer surface. The user may couple each drug reservoir 5 to the mixer 62 or separate it from the mixer 62 by rotating each drug reservoir 5 in the coupling direction or in the opposite direction.

The first branch pipe 63 is a pipe branched from the water supply pipe 4 on the front side of the main valve 45 and supplies some of the fire extinguishing water flowing through the water supply pipe 4 to the mixer 62 . The first branch pipe 63 is a pipe thinner than the water supply pipe 4 , and its inlet is connected to a branch hole of the water supply pipe 4 located in front of the main valve 45 , and its outlet is connected to the inlet hole of the mixer 62 . do. In a state in which the door module 3 is closed, that is, the underground buried multi-purpose fire fighting system is not used, the main valve 45 and the plurality of chemical valves 61 are entirely shielded. In this way, the interior of the mixer 62 in a state in which the main valve 45 and the plurality of chemical valves 61 are entirely shielded maintains a state filled with the fire extinguishing water introduced through the first branch pipe 63 .

When the main valve 45 and any one of the chemical valves are opened, the fire extinguishing water filled in the mixer 62 and any one type of medicine passing through any one of the chemical valves are mixed, and the fire extinguishing flowing into the mixer 62 The mixture produced in the mixer 62 by the water pressure is discharged into the water supply pipe 4 . When the main valve 45 and the two chemical valves are opened, the fire extinguishing water filled in the mixer 62 and the two types of chemicals passing through the two chemical valves are mixed and discharged into the water supply pipe 4 . When the medicament is introduced into the mixer 62 in a state in which the inside of the mixer 62 is empty, the medicament is deposited on the inner bottom surface of the mixer 62 and may gradually accumulate. According to this embodiment, since the inside of the mixer 62 is always filled with fire extinguishing water, drug deposition can be prevented, and the management of the mixer 62 becomes very easy.

The second branch pipe 64 is a pipe branched from the water supply pipe 4 at the rear side of the main valve 45, and is a mixer by the hydraulic pressure of fire water flowing into the mixer 62 through the first branch pipe 63. The mixture generated in (62) is discharged into the water supply pipe (4). The second branch pipe 64 is a pipe thinner than the water supply pipe 4 , and its inlet is connected to the water outlet hole of the mixer 62 , and its outlet is connected to the branch hole of the water supply pipe 4 located at the rear side of the main valve 45 . do. As the valve module 6 is composed of a plurality of drug valves 61, mixer 62, first branch pipe 63, and second branch pipe 64 as described above, the drug and fire extinguishing water are sufficiently mixed It can be, and the mixture of the drug and fire extinguishing water can be smoothly introduced into the water supply pipe (4).

Inside the mixer 62, a partition pipe 620 in a form in which the second branch pipe 64 extends to the inside of the mixer 62 is formed. As shown in Figure 6, as the outlet of the plurality of drug valves 61 is located below the height of the inlet of the partition pipe 620, any one kind of drug passing through any one drug valve is the drug valve 61 ) flows backward after flowing out from the outlet, passes through the partition pipe 620 and the second branch pipe 64 in turn, and flows into the water supply pipe 4 . After the two kinds of drugs that have passed through the two drug valves flow out from the outlets of the two drug valves 61, they flow backward and pass through the partition pipe 620 and the second branch pipe 64 in turn to the water supply pipe (4). may be imported.

Fire water travels through the water supply pipe (4) at a very high speed so that it can reach very far from the outlet of the hose (8). Even if the drug is introduced into the water supply pipe (4), the drug may be discharged from the hose (8) as a lump of drug in a state in which the drug is not sufficiently mixed with the fire extinguishing water. According to this embodiment, the drug can be sufficiently mixed with the fire extinguishing water in the process of backflow in the fire extinguishing water filled in the mixer 62, and as a result, the mixture generated in the mixer 62 can be homogenized.

7 is an enlarged view of the inner cross section of the water supply pipe 4 shown in FIG. Referring to FIG. 7 , the pipeline of the water supply pipe 4 gradually narrows from the branched position of the first branch pipe 63 toward the branched position of the second branch pipe 64 , and the second branch pipe 64 . It is formed in a form that gradually widens as it goes away from this branched position. According to the Bernoulli principle, in the wide part of the water supply pipe (4), the pressure of the fire extinguishing water is high and the flow rate is slow. On the other hand, in the narrow part of the pipeline, the pressure of the fire water is low and the flow rate is high. That is, the water pressure of the fire water in the water supply pipe 4 at the branching position of the first branch pipe 63 is higher than the water pressure in the water supply pipe 4 at the branching position of the second branch pipe 64 .

In proportion to the difference between the water pressure of the fire extinguishing water in the water supply pipe 4 at the branched position of the first branch pipe 63 and the water pressure of the fire extinguishing water in the water supply pipe 4 at the branched position of the second branch pipe 64 . A suction force for sucking the mixture inside the mixer 62 into the water supply pipe 4 is generated. When any one of the drug valves is opened by this suction force, the drug in any one of the drug reservoirs may be sucked into the mixer 62 . When the two drug valves are opened, the drugs inside the two drug reservoirs may be sucked into the mixer 62 . Some drugs are highly viscous, so it may not be easy to flow into the mixer 62 from the drug reservoir 5 only by dropping by its own weight. According to this embodiment, since the drug in the drug reservoir can be sucked into the mixer 62 with a constant suction force by the branching and pipe structure of the water supply pipe 4 as described above, the drug and the extinguishing water can be used regardless of the drug viscosity. It can be mixed in a certain ratio.

8 is a cross-sectional view of an underground multi-purpose fire fighting system according to another embodiment of the present invention. Compared with the embodiment shown in Figure 4 and the embodiment shown in Fig. 8, the drug reservoir 5 of the embodiment shown in Fig. 4 is disposed above the mixer 62, but the drug reservoir of the embodiment shown in Fig. 8 (5) is arranged below the mixer (62). When the medicament moves from the medicament reservoir 5 to the mixer 62, in the embodiment shown in Figure 4, the medicament flows down in the direction of gravity, but in the embodiment shown in Figure 8, the medicament flows up in the opposite direction. As described above, since the medicine inside the chemical reservoir can be sucked into the mixer 62 with a constant suction force, the flow rate of the fire extinguishing water is fast and the fire extinguishing in the water supply pipe 4 at the branched position of the first branch pipe 63 If the difference between the water pressure and the fire water pressure in the water supply pipe 4 at the branched position of the second branch pipe 64 is large, as shown in FIG. 8 , the chemical reservoir 5 is placed under the mixer 62 . can be If the suction force for the drug inside the drug reservoir is large and the viscosity of the drug is very low, the embodiment shown in FIG. 8 may be more preferable than the embodiment shown in FIG. 4 .

Referring back to FIG. 7 , the branch hole of the water supply pipe 4 formed at the branching position of the second branch pipe 64 and the second branch pipe 64 are branched as the distance from the branched position is increased. A vortex groove 400 in which the passage wall of the branch hole of the water supply pipe 4 is recessed is formed at the meeting portion. The mixture passing through the branch hole of the water supply pipe 4 moves toward the vortex groove 400 while colliding with the fire extinguishing water flowing in the water supply pipe 4, and the mixture moved toward the vortex groove 400 collides with the wall surface of the vortex groove 400. Thus, a vortex is generated in the space of the vortex groove 400 in the process of retreating. The mixture moved to the vortex groove 400 due to the vortex generated in this way is mixed with the fire extinguishing water flowing in the water supply pipe 4 while temporarily stagnating in the vortex groove 400 space.

As described above, since the flow rate of fire extinguishing water in the water supply pipe 4 at the branched position of the second branch pipe 64 is much faster than that of other water supply pipe portions, the mixture passing through the branch hole of the water supply pipe 4 is in the water supply pipe 4 . It may not be sufficiently mixed with running fire water. Because the mixture moved to the vortex groove 400 side due to the vortex generated in the space of the vortex groove 400 is mixed with the extinguishing water flowing in the water supply pipe 4 while temporarily stagnating in the vortex groove 400 space, the water supply pipe (4) ) Even if the flow rate of the fire extinguishing water flowing in it is fast, the fire extinguishing water flowing in the water supply pipe (4) and the mixture passing through the branch hole of the water supply pipe (4) can be sufficiently mixed.

The elbow 48 is a "T"-shaped metal pipe that is inserted between the water supply pipe 4 and the hose 8 to connect the water supply pipe 4 and the hose 8, and at the same time, the water supply pipe 4 and the hose 8 ) to drain the remaining water in the connection line. The lower outlet of the elbow storage 48 is opened or shielded according to the operation of the lever of the elbow storage 48 by the user. When the lower outlet of the elbow storage 48 is opened, the water remaining in the connection line between the water supply pipe 4 and the hose 8 is discharged.

The reel 7 is attached to the lower surface of the door module 3 by bolting, and the hose 8 is wound around the cylindrical portion and stored.

The hose 8 is a soft pipe made of a synthetic resin material for spraying a mixture of any one type of drug introduced into the water supply pipe 4 and the fire extinguishing water supplied through the water supply pipe 4 . Two kinds of drugs may be introduced into the water supply pipe 4, and in this case, the hose 8 sprays a mixture of the two kinds of drugs and fire extinguishing water. The inlet of the hose 8 is connected to the outlet of the water supply pipe 4 through the elbow 48, and the outlet of the hose 8 sprays a mixture of the chemical and fire extinguishing water. As the outlet of the hose 8 is formed in the form of a nozzle, the mixture of the chemical and fire extinguishing water can be strongly sprayed.

As shown in FIG. 3 , when the door module 3 is closed, the reel 7 attached to the lower surface of the door module 3 and the hose 8 wound around the reel 7 are It is located inside and the open part of the upper surface of the buried box (1) is sealed by the door module (3). 1 and 2, as the door module 3 is opened by the user, the reel 7 attached to the lower surface of the door module 3 and the hose 8 wound around the reel 7 are buried. It is moved from the inside of the buried box (1) to the ground above the buried box (1) through the upper surface open portion of the box (1). Then, by the user, the hose 8 is released from the reel 7 and moved near the ground target, such as a building where a fire has occurred. According to the lever operation of the main valve 45 by the user, the mixture inside the hose 8 is sprayed to the ground target. When the use of the underground multi-purpose firefighting system is completed, the door module 3 is closed after the hose 8 is wound on the reel 7 by the user.

Roads in downtown attractions, traditional markets, and residential areas are often narrow, so fire engines, quarantine vehicles, snow removal vehicles, and washing vehicles cannot enter. There were difficulties in the work, and it took a considerable period of time to complete the work. Due to this, there were problems such as the occurrence of large fires due to the delay in extinguishing the fire, the outbreak of infectious diseases due to the delay in quarantine, and the occurrence of various accidents due to the delay of snow removal. The underground buried multi-purpose firefighting system according to the present invention is installed in the basement of a narrow road or alley where it is difficult to enter a fire engine, a quarantine vehicle, a snow removal vehicle, a washing vehicle, etc. You can get it done quickly.

The gas spring 9 is installed between the door module 3 and the buried box 1 to serve as an assisting device to increase the user's manpower. The upper end of the gas spring 9 is rotatably coupled to the lower surface of the door module 3 , and the lower end is rotatably coupled to the inner surface of the buried box 1 . Such a gas spring is mainly used in the hood and trunk of automobiles. 1 and 2 illustrate an example in which one gas spring 9 is installed on the right side, two gas springs 9 may be installed on the left and right sides. The gas spring 9 not only serves to reduce the user's manpower burden when the user opens the door module 3, but also includes the door module 3 and the box holder ( 2) Damage due to collision between them can also be prevented.

As shown in FIG. 5 , the plurality of dehumidifying pads 34 are installed in the dehumidifying and insulating space 30 between the upper plate 31 and the lower plate 33 . The number of dehumidification pads 34 installed in the dehumidification insulation space 30 may vary depending on the climate and surrounding environment of the area where the underground buried multi-purpose fire fighting system is installed. For example, in the dehumidification insulation space 30 between the upper plate 31 and the lower plate 33, one dehumidifying pad 34 may be installed depending on the climate and surrounding environment of the area where the underground buried multi-purpose fire fighting system is installed. there is. The dehumidifying pad 34 can minimize the change in the internal temperature of the buried box 1 by absorbing or discharging moisture in the dehumidifying and insulating space 30 , and can maintain the internal humidity constant.

Each of the plurality of unidirectional drains 100 is installed at each corner of the inner bottom surface of the buried box 1, allows water flow from the inside of the buried box 1 to the outside of the buried box 1, and the buried box 1 ) to block the flow of water from the outside to the inside of the buried box (1). When the door module 3 is closed, the moisture accumulated in each dehumidifying pad 34 in a liquid state falls toward the inner bottom surface of the buried box 1, and toward the inner bottom surface of the buried box 1 The dropped liquid moisture is discharged to the outside of the buried box 1 through at least one unidirectional drain 100 . As shown in FIGS. 4 and 6 , each of the plurality of unidirectional drains 100 corresponds to the lower vertical direction of the gap between the upper plate 31 and the lower plate 33 of the door module 3 . It is installed at the corner point of the inner floor surface. Accordingly, the liquid moisture generated from each dehumidifying pad 34 directly falls to the inlet of each unidirectional drain 100 , and it is possible to prevent the liquid moisture from falling on the internal parts of the buried box 1 .

So far, the present invention has been looked at with respect to preferred embodiments thereof. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in a modified shape without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

1 ... buried box
100 ... unidirectional drain
2 ... box holder
21 ... horizontal frame
22 ... inner vertical frame
23 ... external vertical frame
201 ... drain
202 ... clapboard
203 ... ring
3 ... door module
31 ... tops
32 ... auxiliary door
310 ... lock
33 ... lower plate
30 ... dehumidification insulation space
34 ... dehumidifying pad
35 ... waterproof band
4 ... water pipe
400 ... vortex groove
45 ... main valve
5 ... drug store
6 ... valve module
61 ... chemical valve
62 ... mixer
620 ...
63 ... 1st branch
64 ... 2nd branch
48 ... Elbow
7 ... reel
8 ... hose
9 ... gas spring

Claims (8)

The side and lower surfaces of the front direction are sealed, and a part of the upper surface is buried underground in the form of an open manhole (1);
a door module (3) for covering or exposing an open portion of the upper surface of the buried box (1);
a water supply pipe (4) installed inside the buried box (1) to receive fire extinguishing water from the outside of the buried box;
A plurality of drug reservoirs (5) installed inside the buried box (1) for storing a plurality of types of drugs including a fire extinguishing agent used for fire extinguishing purposes and a different kind of drug used for a purpose different from the fire extinguishing purpose;
A valve module (6) for allowing at least one kind of drug to be introduced into the water supply pipe (4) from at least one drug reservoir (5) among the plurality of drug reservoirs (5) according to a user operation; and
A hose (8) for spraying a mixture of at least one kind of drug introduced into the water supply pipe (4) and fire extinguishing water supplied through the water supply pipe (4),
When the door module (3) is closed, the open portion of the upper surface of the buried box (1) is sealed by the door module (3),
As the door module 3 is opened, the hose 8 is moved from the inside of the buried box 1 to the ground above the buried box 1 through the upper surface open portion of the buried box 1 . An underground multi-purpose firefighting system characterized by a buried underground. The method of claim 1,
The valve module 6 includes a plurality of drug valves 61 installed between the plurality of drug reservoirs 5 and the water supply pipe 4,
Each of the drug valve 61 is opened or blocked according to the user's operation to allow or block the inflow of the drug from the respective drug reservoir (5) to the water supply pipe (4),
Underground multi-purpose firefighting system, characterized in that the at least one kind of drug is introduced into the water supply pipe (4) by opening of at least one drug valve among the plurality of drug valves (61) and blocking the remaining drug valves. 3. The method of claim 2,
The valve module 6 is
Underground multipurpose firefighting system, characterized in that it further comprises a mixer (62) for mixing a part of the fire extinguishing water supplied through the water supply pipe (4) and at least one type of drug that has passed through the at least one drug valve. 4. The method of claim 3,
The valve module 6 is
a first branch pipe (63) for supplying a portion of the fire extinguishing water flowing through the water supply pipe (4) to the mixer (62) as a pipe branched from the water supply pipe (4); and
The mixture generated in the mixer 62 by the hydraulic pressure of the fire extinguishing water flowing into the mixer 62 through the first branch pipe 63 through a pipe branched from the water supply pipe 4 is transferred to the water supply pipe 4 ) Underground multi-purpose fire fighting system, characterized in that it further comprises a second branch pipe (64) for discharging to the inside. 5. The method of claim 4,
It is installed in the water supply pipe (4) pipe between the first branch pipe (63) and the second branch pipe (64) and is opened or shielded according to a user operation, so that from the outside of the buried box (1) to the water supply pipe (4) Further comprising a main valve (45) for allowing or blocking the supply of fire water of
In a state in which the main valve 45 and the plurality of drug valves 61 are entirely closed, the inside of the mixer 62 is kept filled with the fire extinguishing water introduced through the first branch pipe 63, ,
When the main valve 45 and the at least one drug valve are opened, the extinguishing water filled in the mixer 62 and at least one kind of drug passing through the at least one drug valve are mixed, and the mixer 62 ), the mixture generated in the mixer (62) by the hydraulic pressure of the fire extinguishing water flowing into the water is discharged into the water supply pipe (4). 5. The method of claim 4,
A partition pipe 620 in a form in which the second branch pipe 64 extends inward of the mixer 62 is formed inside the mixer 62,
As the outlet of the plurality of drug valves 61 is located below the inlet of the partition pipe 620, at least one kind of drug that has passed through the at least one drug valve flows out from the outlet of the at least one drug valve. An underground buried type multi-purpose firefighting system, characterized in that the reverse flow passes through the partition pipe (620) and the second branch pipe (64) in sequence and flows into the water supply pipe (4). 5. The method of claim 4,
The pipeline of the water supply pipe 4 gradually narrows from the branched position of the first branch pipe 63 toward the branched position of the second branch pipe 64, and then the second branch pipe 64 is branched. It is formed in a form that gradually widens as it gets farther from the established position,
In proportion to the difference between the water pressure of fire extinguishing water in the water supply pipe 4 at the branched position of the first branch pipe 63 and the fire water water pressure in the water supply pipe 4 at the branched position of the second branch pipe 64 . A suction force for sucking the mixture inside the mixer 62 into the water supply pipe 4 is generated, and the drug in the at least one drug reservoir is sucked into the mixer 62 by the suction force. Buried multipurpose firefighting system. 8. The method of claim 7,
The water supply pipe has a portion where the branch hole of the water supply pipe 4 formed at the branched position of the second branch pipe 64 and the pipe that gradually widens as the distance from the branched position of the second branch pipe 64 meet A vortex groove 400 in the form of a recessed passage wall of the branch hole of (4) is formed,
The mixture passing through the branch hole of the water supply pipe 4 moves toward the vortex groove 400 while colliding with the fire extinguishing water flowing in the water supply pipe 4,
The mixture moved toward the vortex groove 400 collides with the wall surface of the vortex groove 400 and generates a vortex in the space of the vortex groove 400 in the process of retreating,
The mixture moved to the vortex groove 400 side is temporarily stagnated in the vortex groove 400 space due to the vortex and is mixed with the fire extinguishing water flowing in the water supply pipe 4 . .

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