KR20130034384A - Gas tight leakage walking device for automatic fire extinguisher - Google Patents

Abstract

PURPOSE: A diffusion fire extinguisher is provided to have a sealing leak alarm which notifies the user visually or aurally by operating the alarm in case the compressed air is leaked. CONSTITUTION: A diffusion fire extinguisher built-in with a sealing leak alarm comprises a main body(100) which contains fire extinguishment fluid and is filled with compressed air; a valve(200) which is formed with a charge unit for charging compressed air to the main body, and includes a jet nozzle spraying the fire extinguishment fluid in fire; a housing(300) which is formed with a first housing connector connecting to the main body on one side, and a second housing connector connecting to the outside on the other side; a moving part(400) connecting the first housing connector and the second housing connector in case the compressed air within the main body is under a predetermined pressure; and an alarm signal unit(600) which is formed on the other side of the housing in order to generate the alarm signal by the compressed air leaking to the outside within the main body.

Description

Gas tight leakage walking device For automatic fire extinguisher

The present invention relates to a diffuse fire extinguisher having a charge pressure sensor that allows a user to visually and visually confirm whether or not the charge pressure inside the diffuse fire extinguisher is appropriate.

Typically, inside the building, a fire suppression means is taken in preparation for a fire. Various fire protection measures are taken, such as fire extinguishers installed at important locations of buildings and at entrances or exits of buildings, sprinklers spraying extinguishing water installed on ceilings, and diffusion type fire extinguishers spraying extinguishing fluid.

As such, automatic diffusion fire extinguishers are installed in firefighting rooms, engine rooms, oil rooms, or home kitchens, where small spaces where fire-fighting equipment cannot be installed or where fire can not be extinguished.

As shown in Figure 1, the automatic diffusion fire extinguisher (1), the storage tank (2) and the storage tank (2) which is configured in a circular shape so as to fill the extinguishing liquid can be fixed to the upper storage ceiling ( It is formed of a fastener (3) formed on the top of 2).

In addition, a valve 4 communicating with the storage tank 2 is formed at a lower end of the storage tank 2, and at one side of the valve 4, a pressure sign plate capable of visually confirming the pressure inside the storage tank 2 ( 5) is combined.

Referring to FIG. 1, an injection nozzle 6 for injecting extinguishing fluid is coupled to a lower end of the valve 4, and the injection nozzle 6 is formed by finishing with a cap 7.

The cap 7 is fixed to lead melted at a temperature of 72 ℃ is formed so that the extinguishing liquid is injected into the leaf while melting the lead when the temperature rises above 72 ℃ when the fire occurs.

This type of diffused fire extinguisher is frequently leaked with compressed air or non-combustible gas leaked in time, and the extinguishing fluid is not injected in the event of a fire. In order to prevent such a problem, the pressure sign plate 5 was installed on the side of the valve 4 to visually check the pressure state of the fire extinguisher as described above, but this is a hassle for the user to check regularly every time. Occurred.

Utility Model Registration 20-0447990 {Auto-Proliferation Fire Extinguisher}

Therefore, the present invention is installed in the storage tank for storing the compressed air and extinguishing fluid in order to solve the disadvantage that the compressed air charged inside the conventional automatic fire extinguisher does not work in case of fire, the compressed air leaks If necessary, an alarm will be activated to provide a diffuse fire extinguisher with a built-in leak detector that visually or audibly alerts the user.

Diffusion fire extinguishing device having a leak detection device of the present invention includes a main body (100) containing a digestive fluid and filled with compressed air; A valve (200) installed at a lower end of the main body (100) and including a injection nozzle (220) for forming a charging unit (210) for filling compressed air in the main body (100) and for injecting the extinguishing liquid in the event of a fire; A housing 300 having a first housing communication hole 310 communicating with the main body 100 at one side, and a second housing communication hole 320 communicating with the outside at one side thereof; The housing 300 is installed to be movable along the inner wall of the housing 300, and when the compressed air in the main body 100 is below a specific pressure, the housing 300 is moved by the elastic force of the spring 500. A moving part 400 moving in one direction of the housing 300 along a wall to communicate the first housing communication hole 310 and the second housing communication hole 320 with each other; When the compressed air inside the main body 100 leaks and the compressed air inside the main body 100 falls below a specific pressure, the compressed air inside the main body 100 passes through the first housing communication hole 310 and the second housing communication hole 320 to the outside. And an alarm signal unit 600 formed at the other side of the housing 300 to generate an alarm signal by the compressed air inside the discharged main body 100.

In the present invention, the moving part 400 is the piston 410, one side is connected to the piston 410 is formed extending in the other direction of the housing 300 and the stop pin 430 on the other peripheral surface And a shaft 420 protruding from each other, wherein the piston 410 is disposed between the first housing communication hole 310 and the second housing communication hole 320 before the compressed air is filled in the main body 100. Intersects with the first guide groove 451 and the first guide groove 451 fitted into the stop pin 430 so as to be positioned more deeply than the first guide groove 451 and the inside of the main body 100 The second guide is fitted to the stop pin 430 to leak the compressed air of the piston 410 to move the first housing communication hole 310 and the second housing communication hole 320 to each other The rotary lever 450 in which the groove 452 is formed is fitted to the shaft 420 so as to be rotatable, and in the main body 100. When the stop pin 430 is separated from the first guide groove 451 by the compressed air in the part, the rotation lever 450 is rotated by a predetermined angle so that the stop pin 430 is the second guide groove. In order to be seated on the 452, the rotary lever 450 is characterized in that the rotary lever spring 460 is connected.

In the present invention, the rotary lever 450 has a first locking projection 453 is formed to protrude, so that the rotary lever 450 is rotated by the predetermined angle by the rotary lever spring 460, the The inside of the housing 300 is characterized in that the second locking jaw 340 that is caught on the first locking jaw 453 is formed protruding.

In the present invention, the support plate 330 is formed through the shaft guide hole 310-H for guiding the shaft 420 inside the housing 300, the spring 500 is the shaft 420 It is inserted into the) and is supported by the piston 410 and the support plate 310, the rotary lever 450 is characterized in that positioned between the support plate 330 and the stop pin 430.

In the present invention, a sealing material 700 for sealing the shaft guide hole (330-H) is formed on the outer circumferential surface of the shaft 420 in order to prevent the compressed air inside the main body 100 is discharged to the outside It is characterized by.

Diffuse fire extinguisher with a built-in air leakage alarm device of the present invention can be attached to a separate alarm device on the body of the diffuse fire extinguisher can obtain the effect that the user can recognize the leakage of the compressed air charged therein by hearing and vision.

In addition, in the manufacture of the diffusion fire extinguisher that can detect the leakage of the compressed air, there is an advantage that can be produced leak detector so that a separate power supply is unnecessary.

1 is a cross-sectional view showing a conventional diffusion fire extinguisher.
2 is a cross-sectional view of a diffusion fire extinguisher with a leak detection system of the present invention.
Figure 3 is an exploded cross-sectional view of a diffusion fire extinguisher with a leak detection system of the present invention.
4 is an operational state diagram of the built-in diffusion fire extinguisher with airtight leak alarm of the present invention.
Figure 5 is a perspective view of the parts of the built-in diffusion fire extinguisher of the present invention leak tight alarm.
6 is a cross-sectional view showing another embodiment of the present invention.
7 is a perspective view showing another embodiment of the present invention.
8 is a front view showing another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a cross-sectional view showing a conventional diffusion fire extinguisher, Figure 2 is a cross-sectional view of a diffusion fire extinguisher with a leak detection system of the present invention, Figure 3 is an exploded cross-sectional view of the diffusion fire extinguisher with a leak detection system of the present invention. . 4 is an operational state diagram of a diffusion fire extinguisher with a leak detection system of the present invention, Figure 5 is a perspective view of a part of the diffusion fire extinguisher with a leak detection system of the present invention, Figure 6 is another embodiment of the present invention It is sectional drawing shown. 7 is a perspective view showing another embodiment of the present invention, Figure 8 is a front view showing another embodiment of the present invention.

The present invention relates to a diffused fire extinguisher with a built-in charge pressure sensor that allows the user to visually and visually confirm whether the charge pressure inside the diffused fire extinguisher is appropriate.

Referring to FIG. 2, the present invention includes a main body 100 including a digestive liquid and filled with compressed compressed air. The compressed air filled therein may be composed of nitrogen and carbon dioxide as various incombustible gases.

The valve 200 is installed at the lower end of the main body 100. One side of the valve 200 is formed with a charging unit 210 for the purpose of filling the compressed air inside the main body 100. Through the charging unit 210 may be filled with the extinguishing liquid as well as compressed air. The injection nozzle 220 is formed at the lower end of the valve 200. When the fire occurs through the injection nozzle 220, the extinguishing liquid inside the main body 100 is diffused and sprayed. The lower end of the injection nozzle 220 is blocked with lead. The heat is transferred to the injection nozzle 220 when a fire occurs. When the transferred temperature reaches a temperature at which lead is melted, the injection nozzle 220 is automatically opened to extinguish the liquid.

2, the housing 300 is installed on one side of the main body 100. The housing 300 is formed in a hollow shape. One side of the housing 300 has a first housing communication hole 310 communicated with the inside of the main body 100 is formed through the housing 300, the first housing communication hole 310 is one side circumferential surface of the housing 300 Can be formed in plural. In addition, the second housing communication hole 320 in communication with the outside is formed at a position opposite to the first housing communication hole 310. That is, the second housing communication hole 320 is formed to penetrate through the other side of the housing 300 and communicate with the outside.

2 and 3, the moving part 400 is installed inside the housing 300. The moving part 400 is installed to be movable along the inner wall surface of the housing 300. The moving part 400 includes a piston 410 formed to be in close contact with the inner surface of the housing 300. The shaft 420 integrally formed with the piston 410 is protruded from one side of the piston 410. The shaft 320 is formed to protrude a predetermined distance in the longitudinal direction of the housing 200. On the other side of the shaft 420, the stop pin 430 is formed to protrude, and the stop pin 430 may be formed integrally with the shaft 420, and formed at the end of the shaft 420 to be separated from the shaft 420. The stop pin 430 may be formed to fit in the long hole (not shown).

Referring to FIG. 3, a support plate 330 is formed inside the housing 300. The shaft guide hole 310 -H is formed in the center of the support plate 310. The shaft guide hole 310 -H is formed to guide the movement of the shaft 420 in the longitudinal direction of the housing 300. A spring 500 fitted to the shaft 420 and supported on one side of the piston 410 and supported on the support plate 330 is installed inside the housing 300. The spring 500 is supported by the support plate 330 to support the piston 410 by elasticity of the spring 500.

That is, the piston 410 may be moved between the first housing communication hole 310 and the second housing communication hole 320 by moving in one direction of the housing 300 by the pressure of the compressed air in the main body 100. have.

When the compressed air in the main body 100 is below a certain pressure, the piston 410 is connected to the housing 300 so that the first housing communication hole 310 and the second housing communication hole 320 communicate with each other by the elastic force of the spring 500. Can move in the other direction.

Referring to FIG. 3, a rotation lever 450 fitted to the shaft 420 and rotatable inside the housing 300 is installed. The rotary lever 450 is installed at a position symmetrical with the spring 500 about the support plate 330. That is, the rotary lever 450 is installed to be located between the support plate 330 and the stop pin 430. One side of the rotary lever 450 is supported by the support plate 330 is formed so that the projection jaw (not shown) is formed and the projection jaw is formed for the purpose of reducing the friction coefficient of the rotary lever 450.

Referring to FIG. 5, the other side of the rotary lever 450 is recessed to form a first guide groove 451 and a second guide groove 452. The second guide groove 452 is formed to be recessed more deeply than the first guide groove 451 and is formed to cross the first guide groove 451. The first guide groove 451 and the second guide groove 452 should be formed at least the same size as the stop pin 430 so that the stop pin 430 can be smoothly seated.

Referring to FIG. 3, a rotation lever spring 460 is installed at one side of the rotation lever 450. The rotary lever spring 460 rotates the rotary lever 450 by a predetermined angle to allow the stop pin 430 to be seated in the first guide groove 451 and the second guide groove 452.

Referring to FIG. 4, when the stop pin 430 is seated in the first guide groove 451, the piston 410 is positioned between the first housing communication hole 310 and the second housing communication hole 320 to rotate. The rotary lever 450 which is to be rotated by the elastic force of the lever spring 460 is fixed. At this time, the spring 500 holding the piston 410 is maintained in a compressed state.

Referring to FIG. 4, when the stop pin 430 is seated in the second guide groove 452, the piston 410 is moved to the other side of the housing 300 by the restoring force of the spring 500. That is, the piston 410 moves to the other side of the housing 300 such that the first housing communication hole 310 and the second housing communication hole 320 are located at the other side of the piston 410. In this case, the first housing communication hole 310 and the second housing communication hole 320 communicate with each other and communicate with the inside of the main body 100.

The above description shows the operating state of the present invention, the operation method of the present invention will be described in more detail in the following description of the operation method of the present invention.

Referring to FIG. 4, the first locking jaw 453 is protruded from the other side of the rotary lever 450. The first locking jaw 453 is formed to be rotated by a predetermined angle when the rotary lever 450 is rotated by the elasticity of the rotary lever spring 460. A second locking jaw 340 that is caught by the first locking jaw 453 is formed inside the housing 300. The first locking jaw 453 and the second locking jaw 340 are positioned on the same vertical line so that the first locking jaw 453 is caught by the second locking jaw 340.

Referring to FIG. 3, a sealing material 700 is formed on an outer circumferential surface of the shaft 420. The sealing material 700 is to prevent the compressed air inside the main body 100 from being discharged to the outside by sealing a gap between the shaft guide hole 310 -H and the shaft 420 when the shaft 420 is fitted. .

Referring to FIG. 3, a shaft stop 421 is formed between the piston 410 and the sealing member 700. The shaft stop 421 is installed to limit the distance that the moving part 400 moves when the moving part 400 is moved by the pressure of the compressed air inside the main body 100.

That is, when the pressure of the compressed air inside the main body 100 is high and the sealing material 700 formed in the shaft 420 is separated from the shaft guide hole 310 -H, the compressed air inside the main body 100 may leak to the outside. It is installed for the purpose of preventing this.

Referring to FIG. 3, one side of the housing 300 is installed at one side of the main body 100 to communicate with the inside of the main body 100, and an alarm signal unit 600 is formed at the other side of the housing 300. When the compressed air inside the main body 100 leaks and the pressure in the main body 100 falls below a certain pressure, the alarm signal unit 600 receives the piston 300 from the housing 300 by restoring force of the spring 500. To the side. When the piston 410 moves to the other side of the housing 300, the first housing communication hole 310 and the second housing communication hole 320 communicate with each other so that the compressed air inside the main body 100 communicates with the second housing. The ball 320 is discharged to the outside. The compressed air discharged to the outside may operate the sounding plate (not shown) formed inside the alarm signal unit 600 to be audibly recognized by the user to inform that the compressed air inside the main body 100 leaks.

With reference to Figure 4 will be described a method of operating a diffusion fire extinguisher with a gas tight leak alarm device of the present invention.

Referring to Figure 4 (a) when the compressed air is not filled in the main body 100

The piston 410 is positioned between the first housing communication hole 310 and the second housing communication hole 320. The stop pin 430 is seated in the first guide groove 451 of the rotary lever 450 to prevent the piston 410 from moving to the other side of the housing 300 by the elasticity of the spring (500). The shaft guide hole 310-H is sealed by the sealing material 700.

Referring to Figure 4 (b) when the compressed air is filled in the main body 100

When compressed air presses the piston 410 through the first housing communication hole 310 of the housing 300, the spring 500 is also compressed by the compressed air. When the piston 410 and the shaft 420 move a predetermined distance inwardly of the housing 300, the shaft stop 421 is in close contact with the support plate 330 to block the movement of the piston 410. The stop pin 430 is separated from the first guide groove 451 of the rotary lever 450. The rotary lever 450 fixed by the stop pin 430 is rotated at an angle due to the elastic force of the rotary lever spring 460.

At this time, the second locking jaw 423 formed in the housing 300 is caught by the first locking jaw 453 of the rotation lever 450 to block rotation of the rotation lever 450. The rotary lever 450 is rotated only by the angle at which the first guide groove 451 and the second guide groove 452 cross each other. Therefore, the second guide groove 452 and the stop pin 430 is located at the same position.

Referring to FIG. 4C, when the compressed air inside the main body 100 leaks and the pressure inside the main body 100 drops.

When the compressed air that pressurizes the piston 410 gradually leaks, the moving part 400 gradually moves to the other side of the housing 300 by the elastic force of the spring 500. The stopper pin 430 is also seated in the second guide groove 452 of the rotary lever 450 and the sealing member 700 formed in the shaft 420, which has closed the shaft guide hole 310-H, is also the shaft guide hole 310. Slowly deviates from -H). When the compressed air in the main body 100 is lower than the set pressure, the stop pin 430 is seated in the second guide groove 452, and the piston 410 moves to the other side of the housing 300 so that The first housing communication hole 310, the shaft guide hole 310 -H, and the second housing communication hole 320 communicate with each other. Then, the compressed air in the main body 100 is discharged to the outside through the second housing communication hole 320 to operate the ringing plate (not shown) of the alarm signal unit 600 to be perceived to the user by hearing.

Another embodiment of the present invention will be described with reference to FIG.

When the compressed air is discharged by installing a ringing hole inside the alarm signal unit 600, the ringing ball hits the wall surface of the alarm signal unit 600 to generate a notification sound.

Another embodiment of the present invention will be described with reference to FIG.

The alarm signal unit 600 has a rotary blade 610 is fixed to the housing 300 to rotate. The rotary blade 610 is rotated due to the compressed air while the compressed air is discharged to the outside. One side of the rotary blade 610 is formed with a striking stand 620 and the striking stand 620 is installed in a structure that rotates at the same time when the rotary blade 610 is rotated. An impact plate 630 is formed inside the alarm signal unit 600 to strike the striker 620 to generate a notification sound.

A third embodiment of the present invention will be described with reference to Fig. 6C.

The alarm signal unit 600 is provided with a magnet having a magnetic force on one side of the rotary wing 610 and a power generating device 640 is wrapped around the coil and wound around the magnet. When the rotary blade 610 rotates the current is generated in the power generator 640. The generated current is supplied to the LED 650 installed on the outside of the alarm signal unit 600 so that the LED (00) is turned on so that the user can visually recognize the leakage of compressed air.

A fourth embodiment of the present invention will be described with reference to FIG.

Referring to FIG. 7A, a cap 660 is formed at the end of the alarm signal part 600 to surround the alarm signal part 600. The cap 660 is tightly fitted to seal the alarm signal part 600 and fitted to the alarm signal part 600.

Referring to FIG. 7B, a notification unit 670 is installed inside the cap 660. The notification unit 670 may be formed of fabric paper containing various phrases so as to visually inform the user. One side of the notification unit 670 is fixed to the alarm signal unit 600 and the other side is fixed to the cap 660. As the compressed air discharged from the main body 100 is discharged, the cap 660 is separated from the alarm signal unit 500 by the compressed air, and the notification unit 670 formed inside the cap 660 is unfolded. The notification unit 670 is formed for the purpose of informing the user to recognize the leakage of compressed air is the phrase or color written on the notification unit 670.

As such, the alarm signal unit 600 is formed in a structure that can be operated only by the compressed air inside the main body 100 because a separate power supply is unnecessary. The alarm signal unit 600 may be installed in various ways other than the prepared method.

Referring to FIG. 8, a moving part 400 may be installed inside the valve 200 installed at the bottom of the main body 100, and a housing 300 having an alarm signal part 600 provided on one side thereof may be installed. In this case, the housing 300 communicates with a communication hole (not shown) formed in the valve 200, and the communication hole communicates with the inside of the main body 100, so that the housing 300 communicates with the inside of the main body 100. It is formed to be. Therefore, it operates in the same way as the operating method of the built-in diffusion fire extinguisher with the leak leakage alarm.

100: main body 200: valve
210: charging unit 220: injection nozzle
300: housing 310: first housing communication hole
320: second housing communication hole 330: support plate
330-H: support plate communication hole 340: second locking jaw
400: moving part 410: piston
420: shaft 421: shaft stop
430: stop pin 450: rotary lever
451: first guide groove 452: second guide groove
453: first locking jaw 460: rotary lever spring
500: spring 600: alarm signal part
610: rotor blade 620: batter
630: blow plate 640: power generating device
650: LED 660: cap
570: notification unit 700: sealing material

Claims (5)

A main body 100 including a digestive liquid and filled with compressed air therein;
A valve (200) installed at a lower end of the main body (100) and including a injection nozzle (220) for forming a charging unit (210) for filling compressed air in the main body (100) and for injecting the extinguishing liquid in the event of a fire;
A housing 300 having a first housing communication hole 310 communicating with the main body 100 at one side, and a second housing communication hole 320 communicating with the outside at one side thereof;
The housing 300 is installed to be movable along the inner wall of the housing 300, and when the compressed air in the main body 100 is below a specific pressure, the housing 300 is moved by the elastic force of the spring 500. A moving part 400 moving in one direction of the housing 300 along a wall to communicate the first housing communication hole 310 and the second housing communication hole 320 with each other;
When the compressed air inside the main body 100 leaks and the compressed air inside the main body 100 falls below a specific pressure, the compressed air inside the main body 100 passes through the first housing communication hole 310 and the second housing communication hole 320 to the outside. An alarm signal unit 600 formed at the other side of the housing 300 to generate an alarm signal by the compressed air inside the discharged main body 100;
Diffuse fire extinguisher with a leak-tight alarm, characterized in that it comprises a.
The method of claim 1,
The moving part 400 has a piston 410, one side is connected to the piston 410 is formed extending in the other direction of the housing 300 and the shaft protruding the stop pin 430 formed on the other peripheral surface ( 420),
The piston 410 is fitted to the stop pin 430 such that the piston 410 is located between the first housing communication hole 310 and the second housing communication hole 320 before the compressed air is filled in the main body 100. The piston 410 intersects with the first guide groove 451 and the first guide groove 451 and is embedded in a predetermined depth more than the first guide groove 451 and leaks compressed air inside the main body 100. Rotation lever 450 is formed with a second guide groove 452 is fitted to the stop pin 430 to move the first housing communication hole 310 and the second housing communication hole 320 to each other. ) Is pivotally fitted to the shaft 420,
When the stop pin 430 is separated from the first guide groove 451 because the compressed air is filled in the main body 100, the stop pin 430 is rotated by rotating the rotary lever 450 by a predetermined angle. A diffusion fire extinguisher with a leak-tight alarm device, characterized in that the rotary lever spring 460 is connected to the rotary lever 450 so as to be seated in the second guide groove (452).
The method of claim 2,
A first locking jaw 453 is protruded from the rotary lever 450,
The second locking jaw 340 that is caught by the first locking jaw 453 inside the housing 300 so that the rotation lever 450 may be rotated by the rotation lever spring 460 only by the predetermined angle. Diffuse fire extinguisher with a leak-tight alarm characterized in that the protrusion is formed.
The method of claim 2,
A support plate 330 having a shaft guide hole 310 -H formed therein for guiding the shaft 420 is formed inside the housing 300.
The spring 500 is fitted to the shaft 420 and supported by the piston 410 and the support plate 310,
The rotary lever 450 is a fire extinguisher with a leak-tight alarm device, characterized in that located between the support plate 330 and the stop pin (430).
The method of claim 4, wherein
Sealing material 700 for sealing the shaft guide hole (330-H) is formed on the outer circumferential surface of the shaft 420 in order to prevent the compressed air inside the main body 100 is discharged to the outside Diffuse fire extinguisher with leak alarm.

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