KR20220021294A - Injection Nozzle Structure for Fire Extinguisher with Variable Length - Google Patents

Abstract

The present invention relates to a spray nozzle structure for a fire extinguisher that has a variable length so as to quickly extinguish a fire. The present invention provides a spray nozzle structure for a fire extinguisher comprising a first spray tube through which a fire extinguishing agent passes; a second spray tube slidably coupled to the inside of the first spray tube; and a spray nozzle coupled to an end of the second spray tube coupled to an end of the second spray tube, wherein the second spray tube is automatically drawn out of the first spray tube to increase the length when the fire extinguishing agent is sprayed through the spray nozzle.

Description

Injection Nozzle Structure for Fire Extinguisher with Variable Length

The present invention relates to a spray nozzle structure for a fire extinguisher having a variable length so as to quickly extinguish a fire.

A fire extinguisher used to extinguish a fire is equipped with a spray nozzle that sprays fire extinguishing powder, and the spray nozzle has a structure connected to the fire extinguisher by a hose.

Since the spray nozzle of the fire extinguisher has a certain fixed length, when a fire occurs, the user holds the spray nozzle and sprays the extinguishing powder toward the location of the fire.

However, since the spraying operation for suppressing the fire is performed by holding the spray nozzle, it is virtually impossible to spray the extinguishing powder at a high location or far away from the fire, and thus there is a limit to effectively suppressing the fire.

Accordingly, the present invention was invented to solve the problems of the prior art, and the problem to be solved by the present invention is that the length of the spray nozzle increases when the fire extinguishing agent is sprayed, so that it can be sprayed far away and the length that can exert the spraying force more strongly It is to provide a spray nozzle structure for a variable fire extinguisher.

The present invention is a first injection pipe through which the extinguishing agent passes; a second injection tube slidably coupled to the inside of the first injection tube; and a spray nozzle coupled to an end of the second spray pipe,

When the fire extinguishing agent is injected through the injection nozzle, the second injection pipe is automatically drawn out in the first injection pipe to extend the length of the fire extinguisher injection nozzle structure may be provided.

The present invention can have the following effects.

1) When a fire extinguisher is used for firefighting, the length of the spray nozzle structure can be automatically extended.

The first injection pipe and the second injection pipe drawn out so as to extend in length from the inside of the first injection pipe, and a jet nozzle coupled to the end of the second injection pipe, the second injection pipe formed on one end side of the second injection pipe In the first inclined hole, the second inclined hole formed on the opposite end side, and the straight hole formed between the first inclined hole and the second inclined hole, the inlet diameter of the first inclined hole is the first diameter and the outlet side of the second inclined hole When the diameter is the second diameter and the diameter of the straight hole is the third diameter, the second diameter of the outlet side of the second inclined hole is formed the smallest, so that the injection pressure of the fire extinguishing agent is increased, and the fire extinguishing powder sprayed with a strong force By the injection pressure, the length of the second injection pipe is automatically extended as it slides and withdraws from the inside of the first injection pipe, so it is radiated to an optimal radiation range that can completely suppress a distant fire-occurring object, resulting in an urgent fire Even in a situation, it is possible to extinguish the initial fire or effectively extinguish the fire by quick response.

2) When the second injection pipe is withdrawn, the airtightness of the first injection pipe can be reliably maintained.

The second injection pipe is drawn out with a strong force from the inside of the first injection pipe, so that the end of the second injection pipe is engaged in a state in which airtightness is reliably maintained inside the first injection pipe, and furthermore, the second injection pipe Since the sealing is made secondary by the sealing ring formed on the outer peripheral surface of the end, it is possible to reliably prevent the phenomenon that the fire extinguishing agent leaks into the gap between the first injection pipe and the second injection pipe when the fire extinguishing agent is fired.

As such, the present invention can be radiated in an optimal radiation range that can completely suppress a distant fire suppression target by using a spray nozzle structure having a variable length when a fire occurs, particularly in a factory, etc.

In addition, the present invention can prevent the spread of fire in advance by enabling the initial suppression or effective fire suppression by a quick response even in an emergency fire situation to be executed.

1 is a combined perspective view of a spray nozzle structure according to the present invention.
FIG. 2 is a perspective view of a state in which the second injection tube is drawn out in FIG. 1 .
3 is a cross-sectional view of a spray nozzle structure according to the present invention.
4 is an enlarged cross-sectional view of part A of FIG. 3 .
5 is a schematic cross-sectional view of a second injection pipe of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a combined perspective view of a spray nozzle structure according to the present invention.

Referring to FIG. 1 , the spray nozzle structure 10 of the present invention includes a first injection pipe 100 , a second injection pipe 200 that is slidably coupled to the first injection pipe 100 , and a second injection stand It may be made of a spray nozzle 300 coupled to the end of the 200.

The first injection pipe 100 may be provided with a hose 20 connected to the fire extinguisher, and a firing switch 110 (trigger) for spraying the fire extinguishing agent provided in the fire extinguisher may be formed.

As the extinguishing agent used in the present invention, it may consist of extinguishing powder, extinguishing gas, and extinguishing liquid, and in the embodiment of the present invention, extinguishing powder will be described as an example.

A holder for hanging the spray nozzle structure 10 is provided on the fire extinguisher, and a hose holder for winding the hose 20 and a grippable handle to easily move the fire extinguisher may be formed on one surface of the holder.

The fire extinguisher in which the spray nozzle structure 10 of the present invention is installed can be used regardless of capacity, and in particular, it may be preferable to use it for a large capacity.

The length of the second injection pipe 200 may be increased as it slides and withdraws from the inside of the first injection pipe 100 by the injection pressure of the fire extinguishing powder to be injected.

2 is a perspective view of a state in which the second injection tube is drawn out in FIG. 1 , FIG. 3 is a cross-sectional view of the injection nozzle structure according to the present invention, and FIG. 4 is an enlarged cross-sectional view of part A of FIG. 3 .

2 to 4, when the length of the second injection pipe 200 is increased while being drawn out from the inside of the first injection pipe 100, the end 210 of the second injection pipe 200 is 1 It may be jammed in the inside of the injection pipe 100 .

An inclined surface 102 may be formed on one side of the through hole 101 formed in the first injection pipe 100 so that the second injection pipe 200 is caught when it is withdrawn.

The inclined surface 102 may be inclined so that the inner diameter of the through hole 101 is narrowed in the direction in which the fire extinguishing powder is fired.

The outer circumferential surface of the end 210 of the second injection pipe 200 slides in the first injection pipe 100 and at the same time, an inclined surface 211 may be formed to maintain a stationary state when drawn to a predetermined length. .

The inclined surface 211 may be inclined so that the outer diameter of the end 210 is narrowed in the direction in which the extinguishing powder is fired.

The through hole 220 formed over the entire inner length of the second injection pipe 200 may have a structure formed by being divided into three sections L1, L2, and L3. That is, the inside of both ends of the second injection pipe 200 is formed of a first section (L1) and a second section (L2) in which the first inclined hole 221 and the second inclined hole 222, which are inclined holes, are formed, , between the first inclined hole 221 and the second inclined hole 222 on both sides may be formed of a third section L3 in which a straight hole 223 is formed.

Referring to FIG. 5 , the inlet diameter of the first inclined hole 221 is the first diameter d1 , the outlet diameter of the second inclined hole 222 is the second diameter d2 , and the straight hole 223 is When comparing the third diameter d3, the second diameter d2 may be formed to be the smallest.

The diameter of the first inclined hole 221 decreases from the entrance side toward the point where it meets the straight hole 223 , but the diameter of the point where it meets the straight hole 223 is the third diameter d3 of the straight hole 223 . Since it may be formed in the same way as , the first diameter d1 , the second diameter d2 , and the third diameter d3 may be compared.

Here, if the size of the second diameter d2 is too large, the injection pressure of the fire extinguishing powder passing through the through hole 220 of the second injection pipe 200 may be reduced, and if it is too small, the Since the injection may not be made smoothly, it is preferable to form it in an appropriate size. For example, it can be formed to 11 ~ 13mm. However, it is not necessarily limited to this diameter size.

When the fire extinguishing powder is discharged from the fire extinguisher during the withdrawal operation of the second injection pipe 200 , it passes through the first inclined hole 221 formed at the end 210 of the second injection pipe 200 , and then the straight hole 223 ) to pass through the second inclined hole 222 .

At this time, since the first inclined hole 221 has a structure inclined to be narrow in the firing direction of the fire extinguishing powder, the injection pressure can be increased, and the process of passing the second inclined hole 222 through the straight hole 223 At the same time as the injection pressure of the fire extinguishing powder is further increased, it may act as a force for drawing out the second injection pipe 200 .

Therefore, since the second injection pipe 200 is pushed with an increased force in the process of spraying the fire extinguishing powder, the second injection pipe 200 is drawn out by sliding inside the first injection pipe 100, The end 210 of the second injection pipe 200 may be in close contact with the inclined surface 102 formed at the end of the first injection pipe 100 and may be caught.

In other words, the first inclined hole 221 serves to increase the spraying pressure when the fire extinguishing powder is sprayed, and the second inclined hole 222 ensures the second spraying pipe 200 as the spraying pressure of the fire extinguishing powder is further increased. It can play a role in pulling out.

If the second injection pipe 200 is not drawn out with a strong force from the inside of the first injection pipe 100 , the end 210 of the second injection pipe 200 is inside the first injection pipe 100 . It may not be securely attached to the formed inclined surface 102 , and then the possibility that the airtight leaks and the extinguishing powder leaks cannot be excluded.

On the other hand, the inner passage hole from the end 210 to the opposite end side over the entire length of the second injection pipe 200 may be formed as an inclined inclined hole. However, in this case, considering the specifications of the second injection pipe 200 for manufacturing, the diameter (d2) of the second inclined hole 222 may be too small, and then it may interfere with the injection of the fire extinguishing powder. . Therefore, in the case of forming the inclined hole inclined in the firing direction of the fire extinguishing powder over the entire length of the second injection pipe 200, it can be manufactured in consideration of an appropriate size.

In addition, when the second injection pipe 200 is withdrawn from the outer peripheral surface of the end 210 of the second injection pipe 200 , it is in close contact with the inclined surface 102 of the through hole 101 formed inside the first injection pipe 100 . A sealing ring 230 may be formed so as to be sealed while being closed.

Since the sealing is achieved by removing the gap between the first injection pipe 100 and the second injection pipe 200 by the sealing ring 230, the fire extinguishing powder leaking while spraying pressure is leaked when the extinguishing powder is sprayed. can be prevented

Therefore, when the second injection pipe 200 is drawn out from within the first injection pipe 100, the sealing ring 230 automatically closes, so that the fire extinguishing powder can be sprayed to a predetermined distance without reducing the pressure. can

In the present invention, the fire extinguishing powder passes through the second inclined hole 222 of the second injection pipe 200 and the second injection pipe 200 is withdrawn from the inside of the first injection pipe 100 by the increased injection pressure. The end 210 of the second injection pipe 200 is firmly caught on the inclined surface 102 of the first injection pipe 100 and is closely adhered to maintain the airtightness, and furthermore, the airtightness is maintained secondarily by the sealing ring 230 . Since this is maintained, a phenomenon in which the extinguishing powder leaks can be reliably prevented.

In other words, when the second injection tube 200 is withdrawn, the end 210 of the second injection tube 200 is jammed due to the diameter difference according to the movement in the inclined hole 221 of the first injection tube 100 . In this case, the sealing ring 230 formed on the outer peripheral surface of the end 210 may be in close contact with the inner surface of the inclined hole 221 to be sealed.

If the fire extinguishing powder leaks even in a small amount, it cannot be used as fire extinguisher equipment and cannot be approved according to the prescribed laws.

The injection nozzle 300 provided at one end of the second injection pipe 200 may be detachably coupled. That is, the second injection pipe 200 and the injection nozzle 300 may be detachably coupled by screw coupling, and may also be coupled in another detachable structure.

The injection hole 310 may be formed in the interior of the injection nozzle 300 so that the area increases toward the end.

In the spray nozzle structure 10 according to the present invention, when the firing switch 110 is pressed to suppress a fire, when the fire extinguishing powder in the fire extinguisher passes through the inside of the first injection pipe 100 with a predetermined pressure, automatically As the second injection pipe 200 is withdrawn, the extinguishing powder may move, and may be injected through the injection nozzle 300 coupled to the end of the second injection pipe 200 .

In the present invention, when the fire extinguishing powder is sprayed by the operation of the firing switch 110, the length of the spray nozzle structure is longer than when the fire extinguishing powder is sprayed through the spray nozzle structure 10 in a short length and fixed state. When passing through (10), since the firing speed of the fire extinguishing powder is proportional to the internal firing distance of the spray nozzle structure 10, it is possible to spray the fire extinguishing powder further through the spray nozzle 300.

When the firing switch 110 is pressed, the valve is opened inside the upper part of the firing switch 110 , and the fire extinguishing powder in the fire extinguisher can be injected through the hose 20 through the inside of the spray nozzle structure 10 .

Moreover, if the length of the spray nozzle structure 10 is increased, it is possible to more accurately aim and fire the spraying position of the fire extinguishing powder.

In this way, the length of the first injection pipe 100 and the length of the drawn second injection pipe 200 are added to form a spray nozzle structure having a length longer than the initial state, and in this state, when the extinguishing powder is sprayed, the farther away It can be sprayed up to

When a fire occurs in a place such as a factory, the size of the factory is larger than that of a general building and the ceiling is high, so a conventional fire extinguisher provided for fire suppression cannot fire extinguishing powder toward a high ceiling or a distant location, so the fire can be extinguished in the early stage. Although there were many cases where it was not possible to do this, the spray nozzle structure 10 of the present invention can fire extinguishing powder far away, so it can be used particularly usefully in case of a fire in factories, etc., and the firing direction is also more Since it can be fired accurately, it can be extinguished by accurately aiming at the location of the fire.

10... Spray nozzle structure 20... Hose
100... First injection pipe 101... Through hole
102... slope 110... fire switch
200...Second injection tube 210...End
211... slope 220... through hole
221... First bevel hole 222... Second bevel hole
223... straight hole 230... sealing ring
300...blast nozzle 310...blaster
L1... 1st segment L2... 2nd segment
L3... 3rd segment

Claims (5)

a first injection pipe through which the extinguishing agent passes;
a second injection tube slidably coupled to the inside of the first injection tube;
an injection nozzle coupled to an end of the second injection pipe;
including,
When the fire extinguishing agent is injected through the injection nozzle, the second injection pipe is automatically drawn out in the first injection pipe to extend the length of the injection nozzle structure for a fire extinguisher.
The method of claim 1,
An inclined surface is formed on one side of the through hole formed inside the first injection pipe, and an inclined surface is formed on the outer peripheral surface of the end of the second injection pipe,
When the second injection pipe is withdrawn from the first injection pipe, the end of the second injection pipe is caught on the inclined surface of the first injection pipe and is closely adhered to the fire extinguisher injection nozzle structure to maintain airtightness.
The method of claim 1,
The through hole formed in the inside of the second injection pipe,
A first inclined hole and a second inclined hole formed inside both ends of the second injection pipe,
A spray nozzle structure for a fire extinguisher comprising a straight hole formed between the first inclined hole and the second inclined hole.
4. The method of claim 3,
When the inlet diameter of the first inclined hole is the first diameter, the outlet diameter of the second inclined hole is the second diameter, and the diameter of the straight hole is the third diameter,
A spray nozzle structure for a fire extinguisher in which the second diameter of the second inclined hole is formed to be the smallest, and the second spray pipe is drawn out from the inside of the first spray pipe when the fire extinguishing agent passes through the second inclined hole.
According to claim 1,
A sealing ring is provided on the outer peripheral surface of the end of the second injection pipe,
When the second injection pipe is pulled out from the inside of the first injection pipe, when it is caught on the inclined surface of the end of the first injection pipe, the fire extinguisher injection nozzle is sealed by the sealing ring.

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