KR200447031Y1 - Throwing Aerosol Digester - Google Patents

Abstract

The present invention relates to a throwing aerosol fire extinguisher used to initially extinguish when a fire occurs in a room or an enclosed space, the cylindrical body 30 having a throwable size and the upper and lower portions open; An upper cover (33) covering an upper portion of the main body (30); Comprising the ignition device 40 having a primer 42 and the ball 46 on the upper portion of the upper cover 33; In the main body 20, a solid aerosol compound 10, a firing agent 12 placed under the aerosol compound 10, and a lower side of the firing agent 12 are installed below the solid aerosol compound 10 The coolant 20 for cooling the extinguishing gas according to the ignition is characterized in that each is separately accommodated.

The present invention can be easily put out by simply removing the safety pin of the fire extinguisher and throwing it into the fire area by the above configuration, so it is convenient to use and also does not block the oxygen at the fire site. There is no fear of choking even if there is a person.

Fire Extinguisher, Throwaway, Aerosol, Extinguishing Agent, Aerosol Fire Extinguisher

Description

Throw aerosol fire extinguisher {THROW A HAND-TYPE AEROSOL FIRE EXTINGUISHER}

The present invention relates to a throwing aerosol fire extinguisher used for the initial fire extinguishing work. More specifically, when thrown at a fire site, the low temperature extinguishing gas emitted from the inside of the fire is the oxygen required for human breathing. The present invention relates to a throwing aerosol fire extinguisher which suppresses further combustion by reacting with a compound required for combustion while leaving it unattended.

Fire extinguishers are used to extinguish a fire at an early stage. Fires are classified into general fires, oil fires, electric fires, and metal fires according to their characteristics. When extinguishing a fire, an appropriate type of fire extinguisher is selected. The fire extinguisher is used to extinguish the fire. The fire extinguisher is further divided into a powder fire extinguisher, a carbon dioxide fire extinguisher, and a halon fire extinguisher according to the type of extinguishing agent charged therein.

Powder extinguishers are widely used extinguishers, which contain a fire extinguishing agent called "monium cyanide" of fine powder such as wheat flour. Carbon dioxide extinguishers, also called carbon dioxide extinguishers, are used in electric fires where water cannot be used. Carbon dioxide, which is heavier than air, cuts off the supply of oxygen to extinguish fires. If there is a person in the field, the oxygen required for breathing is also blocked, which may cause a person to choke.

The halon fire extinguisher is also used for fire sites where water cannot be used, such as computer rooms. Since it has no trace after use and does not cause any damage to the object when it is released, its use range is wide, but the price of halon is high, and ozone layer such as freon is expensive. Its use has recently been regulated because it uses substances that destroy it.

As described above, most of the fire extinguishers currently used are methods of extinguishing fires by cutting off the surrounding oxygen, so when the fire extinguisher is used in an enclosed fire site, the fire extinguisher may remain at the fire site or suffocate the fire extinguisher.

In addition, most extinguishers usually contain a fire extinguishing agent such as powder and gas in a container or device, and use a fire extinguishing agent in the container or device when a fire occurs. Fire is used to extinguish the fire directly from the fire. Its size is heavy and difficult to use, and if the fire spreads around, the fire extinguishing worker may be burned or suffocated. It is necessary to develop a throwing aerosol fire extinguisher capable of extinguishing the fire at some distance from the fire site and supplying the air necessary for breathing if there is a person at the fire site.

The present invention was devised in view of the problems of the conventional fire extinguisher as described above, and the present invention can extinguish a fire by simply throwing a fire extinguisher after the safety pin of the fire extinguisher is removed by a worker or an eyewitness. The purpose is to provide a fire extinguisher.

In addition, the present invention can effectively extinguish a fire by blocking the further combustion by reacting with the compound required for combustion, leaving the oxygen required for human respiration, when the low temperature extinguishing gas discharged from the inside is thrown at the fire site Another purpose is to provide a fire extinguisher.

An object of the present invention as described above consists of a cylindrical body having a throwable size and the upper and lower portions open, the upper cover covering the upper portion of the main body, and located on the upper portion of the upper cover and having a primer and a ball. Undertake; The main body is provided with a solid aerosol compound, a firing agent placed in the lower part of the aerosol compound, and a coolant installed under the firing agent and cooling the extinguishing gas due to the ignition of the solid aerosol compound. do.

Another object of the present invention is achieved by using at least one selected from potassium nitrate (KN0 ₃ ) or potassium chlorate (KClO ₄ ) as a solid aerosol compound 10 for generating a digestive gas.

By using the present invention, the fire extinguisher can be easily carried out by simply removing the safety pin of the fire extinguisher and throwing the fire extinguisher around the ignition site at the fire site, and the human injury that may occur in the process of extinguishing the fire. Can be minimized.

In addition, the present design of O in the digestive gas combustible materials released in the digestive ^-, H ^+, OH ^- so well, the oxygen of the fire will remain intact to bind as to the person to remain in the fire suppression or fire breathing As a result, suffocation concerns are eliminated.

In addition, since the present invention leaves no residue other than the extinguishing gas, it is possible to prevent secondary damages caused by extinguishing agents of electronic devices or various devices around the fire site.

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

The present invention is a throwing aerosol fire extinguisher to extinguish the fire by throwing the fire extinguisher to the size and weight of the fire extinguisher as shown in Figure 1, the solid aerosol compound 10 and the coolant 20 is largely inside It consists of the main body 30 accommodated, respectively, and the upper side of this main body 30, and the ignition apparatus 40 provided with the primer 42 and the ball 46 for igniting the solid aerosol compound 10.

As shown in FIGS. 1 and 2, the main body 30 has a cylindrical upper and lower portions, and is made of a light metal, and the inside of the wall has a heat insulating cloth (shown in FIG. 3). 60) is charged to maintain insulation to the outside.

The insulation cloth 60 is made of a kevlar that has excellent heat insulation performance and heat resistance, so that the solid aerosol compound 10 is ignited so that the high temperature heat generated thereby does not escape to the outside and cause another fire.

Inside the cylindrical body 30, a heat insulating cloth 60, a solid aerosol compound 10, an ignition material 12, an upper diaphragm 50A, a separation pipe 32, an intermediate diaphragm 50B, and a coolant 20 are formed from the top. ), The lower diaphragm 50C, the auxiliary seating table 32A, and the lower cover 34 are sequentially placed, and these components are formed by bending the upper and lower ends of the main body 10 by bending the inner side (A). It is fixed to the inside of the main body 10, the upper cover 33 is installed on the upper portion and is sealed by the outside, whereby the locking jaw (A) is placed in the main body 30, all the components after the cover on the top After covering 33, it is bent.

The heat insulating cloth 60 is installed not only inside the wall of the main body 30 but also inside the upper part of the main body 30, and a material of the same material as that of being filled inside the wall of the main body 30 is used, and the solid to be described later The heat generated while the aerosol compound 10 is burned is blocked from being discharged to the upper portion of the main body 30.

The lower part of the heat insulating cloth 60 is filled with a cylindrical solid aerosol having a through hole 11 therein (exists in a solid state and generates solid particulates upon combustion). The solid aerosol compound (10 ) Is manufactured to include at least one selected from potassium nitrate (KN0 ₃ ) or potassium chlorate (KClO ₄ ), the high temperature ignition gas through the ignition device 40 to be described later When the igniter 12 is ignited, a solid aerosol compound 10 is taken in from the bottom to produce a digestive gas containing potassium (K) ions, and when the extinguishing gas is discharged from the body 30, the extinguishing gas is extinguished. gas acts to keep the combustion in the O combustible material to the combustion to take place ^-, H ^+, OH ^- and by combining combustion so as to block the combustible material is not more than combustion, where oxygen in the air is a bond are Not because of the fire of oxygen are left intact, so that the person can remain in the fire is solved in accordance with a risk of choking because it can breathe.

In the lower portion of the solid aerosol compound 10, a disc-shaped igniter 12 is placed. The igniter 12 is ignited by the high-temperature, high-pressure combustion gas generated from the ignition device 40, so that the solid aerosol compound 10 ) From the bottom.

Meanwhile, the diaphragm 50 having a plurality of through-holes 51 formed in the main body 10 is horizontally arranged in three of upper, middle, and lower portions, and the upper diaphragm 50A is positioned below the igniter 12 and The gas discharged when the solid aerosol compound 30 is combusted while supporting the agent 12 is discharged downward through the plurality of through holes 51, and the middle diaphragm 50B has a pipe-shaped separation pipe having an upper and lower part opened. Located at the lower portion of the space portion 70 formed by the 32 to induce the combustion gas discharged to the space portion 70 to flow into the coolant 20 installed in the lower portion, the bottom plate (50C) ) Serves to release the combustion gas passing through the coolant 20 to the outside of the fire extinguisher while supporting the coolant 20.

Between the upper diaphragm 50A which supports the ignition agent 12, and the intermediate diaphragm 50B which is located in the upper part of the coolant 20, the separation pipe 52 which has a predetermined height is installed, and these diaphragm 50 is accordingly installed. A space portion 70 having a predetermined height is formed therebetween, whereby a large amount of combustion gas is generated at one time, thereby providing a space in which the combustion gas that can not escape through the coolant 20 can remain and at the same time a solid aerosol compound 10 The coolant is protected by preventing direct contact of the flame with the flame) and the ignition agent (12).

The coolant 20 is filled in the space formed by the middle diaphragm 50B and the lower diaphragm 50C, and the coolant 20 is magnesium hydroxide (Mg (OH) ₂ ), sodium carbonate (Na ₂ CO ₃ ), Combustion of solid aerosol compound 10 as a solid compound comprising at least one selected from boric acid (H ₃ BO ₃ ), potassium chlorate (KClO ₄ ), potassium nitrate (KN0 ₃ ) and calcium carbonate (CaCO ₃ , CaCO ₄ ) In order to cool the high temperature combustion (digestion) gas generated by the low temperature, when the high temperature extinguishing gas is discharged to prevent the secondary fire may occur by this high temperature extinguishing gas.

In this case, the type and amount of the coolant 20 to be charged vary depending on the type of combustible material present in the fire extinguishing space. However, the coolant 20 is charged to a temperature lower than the ignition point of the material present in the fire extinguishing space and cooled to a temperature above the freezing point. When cooled below, the extinguishing agent solidifies again as a solid and blocks the diaphragm 50 so that the extinguishing gas may not be smoothly discharged to the outside of the extinguisher.

The lower diaphragm 50C is installed in the lower part of the coolant 20, and this lower diaphragm 50C is supported by the pipe-shaped auxiliary seating stand 32A whose upper and lower parts which have a predetermined height are opened, and this auxiliary seating stand ( 32A is supported by the lower cover 34 again, and a space having a predetermined height is formed between the auxiliary seating table 32A and the lower cover 34.

Unlike the upper cover 33, the lower cover 34 is provided with a plurality of extinguishing gas discharge ports 34A, through which the extinguishing gas is discharged to the outside of the extinguisher.

In order for the solid aerosol compound 10 filled in the fire extinguisher to combust, first, the ignition agent 12 placed in the lower portion of the solid aerosol compound 10 needs to be ignited, and therefore, the ignition device 40 is required. As shown in FIG. 4, a primer 42 containing the ignition agent 41 and an injection hole 43 for guiding the gas generated by ignition at the primer 42 toward the solid aerosol compound 10 in the main body 30. Is provided with a primer body 40A is formed, the ball is rotated by the torsion spring hitting the primer 42 and the ball 46 is installed on top of the ball 46 by the torsion spring installed in the ball ( Safety ring for limiting the rotational movement of the ball (46) is inserted into the lever 45 and the fastening holes (h1, h2) respectively formed in the lever 45 and the primer body (40A) rotated together with ( 44 is provided with a sink 40B.

Hereinafter, a method for operating a fire extinguisher of the present invention having the structure as described above will be described according to the operating sequence.

The operation method of the throwing aerosol fire extinguisher of the present invention is similar to the operation method of the grenade.If the fire extinguisher of the present invention is to be used at the fire site, the user first grasps the fire extinguisher of the present invention in one hand near the fire site, As shown in FIG. 5, the safety ring 44 fitted into the fastening holes h1 and h2 of the primer body 40A and the sinking portion 40B of the ignition device 40 is pulled out and removed.

At this time, even if the safety ring 44 is removed from the fastening holes h1 and h2, since the user grips the lever 45 by hand, the ball 46 cannot be rotated and its installation state is maintained as it is, thereby removing the primer 42. Does not work because it does not hit.

After removing the safety ring 44 and throwing the fire extinguisher at the main ignition point of the fire site, the rotation limit of the torsion spring installed in the ball 46 is released while the lever 45 and the ball 46 of the ignition device 40 are released. Is simultaneously rotated about one end of the primer body 40A, whereby the ball 46 strikes the primer 42 to ignite the ignition agent 41.

When the ball 46 strikes the ignition agent 41 and starts ignition, a high temperature ignition gas flows rapidly into the main body 30 along the injection hole 43 in the primer body 40A, and the solid contained in the main body 30. It flows along the through hole 11 of the aerosol compound 10 to ignite the igniter 12 deposited on its bottom, whereby the solid aerosol compound 10 located thereon combusts from below.

When the solid aerosol compound 10 starts to burn, as shown in FIG. 6, a digestive gas containing a large amount of potassium (K) ions is generated, and the generated digestive gas is a through hole of the diaphragm 50 located at the bottom thereof. Evenly distributed by the 51 passes through the coolant 20.

The extinguishing gas passing through the coolant 20 is led to the downstream side of the coolant 20 and is discharged to the outside through the extinguishing gas discharge port 34A formed in the lower cover 34, and the discharged extinguishing gas acts on combustion to burn the gas. continue O of the combustible material to occur ^-, H ^+, OH ^- by binding to and blocking the combustion so that the combustible material is not more than combustion, where because of the extinguishing gas is not binding the oxygen in the air oxygen of the fire is as As a result, it is possible to breathe by oxygen when remaining at the fire site, so that the concern of suffocation is eliminated, and the fire extinguisher is thrown at a distance from the fire site so that the fire can be watched in a safe position. In addition, since the extinguishing gas containing the extinguishing agent does not leave a residue, it may cause damage to equipment around the fire site. If not there is no secondary damage caused by extinguishing agents.

1 is a perspective view showing a throwing aerosol digester according to the present invention,

Figure 2 is an exploded perspective view showing a throwing aerosol digester according to the present invention,

3 is a cross-sectional view showing a combination of a body, a solid aerosol compound and a coolant according to the present invention,

Figure 4 is a cross-sectional view showing a ignition device according to the present invention,

5 is a use state showing the ignition process of the solid aerosol in the throwing aerosol digester according to the present invention,

Figure 6 is a state diagram showing the flow of the digestive gas in the throwing aerosol digester according to the present invention.

[Explanation of symbols on the main parts of the drawings]

10: solid aerosol compound 11: through hole

12: igniter 20: refrigerant

30: main body 31: receiving portion

32: separation pipe 32A: auxiliary seat

33: top cover 33A: coupling portion

34: lower cover 34A: extinguishing gas outlet

40: ignition device 40A: primer body

40B: sink 41: ignition agent

42: primer 43: nozzle

44: safety loop 45: lever

46: ball 50: diaphragm

50A: upper plate 50B: middle plate

50C: lower plate 51: through hole

60: heat insulation cloth 70: space part

A: locking jaw h1, h2: fastener

Claims (7)

A cylindrical body 30 having a throwable size and having a top and a bottom open; An upper cover 33 covering an upper portion of the main body 30; Located in the upper portion of the upper cover 33 and made of a ignition device 40 having a primer 42 and the ball 46; In the main body 20, a solid aerosol compound 10, a firing agent 12 placed under the aerosol compound 10, and a lower side of the firing agent 12 are installed below the solid aerosol compound 10 Throwing aerosol digester, characterized in that the coolant 20 for cooling the digestive gas according to the ignition are respectively accommodated separately. The method according to claim 1, The upper diaphragm 50A, the intermediate diaphragm 50B, and the lower diaphragm 50C in which the several through-holes 51 were formed in the lower part of the ignition agent 12, and the upper and lower parts of the coolant 20, respectively, are installed horizontally. An aerosol digester for throwing. The method according to claim 2, Throwing aerosol digester, characterized in that the space portion 70 is further formed by the separation pipe 32 having a predetermined height between the upper plate (50A) and the middle plate (50B). The method according to claim 1, The solid aerosol compound (10) is a throwing aerosol digester, characterized in that the solid compound containing at least any one selected from potassium nitrate (KN0 ₃ ), potassium chlorate (KClO ₄ ). The method according to claim 1, The coolant 20 is magnesium hydroxide (Mg (OH) ₂ ), sodium carbonate (Na ₂ CO ₃ ), boric acid (H ₃ BO ₃ ), potassium chlorate (KClO ₄ ), potassium nitrate (KN0 ₃ ), calcium carbonate (CaCO ₃ , CaCO ₄ ) Throwing aerosol digester, characterized in that the solid compound containing at least one selected from. The method according to any one of claims 1 to 5, The main body 30 is made of a double wall, throwing aerosol digester, characterized in that the heat insulating cloth 60 is filled in the lower portion of the inner wall and the upper cover 33, respectively. The method according to any one of claims 1 to 5, The ignition device 40 is provided on the upper surface of the main body 30, the primer 42 containing the ignition agent 41 and the solid aerosol compound in the main body 30 generated gas ignited by the primer 42 Primer body (40A) formed with a jet port (43) leading to (10); The ball 46 is shot by the torsion spring and strikes the primer 42 of the primer body 40A, and the ball 46 is installed on the ball 46 by the torsion spring installed on the ball 46. The safety ring 44 is inserted into the lever 45 and the fastening holes h1 and h2 respectively formed in the lever 45 and the primer body 40A to be rotated together with the ball 45 to limit the rotational movement of the ball 46. Throwing aerosol digester, characterized in that consisting of a sinking portion (40B) provided.

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