KR200280754Y1 - Spraying device for fire extinguishing - Google Patents

Abstract

The present invention relates to a fire-fighting injector for use in extinguishing a fire, comprising: a nozzle for a fire-fighting apparatus having a truncated cone-shaped head portion and a connection body extending upwardly from a rear end of the head portion; A chamber having a predetermined depth in a cylindrical shape from an upper end surface of the connecting portion toward a head portion; A plurality of injection passages which are in communication with the bottom surface of the chamber and disposed at regular intervals along the outer circumference of the head; A spray nozzle for spraying and detachably screwed to an end of the spray passage; A lower end corresponding to a diameter of the chamber, and a portion other than the lower part of the chamber has a diameter smaller than that of the chamber, and is inserted into the chamber to selectively introduce digestion water into the chamber according to water pressure; An elastic spring interposed between the valve spring and the bottom surface of the chamber; And a joint frame which is screwed into the connection portion of the nozzle body and has a supply flow path in communication with the chamber and is in intimate contact with the top of the valve sprocket.

According to the present invention, it is easy to fasten and separate the nozzle for supplying the extinguishing water, and since the extinguishing water is automatically adjusted to a certain pressure and supplied to the chamber, the size of the water particles sprayed through the end of the spray nozzle is uniform and large particles. The probability of water droplet formation is minimized, and the supplied extinguishing water can be simply sprayed in the form of a mist by the vortex generating member, which is particularly suitable for extinguishing fires in oil fires and electrical equipment.

Description

Fire Fighting Injector {SPRAYING DEVICE FOR FIRE EXTINGUISHING}

The present invention relates to a water injector used for extinguishing a fire, and more particularly, a fire fighting injector improved to induce water supplied in a straight form from a fire hydrant or a water supply in the event of a fire to spray in the form of a mist at the nozzle end. It is about.

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 was put out by spraying water directly on the fire.

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

However, in the case of automatic fire extinguishing facilities such as sprinklers, the water particles for extinguishing fire are large, and in the case of an oil fire such as petroleum or diesel, the oil and water are separated, and thus, the burning oil cannot be properly extinguished. There was a difficulty in the initial suppression, and there were also disadvantages that caused secondary problems such as flooding or electric shock due to excessive water injection.

In recent years, injectors capable of efficiently extinguishing fires while overcoming such damages have been studied, and as one of them, for example, Korean Patent No. 210033, "Fire Extinguishing Device", and Korean Utility Model No. 258499, "Fire fighting fluid spray nozzle" are disclosed. It has been.

According to these disclosed techniques, water is sprayed around the fire source in the form of a mist, and water particles are changed into water vapor by the heat of the fire source to form an air barrier to block the oxygen supplied to the fire source. It can be seen that even if the case can be suppressed quickly and easily.

However, these open technologies have overlooked some of the following points, and their utility is deteriorating, and improvement is required.

First, since the spraying operation is performed through the spray nozzle at the moment of supplying the fire extinguishing water from the fire hydrant or the water source irrespective of the water supply pressure, in the case of low pressure, the water is not sprayed at the end of the spray nozzle and falls as a large particle. However, there is a disadvantage in that the inflow of water, including the portion where the electrical installation is installed, easily penetrates into the equipment that is thoroughly controlled, resulting in burnout of the installation.

Secondly, even when the nozzle is closed, the water remaining in the tube drops into large particles, causing the same problem as the first. That is, according to the disclosed technology, there is a limit that cannot prevent the outflow of large droplets at source.

Third, the partial pressure was not efficient because the water supplied through the flow path was directly connected to each injection nozzle without the convergence process.

The present invention was created in view of the above-mentioned problems of the prior art, and was created to solve the problem. Simultaneous supply allows efficient partial pressure to be maintained and at the same time the injection pressure can be adjusted regardless of low and high pressures, and a vortex generating member is inserted into the nozzle inner diameter to easily and smoothly spray the fire extinguishing water to prevent damage to the equipment. It is an object of the present invention to provide an improved fire extinguishing device so that an effective fire suppression can be made while minimizing.

1 is a view showing the internal structure of the injecting and cross-sectional cutting part of the injection device according to the present invention,

Figure 2 is a cross-sectional view of the valve spool constituting the injector according to the present invention.

Figure 3 is a cross-sectional view of the joint frame constituting the injector according to the present invention.

Figure 4 is a cross-sectional view of the injection nozzle constituting the injector according to the present invention.

5 is a cross-sectional view of the vortex generating member constituting the injector according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10: nozzle body 12: head portion

14: connection portion 20: chamber

22: injection flow path 30: injection nozzle

32: vortex generating member 40: elastic spring

50: valve spline 70: joint frame

74: O-ring 76: seal material

The above object of the present invention is a fire-fighting injector having a truncated cone-shaped head portion and a nozzle body consisting of a connecting portion extended upward from the rear end of the head portion; A chamber having a predetermined depth in a cylindrical shape from an upper end surface of the connecting portion toward a head portion; A plurality of injection passages which are in communication with the bottom surface of the chamber and disposed at regular intervals along the outer circumference of the head; A spray nozzle for spraying and detachably screwed to an end of the spray passage; A lower end corresponding to a diameter of the chamber, and a portion other than the lower part of the chamber has a diameter smaller than that of the chamber, and is inserted into the chamber to selectively introduce digestion water into the chamber according to water pressure; An elastic spring interposed between the valve spring and the bottom surface of the chamber; It is achieved by providing a fire fighting injector characterized in that it comprises a joint frame which is screwed with the connection portion of the nozzle body and in communication with the chamber and having a supply flow path in close contact with the top of the valve sprocket.

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

1 is a view showing a cut and cross-sectional view of the main portion of the injection device according to the present invention.

According to FIG. 1, the nozzle body 10 is largely divided into a head portion 12 which is a front end portion and a connection portion 14 which is a rear end portion.

The head part 12 is formed in a truncated cone shape, and a plurality of injection nozzles 30 are mounted along the outer circumference thereof, preferably at constant intervals, and one at the center of the truncated tip surface, all 7 Injection nozzles 30 having the same shape and structure can be detachably mounted.

Each of the injection nozzles 30 is fastened to the front end of the injection passage 22 by screwing, and the injection passage 22 communicates with the chamber 20 formed at the inner center of the head part 12 while making a predetermined inclination. It is provided.

The chamber 20 is preferably formed in the inner center of the nozzle body 10 to which the head portion 12 and the connecting portion 14 are connected, and extends toward the rear end of the connecting portion 14 to take an open shape.

A lower end of the valve spring 50 is seated at the lower end of the chamber 20 so as to be inserted into the elastic spring 40 in the form of a coil.

As shown in FIG. 2, the valve spline 50 has a hollow cylindrical shape, the front end portion 52 of which is closed in a conical shape, and the rear end portion thereof is opened to form a discharge hole 58.

A flange portion 54 having an outer diameter larger than the diameter of the body, that is, a size corresponding to the inner diameter of the chamber 20 is formed at the lower outer periphery of the valve spring 50 so that the lower surface thereof is the elastic spring 40. It is seated at the upper end of the), the diameter of the length from the flange portion 54 toward the tip portion 52 is formed smaller than the diameter of the flange portion (54).

This is to form a flow path of the extinguishing water introduced.

A plurality of inlet holes 56 are formed at the outer circumference of the valve spline 50, and the inlet holes 56 communicate with the inner hollow of the valve spline 50 to communicate with the outlet holes 58.

A thread is formed on the inner circumferential edge of the chamber 20, and a joint frame 70 is fastened to the thread.

In addition, the joint frame 70 tightly seals the front end 52 while the rear end contacts each other under the interposition of the seal member 76 while pressing the front end 52 of the valve spline 50.

As shown in FIG. 3, the joint frame 70 is a cylindrical member having both ends open and hollow inside and having a water supply passage 72. 80a and 80b are formed, and these are partitioned by the locking jaw 78.

At the end of the locking jaw 78 is inserted into the chamber 20 and screwed together, a seal member storage groove 82 is formed along an edge thereof, and the seal member 76 is formed in the seal member storage groove 82 at the time of fastening. ) Is interposed.

In addition, in the space between the seal receptacle groove 82 and the locking jaw 78, the chamber of the joint frame 70 and the nozzle body 10 is caught by the locking jaw 78 when the joint frame 70 is fastened. The O-ring 74 is fitted to keep the airtight between 20).

On the other hand, the injection nozzle 30 is screwed with the front end of the plurality of injection passages 22 formed in the head portion 12 of the nozzle body 10, as shown in Figure 3, for this purpose, the outer end of the screw thread A discharge path 36 is formed therein, and a discharge passage 36 communicating with the injection passage 22 is formed therein, and the discharge passage 36 is formed at the tip of the injection nozzle 30, which is a tip of the discharge passage 36. Compared to the present invention, an injection hole 34 having a significantly smaller diameter and easier to spray water is formed.

The shape of the outer circumference of the injection nozzle 30 in which the injection hole 34 is formed is preferably in the form of a hexagon bolt head for ease of fastening, and as a seal material (not shown) to increase the closeness with the head portion 12. Keep tightly closed.

In addition, the vortex generating member 32 as shown in FIG. 5 is embedded in the discharge passage 36 of the injection nozzle 30 to form the vortex.

The vortex generating member 32 is preferably formed by twisting two strands of a member such as a wire, which is easy to process, in a spiral shape, and discharges the discharge water smoothly by leaving a little gap with the inner circumferential surface of the discharge passage 36 when built. It is desirable to form a vortex naturally.

That is, the discharged water temporarily intersects through the grooves formed between the twisted vortex generating members 32 to generate a flow rate difference with the adjacent discharged water, and causes a vortex (turbulent flow) due to a collision with the discharged water that is subsequently introduced. In addition, when the water is discharged through the injection hole 34 while being formed into fine water particles by the collision with water going straight between the vortex generating member 32 and the inner wall surface of the discharge passage 36 is sprayed in the form of a mist.

The present invention consisting of such a configuration has the following operation relationship.

First, when the rear end of the joint frame 70 is screwed to the top of the chamber 20 of the nozzle body 10 for the fire suppression, the joint is maintained while the sealing member 76 and the O-ring 74 are tightly sealed. The rear end of the frame 70 contacts and presses the conical tip portion 52 of the valve spool 50.

At this time, since the valve spring 50 is fully inflated by the expansion force (elastic force) of the elastic spring 40, the front end portion 52 is supplied while maintaining the rear end and the airtightness of the joint frame 70. The flow path 72 is placed in a closed state.

Subsequently, when the extinguishing water is supplied through the supply passage 72, the tip portion 52 is further pressurized by the water pressure, and when the set pressure or more is acted on, that is, the elastic coefficient of the elastic spring 40 is exceeded. When the elastic spring 40 is suppressed by the hydraulic pressure, the valve spring 50 is retracted (falling).

Accordingly, while the airtight is released, water is introduced into the chamber 20 by taking the conical surface of the distal end portion 52, and the water for extinguishing introduced into the chamber 20 is formed in the outer circumference of the valve spline 50. Through the 56 and the discharge hole 58 communicated with the 56 is temporarily collected at the lower end of the chamber 20 while maintaining a constant pressure.

The collected water is sprayed through the spray nozzles 30 at the same time as it is distributed through each spray passage 22 and sprayed in the form of a mist by the above-described vortex generating member 32.

Extinguishing water sprayed around the garden in the form of a mist (exhaust water = water for fire extinguishing) is vaporized by the heat of the garden and forms an air barrier to block oxygen from being supplied to the garden, thereby suppressing the ignition of the garden.

Therefore, in the general fire as well as the oil fire, it is possible to quickly extinguish the fire source before the digestion water and the oil are separated.

In addition, since the extinguishing water supplied to the injection nozzle 30 is already maintained at a constant pressure by the operation of the valve spline 50, there is almost no change in the hydraulic pressure during spraying or spraying, so there is no change in the size of the sprayed particles. As a result, large droplets may not be easily formed, and in particular, it may be very efficiently used in a fire such as an electrical installation causing secondary problems due to water inflow.

In addition, even if the supply of the extinguishing water after the extinguishing is cut off quickly and automatically so that the remaining water is not supplied to the injection nozzle (30) by the operation of the valve spool 50, the injection hole of the injection nozzle (30 34) water droplets of the large particles are not formed, and the probability of short circuit in the above-described circuit or inflow into the enclosed protective material is significantly reduced when the electrical equipment and the like are extinguished.

As described in detail above, according to the present invention provides the following effects.

First, the joint frame, which serves as an inlet for inleting the extinguishing water into the nozzle body, is easily attached to the nozzle body for easy installation and removal.

Second, the size of the water particles sprayed through the end of the injection nozzle is uniform because the digestion water flowing through the valve spout is automatically adjusted to a predetermined pressure and supplied to the chamber.

Third, since the supply pressure of the extinguishing water is constant, the occurrence rate of huge water droplets is minimized when the extinguishing water is sprayed through the injection hole, so that an efficient fire extinguishing can be performed without any secondary problems in the case of an electrical installation or an oil fire.

Fourth, it is easy to switch the spray to the mist form through the vortex generating member of a simple structure, and easy maintenance.

Claims (5)

A fire extinguishing device having a truncated cone-shaped head portion (12) and a nozzle body (10) consisting of a connecting portion (14) extended upward from a rear end of the head portion (12); A chamber 20 recessed and formed in a cylindrical shape from an upper end surface of the connecting portion 14 toward the head portion 12; A plurality of injection passages 22 communicating with the bottom surface of the chamber 20 and disposed at regular intervals along the outer circumference of the head portion 12; A spray nozzle for spraying 30 detachably screwed to an end of the spray passage 22; The lower end corresponds to the diameter of the chamber 20 and the other part has a diameter smaller than that of the chamber 20 and is inserted into the chamber 20 to selectively introduce digestive water into the chamber 20 according to the water pressure. And valves 50 to make; An elastic spring 40 interposed between the valve spring 50 and the bottom surface of the chamber 20; And a joint frame 70 which is screwed into the connection portion 14 of the nozzle body 10 and has a supply passage 72 in communication with the chamber 20 and is in intimate contact with an upper end of the valve spline 50. Fire injection device characterized in that configured to. The fire injection device according to claim 1, characterized in that a vortex generating member (32) is provided on the discharge passage (36), which is inside of the injection nozzle (30), having a clearance therein and having a clearance therein to cause vortex. 3. The fire fighting device according to claim 2, wherein the vortex generating member (32) has a twisted shape of two strands of wire. According to claim 1, wherein the valve spring 50 is the tip portion 52 of the conical shape is closed, The middle part is formed in a hollow shape, The rear end is opened while communicating with the hollow to form a discharge hole (58), The outer circumference of the adjacent side of the discharge hole 58 is formed with a flange portion 54 having an outer diameter of a size corresponding to the inner diameter of the chamber 20, Fire injection device, characterized in that the outer periphery except for the flange portion 54 is formed with a plurality of inlet holes (56) communicating with the hollow. The joint frame 70 of claim 1 is hermetically fixed to the connecting portion 14 of the nozzle body 10 by an O-ring 74, and the tip portion of the valve spline 50 is connected to the seal member 76. Fire-fighting injector, characterized in that the contact is arranged in close contact by air.