KR100807170B1 - foam generator for firefighting - Google Patents

Abstract

The present invention relates to a fire extinguishing foam generator capable of forming a foam sufficient to extinguish a fire even with a small amount of foam stock.

The present invention for this purpose is to supply a mixed water consisting of a mixture of the raw material and sea water (or fresh water) through a supply pipe in the form of fire extinguishing foam generator to extinguish the fire by expanding the mixed water into a foam form, the supply pipe and the flange coupling And a plurality of injection nozzles installed on a circumferential surface of the branch body and spraying the mixed water supplied to the branch body, and spaced apart from each other by a predetermined distance below the injection nozzle. With a cylindrical tube for expanding the mixed water sprayed from the injection nozzle first in the form of a foam, and a plurality of micropores installed under the cylindrical tube and passing the primary expanded foam in the cylindrical tube in a state in which the foam is expanded more One end is attached to the net mesh to be ejected and the peripheral surface of the cylindrical tube and the other end is attached to the flange to branch the cylindrical tube Including support for fixing to present a fire extinguishing foam generator according to claim that the configuration.

Fire extinguishing, foam, generator, spray nozzle, cylinder pipe, mesh

Description

Foam generator for firefighting

1 is a view schematically showing a fire extinguishing system of a ship according to the present invention.

FIG. 2 is a three-dimensional view of the structure of the fire extinguishing foam generator shown in FIG. 1; FIG.

3 is a cross-sectional view of the fire extinguishing foam generator shown in FIG.

          <Description of the symbols for the main parts of the drawings>

10: foam generator for fire extinguishing 12: branch

16: injection nozzle 18: first nozzle

22: second nozzle 24: cylinder tube

26: network 200: supply pipe

The present invention relates to a fire extinguishing foam generator, and more particularly, to a fire extinguishing foam generator capable of forming a foam sufficient to extinguish a fire even with a small amount of foam stock solution.

As is well known, a fire extinguishing nozzle is installed in the interior of a ship, especially in an engine compartment, to prevent flame propagation during a fire and at the same time to extinguish a fire.

On the other hand, a representative technique related to the above-mentioned fire extinguishing nozzle is the present application filed by the present inventors in 2002. 02. 08. (10-2002-0007236) (name: fire extinguishing nozzle).

The prior art includes a nozzle body having a microhole along a lower inner circumferential surface, a nozzle cap having a guide tube and an orifice formed therein, and a chamber is formed between the nozzle body and the nozzle cap.

The prior art of the above configuration is sprayed in the form of a fog (fog) in the process of spraying the water supplied from the water tank to the chamber through the guide tube and the orifice in the first state into the chamber when the fire occurs to suppress the fire.

On the other hand, the fire-extinguishing equipment installed in the engine room of the vessel is not a method of extinguishing fire by spraying water in the form of a fog, but mixing the raw solution with water and then generating a foam in the form of foam by using the mixed solution. Will be suppressed.

However, the foam generating fire extinguishing system uses a large amount of the foam stock solution to increase the amount of foam generated for the purpose of effectively extinguishing the fire. Therefore, a sufficient amount of the foam stock solution, preferably five times the designated quantity, is always on the ship. There has been a problem that the weight of the ship has to be increased by storing it.

Therefore, the present invention for solving the above problems is to provide a foam generator for extinguishing the fire to foam foam form.

In addition, the present invention is to provide a foam generator for fire extinguishing to form a foam sufficient to extinguish the fire even with a small amount of the foam stock solution.

In addition, the present invention provides a fire extinguishing foam generator capable of extinguishing all kinds of fires regardless of fire type.

Technical configuration of the present invention for achieving the above object is a foam generator for extinguishing the fire by extinguishing the mixed water in the form of foam by receiving the mixed water consisting of a mixture of the raw material and sea water (or fresh water) through the supply pipe And a plurality of injection nozzles flanged to the supply pipe to receive the mixed water, a plurality of injection nozzles installed on the circumferential surface of the branch body and spraying the mixed water supplied to the branch body, and below the injection nozzle. Located in the spaced apart state and having a cylindrical tube for primary expansion of the mixed water sprayed from the injection nozzle in the form of foam, and a plurality of micropores installed under the cylindrical tube and passing the primary expanded foam in the cylindrical tube One end is attached to the circumferential surface of the mesh and the cylindrical tube which is ejected in a state in which the foam is expanded even more and the other end is The present invention provides a fire extinguishing foam generator characterized in that it comprises a support attached to a flange to secure a cylindrical tube under a branch.

The injection nozzle is characterized by consisting of a first nozzle coupled to the circumferential surface of the branch, and a second nozzle connected perpendicularly to the first nozzle and the elbow.

The first nozzle is inclined downward on a horizontal line, and the inclination angle is 15 °.

The injection pressure of the mixed water injected into the cylindrical tube 24 is characterized in that 4BAR.

Hereinafter, a detailed description of a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a view schematically showing an engine room fire extinguishing system of a ship using a fire extinguishing generator of the present invention.

As shown, a plurality of fire extinguishing foam generators 10 are installed on the ceiling of the engine room 100 of the ship while maintaining a constant interval.

The extinguishing foam generators 10 are respectively connected to the supply pipe 200. The supply pipe 200 supplies the mixed water supplied through the mixer 300 to the extinguishing foam generator 10.

The mixer 300 is supplied to the supply pipe 200 by mixing them in a state in which the foam stock solution and the sea water (sea water) stored in the foam stock solution tank 400 are respectively supplied by the pumps 400a and 500a.

On the other hand, the mixed water is injected to the injection nozzle 16 of the foam generator 10 for the fire extinguishing through the supply pipe 200 is most preferably to be injected at the injection pressure of 4BAR. That is, the injected mixed water is expanded in the form of a foam due to the impact generated in the process of adjoining the inner diameter of the cylindrical tube 24. In this case, when the injection pressure of the mixed water is higher or lower than necessary, the expansion force of the foam is increased. There is a problem of deterioration, and therefore, the applicant was able to know through experiments that the expansion force of the foam is the highest when the injection pressure is set to 4BAR.

In addition, the feedstock and the seawater supplied to the mixer 300 is supplied in a 1:99 ratio, that is, the feedstock solution 1% and the seawater 99% ratio to supply a smaller amount of the form stock than conventional, which will be described below This is because the foam can be inflated enough to extinguish the fire even when using a minimum amount of the stock solution through the structure of the extinguishing foam generator 10 of the present invention. Through this effect, the fire extinguishing system of the present invention can reduce the amount of the foam stock solution by more than half as compared to the prior art, thereby minimizing the loading amount of the foam stock solution loaded on the vessel, thereby making it possible to reduce the weight of the vessel.

2 and 3 are views illustrating the structure of a fire extinguishing foam generator according to the present invention.

As illustrated, the fire extinguishing foam generator 10 includes a branch 12, a spray nozzle 16, a cylindrical tube 24, a mesh 26, and a support 28.

The branch body 12 is coupled to the supply pipe 200 and the flange 14, which are piped to the ceiling of the engine room 100 of the ship is supplied with a mixed water consisting of the form stock solution and sea water through the supply pipe 200 .

Injection nozzles 16 are installed at three circumferential surfaces of the branch 12. The injection nozzles 16 inject the mixed water supplied to the branch body 12 into the cylindrical tube 24 located below the branch body 12, preferably the inner diameter 24a of the cylindrical tube 24.

The injection nozzles 16 are all manufactured in the same structure, and will be described below to represent one injection nozzle 16.

The injection nozzle 16 has a first nozzle 18 directly coupled to the circumferential surface of the branch 12, and a second nozzle connected perpendicularly to the end of the first nozzle 18 by an elbow 20 ( 22).

On the other hand, the first nozzle 18 is formed to be inclined downward 15 ° on the horizontal line. The inclination angle R is such that when the mixed water is injected, the sprayed mixed water exactly matches the inner diameter 24a specific position of the cylindrical tube 24 (preferably 1/3 point upward from the lower end of the inner diameter of the cylindrical tube). In order to prevent the mixed water from leaking to the outside of the cylindrical tube 24 in the collision process is set angle to increase the amount of foam generated.

Under the branch 12, the cylindrical tube 24 is positioned in a state spaced apart. The cylindrical tube 24 is made of a hollow structure and the upper and lower ends are open.

The cylindrical tube 24 is when the mixed water injected from the injection nozzle 16 collides with the inner diameter 24a of the cylindrical tube 24, the mixed water is first expanded in the form of foam due to the impact generated in this process, the expanded The foam is ejected to the outside through the mesh 26 installed below the cylindrical tube 24 in accordance with the continuous supply pressure of the mixed water in the state stored in the cylindrical tube 24.

Below the cylindrical tube 24, a mesh 26 having a plurality of micropores 26a is attached. The mesh 26 expands and blows the foam to the extent that the primary expanded foam passes through the micropores 26a in the cylindrical tube 24 to extinguish the fire.

That is, the primary expanded foam in the cylindrical tube 24 is pushed down by the supply pressure of the mixed water continuously injected into the cylindrical tube 24 to pass through the micro-hole 26a of the mesh 26 In this case, the foam is mixed with the outside air in the process of passing through the micro-pores 26a, so that the foam expands to a greater extent to extinguish the fire.

On the other hand, a support 28 is further provided between the cylindrical tube 24 and the branch body 12. One end of the support 28 is attached to the circumferential surface of the cylindrical tube 24, and the other end is attached to the circumferential surface of the flange 14 described above to branch the cylindrical tube 24 provided with the mesh 26. 12) It is fixed below.

Hereinafter, the operation of the fire extinguishing foam generator according to the present invention will be described with reference to FIGS.

First, when a fire occurs in the engine chamber 100 of the vessel, sensors (not shown), etc. detect this and operate the pumps 400a and 500a to form the raw liquid and the seawater stored in the foam liquid tank 400. Will be pumped. At this time, the ratio of the raw material foam and the seawater supplied to the mixer 300 is supplied at a ratio of 1% foam raw material and 99% of seawater.

Thereafter, the raw material and the seawater supplied to the mixer 300 are mixed with each other, and then supplied to the extinguishing foam generator 10 installed on the ceiling of the engine room 100 through the supply pipe 200.

Specifically, the mixed water supplied to the supply pipe 200 is circled through the injection nozzle 16 installed on the circumferential surface of the branch 12 in a state flowing into the branch 12 installed below the supply pipe 200. It is injected into the clearance (24). At this time, the mixed water injected from the injection nozzle 16 is buried in the inner diameter 24a of the cylindrical tube 24, and the mixed water is first expanded in the form of foam in the cylindrical tube 24 by the impact generated at this time. In addition, the mixed water is sprayed in the axial direction of the second nozzle 22 in the process of being sprayed by the inclination angle R (which is inclined 15 ° downward on the horizontal line) of the first nozzle 18 of the spray nozzle 16. To hit a specific portion of the inner diameter 24a of the cylindrical tube 24 (approximately one third point upward from the lower end of the inner diameter of the cylindrical tube) to generate a primary foam, and the generated foam is a fine hole 26a of the mesh 26. ), It mixes with the outside air and expands further, and uses the generated foam to extinguish the fire.

As described above, the present invention achieves many effects as follows.

First, the present invention has the effect of extinguishing all kinds of fires by expanding the mixed water consisting of a mixture of the foam stock solution and seawater to foam foam to extinguish the fire.

In addition, the present invention can form a foam enough to extinguish the fire even with a small amount of foam stock compared with the prior art can reduce the amount of foam stock loaded on the ship with the cost savings due to the use of foam stock It has the effect of realizing the weight reduction.

Claims (4)

delete delete delete In accordance with the pumping operation of the pumps 400a and 500a, the mixer 300, which receives 99% of the foam stock solution and 1% of the seawater stored in the foam stock solution tank 400, and is mixed with each other, is mixed and formed in the mixer 300. In the supply pipe 200 receiving the mixed water and the mixed water discharged from the supply pipe 200 in the form of a foam to extinguish the fire in the foam generator, A branch 12 coupled to the supply pipe 200 and the flange 14 to receive mixed water; A plurality of injection nozzles (16) installed on a circumferential surface of the branch body (12) and for injecting the mixed water supplied to the branch body (12); A cylindrical tube 24 positioned below the spray nozzle 16 at a predetermined distance and for expanding the mixed water sprayed from the spray nozzle 16 in a foam form; A net mesh 26 installed below the cylindrical tube 24 and having a plurality of micropores 26a through which the primary expanded foam passes through the cylindrical tube 24 to eject the foam in a more expanded state; ; One end is attached to the circumferential surface of the cylindrical tube 24 and the other end is attached to the flange 14 and includes a support 28 for fixing the cylindrical tube 24 under the branch 12; The injection nozzle 16 has a first nozzle 18 coupled to the circumferential surface of the branch 12, and a second nozzle 22 connected perpendicularly to the first nozzle 18 and the elbow 20. Consisting of; The first nozzle 18 is configured to be inclined downward at a 15 ° on a horizontal line so that the mixed water is sprayed to a third point upward from the lower end of the inner diameter of the cylindrical tube 24; Mixing water injected into the cylindrical tube (24) through the injection nozzle 16 is characterized in that the fire extinguishing foam generator, characterized in that configured to be injected at the injection pressure of 4BAR.

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