KR101282702B1 - Water mist nozzle for extinguishing fire with water supply hole - Google Patents

Abstract

PURPOSE: A spraying nozzle for extinguishing fire is provided to reduce the number of components without a necessity of a vortex generation van by forming vortex water supply holes which supply fire-extinguishing water in a tangential direction which borders on an inside diameter of a vortex chamber in a vortex member. CONSTITUTION: A spraying nozzle for extinguishing fire which has a water supply hole includes an adapter (100), a body (200), and multiple nozzle tip parts (300). The adapter is combined with a water supply pipe. The body includes multiple tip holes (233) in which the multiple nozzle tip parts are formed in the bottom surface and is combined with the adapter through the upper surface. The nozzle tip part includes a vortex member and a nozzle tip (310). The vortex member is mounted on the tip hole and includes a vortex chamber and one or more vortex holes (375). The vortex water supply hole is formed on the outer side surface of the vortex chamber in order to supply fire-extinguishing water to the vortex chamber. The nozzle tip fixes the vortex member by being inserted into the tip hole after the vortex member is inserted into the tip hole and sprays supplied vortex supply water in the vortex member.

Description

Fire extinguishing spray nozzle with water supply hole {WATER MIST NOZZLE FOR EXTINGUISHING FIRE WITH WATER SUPPLY HOLE}

The present invention relates to a fire spray nozzle for extinguishing a fire, and in particular, in the event of a fire in a certain space, inducing the fire extinguishing water supplied in a straight form from a fire hydrant or a water source to vortex fine water particles at the nozzle end. It is a low pressure nozzle of about 10bar to extinguish by extinguishing the extinguishing water in the form of a mist, and relates to a fire extinguishing nozzle having a water supply hole for extinguishing oil fire as well as a general fire.

In the event of a fire, a powder fire extinguisher (including a foam fire extinguisher) is used to inject a fire extinguishing agent filled therein into a fire source (hereinafter referred to as a "fire source"), or a high pressure supplied from a fire hydrant after connecting a hose to the fire hydrant. Fire extinguished by extinguishing water directly into the fire. As a kind of fire extinguishing agent, halogen has been used as a fire extinguishing agent for a long time. However, due to environmental problems, gas and water systems are used in fire extinguishing facilities.

In recent years, due to the development of technology, an automatic fire extinguishing system such as SPRINKLER, which detects fire immediately upon occurrence of fire and sprays extinguishing water from the ceiling of buildings, etc., has been improved.

However, in the case of automatic fire extinguishing equipment such as sprinkler, the fire extinguishing spray particles are a large cooling suppression method. In the case of, the oil and the extinguishing water are separated, and thus, the burning oil cannot be properly extinguished. In addition, a large amount of extinguishing water is sprayed to prevent fire-related material. Occasionally, items are damaged by the digestive water.

Gas-based (CO2, N2) fire extinguishing equipment has the disadvantage of not only having difficulty in suppressing the initial suppression of fire because it requires evacuation of life and closing all ventilating furnaces before operation, but also high risk of safety accidents due to malfunctions. .

Therefore, it is possible to extinguish the fire extinguishing water in the form of mist by spraying the surrounding water in the form of mist, to reduce the secondary damage caused by the extinguishing water, to reduce the cost of construction and equipment, As a result of the change of water vapor into heat, it is possible to reduce the oxygen concentration around the combustion products due to the formation of water vapor and the expansion of volume, as well as to block the radiant heat emitted by the combustible materials, and to develop a fine atomized fire extinguishing system that can safely extinguish the fire safely. It is becoming.

As the above, the research on the fine atomized fire extinguishing facility that can effectively extinguish the fire has been in progress. As one of the examples, 'Shuntholm' of Finland has been filed in Korea and registered in Korean Patent No. Fire extinguishing device, and "Fire spray nozzle for fire protection" filed by Korean Hyundai Motor Corporation and registered as Utility Model No. 258499 (Dec. 11, 2001) and Utility Model No. 208754 (2002.06). There is a nozzle using only digestion water, such as "fire fighting apparatus" registered under .25), and another type of nozzle is a two-fluid nozzle which mixes gas and digestive water. The patent for such a two-fluid nozzle is US 5014790. No. US4989675, US2361144, and the like.

Most of these airflow nozzles were applied to fire suppression in a small space, and there was a problem in that the amount of the system was increased and maintenance was difficult due to the piping work for the gas and the digestive water.

By the way, the existing atomizing nozzle is difficult to separate the internal nozzle when the nozzle body is composed of a single body, such as the Patent No. 210033 is difficult to maintain, it is to use a high pressure of about 50 ~ 200 bar, Due to the risk of leakage in the pipe can cause a safety accident and maintenance was difficult.

In addition, the registered utility model No. 258499 and the applicant's registered utility model No. 208754, which are a single nozzle body, are provided with a mesh or a filter inside the chamber space when digestive water containing foreign matter is supplied from a hydrant or a water supply source. There was also a problem that can not utilize the function of the fire extinguishing nozzle due to the clogging phenomenon of the injection nozzle.

Accordingly, the applicant of the present invention, in order to solve the above-mentioned problems of the prior art, a plurality of nozzle tips having an upper body which functions as a nozzle adapter, and a swirl generating vane formed by twisting two wires therein; Patent registration as 'No. 10-0585936' by developing 'digestion spraying device', which includes an intermediate material coupled to the body, and a lower body attached to the intermediate material and equipped with a plurality of nozzle tip portions. There is a bar.

However, in the case of the 'spraying device for fire extinguishing' of the above-described patent, since the two wires are twisted to form inside the nozzle tip part to form the vortex, the nozzle tip part is manufactured by CNC or the like and then the vortex generating vane is Since the fabrication and assembly work for mounting the manufactured vortex generating vane to the nozzle tip part must be performed, it is difficult to manufacture a spraying device for fire extinguishing and a lot of time and cost have arisen.

In addition, the 'spraying device for fire extinguishing' of the registered patent is to produce a vortex generating vane by twisting two wires, the produced vortex generating vanes do not have a uniform shape and size, which occurs in the extinguishing spraying device The spray particles are not uniform, so that a problem that may not be effective for fire extinguishing occurs.

In addition, in the case of the registered patent, the width of the flow path of the tip hole in which the vortex generating vane is mounted is narrow, and thus foreign matters are easily caught, and thus, a mesh for filtering foreign matters is further included. There is a problem that the increase in manufacturing time and the manufacturing cost increases.

In addition, the 'spraying device for fire extinguishing' of the registered patent has a bolt head portion protruding from the lower body of the nozzle tip, when the protruding bolt head is subjected to an external force such as colliding with an external object, the bent or spray injection hole is There was also a problem that could not work properly, such as clogging.

Accordingly, the present invention is to solve the problems of the prior art described above, without having a vortex generating van and a mesh for filtering foreign matter, and has a structure for easily converting the digestive water supplied for spray injection into vortex It is an object of the present invention to provide a spray nozzle for fire extinguishing having a water supply hole to reduce the number of parts, to facilitate the manufacture and assembly, and to significantly reduce the production cost and production time.

The present invention also enables the nozzle tip portion to be easily mounted while preventing the nozzle tip portion from protruding to the outside, so that when the external force acts in the installed state, the external force does not directly act as the nozzle tip portion. It is another object of the present invention to provide a fire spray nozzle having a water supply hole having an improved structure for improving the durability of the nozzle tip against external force.

Fire extinguishing spray nozzle having a water supply hole of the present invention for achieving the above object, the adapter 100 is coupled to the water supply pipe; And,
Body 200 is coupled to the adapter 100 through the upper surface is formed a plurality of tip holes 233 is inserted into the plurality of nozzle tip portion 300 on the bottom surface;
A nozzle tip part 300 mounted to the tip hole 233 to generate vortex and spray by spraying the extinguishing water in a horizontal tangential direction of the vortex chamber 361 inside the outer surface;
The vortex chamber 361 formed at the center to form and supply the vortex penetrates in the tangential direction of the circumferential surface of the vortex chamber 361 from the outer surface of the vortex chamber 361 to supply the digestion water into the vortex chamber 361. One or more vortex water supply holes 375 are formed and are formed in the tip hole 233 after the vortex member 350 mounted in the tip hole 233 and the vortex member 350 are inserted into the tip hole 233. And a nozzle tip part 300 having a nozzle tip 310 inserted into and supporting the vortex member 350 and spraying the vortex supply water supplied from the vortex member 350 in a spray form. It features.

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The nozzle tip 310 has a tool groove 323 formed at a bottom thereof to completely insert the nozzle tip 310 into the tip hole 233 so as not to protrude from the bottom of the body 200. It features.

The vortex member 350 is. One or more water supply passage creation surfaces 371 are formed by cutting an outer circumferential surface to form a water supply passage 371a between the inner circumferential surface of the tip hole 233, and the vortex in the water supply passage creation surface 371. The water supply hole 375 is characterized in that it is formed so as to extend to the vortex chamber 361.

A portion of the end portion of the vortex member 350 that faces the body 200 is formed as a dome portion 372 whose outer diameter increases in the direction toward the nozzle tip portion 300 from the body 200 side. It is characterized in that it is configured to minimize the flow rate reduction toward the furnace (371a).

The vortex member 350 further includes a central water supply hole 373 formed to penetrate from the center of the dome portion 372 to the center of the vortex chamber 361, into the vortex chamber 361. It is characterized in that it is configured to increase the flow velocity in the vortex chamber 361 while supplying a sufficient flow rate.

According to the present invention having the above-described configuration, by forming the vortex water supply holes 375 for supplying the digestion water in a tangential direction in contact with the inner diameter of the vortex chamber 361 in the vortex member 350, as in the prior art By not having a vortex generating vane for forming, it reduces the number of parts, facilitates the manufacture, and provides the effect of reducing the manufacturing cost.

In addition, since the present invention does not include the vortex generating vane, the reduction phenomenon caused by the vortex generating vane of the inner cross-sectional area of the tip hole does not occur, so that the tip hole is not clogged by small foreign matters, thereby removing foreign substances. There is no need to have a mesh for it, which further reduces the number of parts, makes the production easier, and provides the effect of further reducing the manufacturing cost.

In addition, in the present invention, by supplying the digestion water to generate the vortex by the vortex water supply hole 375 without having a vortex generating vane, the member does not form an obstacle to the flow of the digestive water supplied flow rate And since the flow rate does not occur, the vortex water supply vane acts as an obstacle to the flow of the digestive water in the process of generating the vortex by the vortex water supply van as in the prior art, thereby preventing the decrease in the flow rate and flow rate. Of course, it provides an effect of improving the spray-forming efficiency by preventing the occurrence of flow rate and flow rate drop.

In addition, according to the present invention, the nozzle tip 310 is completely inserted into the tip hole 233, thereby preventing external force from being applied to the nozzle tip 310, so that the bolt head of the nozzle tip is moved outward in the prior art. Exposed to provide the effect of solving the problem that the nozzle tip is bent by the external force or the hole for the spray is clogged.

1 is a perspective view of a spray nozzle for fire extinguishing 1 according to an embodiment of the present invention,
2 is an exploded perspective view of the spray nozzle 1 for fire extinguishing.
3 is an exploded perspective view of the nozzle tip 300 of FIGS. 1 and 2,
4 is an upward perspective view of the nozzle tip 310 as viewed from the top,
5 is a bottom perspective view of the nozzle tip 310 in which the nozzle tip 310 is viewed from the bottom,
6 is a perspective view of the vortex member 350 in which the internal flow path of the vortex member 350 of FIGS.
FIG. 7 is a bottom view of the vortex member 350 of FIG. 6 in which the vortex water supply hole 375 is formed to be sprayed in the tangential direction of the inner surface of the vortex chamber 361 with a hidden line.
8 is a cross-sectional view of the water spray nozzle 1 showing the coupling state of the adapter 100, the body 200 and the nozzle tip 300,
FIG. 9 is a diagram illustrating a state in which the fire extinguishing water spray nozzle 1 of FIG. 8 is mounted on the water supply pipe 400.

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

1 is a perspective view of a fire spray nozzle 1 for fire extinguishing according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of the fire spray nozzle 1 for fire extinguishing.

As shown in FIGS. 1 and 2, the fire extinguishing nozzle 1 includes an adapter 100 coupled to a water supply pipe 400 (see FIG. 9), a body 200 coupled to a bottom surface of the adapter 100, and a body ( It comprises a plurality of nozzle tip portion 300 is mounted to the plurality of tip holes 233 formed radially on the bottom of the 200.

The structure of the adapter 100 and the body 200 in the above configuration will be described together with reference to FIGS. 2 and 8 in the description of FIG. 8, and the configuration of the nozzle tip unit 300 will be described in detail below.

3 is an exploded perspective view of the nozzle tip part 300 of FIGS. 1 and 2.

As shown in FIG. 3, the nozzle tip part 300 is first inserted into the tip hole 233 to convert the extinguishing water into vortex and supply the nozzle tip 310 to the vortex member and the vortex member. Is inserted into the tip hole 233 in the lower portion of the 350, and comprises a nozzle tip 310 for spraying the vortex digestion water supplied from the vortex member 350 in the form of a spray.

The nozzle tip 310 will be described first with reference to FIGS. 3 to 5.

4 is an upward perspective view of the nozzle tip 310 as viewed from the top, and FIG. 5 is a bottom perspective view of the nozzle tip 310 as viewed from the bottom.

As shown in FIGS. 3 to 5, the nozzle tip 310 includes a vortex member support part 311 supporting the vortex member 350 inserted into the tip hole 233, and an outer diameter of the vortex member support part 311. It is formed to have a larger outer diameter and formed into a cylindrical shape having a tip hole coupling portion 317 for tightly coupling after inserting the nozzle tip 310 into the tip hole 233 in the lower portion of the vortex member support portion 311 do.

The vortex member support part 311 is formed in a cylindrical shape having an outer diameter corresponding to the outer diameter of the vortex part 360 of the vortex member 350, and the vortex supplied from the vortex member 350 flows into the center of the upper end. The receiving vortex inflow chamber 313 is recessed.

The tip hole coupling portion 317 is formed to have an outer diameter corresponding to the inner diameter of the tip hole 233, the vortex support portion 311 side is a cylindrical protruding a predetermined length from the outer surface of the vortex portion support portion 311 Is formed. In addition, a spray hole 319 is formed in the center of the tip hole coupling part 317 so as to penetrate to the bottom surface of the vortex inflow chamber 313 and the nozzle tip 310 to have an inner diameter smaller than that of the vortex inflow chamber 313. On the outer circumferential surface of the tip hole coupling portion 317, a nozzle tip male thread portion 321 is formed to be screwed with the tip hole female screw portion 235 (see FIGS. 2 and 8) formed in the tip hole 233. In addition, as shown in FIG. 5, a tool groove 323 into which a tool is inserted is formed at the bottom of the tip hole coupling part 317 so as to closely screw the nozzle tip 310 to the nozzle tip male screw part 321.

Next, the vortex member 350 will be described with reference to FIGS. 6 to 7.

FIG. 6 is a perspective view of the vortex member 350 in which the inner flow path of the vortex member 350 of FIGS. 1 to 3 is indicated by a hidden line, and FIG. 7 shows that the vortex water supply hole 375 is inside the vortex chamber 361. It is a bottom view of the vortex member 350 of FIG. 6 which shows that it is formed so that it may spray in surface tangent direction by a hidden line.

6 to 7, the vortex member 350 has a water supply part 370 for supplying the digestion water supplied from the body 200 to form a vortex, and the vortex is supplied by the water supply part 370. It is configured to include a vortex portion 360 to be supplied to the nozzle tip 310 to convert the digestion water supplied to be generated to form a vortex to convert to vortex.

The water supply part 370 is formed in a cylindrical shape having an outer diameter smaller than the outer diameter of the tip hole coupling portion 317, that is, an outer diameter smaller than the inner diameter of the tip hole 233. In addition, the water supply passage creation surface 371 is formed on the outer surface of the water supply portion 370 in which a part of the outer surface is cut, and the water supply passage creation surface 371 has one or more vortex water supply holes 375. Is formed.

By the above-described configuration, the outer surface of the water supply part 370 maintains a predetermined interval with respect to the inner circumferential surface of the tip hole 233, and the water supply passage generating surface 371 is further spaced apart, thereby A water supply path 371a (see FIG. 8) flowing into the vortex water supply hole 375 side from the outside surface is formed. The water supply passage 371a forms a predetermined space between the outer surface of the vortex member support part 311 and the inner circumferential surface of the tip hole 233 to secure the flow rate of the extinguishing water supplied from the adapter 100 from the adapter 100. The fire extinguishing water to be supplied is smoothly supplied to the inside of the vortex chamber 361 to be described below from the outer surface of the vortex member 350 through the vortex water supply hole 375.

The vortex water supply hole 375 is configured to supply the digestive water to the vortex chamber 361 formed inside the vortex unit 360 on the outer surface of the water supply unit 370. Specifically, as shown in FIGS. 6 and 7, the vortex water supply hole 375 is eccentric to one side in the direction of the center of the vortex chamber 361, and the digestive water supplied by the body 200 is formed in the vortex chamber 361. Vortex supplied to the nozzle tip 310 while rotating, as shown by the spiral arrow in FIG. 6, formed by penetrating from the feed passage generating surface 371 to the vortex chamber 361 so as to divide in the tangential direction in contact with the inner diameter. Will form.

In addition, a portion of the end of the water supply portion 370 facing the body 200, the nozzle tip portion 300 on the body 200 side to minimize the flow rate and flow rate decrease toward the water supply passage 371a. It is formed of a dome portion 372, the outer diameter of which increases in the direction toward. In the center of the water supply part 370, a central water supply hole 373 penetrates vertically to supply direct water to the vortex chamber 361. The central water supply hole 373 serves to supply the digestive water to have a flow rate and flow rate sufficient to spray the flow rate inside the vortex chamber 361.

Since the vortex member 350 of the above configuration does not have a vortex forming van made by twisting a wire for vortex forming, it does not include a separate assembly work other than CNC processing, thereby facilitating the manufacture of the spray nozzle for fire extinguishing. . In addition, since the vortex member 350 is manufactured by CNC machining or the like, it is possible to manufacture the vortex member 350 having a uniform quality, whereby the consistency of spray particles can be maintained, thereby improving spray generation efficiency. In addition, since the vortex generating vanes are not coupled, the reduction of the cross section of the flow path is not generated, and foreign matters are not caught inside, thereby making it impossible to provide a mesh for removing the foreign matters, thereby reducing manufacturing costs and time. Provides further savings.

8 is a cross-sectional view of the fire water spray nozzle 1 showing the coupling state of the adapter 100, the body 200, and the nozzle tip 300.

First, the structure of the adapter 100 and the body 200 of the present invention will be described with reference to FIGS. 2 and 8.

First, the adapter 100 is formed in multiple stages having different outer diameters, and as shown in FIGS. 2 and 8, the water supply pipe coupling water having a tubular water supply coupling screw having a water supply pipe coupling thread coupled to the water supply pipe 400 (see FIG. 9) on the upper side. The threaded portion 101 is formed. The lower portion of the water supply pipe coupling water screw portion 101 is formed of a tube having an outer diameter larger than the outer diameter of the water supply pipe coupling water screw portion 101, and the adapter 100 is connected to the water supply pipe coupling water screw portion 101 at a water supply pipe 400 (FIG. 9) is formed in the water supply pipe engaging portion 103 formed of a step to stop so that it is no longer drawn into the inside. In the lower portion of the pipe forming the water supply pipe catching portion 103, an adapter catching portion 105 having an outer diameter larger than the outer diameter of the water supply pipe catching portion 103 protrudes in a flange shape from the entire outer circumference. An adapter ring groove 109 into which the sealing ring 500 (see FIG. 8), which is a sealing member, is inserted, is formed at the lower portion of the adapter locking portion 105. A tubular adapter male threaded portion 111 is formed below the adapter ring groove 109. The adapter 100 having the above-described configuration has an adapter water supply hole 107 penetrating through the center from the water supply pipe coupling thread portion 101 to a predetermined lower length, and the adapter water supply hole (107) is provided under the adapter water supply hole 107. The adapter water supply chamber 113 having an inner diameter larger than the inner diameter of 107 is formed. The adapter water supply chamber 113 is to perform the function of the storage tank of the digestive water.

Next, the body 200 is formed in a cylindrical shape, the coupling portion 210 to which the adapter male screw portion 111 of the adapter 100 is coupled, and a plurality of tip holes 233 are formed to form a plurality of nozzle tip portions 300. It is configured to include a tip hole 230 is inserted.

The coupling portion 210 has a body catching jaw 214a (see FIG. 8) to which the adapter catching portion 105 is caught, and a body ring groove 215 is formed below the body catching jaw 214a, and a body ring groove ( A body female threaded portion 216 is formed in the lower region of the 215 to be screwed with the adapter male threaded portion 111. The lower portion of the body female screw portion 216 is formed along the inner circumference of the working groove 217 is inserted into the tool tip for the CNC machining of the body female screw portion 216.

The lower portion of the working groove 217 is formed as a tip hole portion 230, the tip hole portion 230, the inside of the lower portion of the working groove 217 in the arc shape of the adapter water supply chamber is formed so that the inner diameter is narrowed toward the lower portion 113 is formed. In addition, a plurality of tip holes 233 are radially formed in the lower portion of the adapter water supply chamber 113 in a radially downward direction in the arc-shaped plane. The bottom of the tip hole portion 230 having the internal structure described above is formed with a convex surface convex downward, so that the tip hole 233 has the same flow path length.

As described above, the extinguishing spray nozzle 1 formed of the adapter 100, the body 200, and the nozzle tip portion 300 includes an adapter male threaded portion 111 and a body female threaded portion 216. It is coupled with the body 200 by screwing. At this time, a sealing ring 500 is interposed in the hollow formed by the adapter ring groove 109 and the body ring groove 215 to prevent leakage of the digestive water.

The nozzle tip part 300 is inserted into and coupled to each tip hole 233 so that the water supply part 370 of the vortex member 350 is drawn in first, and then the nozzle tip 310 moves the vortex member 350 into the tip hole 233. It is inserted into the tip hole 233 to be fixed to the inside of the. Thereafter, by inserting a tool (not shown) into the tool groove 323 to rotate the nozzle tip 310, the nozzle tip male screw portion 321 is tightly screwed and fixed to the tip hole female screw portion 235. At this time, by forming the tool groove 323 on the bottom of the nozzle tip 310, it is not necessary to form a bolt head for holding and rotating the nozzle tip using a separate wrench or wrench, as in the prior art, nozzle tip 310 can be completely inserted into the tip hole 233, so that the nozzle tip 310 does not protrude to the outside of the tip hole 233.

FIG. 9 is a diagram illustrating a state in which the fire extinguishing water spray nozzle 1 of FIG. 8 is mounted on the water supply pipe 400.

Fire extinguishing spray nozzle (1) coupled as described above, is coupled to the water supply pipe 400 for supplying the extinguishing water installed in the ceiling surface, such as Figure 9 using the water supply pipe coupling water screw portion 101 formed in the adapter 100. Installation is completed by becoming.

In this state, when the extinguishing water is supplied through the water supply pipe 400, the supplied extinguishing water is supplied in the horizontal tangential direction of the inner diameter of the vortex chamber 361 through the water supply path 371a. Since the digested water supplied in the tangential direction of the vortex chamber 361 flows along the inner diameter of the vortex chamber 361, it is formed as a naturally rotating vortex, and the vortex path 352 to the nozzle tip 310 by hydraulic pressure and gravity. , See FIG. 6). At this time, the vertically supplied fire extinguishing water supplied from the central water supply hole 373 (see FIG. 6) ensures a flow rate and increases the vertical downward flow velocity. Thus formed vortex, the flow rate is secured, the digestion water is increased vertically downward flow rate is discharged through the spray hole 319 of the nozzle tip 310, is converted into a spray due to a sudden pressure drop is injected.

In the present invention, the adapter 100 and the body 200 and the nozzle tip 300 are coupled to each other, and the female threaded portion is formed in the adapter 100 and the male threaded portion is formed in the body 200, or the coupling is interposed through an O-ring. It can be carried out in various ways such as to be.

1: Fire extinguishing spray nozzle
100: adapter, 101: water supply screw thread, 103: water supply hook
105: adapter locking portion, 107: adapter water supply hole, 109: adapter ring
111: Absorber thread, 113: Advance water supply chamber
200: Body
210: coupling portion, 215: body ring groove, 216: body female thread portion, 217: working groove
230: tip hole part, 233: tip hole, 235: tip hole female thread part
300: nozzle tip part
310; Nozzle tip
311: vortex member support portion, 313: vortex inflow chamber, 317: tip hole coupling portion
319: spray hole, 321: nozzle tip male thread, 323: tool groove
350: vortex member,
360: Vortex
361: Vortex Chamber, 362: Vortex Path
370: water supply
371: water supply line creation surface, 372: dome part, 373: medium pressure water supply hole, 375: vortex water supply hole
400: water pipe
500: sealing ring

Claims (6)

delete Adapter 100 coupled to the water supply pipe; And,
Body 200 is coupled to the adapter 100 through the upper surface is formed a plurality of tip holes 233 is inserted into the plurality of nozzle tip portion 300 on the bottom surface;
A nozzle tip part 300 mounted to the tip hole 233 to generate vortex and spray by spraying the extinguishing water in a horizontal tangential direction of the vortex chamber 361 inside the outer surface;
The vortex chamber 361 formed at the center to form and supply the vortex penetrates in the tangential direction of the circumferential surface of the vortex chamber 361 from the outer surface of the vortex chamber 361 to supply the digestion water into the vortex chamber 361. One or more vortex water supply holes 375 are formed and are formed in the tip hole 233 after the vortex member 350 mounted in the tip hole 233 and the vortex member 350 are inserted into the tip hole 233. And a nozzle tip part 300 having a nozzle tip 310 inserted into and supporting the vortex member 350 and spraying the vortex supply water supplied from the vortex member 350 in a spray form. Spray nozzle for digestive water, characterized in that.
The method according to claim 2, wherein the nozzle tip 310
The spray nozzle for fire extinguishing, characterized in that the tool groove 323 for completely inserting the nozzle tip 310 into the tip hole 233 is formed on the bottom so as not to protrude from the bottom of the body 200.
The method of claim 2, wherein the vortex member (350).
At least one water supply passage creation surface 371 is formed by cutting an outer circumference surface so as to form a water supply passage 371a between the inner circumferential surface of the tip hole 233,
The water supply passage generating surface 371 is characterized in that the vortex water supply hole 375 is formed so as to extend through the vortex chamber (361).
The method of claim 4,
A portion of the end portion of the vortex member 350 facing the body 200 is formed as a dome portion 372 whose outer diameter increases in the direction toward the nozzle tip portion 300 from the body 200 side. Spray nozzle for fire extinguishing.
The method of claim 5, wherein the vortex member 350,
And a central water supply hole 373 penetrating from the center of the dome part 372 to the center of the vortex chamber 361.

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