KR20200090534A - Rotary type fire extinguishser - Google Patents

Abstract

The present invention relates to a rotary fire extinguisher device wherein at least 3 parts of a side of a fire extinguisher container are ruptured along a groove pattern to be opened in the form of wings when a fire extinguisher explodes, and the fire extinguisher container rotates by force that an extinguishing agent is sprayed through the groove pattern portion of the side of the opened fire extinguisher. Therefore, the extinguishing agent is evenly sprayed in a sufficient range while preventing secondary damage caused by the fire extinguisher container that is torn and scattered in a disorderly shape when a fire occurs.

Description

Rotary fire extinguisher device {ROTARY TYPE FIRE EXTINGUISHSER}

The present invention relates to a rotary fire extinguisher device, and more specifically, the pressure to extinguish the fire by discharging the extinguishing agent filled in the fire extinguisher container while the explosive means located inside the fire extinguisher container explodes by electric or thermal signals In a fire extinguisher device using a, a fire extinguisher container filled with extinguishing agent in an explosion is configured to open and rotate at the same time as designed, so that the extinguishing agent in the extinguisher container can be discharged evenly with a sufficient radius. It is about.

Explosive fire extinguishers are mainly used in places where damage may increase if the fire is not extinguished quickly, or when the fixed type is installed, the fire extinguishing means inside the fire extinguishers explode and extinguish the fire extinguishing agent. Fire is extinguished by spraying.

When the fire extinguisher explodes in the event of a fire, the fire extinguisher container is torn into several pieces and scattered around with the fire extinguishing agent. At this time, the fire extinguisher container is torn into pieces having various irregular shapes, and scattered under strong pressure with explosion. Because there is a problem of secondary damage caused by the fragments of the fire extinguisher container.

In addition, there is a problem that the internal fire extinguishing agent is not uniformly sprayed due to irregular rupture of the fire extinguisher container, and accordingly, the range in which the fire extinguishing agent is sprayed is also uneven.

In accordance with this situation, the present invention is to prevent the occurrence of secondary damage caused by the fire extinguisher container torn and scattered in a disordered shape in the case of an explosive fire extinguisher as described above, and at the same time a new extinguishing agent can be sprayed evenly to a sufficient extent. I would like to present a technique for fire extinguisher devices.

Next, the prior art existing in the field to which the technology of the present invention pertains will be briefly described, and then the technical matters to be differentiated from the prior art will be described.

First, Patent Publication No. 10-2017-0065067 (December 13, 2017) discloses a thermal expansion explosive fire extinguisher that automatically extinguishes and extinguishes by thermal expansion when a certain temperature is reached due to a fire in the event of a fire. More specifically, a technology related to a fire extinguisher is described in which a pressure gas and an extinguishing agent are accommodated in a cylinder, and when the fire occurs, the pressure gas explodes by thermal expansion and blows out the extinguishing agent. Patent Publication No. 10-2014-0023922 (published on Feb. 27, 2014) relates to a fire extinguishing container having a closed filling opening for a liquid extinguishing agent, and more specifically, extinguishing a closed filling opening for a liquid extinguishing agent It is a container, characterized by deformability in an unfilled storage state and dimensional stability in an operating state in which the extinguishing agent is filled in the extinguishing container, the deformability being not only by the compartment for accommodating the explosive but also by the degree of filling being increased Decreasing, the compartment is described at least in an operating condition and a description of a fire extinguishing container comprising an opening that is closed inside or outside the fire extinguishing container.

The prior art publications Patent Publication No. 10-2017-0065067 and Patent Publication No. 10-2014-0023922 relates to a fire extinguisher that releases an extinguishing agent while explosives in the fire extinguisher container filled with extinguishing agent when a fire occurs In terms of technology, there are similarities in the present invention and the technical field, but the secondary damage caused by the fragments of the extinguisher container occurs because it does not include the technology to prevent the fire extinguisher container from being burst and scattered by the explosion as in the present invention. There was.

In addition, Korean Patent Publication No. 10-2007-0101677 (2007.10.17. Publication date) relates to a fire extinguishing bomb for fire extinguishing, and more specifically, to uniformly break the body well in the event of a surface explosion. Description of the technology for extinguishing grenade forming a large number of incision grooves is described, and Korean Patent Publication No. 10-1995-0002802 (published on February 16, 1995) uses the explosive power of gunpowder to rapidly extinguish the fire extinguishing agent in a wide area. Dispersing fire extinguishers, and more specifically, by loading a dispersing container with a gunpowder inside and exploding the gunpowder by the fuse, primer, etc. of the igniter to obtain a high-pressure expansion force, bursting the digestive container along the rupture groove with this force A description of a fire extinguisher that allows scattering of extinguishing agents at a time is described.

The Korean Patent Publication No. 10-2007-0101677 and Korean Patent Publication No. 10-1995-0002802 disclose that a bursting groove is formed in the fire extinguisher container so that the fire extinguisher container is broken into a pre-designed shape in the event of an explosion. Although there are some similarities to the present invention in that it is related to the present invention, the prior art documents merely allow the extinguishing agent inside the fire extinguisher container to be sprayed more effectively while the fire extinguisher container is ruptured along the rupture groove. It did not include the technology to prevent the occurrence of secondary damage and the technology to select the fire extinguishing agent by rotating the fire extinguisher in case of an explosion and spray it in a wide range.

The present invention was created to solve the above problems, in the fire extinguisher device, in order to prevent secondary damage caused by the fire extinguisher container generated when the fire extinguisher container bursts into an irregular shape when exploded, the fire extinguisher container An object of the present invention is to provide a rotary fire extinguisher device that forms a groove pattern on an outer surface to cause a container to rupture along the shape of the groove pattern in the event of an explosion, but to prevent fragments of the broken container from scattering around.

In addition, according to the present invention, when the fire extinguisher explodes, the fire extinguisher container is rotated by the energy of the fire extinguishing agent ejected to the portion of the bursting container, so that the fire extinguishing agent can be sprayed evenly over a wide range in the rotating fire extinguisher container. The purpose is to provide.

The rotary fire extinguisher device according to an embodiment of the present invention has a cylindrical shape, an inner space filled with a fire extinguishing agent is formed, and a fire extinguisher container having a cylindrical protrusion having an open top surface is formed in the center of the upper surface. ; An explosive part which is introduced into the fire extinguisher container through the cylindrical protrusion, and is located at the center of the internal space of the fire extinguisher container; A fire extinguisher head part connected to the explosive part in a downward direction and coupled to a cylindrical protrusion formed in the center of the upper surface of the fire extinguisher container; And an explosion signal line connected to the explosion unit from the outside of the fire extinguisher container through the fire extinguisher head unit to transmit an electrical signal or a thermal signal to explode the explosion unit. Groove pattern is formed to induce at least three or more parts of the side of the container to rupture in an open direction, and the cylindrical protrusion of the fire extinguisher container has a structure that rotates while being coupled to the fire extinguisher head. By providing a bearing between the cylindrical protrusion and the head of the fire extinguisher, at least three or more parts of the side surface of the fire extinguisher container are ruptured and opened along the groove pattern when the explosion part is exploded, thereby extinguishing the fire extinguisher container by the force of spraying the fire extinguishing agent. It is characterized in that the fire extinguishing agent is sprayed while rotating.

In addition, as an embodiment, the fire extinguisher container is composed of a metal, synthetic resin, or a combination thereof, and is characterized in that it comprises a net-like interior material in the extinguisher container part except for the portion where the groove pattern is formed.

In addition, as an embodiment, the explosion signal line is composed of a temperature-sensitive signal line, the temperature-sensitive signal line is composed of a nitrocellulose (nitrocellulose), characterized in that the protective sleeve is coated on the outside.

In addition, in one embodiment, the explosion signal line, oxidizing solid, nitrate, chlorate, perchlorate, inorganic peroxide, passing through a standard body of 53 micrometers Fe, less than 50% by weight, and a standard body of 150 micrometers Characterized in that it is configured to further include at least one of Al less than 50% by weight.

In addition, in one embodiment, the explosion unit is characterized in that it explodes instantaneously by an explosive material, expands momentarily by compressed gas, or releases a gas by a chemical reaction.

In addition, as an embodiment, the fire extinguisher container is characterized in that at least three groove patterns are formed at equal intervals on the side surface of the fire extinguisher container.

In addition, as an embodiment, the groove pattern is characterized in that a part of a line in the vertical direction among polygons, circles, ellipses, or a combination of them is formed in a shape in which the lines are omitted.

In addition, as an embodiment, the lower surface of the fire extinguisher container has a groove pattern in the form of a shape in which a line in the vertical direction is omitted among polygons, circles, ellipses, or a combination thereof, in the center of the lower surface of the fire extinguisher container. Characterized in that at least three are formed at the same interval along the circumference of the circle centering on.

In addition, as an embodiment, the explosive portion, chlorate, perchlorate, potassium nitrate, excipient, 53 micrometers of Fe passing through a standard body of less than 50% by weight and 150 micrometers of Al passing through a sieve of less than 50% by weight It includes a mixture selectively mixed at least one or more of.

Rotating fire extinguisher device according to the present invention is to form a groove pattern on the outer surface of the fire extinguisher container, when the fire extinguisher explodes, the fire extinguisher container ruptures a regular shape along the groove pattern, and the internal extinguishing agent is sprayed evenly to improve the fire extinguishing effect At the same time, since the fire extinguisher container that is ruptured is fixed to the fire extinguisher and is not sprayed to the surroundings, there is an effect of preventing the occurrence of secondary damage to the surroundings by the fire extinguisher container pieces.

In addition, the rotary fire extinguisher device according to the present invention is configured to rotate while the fire extinguisher container is ruptured in a regular shape along the groove pattern when the fire extinguisher explodes, thereby extinguishing the fire extinguishing agent more effectively, thereby maximizing the extinguishing effect. have.

1 is a cross-sectional view showing the structure of a rotary fire extinguisher device according to an embodiment of the present invention.
2 is a cross-sectional view showing a structure of a fire extinguisher head of a fire extinguisher device during a rotary explosion according to an embodiment of the present invention.
3 to 6 are views showing a groove pattern of a rotary explosive fire extinguisher container according to an embodiment of the present invention.
7 is a plan view showing a state of an exploded rotary fire extinguisher device according to an embodiment of the present invention.
Figure 8 is a bottom view showing the appearance of the rotary fire extinguisher device according to an embodiment of the present invention during an explosion.
9 is an exploded view of a fire extinguisher container for explaining an interior material of a rotary fire extinguisher device according to an embodiment of the present invention.

In each drawing of the present invention, the size or dimensions of the structures are enlarged or reduced than actual ones for clarity of the present invention, and well-known components are omitted and shown to reveal characteristic features, and thus are not limited to the drawings. .

In the detailed description of the principles of the preferred embodiment of the present invention, when it is determined that detailed descriptions of related well-known functions or configurations may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted.

In addition, the embodiments shown in the embodiments and drawings described in this specification are only the most preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, and can replace them at the time of this application. It should be understood that there may be equivalents and variations.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by a person skilled in the art to which the present invention pertains.

Throughout this specification, when a part “includes” a certain component, it means that the component may further include other components, not to exclude other components, unless otherwise stated.

The present invention relates to an ejection-type fire extinguisher device using pressure to extinguish a fire by discharging an extinguishing agent filled in the extinguisher container while an explosion means located in the center of the extinguisher container explodes by electric or thermal signals. When the fire extinguisher container rotates during the explosion, the fire extinguishing agent is ejected, so that the fire extinguishing agent is sprayed in a sufficient range, and the fragments of the fire extinguisher container are not scattered around, thereby preventing damage caused by the fire extinguisher container debris. It relates to a rotating fire extinguisher device.

To this end, the fire extinguisher device according to the present invention forms a groove pattern that serves as a burst guide so that a part of the side surface of the fire extinguisher container can be opened outward in the case of an explosion, thereby exposing the fire extinguisher container along the shape of the groove pattern during an explosion. At the same time, while inducing the opening of the fire extinguisher container, the parts of the fire extinguisher container that are not formed with the groove pattern and the pieces of the fire extinguisher container that are not formed in the groove are connected to each other to prevent the fire extinguisher container pieces from scattering around. Can.

Hereinafter, a rotary fire extinguisher device will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily implement the present invention.

1 is a cross-sectional view showing the structure of a rotary fire extinguisher device 100 according to an embodiment of the present invention.

As shown in Figure 1, the rotary fire extinguisher device 100 according to the present invention, largely including the fire extinguisher container 110, the explosion unit 120, the fire extinguisher head unit 130 and the explosion signal line 140 It is composed.

The fire extinguisher container 110 is filled with an extinguishing agent 10 in an interior space, and an upper surface is opened so that the explosion unit 120 is introduced into the center of the upper surface and the fire extinguisher head unit 130 is coupled. It has a structure in which a cylindrical projection 111 is formed.

In addition, the fire extinguisher container 110 is configured such that the upper and lower surfaces have an obtuse corner where the corners meet the side surfaces, thereby preventing the explosion of the corners by exploding pressure evenly over the corners.

In addition, the fire extinguisher container 110 is a groove pattern (groove pattern) that induces a fragment of the fire extinguisher container 110, which is ruptured when the explosion unit 120 is exploded, to rupture in a shape connected to the cylindrical protrusion 111 ( 112) is formed in an area except for the cylindrical protrusion 111, so that the fire extinguisher container 110 bursts along the groove pattern 112 when the explosion unit 120 explodes, and the extinguishing agent 10 is sprayed to the surroundings. The ruptured fire extinguisher container 110 piece remains intact with the cylindrical protrusion 111.

The groove pattern 112 is such that the fire extinguisher container 110 has a weaker strength than a fire extinguisher container portion in which a groove pattern is not formed so that the fire extinguisher container 110 ruptures only along the groove pattern 112 upon explosion of the explosion unit 120. Includes all structures. Preferably, the groove pattern 112 may be formed in a linear groove, a braille groove, or a combination of these on the inner and/or outer surfaces of the fire extinguisher container.

In addition, the material of the fire extinguisher container 110 is made of a metal, synthetic resin, or a combination of these. The synthetic resin is composed of polypropylene, polyethylene, or a combination thereof.

The explosion unit 120 is connected to the fire extinguisher head portion 130 is drawn into the fire extinguisher container 110 from the cylindrical projection 111 formed in the center of the upper surface of the fire extinguisher container 110, the fire extinguisher It has a structure located in the inner center of the container 110.

The explosion unit 120 serves to release the extinguishing agent 10 to the surroundings by exploding the fire extinguisher container 110 while explosively expanding by a signal received from the explosion signal line 140.

At this time,'explosion' by the signal transmitted from the explosion signal line 140 by the explosion signal line 140 is an instantaneous explosion by an explosive material, an instantaneous expansion by compressed gas, or a chemical reaction for several seconds. Includes all forms of gas evolution.

For example, chlorate, perchlorate, potassium nitrate, excipient, Fe (less than 50% by weight passing through a standard body of 53 micrometers) and Al (50% by weight through a body of 150 micrometers) in the explosive part The mixture may be filled by selectively mixing at least one of the following).

The fire extinguisher head 130 has a structure in which the explosion part 120 is connected in a downward direction, and is coupled to a cylindrical protrusion 111 formed in the center of the upper surface of the fire extinguisher container 110.

In addition, the fire extinguisher head portion 130 maintains a combined state with the cylindrical protrusion 111 even after the explosion of the explosion portion 120, and the fire extinguisher head portion 130 is in response to the force that the fire extinguishing agent is sprayed upon explosion. It is configured to rotate while being coupled to the explosive part. This will be described in more detail with reference to FIG. 2 below.

The explosion signal line 140 is connected to the explosion unit 120 through the fire extinguisher head unit 130 from the outside of the fire extinguisher container 110 to transmit an electrical signal or a thermal signal to explode the explosion unit 120. .

That is, the explosion signal line 140 is composed of a wire that transmits an electrical explosion control signal from the outside to the explosion unit 120, or when exposed to a fire, the explosion unit 120 is burned toward the explosion unit 120 It may be composed of a temperature-sensitive signal line for transmitting a thermal signal to the (120).

When the explosion signal line 140 is composed of a temperature-sensitive signal line as described above, the temperature-sensitive signal line is configured to include a component of a conductor such as a nitrocellulose. Preferably, the nitrogen (N) content is 12.2% or less.

In addition, the component of the lead wire of the explosion signal line 140, in addition to the excipients, is an oxidizing solid, nitrate, chlorate, perchlorate, inorganic peroxide, Fe having less than 50% by weight passing through a standard body of 53 micrometers, and 150 micrometers It may be composed of a mixture of one or more components of Al less than 50% by weight passing through the standard body of.

In addition, the explosion signal line 140 has a structure in which a protective sleeve is coated, thereby protecting the component of the conduction wire inside the protection sleeve from external moisture, and the component of the conduction wire is not oxidized at low temperatures (eg, 170° C. or less). The temperature sensitivity of the fire extinguisher device.

More specifically, the explosion signal line may have a structure in which the conducting wire component is coated on a wire, and the protective sleeve is coated thereon, or may have a structure in which the conducting wire component is filled in the protective sleeve. have.

2 is a cross-sectional view showing a structure of a fire extinguisher head of a fire extinguisher device during a rotary explosion according to an embodiment of the present invention, and FIGS. 3 to 6 are grooves of a rotary explosive fire extinguisher container according to an embodiment of the present invention It is a diagram showing a pattern.

2 to 6, the rotary fire extinguisher device 100 according to the present invention is a part of the fire extinguisher container 110 along the groove pattern 112 formed in the fire extinguisher container 110 during an explosion By opening the outside, the fire extinguisher container 110 is configured to rotate while being connected to the fire extinguisher head portion 130, so that the fire extinguishing agent 10 in the fire extinguisher container 110 can be more effectively sprayed to the periphery.

2, the rotary fire extinguisher device 100 according to the present invention, the fire extinguisher container (110) in order to have a structure in which the fire extinguisher container 110 is coupled to the fire extinguisher head portion 130 to rotate. It has a structure in which a plurality of bearings 131 are provided between the cylindrical protrusion 111 located on the upper surface of 110 and the fire extinguisher head 130.

The bearing 131 may be configured to be provided on the inner surface of the fire extinguisher head portion 130, or may be configured to be provided on the outer surface of the cylindrical protrusion 111, or the rotary fire extinguisher device 100 of the present invention In the process of combining the fire extinguisher head portion 130 and the cylindrical protrusion 111 during the manufacturing process of, it may be configured to be assembled between the cylindrical protrusion 111 and the fire extinguisher head portion 130.

In addition, FIG. 2 shows the bearing of the ball bearing method briefly, but the bearing 131 of the present invention is not limited thereto, and may include both a ball bearing method and a roller bearing method.

In addition, as shown in Figures 3 to 6, the rotary fire extinguisher device 100 is configured to rotate the fire extinguisher container 110 in accordance with the present invention, the fire extinguisher container 110 at the same time to obtain the rotational force in case of explosion In order to prevent all of the internal fire extinguishing agent 10 from being discharged even before being rotated, at least three or more of the side surfaces of the fire extinguisher container 110 have the same spacing and have a structure that opens in the outward direction of the fire extinguisher container 110.

As described above, when the explosion unit 120 explodes, the fire extinguisher container 110 is ruptured along the groove pattern 112 while being pressured from the inside outward, and the fragment of the fire extinguisher container 110 that is ruptured is not scattered. The groove pattern 112 is opened while extending in the direction of the cylindrical protrusion 111 that is not formed.

At this time, the groove pattern 112 has a structure in which at least three or more are formed at the same interval, so that the extinguishing agent 10 can be sprayed relatively evenly in the 360-degree direction without reducing the rotational force.

In addition, the groove pattern 112 formed on the side surface of the fire extinguisher container 110 is formed in a shape of a polygon, a circle, an ellipse, or a combination of these shapes in which a part of the line in the vertical direction is omitted.

For reference, FIG. 3 shows a fire extinguisher container 110 in which a groove pattern 112 having a “C” shape, a “<” shape in FIG. 4, and a “C” shape in FIG. 5 are formed.

In addition, as shown in Figure 6, the rotary fire extinguisher device of the present invention, by forming a groove pattern on the lower surface 110-2 of the fire extinguisher container, a blind spot where the fire extinguishing agent is not sprayed on the lower portion of the fire extinguisher container Can be prevented from occurring.

At this time, in order not to reduce the rotation of the fire extinguisher container, the lower surface of the fire extinguisher container has a groove pattern in the form of a figure in which a line in the vertical direction is omitted among polygons, circles, ellipses, or a combination thereof. It has a structure in which at least three are formed at equal intervals along the circumference of a circle centering on the center of the lower surface of the fire extinguisher container.

7 is a plan view showing the appearance of the rotary fire extinguisher device according to an embodiment of the present invention when exploded, and FIG. 8 is a bottom view showing the state of the rotary fire extinguisher device according to an embodiment of the present invention during an explosion. .

As shown in Figure 7, the rotary fire extinguisher device 100 according to the present invention when the side surface of the fire extinguisher container 110 is ruptured in the shape of a wing along the groove pattern 112, the fire extinguishing agent 10 is The fire extinguisher container 110 is coupled to the fire extinguisher head portion 130 by the injected force and rotates by the bearing 131 to allow the fire extinguishing agent 10 to be sprayed in a wider range.

In addition, as shown in FIG. 8, when the explosion, the lower surface 110-2 of the fire extinguisher container is also opened in the shape of a groove pattern 112, so that the fire extinguishing agent 10 is also sprayed in the downward direction of the fire extinguisher device.

Due to these structural features, the fire extinguisher container 110 of the rotary fire extinguisher device 100 of the present invention is prevented from being scattered around the fire extinguisher container fragments even during an explosion, and the extinguishing agent 10 inside the extinguisher container 110 Can be sprayed evenly in the peripheral direction.

On the other hand, the rotary fire extinguisher device 100 according to the present invention is a fire extinguisher to prevent the area other than the groove pattern 112 of the fire extinguisher container 110 from bursting or falling off due to the explosive force of the explosion unit 120 It may be configured to include the interior material in the container 110.

9 is an exploded view of the fire extinguisher container 110 for explaining the interior material of the rotary fire extinguisher device 100 according to an embodiment of the present invention.

The rotary fire extinguisher device 100 according to the present invention, as shown in Figure 9, except for the portion where the groove pattern 112 is formed, the fire extinguisher container 110 portion to be configured to include a net-like interior material 113 Can.

In addition, the net-shaped interior material 113 may be located inside the wall surface of the fire extinguisher container 110, or may be a structure coupled to the outer or inner surface of the fire extinguisher container 110.

As described above, the rotary type fire extinguisher device 100 according to the present invention includes an interior material in a portion of the fire extinguisher container 110 other than the groove pattern 112, so that the explosion impact of the explosion unit 120 is also different from the groove pattern 112. The portion of the fire extinguisher container 110 can be further prevented from bursting.

As described above, the rotary fire extinguisher device according to the present invention can rotate a fire extinguisher container while exploding by an external electrical signal or a thermal signal when a fire occurs, so that the extinguishing agent filled in the fire extinguisher container can be widely sprayed to the periphery. In addition, since the fire extinguisher container does not scatter into pieces in the event of an explosion, it is damaged in a sharp irregular shape during the explosion of the existing fire extinguisher device, causing human and physical secondary damage by the fire extinguisher container. Can solve it.

The present invention has been described above with reference to the embodiments shown in the accompanying drawings, but these are only exemplary, and those skilled in the art to which various modifications and equivalent other embodiments are possible. Will understand. Therefore, the technical protection scope of the present invention should be defined by the following claims.

10: digestive agent
100: rotary fire extinguisher device
110: fire extinguisher container
110-1: Fire extinguisher container top surface
110-2: Fire extinguisher container bottom surface
111: cylindrical protrusion
112: groove pattern
113: net type interior material
120: explosion
130: fire extinguisher head
131: bearing
140: explosion signal line

Claims (9)

A fire extinguisher container having a cylindrical shape, an inner space filled with an extinguishing agent, and a cylindrical protrusion having an upper surface open at the center of the upper surface;
An explosive part which is introduced into the fire extinguisher container through the cylindrical protrusion, and is located at the center of the internal space of the fire extinguisher container;
A fire extinguisher head portion connected to the explosive portion in a downward direction and coupled to a cylindrical protrusion formed in the center of the upper surface of the fire extinguisher container; And
In the fire extinguisher device comprising; from the outside of the fire extinguisher container is connected to the explosion unit through the fire extinguisher head portion to transmit an electrical signal or a thermal signal to explode the explosion unit;
A groove pattern is formed on the side surface of the fire extinguisher container to induce at least three or more parts of the side surface of the fire extinguisher container to rupture in an open direction when the explosion part explodes,
A bearing is provided between the cylindrical protrusion of the fire extinguisher container and the fire extinguisher head so that the cylindrical protrusion of the fire extinguisher container rotates while being coupled to the fire extinguisher head part, so that at least 3 of the side surface of the fire extinguisher container when the explosion part is exploded A rotary fire extinguisher device characterized in that the fire extinguisher container is rotated by the force of spraying the fire extinguishing agent, while a portion of the place or more is ruptured and opened along the groove pattern. According to claim 1,
The fire extinguisher container is composed of a metal, synthetic resin, or a combination of these materials, and a rotary fire extinguisher device characterized in that it comprises a net-type interior material in the extinguisher container part except for the portion where the groove pattern is formed. According to claim 1,
The explosion signal line,
A rotary fire extinguisher device comprising a temperature-sensitive signal line, the temperature-sensitive signal line comprising a nitrocellulose, and a protective sleeve coated on the outside. According to claim 3,
The explosion signal line,
Oxidizing solids, nitrates, chlorates, perchlorates, inorganic peroxides, additionally at least one of less than 50 weight percent Fe passing through a 53 micrometer standard, and Al less than 50 weight percent passing a 150 micrometer standard Rotating fire extinguisher device, characterized in that consisting of. According to claim 1,
The explosion unit,
A rotary fire extinguisher device characterized in that it is instantaneously exploded by an explosive substance, momentarily expanded by compressed gas, or released by a chemical reaction. According to claim 1,
The fire extinguisher container,
A rotary fire extinguisher device, characterized in that at least three groove patterns are formed at equal intervals on a side surface of the fire extinguisher container. According to claim 1,
The groove pattern,
Rotating fire extinguisher device, characterized in that a part of the line in the vertical direction among the polygons, circles, ellipses, or a combination of them is formed in the shape of an omitted figure. According to claim 1,
The lower surface of the fire extinguisher container,
At least three groove patterns having a polygonal, circular, elliptical shape, or a combination of these shapes in which a portion of a line in the vertical direction is omitted are equally spaced along the circumference of a circle centered on the center of the lower surface of the extinguisher container. A rotary fire extinguisher device characterized in that it is formed above. According to claim 1,
The explosion unit,
Optionally mix at least one of chlorate, perchlorate, potassium nitrate, nitrocellulose, Fe less than 50% by weight through 53 micrometers and Al less than 50% by weight through 150 micrometers A rotary fire extinguisher device comprising a mixture.

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