KR20240009648A - small space auto fire extinguisher - Google Patents

Abstract

The present invention relates to a small-space automatic fire extinguisher in which at least gas, fire extinguishing agent, and nozzle are installed in an upper, middle, and lower direction. In particular, the spray nozzle is rotated in the desired direction regardless of the left or right installation direction, and the indicating pressure gauge is always displayed at the front. It is about a small space automatic fire extinguisher that allows the user to immediately check the fire.

Description

Small space automatic fire extinguisher

The present invention relates to a small-space automatic fire extinguisher in which at least gas, fire extinguishing agent, and nozzle are installed in an upper, middle, and lower direction. In particular, the spray nozzle is rotated in the desired direction regardless of the left or right installation direction, and the indicating pressure gauge is always displayed at the front. It is about a small space automatic fire extinguisher that allows the user to immediately check the fire.

As a conventional automatic fire extinguishing device, for example, one described in a patent document (Korean Patent No. 10-2253400) has been proposed.

As shown in FIG. 1, the conventional automatic fire extinguishing device includes a fire extinguisher body 100 and a percussion unit 200 provided in the fire extinguisher body 100 to discharge the fire extinguishing agent 111 stored in the fire extinguisher body 100 in the event of a fire. And, the fire extinguisher main body 100 is provided with a percussion operation unit 300 that operates the percussion unit 200 in the event of a fire.

The fire extinguisher main body 100 is coupled to a fire extinguishing container 110 in which the fire extinguishing agent 111 and the gas member 112 are stored, and the lower part of the fire extinguishing container 110, and serves as a discharge passage for the fire extinguishing agent 111 in the event of a fire. It includes a base body 120 to which the percussion unit 200 and the percussion operation unit 300 are coupled.

A sealing plate 113 may be welded to the outlet of the fire extinguishing container 110.

The base body 120 is provided with a second discharge passage 122 vertically communicating with the first discharge passage 121, and at the end of the second discharge passage 122, the operation body 310 of the immersion operation unit 300 is provided. ) can be detachably screwed together.

This conventional automatic fire extinguishing device may be coupled to the inside of an electric control box containing a protective space, as shown in Figures 11 (a) and (b), and as shown in Figure 11 (c). , It is coupled to the outside of the electric control box, and only the sinking operation unit 300 can be arranged to be placed inside the electric control box.

According to the configuration of the conventional automatic fire extinguishing device described above, the following problems occur.

First, since the sealing plate 113 is welded to the outlet of the fire extinguishing container 110, installation of a pressure gauge is impossible. Therefore, it may not be possible to check whether the pressure of the fire extinguishing container 110 is properly formed, so it may not operate properly in the event of a fire.

Even if a pressure gauge is installed on the base body 120, the pressure cannot be measured because there is no fire extinguishing agent in the first discharge passage 121, and the immersion operation unit 300 is fixed to the base body 120. , depending on the installation environment (see FIGS. 7 to 9 and 11), there may be a problem with the installation direction of the automatic fire extinguishing device, that is, the pressure gauge may be turned over and not visible from the front.

Second, because the fire extinguishing agent is sprayed using a immersion method, it can be complicated due to the immersion structure.

Third, in order to weld and join the sealing plate 113 after filling the gas 112 in the fire extinguishing agent 110 filled with the fire extinguishing agent 111, equipment such as sealing to prevent the filled gas from leaking is very complicated and requires a lot of processing. do.

Korean Patent No. 10-2253400

In order to solve the above-described problem, the purpose of the present invention is to provide a small-space automatic fire extinguisher that allows the indicator pressure gauge attached to the fire extinguisher to be checked from the front at all times by rotating the nozzle in a desired direction regardless of the installation direction.

In addition, the purpose of the present invention is to provide a small-space automatic fire extinguisher that is filled with fire extinguishing agent up to the spray portion, thereby maximizing the spray amount of fire extinguishing agent and enabling rapid fire suppression.

Additionally, the purpose of the present invention is to provide a small space automatic fire extinguisher that can also inject gas into a fire extinguishing container filled with a fire extinguishing agent.

In order to achieve the above-mentioned object, the small space automatic fire extinguisher of the present invention includes a fire extinguishing container filled with fire extinguishing agent and gas; A first nozzle unit installed in the fire extinguishing container to form a first discharge path through which the fire extinguishing agent is discharged; an indicating pressure gauge installed in the first nozzle unit; and a second nozzle unit rotatably installed perpendicular to the first nozzle unit, wherein the second nozzle unit includes a rotating body forming a second discharge passage communicating with the first discharge passage, and the rotating body. It is coupled to and includes a spraying part that opens the second discharge passage by a glass bulb that is broken in the event of a fire and sprays the fire extinguishing agent into a small space, and the fire extinguishing agent is supplied to the first discharge passage and the second discharge passage. It is in an atmospheric state and can be placed in a small space so that at least the gas in the fire extinguishing container is directed upward.

In the small space automatic fire extinguisher of the present invention, the first nozzle portion includes a hollow male threaded portion fastened to the inlet of the fire extinguishing container, a spring mounted inside the hollow male threaded portion, and a lifting block placed on the top of the spring. , the indicating pressure gauge is installed, a hollow nut part fastened to the upper part of the hollow male thread part to prevent the upper part of the lifting block from being separated, fastened to the upper part of the hollow nut part, a first discharge hole, and formed on the outer peripheral surface of the above. It includes a cylinder part including a first discharge outer groove through which the first discharge hole communicates, and at the bottom of the cylinder part, a plurality of pins that press the upper surface of the lifting block are formed at predetermined intervals, and the first discharge passage is the hollow It may be connected in the following order: the inside of the male thread portion, the inner peripheral surface of the hollow nut portion and the outer peripheral surface of the lifting block, between the pins, the inside of the cylinder portion, the first discharge hole and the first discharge outer groove.

In the small space automatic fire extinguisher of the present invention, the lifting block has a polygonal shape,

A protrusion protruding downward may be formed at the center of the lower surface of the lifting block.

In the small space automatic fire extinguisher of the present invention, the rotating body includes a ring fitted on the outer peripheral surface of the cylinder portion, and a lever extending outward from one outer peripheral surface of the ring, and the second discharge passage includes the first It includes a second discharge inner groove formed on the inner peripheral surface of the ring facing the outer discharge groove, and a second discharge hole formed in the longitudinal direction of the lever to communicate with the second discharge inner groove, and the second discharge inner groove and the first discharge hole. 2. An upper O-ring and a lower O-ring may be installed on the upper and lower sides between the inner peripheral surface of the ring and the outer peripheral surface of the cylinder portion, bordering the discharge outer groove.

The small space automatic fire extinguisher of the present invention has the following effects.

Since the second nozzle unit rotates 360 degrees relative to the first nozzle unit, regardless of the installation direction of the fire extinguisher, you can always check the indicating pressure gauge attached to the fire extinguisher from the front by rotating the nozzle in the desired direction. That is, after arranging the automatic fire extinguisher with the indicating pressure gauge always facing toward the front, the second nozzle portion can be rotated so that the spray portion of the second nozzle portion faces toward the electric control box.

In addition, during the process of assembling the nozzle unit in the fire extinguishing container, you can simply fill the gas and prepare to spray the fire extinguishing agent. In other words, if the gas filling port is fastened to the hollow nut part, the lifting block is lowered to fill with gas, and the gas filling port is removed, the filling can be easily completed by blocking the gas filled with the rising of the lifting block.

In addition, because the lifting block is formed in a polygonal shape, it can form part of the first discharge path, which is a natural space between the hollow nut portion and the lifting block, and can be placed so that its edge no longer goes down.

In addition, by forming a protrusion protruding downward at the center of the lower surface of the lifting block, the gas filling port can act as a jig that pushes the lifting block along the center without tilting it to one side when gas is injected into the fire extinguishing container.

In addition, when the glass bulb is broken, the fire extinguishing agent contained inside is sprayed only with the pushing pressure of the gas, so a separate penetrating operation to pierce the seal plate is unnecessary, simplifying the structure.

Figure 1 is an external perspective view showing a small space automatic fire extinguisher according to an embodiment of the present invention.
Figures 2 and 3 are top and bottom perspective views showing the nozzle unit of the small space automatic fire extinguisher of Figure 1 separated.
4 to 6 are cross-sectional views showing the procedure for assembling a nozzle unit in a fire extinguishing container.
Figure 7 is a state diagram of the small space automatic fire extinguisher of Figure 1 installed on the external upper surface of the electric control box.
Figure 8 is a state diagram of the small space automatic fire extinguisher of Figure 1 installed on the inner upper surface of the electric control box.
Figure 9 is a diagram showing the small space automatic fire extinguisher of Figure 1 installed on the inner side of the electric control box.
Figure 10 is a cross-sectional view schematically showing a conventional automatic fire extinguisher.
Figure 11 is a state diagram of the conventional automatic fire extinguisher of Figure 10 installed.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, where parts identical to those of the prior art will be assigned the same reference numerals and detailed descriptions will be omitted.

Figure 1 is an external perspective view showing a small space automatic fire extinguisher according to an embodiment of the present invention, Figures 2 and 3 are top and bottom perspective views showing the nozzle unit of the small space automatic fire extinguisher of Figure 1 separated, and Figures 4 to 4 Figure 6 is a cross-sectional view showing the sequence of assembling the nozzle unit in the fire extinguishing container, and Figures 7, 8, and 9 are diagrams showing the small space automatic fire extinguisher of Figure 1 installed on the external upper surface, internal upper surface, and internal side of the electric control box. am.

Referring to Figures 1 to 3, the small space automatic fire extinguisher (1) according to this embodiment may include a fire extinguishing container (3) and a nozzle unit (10) fastened to the inlet of the fire extinguishing container (3). .

The fire extinguishing vessel (3) may be a metal container filled with fire extinguishing agent (5) and gas (7).

The fire extinguishing agent 5 may be in liquid, powder or foam form. The gas 7 is a substance that creates a pressure that releases the fire extinguishing agent 5 to the outside, and may include one of the gas of the fire extinguishing agent 5 or helium, neon, argon, or nitrogen gas.

This fire extinguishing container 3 can be installed in an electric control box so that the gas 7, the fire extinguishing agent 5, and the nozzle unit 10 are arranged up, middle, and bottom, as shown in FIGS. 7 to 9.

The nozzle unit 10 can spray the fire extinguishing agent 5 into a fire space (eg, an electric control box, etc.).

The nozzle unit 10 includes a first nozzle unit 20, a second nozzle unit 40 installed at a right angle to the first nozzle unit 20, and an indicating pressure gauge installed in the first nozzle unit 20 ( 60) may be included.

Referring to FIG. 4, the first nozzle unit 20 may include a first discharge passage through which the fire extinguishing agent 5 of the fire extinguishing container 1 is discharged.

The first nozzle part 20 may include a hollow male thread part 21. The hollow male screw portion 21 may include an upper hollow male screw 21a, a lower hollow male screw 21b, and a flange 21c connecting the upper hollow male screw 21a and the lower hollow male screw 21b.

The upper hollow male screw (21a) may be fastened to the inlet (4) of the fire extinguishing container (3). An O-ring 80 may be installed between the upper hollow male screw 21a and the inlet 4.

The outer peripheral surface of the flange 21c has a polygonal shape and can form a seat surface for tools such as a spanner. The upper surface of the flange 21c can also serve as a locking protrusion at the lower end of the inlet 4.

The first nozzle unit 20 may include a hollow nut unit 22. The hollow nut portion 22 may include an upper hollow female screw 22a, a lower hollow female screw 22b, and a hollow body 22c connecting the upper hollow female screw 22a and the lower hollow female screw 22b.

The upper hollow female screw 22a may be fastened to the lower hollow male screw 21b. An O-ring 81 may be installed between the upper hollow female screw 22a and the lower hollow male screw 21b.

The upper end of the upper hollow female screw 22a can be caught on the lower surface of the flange 21c.

The first nozzle unit 20 may include a spring 23, which will be described later. Referring to FIG. 4 , the spring 23 may be compressibly disposed inside the hollow male thread portion 21 . The upper side of the spring 23 can be caught on the sheet 23a formed inside the upper hollow male screw 21a. The sheet 23a may be composed of an upper sheet.

The first nozzle unit 20 may include a lifting block 24. The lifting block 24 may be disposed inside the hollow nut portion 22. The upper surface of the lifting block 24 may be composed of a lower sheet on which the lower side of the spring 23 is placed. As shown in FIG. 6, when the lifting block 24 moves up, the spring 23 can be compressed. The lower side of the lifting block 24 can be caught on the locking protrusion 24a formed inside the lower hollow female screw 22b.

In particular, as shown in FIG. 3, the lifting block 24 may be formed in a polygonal shape, for example, a square shape. The polygonal lifting block 24 can form a space s1 with the inner peripheral surface of the hollow nut portion 22 at the same time as its edge is caught on the locking protrusion 24a. The space s1 serves as a passage for one of the first discharge passages. In addition, an indicating pressure gauge 60 is installed in the hollow body 22c, so that the pressure of the fire extinguishing agent 5 can be immediately checked from the outside through this space s1.

An O-ring 83 is installed on the lifting block 24 to seal the space between it and the stopping protrusion 24a. The O-ring 83 is in full contact with the locking protrusion 24a and can seal by receiving most of the force.

A protrusion 24b protruding downward may be formed at the center of the lower surface of the lifting block 24. The protrusion 24b serves as a jig to align the center of the lifting block 24 when a gas filling port (not shown) for injecting and filling the fire extinguishing container 3 with the gas 7 is inserted, as shown in FIG. 4. That is, when the gas filling port (not shown) is inserted, the elevating block 24 is not tilted to one side but moves up to the center, and when the gas filling port (not shown) is separated after completion, the O-ring 83 is accurately caught. It can be seated on the chin (24a). If it is not properly seated after completion, the gas filling port (not shown) may be separated and leak.

Referring to FIGS. 2, 3, and 5, the first nozzle unit 20 may include a cylinder unit 25.

The cylinder portion 25 may include a cylinder 25a with an open upper surface. A male screw 25a' may be formed on the upper side of the cylinder 25a. The male screw 25a' may be fastened to the lower hollow female screw 22b. An O-ring 84 may be installed between the male screw 25a' and the lower hollow female screw 22b.

Referring to FIG. 2, the cylinder portion 25 may include a plurality of pins 25b. Each pin 25b may be formed at predetermined intervals along the upper circumference of the cylinder 25a. That is, a space s2 may be formed between the pins 25b and the pins 25b. The space s2 may serve as a passage connecting the space s1 and the interior of the cylinder 25a, as shown in FIG. 6 .

The plurality of pins 25b serve to push up the lower surface of the lifting block 24. That is, when the cylinder 25a is fastened to the lower hollow female screw 22b until the gap h is formed as shown in FIG. 5, the lifting block 24 does not rise. When tightened until the gap (h) is almost empty as shown in Figure 6, the pin (25b) pushes up the lifting block (24), opening the gap (c) between the O-ring (83) and the locking step (24a), creating a space ( s1) and space (s2) can communicate with each other.

The cylinder portion 25 may be formed with a first discharge hole 25c. The first discharge hole 25c may be formed by drilling a portion of the outer peripheral surface of the cylinder 25a. Accordingly, the first discharge hole 25c may form a part of the first discharge path that communicates the space s2 and the inside of the cylinder 25a.

The cylinder portion 25 may include a first external discharge groove 25d. The first outer discharge groove 25d may be formed on the outer peripheral surface of the cylinder 25a including the first discharge hole 25c. Therefore, even if the position of the first discharge hole 25c does not communicate with the second nozzle portion 40, it can communicate through the first outer discharge groove 25d. O-rings 85 and 86 may be installed on the outer peripheral surfaces of the upper and lower cylinders 25a centered on the first outer discharge groove 25d. O-rings 85 and 86 may be mounted in mounting grooves formed on the outer peripheral surface of the cylinder 25a. The O-rings 85 and 86 can seal between the first outer discharge groove 25d and the outer peripheral surface of the cylinder 25a.

The cylinder portion 25 may include a polygonal head portion 25e. The polygonal head portion 25e may be formed in the closed lower portion of the cylinder 25a. The polygonal head 25e may be configured as a tool seat surface. The cylinder 25a having such a polygonal head 25e may have a shape similar to a bolt having a polygonal head.

The first discharge path of the first nozzle part 20 as described above is a space between the inside of the hollow male thread part 21, the inner circumferential surface of the hollow nut part 22, and the outer circumferential surface of the lifting block 24, as shown in FIG. 6. (s1), the space s2 between the pins, the inside of the cylinder part 25, the first discharge hole 25c, and the first discharge external groove 25d may be connected in that order.

As shown in FIGS. 2, 3, and 5, the second nozzle unit 40 may include a second discharge passage communicating with the first discharge passage. Additionally, the second nozzle unit 40 can rotate while being installed perpendicular to the first nozzle unit 20.

The second nozzle unit 40 may include a rotating body 41. The rotating body 41 may be installed to be rotatable with respect to the cylinder 25a. That is, the rotating body 41 can rotate using the cylinder 25a as a rotating axis.

The rotating body 41 may include a ring 41a. The ring 41a can be inserted into the outer peripheral surface of the cylinder 25a and caught on the polygonal head 25e. The ring 41a can rotatably press the O-rings 85 and 86.

The rotating body 41 may include a lever 41b. The lever 41b may extend outward from one side of the outer peripheral surface of the ring 41a. That is, the lever 41b may extend at a right angle to the first nozzle 20.

The rotating body 41 may include a second discharge inner groove 41c. The second discharge inner groove 41c may be formed on the inner peripheral surface of the ring 41a. That is, the second inner discharge groove 41c may be formed at a position facing the first outer discharge groove 25d. Accordingly, the first outer discharge groove 25d and the second inner discharge groove 41c can form an empty space along the circumference.

The rotating body 41 may include a second discharge hole 41d as shown in FIG. 5 . The second discharge hole 41d may be formed along the longitudinal direction of the lever 41b. Both ends of the second discharge hole 41d may communicate with the second inner discharge groove 41c and the injection unit 50.

With the above configuration, the second discharge path may include a second discharge inner groove 41c and a second discharge hole 41d.

The second nozzle unit 40 may include an injection unit 50. The injection unit 50 serves as an injection operation unit. That is, the injection unit 50 may include an injection pipe 51 having an injection opening 52. The injection opening 52 may be formed along its perimeter with a number of slots.

One end of the injection pipe 52 may be fastened to the other end of the lever 41b. A male thread may be formed on one end of the injection pipe 52, and a female thread may be formed on the other end of the lever (41b). An O-ring 87 may be installed on one end of the outer peripheral surface of the injection pipe 52 and the other end of the inner peripheral surface of the lever 41b.

The injection unit 50 may include a movable holder 53. The movable holder 53 may be installed at one end of the injection pipe 51 behind the injection opening 52. An O-ring 88 may be installed on the outer peripheral surface of the movable holder 53. The O-ring 88 may be mounted in a mounting groove formed on the outer peripheral surface of the movable holder 53. The O-ring 88 can be compressed to enable the movable holder 53 to slide while sealing between the inner peripheral surface of the injection pipe 51 and the movable holder 53.

The injection unit 50 may include a spring 54. The spring 54 may be installed between the movable holder 53 and the other end of the lever 41b. Therefore, the spring 54 can apply an elastic force to the other end of the lever 41b to push the movable holder 53 forward.

The spray unit 50 may include a fixed holder 55. The fixing holder 55 may be fastened to the other end of the injection pipe 51 in front of the injection opening 52.

The spray unit 50 may include a glass bulb 56. Both ends of the glass bulb 56 may be installed between the movable holder 53 and the fixed holder 55. When the glass bulb 56 is broken during a fire, the compressed spring 54 pushes the movable holder 53 forward so that the fire extinguishing agent 5 can be sprayed into the spray opening 52 through the second discharge hole 41d. there is.

In the small space automatic fire extinguisher (1) of this embodiment, since the second nozzle unit (40) is rotatable with respect to the first nozzle unit (20), it can be tilted in any direction to the left or right by tilting the electric control box as shown in FIGS. 7 to 9. Even when installed, the indicating pressure gauge 60 can always face the front.

The assembly sequence of the small space automatic fire extinguisher 1 of this embodiment as described above will be described with reference to FIGS. 4 to 6.

First, the first assembly part in which the hollow male screw part 21, the spring 23, the lifting block 24, and the hollow female screw part 22 are fastened and assembled, the cylinder part 25, and the second nozzle part 40 are assembled. Prepare the assembled second assembly part.

As shown in FIG. 4, the first assembly is assembled by fastening the hollow male threaded portion 21 to the inlet 4 of the fire extinguishing container 3 filled with the fire extinguishing agent 5. Of course, the hollow male threaded portion 21, spring 23, lifting block 24, and hollow female threaded portion 22 may be assembled in that order.

When the first assembly part is assembled to the inlet 4, the gas filling port (not shown) is inserted into the lower hollow female screw 22b, and the protrusion 24b of the lifting block 24 is inserted and the lifting block is centered. (24) is pushed up, and the gas (7) can be filled into the interior of the fire extinguishing vessel (3) through the gap (c) and space (s1) as shown in Figure 6. When the filling of the gas 7 is completed, if the gas filling port (not shown) is separated, the lifting block 24 can close the gap c with the restoring force of the spring 23.

Then, as shown in FIG. 4, the first discharge path of the first assembly part is filled with the fire extinguishing agent (5) pushed by the gas (7).

In this state of FIG. 4, the second assembly part is fastened and assembled to the first assembly part.

That is, when the cylinder 25a of the second assembly is screwed to the hollow female screw portion 22, the pin 25b of the cylinder 25a is connected to the lifting block 24 until it is formed at the gap c as shown in Figure 5. Do not push up.

As the cylinder 25a continues to be assembled, the gap c gradually decreases and the pin 25b pushes up the lifting block 24, causing the gap c to widen. Then, as shown in FIG. 6, the fire extinguishing agent 5 passes through the gap c into the space s2, the inside of the cylinder 25a, the first discharge hole 25c, and the first and second discharge external and internal grooves 25d (41c). ), and the second discharge hole (41d) is filled in that order.

After installing the small space automatic fire extinguisher (1) as shown in Figures 7 to 9 in the state shown in Figure 6, when a fire occurs, the glass bulb (56) is broken and the movable holder (53) moves forward to open the spray opening (52). The fire extinguishing agent (5) is sprayed through.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, it is added that such changes are within the scope of the claims.

1: Small space automatic fire extinguisher 3: Fire extinguishing container
5: Extinguishing agent 7: Gas
10: nozzle unit 20: first nozzle unit
21: hollow male thread portion 22: hollow nut portion
23: Spring for lifting block 24: Elevating block
25: cylinder part 25a: cylinder
25b: Pin 25c: First discharge hole
40: Second nozzle part 41: Rotating body
50: injection unit 53: movable holder
54: Spring for movable holder 55: Fixed holder
56: Glass bulb 60: Indicating pressure gauge

Claims (4)

Fire extinguishing vessel filled with extinguishing agent and gas;
A first nozzle unit installed in the fire extinguishing container to form a first discharge path through which the fire extinguishing agent is discharged;
an indicating pressure gauge installed in the first nozzle unit; and
A second nozzle unit rotatably installed perpendicular to the first nozzle unit,
The second nozzle part,
a rotating body formed with a second discharge passage communicating with the first discharge passage;
It is coupled to the rotating body and includes a spraying unit that opens the second discharge path by a glass bulb that is broken in the event of a fire and sprays the fire extinguishing agent into a small space,
The fire extinguishing agent is in a standby state filled up to the first discharge passage and the second discharge passage,
At least disposed in a small space so that the gas of the fire extinguishing vessel is directed upward,
Small space automatic fire extinguisher.
In claim 1,
The first nozzle part,
A hollow male thread part fastened to the inlet of the fire extinguishing container,
A spring mounted inside the hollow male thread portion,
A lifting block placed on top of the spring,
A hollow nut part on which the indicating pressure gauge is installed and fastened to the upper part of the hollow male thread part to prevent the upper part of the lifting block from being separated;
It is fastened to the upper part of the hollow nut portion and includes a cylinder portion including a first discharge hole and a first discharge outer groove formed on the outer peripheral surface and communicating with the first discharge hole,
At the bottom of the cylinder unit, a plurality of pins are formed at predetermined intervals to press the upper surface of the lifting block,
As for the first discharge,
Connected in that order between the inside of the hollow male screw portion, the inner peripheral surface of the hollow nut portion and the outer peripheral surface of the lifting block, between the pins, the inside of the cylinder portion, the first discharge hole and the first discharge outer groove,
Small space automatic fire extinguisher.
In claim 2,
The lifting block has a polygonal shape,
At the center of the lower surface of the lifting block, a protrusion protruding downward is formed,
Small space automatic fire extinguisher.
In claim 2 or claim 3,
The rotating body is,
A ring fitted to the outer peripheral surface of the cylinder portion,
It includes a lever extending outward from one outer peripheral surface of the ring,
As for the second discharge,
a second inner discharge groove formed on the inner peripheral surface of the ring to face the first outer groove,
It includes a second discharge hole formed in the longitudinal direction of the lever to communicate with the second discharge inner groove,
An upper O-ring and a lower O-ring are installed on the upper and lower sides between the inner peripheral surface of the ring and the outer peripheral surface of the cylinder portion, bordering the second inner discharge groove and the second outer groove.
Small space automatic fire extinguisher.

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