KR20220045333A - Nozzle structure of the fire extinguisher - Google Patents

Abstract

The present invention relates to a spray nozzle structure of a fire extinguisher and, more specifically, to a spray nozzle structure of a fire extinguisher, capable of extending a radiation distance by solving an eddy arising in a discharge horn as a fire extinguishing chemical substance is sprayed. To achieve the purpose, in accordance with the present invention, the spray nozzle structure comprises: a discharge horn having a coupling part formed at a rear end, and having a sloped surface formed with the inner diameter becoming more expanded while becoming closer to the front end; an outside air inlet penetrating a start part of the slope surface of the discharge horn or the sloped surface thereof to introduce the air from the outside; and a nozzle having a pipe shape, having a plurality of spray ports formed radially at the front end, having a connection part formed at a rear end to be connected with a hose, and having a combination part formed on the outer circumference. The nozzle is inserted into the discharge horn to couple the combination part and the coupling part of the discharge horn with each other.

Description

Spray nozzle structure of the fire extinguisher {Nozzle structure of the fire extinguisher}

The present invention relates to a spray nozzle structure of a fire extinguisher, and more particularly, to a spray nozzle structure of a fire extinguisher that can increase a radiation distance by resolving a vortex generated inside a discharge horn when spraying a fire extinguishing agent.

A fire extinguisher enables to quickly extinguish a fire in the initial stage in case of a fire. The coupling means 11 formed in the; a spray hole 12 formed inside the end at which the coupling means 11 is formed and communicating with the fire extinguisher inlet; It is formed integrally in succession with the injection hole 12, and the inclined surface 13 formed around the center line of the body; is composed of.

Therefore, the extinguishing agent in powder form having the pressure supplied from the fire extinguisher is spread and sprayed through the injection hole 12 at the inclined surface 13 to extinguish the fire.

However, in the conventional injection nozzle 10, the fire extinguishing agent having pressure is introduced through the straight injection hole 12 and then diffused on the inclined surface 13. At this time, the extinguishing agent is released from the injection hole 12 by the pressure. As it flows into the inclined surface 13 while having straightness, a vacuum is formed at the site where the inclined surface 13 starts, and a vortex is generated.

That is, since the fire extinguishing agent having straightness is not able to spread directly from the starting portion of the inclined surface 13, a vacuum space 20 is formed between the sprayed extinguishing agent and the starting portion of the inclined surface 13, and the vacuum space 20 ) to form a vortex.

Due to the vacuum space 20 and resistance by the vortex, the fire extinguishing agent has a weakened straightness, so that when it is sprayed out of the spray nozzle 10, the diffusion property can be increased, but there is a problem that the radiation distance is rapidly shortened.

In the event of a fire, the heat and fear prevent a person with a fire extinguisher from approaching the fire source. Since the extinguishing agent cannot be sufficiently sprayed, it may fail to extinguish the initial fire and spread into a large fire.

<Prior art literature>

- Republic of Korea Registered Utility Model No. 20-0344303

(Spray nozzle for fire extinguisher)

The present invention for solving these conventional problems is to form a hole for introducing external air to the area where the vortex is formed inside the discharge horn, and when spraying the fire extinguishing agent with pressure, the vacuum space and the vortex by the air introduced from the outside The purpose of this is to provide a spray nozzle structure of a fire extinguisher that allows the fire extinguishing agent to be emitted with straightness and reach the fire source efficiently by solving the problem.

In order to achieve the above object, the injection nozzle structure of the fire extinguisher according to the present invention,

a discharge horn having a fastening portion formed at the rear end, and an inclined surface in which the inner diameter is spread toward the front end;

an external air inlet hole which is formed to penetrate the inclined surface or the starting part of the inclined surface of the discharge horn to introduce external air;

As a pipe shape, a plurality of injection holes are formed in a radial form at the front end, a connection part for connection with a hose is formed at the rear end, and a nozzle formed with a coupling part on the outer periphery; Consists of,

The nozzle is inserted into the discharging horn and characterized in that the coupling portion and the coupling portion of the discharging horn are configured to be fastened to each other.

In addition, an orifice is formed inside the discharge horn, the nozzle is mounted so that its tip is located at the rear end of the orifice, and the external air inlet is formed in the orifice or the rear side of the orifice, and the discharge horn The tip portion is configured to form an elliptical outlet.

In addition, an orifice is formed inside the discharge horn, and the nozzle is mounted so that its tip is located at the rear end of the orifice, and the external air inlet is formed in the orifice or a rear portion of the orifice. A plurality of emission holes are formed in a radial form from the front end portion to the tip portion of the emission horn, and the emission holes are configured to be positioned in a straight line.

The spray nozzle structure of the fire extinguisher according to the present invention is effective in suppressing the initial fire by dissolving the vacuum space and vortex generated during the spraying of the extinguishing agent by the inflow of external air, so that the sprayed extinguishing agent reaches a distant fire source with straightness. am.

In other words, it has the advantage of efficient fire suppression by allowing the fire extinguishing agent to be accurately sprayed to the fire source from a distance even when it is not close to the fire source due to heat and fear.

In addition, there is an advantage in that the spraying force is strengthened by forming a film in the radiation form of the fire extinguishing agent by the discharge port of the discharge horn, which also enables long-distance spraying.

1 is a view showing the structure of a conventional fire extinguisher spray nozzle.
Figure 2 is a view showing the structure of the discharge horn of the fire extinguisher according to the present invention.
3 to 6 are views showing different types of emission horns.
7 and 8 are views showing a partial cross-sectional structure and an external structure of the nozzle.
9 to 11 are views showing a form in which a nozzle is mounted on a discharge horn of various types to radiate a fire extinguishing agent.

The above-described objects, features and advantages will be described below in detail with reference to the accompanying drawings, and accordingly, those of ordinary skill in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention.

In describing the present invention, if it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, which may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like.

In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention.

Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

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

However, the embodiments of the present invention illustrated below may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below.

The embodiments of the present invention are provided to more completely explain the present invention to those of ordinary skill in the art.

In the discharge horn 100 of the present invention, a fastening part 110 for screwing is formed at the rear end as shown in FIG. 2, and an inclined surface 101 is formed so as to have a shape in which the inner diameter is expanded toward the front end, and the A plurality of external air inlet holes 120 penetrating the outside and the inside are formed at equal intervals along the circumference at the front portion of the fastening unit 110 , that is, the portion where the inclined surface 101 starts or the inclined surface 101 .

Therefore, when the fire extinguishing agent is sprayed after the fastening part 110 is fastened to the fire extinguisher body or a hose extending from the fire extinguisher body, a vortex and a vacuum space 20 are formed as shown in FIG. 1 by the spray pressure and speed. External air is sucked in and introduced through the external air inlet 120 formed in the part to be formed, thereby dissolving the vacuum, thereby preventing the formation of a vortex.

Therefore, the sprayed extinguishing agent does not receive resistance, and is emitted and radiated while spreading along the inclined surface 101 .

Therefore, the fire extinguishing agent emitted through the discharge horn 100 reaches a remote fire source, so that fire suppression can be made easily.

The nozzle 200 as shown in the cross-sectional view of FIG. 3 and the external structure diagram of FIG. 4 is inserted into the inner side of the discharge horn 100, and the central portion of the fire extinguishing agent that is emitted increases the spraying distance, and the emission horn ( 100), it is possible to control the diffusion range of the extinguishing agent.

To this end, the nozzle 200 is in the form of a pipe, and a plurality of injection holes 240 are formed in a radial shape at a tip portion thereof, and a connection portion for connection with a hose of a fire extinguisher is formed at the rear end thereof, and a coupling portion is formed on the outer periphery. 210 is formed.

Therefore, by inserting the coupling portion 210 from the rear side of the discharge horn 100 and screwing the coupling portion 110 of the discharge horn 100 as shown in FIG. wrapped around and mounted on

The distal end of the nozzle 200 is located in a portion extending to the inside of the inclined surface 101, so that the fire extinguishing agent sprayed radially through the injection hole 240 is restricted by the inclined surface 101, and in addition The vacuum state is resolved by the air sucked in by the external air inlet 120, so that remote injection is possible by the immediate and limited diffusivity.

At this time, the external air inlet hole 120 is formed between the start portion of the inclined surface 101 and the tip portion of the nozzle 200, thereby eliminating the resistance caused by the vacuum and vortex applied to the sprayed extinguishing agent.

On the other hand, the discharging horn 100 has an extended portion 130 having an inclined surface from the fastening portion 110 as shown in FIG. 6 , and the distal end of the discharging horn 100 is formed from the distal end of the extended unit 130 . A straight line portion 140 that does not extend until is formed, and an orifice 150 is formed on the inner side of the straight line portion 100 along the inner diameter circumference.

In addition, an elliptical discharge port 160 is formed at the distal end of the discharging horn 100 , and the distal end of the nozzle 200 is inserted and fixed to be positioned at the rear of the orifice 150 .

Therefore, as shown in Figure 8, the central portion of the fire extinguishing agent injected through the injection hole 240 of the nozzle 200 passes through the orifice 150 to maintain the immediate property, and the edge portion of the fire extinguishing agent is 150), the diffusion range is limited, and it is sprayed to maintain straightness up to a certain distance and then spreads.

That is, the central portion of the sprayed extinguishing agent has immediate property and directly reaches the remote fire source to extinguish the fire, and the edge portion has the immediate property up to a certain distance (for example, close to the fire source) by the orifice 150. By maintaining and spreading, a wide range of digestion is possible.

In addition, the discharge port 160 of the discharge horn 100 is formed in an oval shape, so that the fire extinguishing agent is sprayed in the form of a film, and the fire extinguishing agent can be sprayed by focusing on the flower source.

As a result, the fire extinguishing agent sprayed from the nozzle 200 is limited in diffusion through the orifice 150 after the resistance of vacuum and vortex is resolved by the external air by the external air inlet hole 120, and has straightness, and also Diffusion is possible while maintaining straightness by the discharge port 160 .

The external air inlet 120 may be formed between the extended portion 130 , that is, a portion where the inclined surface starts and a rear end portion of the orifice 150 .

FIG. 9 is another form of the emitting horn 100, and has a structure in which a plurality of emitting holes 170 are formed in a radial form instead of an elliptical emitting hole 160. As shown in FIG.

This discharge hole 170 has a structure in which the fire extinguishing agent sprayed from the nozzle 200 is sprayed in the form of a film by being positioned on a straight line in the up-down direction, and this is also a structure in which diffusion is possible while maintaining straightness.

As described above in detail a specific part of the content of the present invention, for those of ordinary skill in the art, it is clear that this specific description is only a preferred embodiment, and the scope of the present invention is not limited thereby. something to do.

Accordingly, it is intended that the substantial scope of the present invention be defined by the appended claims and their equivalents.

100: emission soul 101: slope
110: fastening part 120: external air inlet hole
130: extended part 140: straight part
150: orifice 160: outlet
170: discharge hole 200: nozzle
210: coupling part 220: connection part
240: injection hole

Claims (4)

a discharge horn having a fastening portion formed at the rear end, and an inclined surface in which the inner diameter is spread toward the front end;
The injection nozzle structure of a fire extinguisher comprising: an external air inlet hole that is formed to penetrate the inclined surface or the starting part of the inclined surface of the discharge horn to introduce external air.
According to claim 1, In the form of a pipe, a plurality of injection holes are formed in a radial form at the front end, a connection portion for connecting to a hose is formed at the rear end, and a nozzle having a coupling portion formed around the outer periphery is inserted into the inside of the discharge horn, and the The injection nozzle structure of a fire extinguisher, characterized in that the coupling part and the coupling part of the discharge horn are configured to be fastened to each other.
[3] The orifice of claim 1 and 2, wherein an orifice is formed inside the discharge horn, and the nozzle is mounted such that a tip portion thereof is positioned at a rear end of the orifice, and the external air inlet is located after the orifice or the orifice. The injection nozzle structure of the fire extinguisher, characterized in that the elliptical discharge port is formed in the side portion as well as the tip portion of the discharge horn.
[3] The orifice of claim 1 and 2, wherein an orifice is formed inside the discharge horn, and the nozzle is mounted such that a tip portion thereof is located at a rear end of the orifice, and the external air inlet is located after the orifice or the orifice. A plurality of discharge holes are formed in a radial form from the front end of the orifice to the front end of the discharge horn as well as formed on the side, and the discharge holes are located in a straight line.

Images