KR100791568B1 - Compression type fire extinguisher - Google Patents

Abstract

An accumulator type fire extinguisher with a poppet valve is provided to control pressure inside and outside a fire extinguisher bottle very effectively and to prevent the effluence of the compressed gas. An accumulator type fire extinguisher includes a fire extinguisher bottle(100) containing high-pressure gas and an extinguishing agent; a pressure controller(200) with one end being conned to an inlet(120) of the fire extinguisher bottle and the other end having a tube shaped piston seal(300), which has an injection port at one side; a poppet valve(400) with an orifice(450) built in the pressure controller to control pressure by moving between an inner side and the piston seal of the pressure controller; and an actuation unit(500) with one side connected to an outer face of the pressure controller, which comprises a pressure control opening(525), an air inlet(545), and a pilot valve(560) for controlling air inflow.

Description

Compression type fire extinguisher

1 is a perspective view according to an embodiment of the present invention.

Figure 2 is a cross-sectional view before opening of the poppet valve in one embodiment of the present invention.

Figure 3 is a cross-sectional view of the operation of the poppet valve in one embodiment of the present invention.

Figure 4 is a cross-sectional view and detail after opening of the poppet valve in one embodiment of the present invention.

<Description of reference numerals for main parts of the drawings>

10: accumulator

100: hydrant 120: hydrant inlet

200: pressure regulator 210: pressure regulator once

220: the other end of the pressure regulator 230: one side of the pressure regulator

240: the other side of the pressure regulator 250: discharge port

300: piston seal

400: poppet valve 450: orifice

460: main seal

500: operating part 520: one side of the operating part

525: pressure regulator 540: one side wall of the operating portion

545: air inlet 550: the other side wall of the operating portion

560: pilot valve 570: working coil

580: working lever

600: inlet

The present invention relates to a pressure-type fire extinguisher, and more particularly, the present invention effectively controls the pressure inside and outside the fire fighting bottle by using a poppet valve having an orifice and an operation unit for controlling the pressure to prevent the outflow of compressed gas in the fire fighting bottle. At the same time, it relates to a pressure-extinguisher that is safer to operate.

Normally, a pressure fire extinguisher valve is attached to a container containing a fire extinguishing agent after the siphon is connected to the inlet, and the valve is opened to fill the compressed gas, and the valve is kept closed. Extinguishing agents are released to the outside through siphons and valves to extinguish fire. In general, the compressed fire extinguisher uses carbon dioxide (CO ₂ ) or nitrogen gas (N ₂ ) as a compressed gas, and is used together with a powdered drug or a halon gas as a fire extinguishing agent.

The structure in which a valve is coupled to a container of a conventional pressure fire extinguisher has a structure in which a stepped portion is formed in the internal flow path of the valve and the stepped portion is shielded by a disk-shaped synthetic rubber seal having a stem. To open and close the valve.

Assemble "1" siphon to the siphon connection screw of the inlet side of the valve, and attach the leak-proof packing to the attachment screw, couple it to the valve attachment screw on the upper part of the container containing the extinguishing agent, and inject the compressed gas through the valve. When the gas is filled, the valve is shut off. Meanwhile, the compressed gas supplied into the container through the valve passes through the siphon and passes through the extinguishing agent in a bubble state to fill the upper compressed gas filling space of the extinguishing agent liquid surface. Here, the siphon is in close contact with the valve inlet-side flow path and the siphon opening is locked vertically to the extinguishing agent is blocked by the pipe wall and the extinguishing agent between the extinguishing agent discharge passage and the compressed gas filling space of the container. Thus, even if the compressed gas in the container acts on the extinguishing agent liquid level and presses the extinguishing agent toward the siphon opening, the extinguishing agent cannot be introduced into the siphon due to the compressed gas filled in the siphon.

In this state, when the fire extinguisher is used, the compressed gas in the siphon is discharged first, and then the extinguishing agent is injected, and thus, the extinguishing agent may not be sprayed quickly, but also causes a problem of wasting the compressed gas used as an energy source.

In addition, even if there is a problem in the synthetic rubber sealing or the step of the valve, a small gap occurs in the shutoff, and the extinguishing agent inside the container leaks out through the siphon and the valve by the same mechanism as the valve opening. As follows. If a small gap occurs in the valve blocking portion, the compressed gas of the extinguishing agent discharge passage of the valve inlet exits the gap and leaks to the outside at atmospheric pressure, causing a pressure drop. At this time, the pressure difference between the extinguishing agent discharge passage and the compressed gas filling space in the container causes the flow of fluid, causing the compressed gas inside the container to push the medicine out through the siphon and the valve blocking part. This release continues until the depleting agent is depleted by not leaking the compressible gas but only the incompressible extinguishing agent, and a significant amount of compressed gas is present in the container even after the extinguishing agent is depleted to the siphon opening height. There is a problem that disables the role of the indicator pressure gauge installed to check for pressure leakage in the container. In addition, the extinguishing agent leaks to the outside, causing problems such as polluting the surroundings. In addition, in the case of compressed gas that has not leaked, there is a risk of explosion of compressed gas due to the temperature rise inside the digestive bottle during the summer when the temperature rises.

In order to solve the above problems, the present invention by using a poppet valve having an orifice and the operation portion for controlling the same effectively controls the pressure inside and outside the digestive bottle to prevent the outflow of compressed gas in the digestive bottle and It is an object to provide a pneumatic fire extinguisher that operates safely.

In order to achieve the above object, the present invention comprises a digestive bottle containing a high pressure compressed gas and extinguishing agent; One end is coupled to the inlet and the other end of the piston seal is formed on the inner surface, the pressure control portion is formed on one side discharge port; A poppet valve which is formed to have an orifice inside the pressure control unit, and moves between an inner surface of one end of the pressure control unit and a piston seal and adjusts a digestive bottle and an external pressure; One surface is coupled to the outer surface of the other end of the pressure regulator, a pressure regulator formed through the pressure regulator on one surface, an air inlet formed on one side wall, a pilot valve for controlling the air inlet by the air inlet Characterized in that it comprises an operating unit including.

In another aspect, the present invention is characterized in that the poppet valve further comprises a main seal attached to the circumference of one surface of the poppet valve toward the inlet of the digestion bottle to closely contact the digestion bottle inlet.

In addition, the present invention is formed on the other side wall of the operating portion, characterized in that further comprises an operating coil and the operating lever for operating the pilot valve.

In addition, the width of the poppet valve of the present invention is characterized in that it is formed wider than the width of the inlet bottle and narrower than the width of the piston seal.

Hereinafter, the present invention will be described in detail with reference to a preferred embodiment of the accompanying drawings. 1 is a perspective view according to an embodiment of the present invention, Figure 2 is a cross-sectional view before opening of the poppet valve in one embodiment of the present invention, Figure 3 is a cross-sectional view of the operation of the poppet valve in an embodiment of the present invention, Figure 4 Is a cross-sectional view and a detailed view after the opening of the poppet valve in one embodiment of the present invention. Since the structural features of the present invention are in the control of the extinguishing bottle and the external pressure using a poppet valve with an orifice built-in, the illustration of the pressure gauge (pressure indicator) and the siphon used in the implementation of the accumulator is omitted.

The present inventors accumulate type fire extinguisher 10 is basically a digestive bottle 100, the pressure control unit 200 is coupled to the digestion bottle inlet 120, the piston seal 300 provided inside the pressure control unit 200 And a poppet valve 400 for adjusting the pressure by moving the gas bottle inlet 120 in a vertical direction, and an operating part 500 coupled with an outer surface of the other end of the pressure adjusting part 220.

The high pressure compressed gas and the extinguishing agent enter the inside of the fire fighting bottle 100 used in the practice of the present invention.

Digestive bottles can be freely selected and implemented in a shape that is generally widely used in addition to the shape shown in FIG.

Compressed gas is to assist the injection of the extinguishing agent in the digestive bottle, it is preferable to use carbon dioxide (CO ₂ ) or nitrogen (N ₂ ).

When the fire extinguishing agent is used as a powder fire extinguishing agent, it is preferable to raise a substance such as sodium hydrogen carbonate, potassium hydrogen carbonate, ammonium monophosphate, etc. into a fine powder, and eject the same by gas pressure. At this time, the powder fire extinguishing agent may be solidified when it reacts with moisture, and to prevent this, it should be used by moisture-proof processing with stearic acid salt or silicone resin of metal. This fire extinguishing agent made of powder is very effective for the surface fire of flammable liquids due to the effect of blocking the radiant heat by the powder cloud, the effect of co-catalyst, the suffocation effect due to the incombustible gas, and the powder is a non-conductor. have.

In addition, water (H ₂ O) may be used as the liquid fire extinguishing agent, or carbon dioxide, halon gas, or the like may be used as the gas fire extinguishing agent, depending on the embodiment conditions.

The pressure control unit 200 used in the practice of the present invention is a portion that serves to control the pressure between the digestive bottle 100 and the outside of the digestive bottle by the poppet valve 400 to be described later, one end of the pressure control unit 210 ) Is coupled to the indigestion bottle inlet 120 and the inner surface of the pressure control unit 220 is formed with a piston seal 300 having a pipe shape, the pressure control unit 230 is discharged from the digestion bottle A discharge port 250 through which the compressed gas and the extinguishing agent are discharged is formed.

One end of the pressure control unit 210 is combined with the digestive bottle inlet 120. At this time, the coupling method may be coupled to various methods, but it is preferable to combine with the inner peripheral surface of the digestion bottle inlet 120 by a screw coupling method.

And the inner surface of the other end of the pressure regulator 220 may be formed by forming a piston seal (300). At this time, the piston seal 300 can be carried out by forming a general pipe shape as shown in Figs. 3 and 4, so that the poppet valve 400 is inserted into the inner circumferential surface of the piston seal 300 during operation of the accumulator type fire extinguisher (10). It serves to guide the direction of movement of the poppet valve (400). Finally, the pressure adjusting unit 230 is formed by forming a discharge port 250 through which the compressed gas and the extinguishing agent are discharged from the digestion bottle 100. 2 to 4 attached to the embodiment of the present invention is somewhat exaggerated to form a wide width of the discharge port 250, the size of the discharge port 250, the use of the fire extinguisher, the degree of compression and use of the compressed gas It is preferable to form and carry out the size suitable for implementation conditions, such as the kind of extinguishing agent.

Poppet valve (poppet valve, 400) used in the practice of the present invention, as shown in Figures 2 to 4 attached, the body of the poppet valve 400 is the digestion bottle inlet 120 and the other end of the pressure regulator 220 As a valve for controlling the pressure of the fire fighting bottle 100 and the outside of the fire fighting bottle while moving in the vertical direction between the piston seals 300 formed on the inner surface of the), may also be referred to as a seat valve. These poppet valves are more reliable than spool valves or rotary valves, so they are generally used as check valves or stop valves.

At this time, in the practice of the present invention, it is preferable to configure the orifice 450 in the poppet valve 400. 2 to 4 show the orifice 450 in a somewhat exaggerated size to aid in the understanding of the present invention.

At this time, the orifice 450 may form an appropriate pressure gradient between the inside and the outside of the digestive bottle 100, and after the predetermined time passes in a state in which the compressed gas and the extinguishing agent inside the digestive bottle are sealed as shown in FIG. 2. Compressed gas inside the bottle is gradually moved to the pressure control unit 200 and the operating unit 500 through the orifice to balance the pressure.

One side of the operating part 520 used in the practice of the present invention is provided to be coupled to the outer surface of the other end of the pressure adjusting unit 220, the operating part one surface 520 is connected to the pressure adjusting unit 200 through It can be carried out by forming a pressure regulator 525 in the form of a hole.

At this time, the pressure adjusting port 525 controls the pressure between the pressure adjusting unit 200 and the operating unit 500 before the poppet valve 400 operates.

In addition, the operation unit side wall 540 may be provided with an air inlet 545 through which air is introduced from the outside, and may be provided with a pilot valve 560 for adjusting the air inlet by the air inlet 545.

Referring to the operation of the present invention, the accumulator fire extinguisher, the operation state and after the operation as follows.

First, the pilot valve 560 is in close contact with the air inlet 545 as shown in FIG. 2 before the operation of the accumulator fire extinguisher 10 according to the present invention, and the inflow of air from the outside to the operating part 500 is blocked. Therefore, the pressure of each of the digestive bottle 100, the pressure regulating unit 200, and the operating unit 500 is gradually brought into equilibrium with each other by the orifice 450 formed in the poppet valve 400.

The present invention operates the accumulator fire extinguisher 10, that is, operating the operating lever 580 and the operating coil 570 to leave the pilot valve 560 from the air inlet 545, the pressure control unit 200 and the operating unit ( As the pressure of 500 is equal to the atmospheric pressure, a pressure difference occurs between the digestive bottle 100 and the pressure regulator 200.

That is, the pilot valve 560 is separated from the air inlet 545 by the operation coil 570 as the operation lever 580 is bent downward as shown in FIGS. After the gas in the air flows out of the inlet 545, the pressure inside the operating unit 500 is equal to the atmospheric pressure, and since the pressure of the pressure regulating unit 200 is also equal to the atmospheric pressure, the digestive bottle 100 and the pressure control When the pressure difference occurs in the part 200, the poppet valve 400 is separated from the inlet bottle 120 to move toward the other end 220 of the pressure control part in which the piston seal is located.

Therefore, since the pressure for pushing the poppet valve 400 toward the other end 220 of the pressure regulator is greater than the pressure passing through the orifice 450 formed in the poppet valve 400, the poppet as shown in FIGS. 3 and 4 is attached. The valve 400 operates to be pushed in the vertical direction, and the small pressure bottle inlet 120 is opened to discharge the compressed gas and the extinguishing agent in the digestion bottle 100 to the outside through the discharge port 250 at high speed.

In this case, although the size of the discharge port 250 is slightly exaggerated in FIGS. 2 to 4, this is one embodiment for clarity. As the size of the discharge port is reduced by Bernoulli's theorem, the velocity of the compressed gas and the extinguishing agent flowing out through the discharge port is increased, so that the size of the inlet port 250 is increased according to the compression of the compressed gas in the digestion bottle 100. It can be performed by adjusting appropriately.

In the practice of the present invention by the above configuration, by using a poppet valve having an orifice and the operation unit for controlling the pressure to maintain a constant pressure inside and outside the digestive bottle to control the sudden accidental explosion of the fire extinguisher, etc. Fire extinguishers can be configured and carried out.

Claims (4)

Digestive bottles containing high pressure compressed gas and extinguishing agents; One end is combined with the inlet of the digestion bottle and the other end of the inner surface is formed with a piston seal of the pipe shape, the pressure control portion is formed on one side discharge port; A poppet valve which is formed with an orifice inside the pressure regulating part, and moves between the inner surface of the pressure regulating part and the piston seal and adjusts the digestion bottle and the external pressure; One surface is coupled to the outer surface of the other end of the pressure regulator, a pressure regulator formed through the pressure regulator on one surface, an air inlet formed on one side wall, a pilot valve for controlling the air inlet by the air inlet Actuator including; Accumulated fire extinguisher, characterized in that comprises a. In claim 1, In the poppet valve, A main seal attached to a circumference of one of the poppet valves facing the inlet of the fire bottle to closely contact the inlet of the fire bottle; Accumulated fire extinguisher, characterized in that further comprises. The method of claim 1 or 2, An operation coil and an operation lever formed on the other side wall of the operation unit to operate the pilot valve; Accumulated fire extinguisher, characterized in that further comprises. The method of claim 1 or 2, The width of the poppet valve, And a width smaller than the width of the piston seal and smaller than the width of the piston seal.

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