KR100962254B1 - A self-acting extinguisher - Google Patents

Abstract

The present invention relates to a fire extinguishing device that is automatically operated according to an increase in ambient temperature in the event of a fire, and to providing an automatic fire extinguishing device which allows injection of a extinguishing agent through a change in physical properties and mechanical linkage without heat control and an operation structure. There is a purpose.

The automatic fire extinguishing device of the present invention for achieving the above object, the press body is installed to be movable inside and the main body is formed on both sides of the press body drug chamber and pressure chamber, respectively; An inflator installed in the pressure chamber to rapidly increase the gas pressure in the pressure chamber through a chemical reaction or a physical change so that the extinguishing agent in the pharmaceutical chamber can be discharged to the outside; A trigger mechanism for operating the inflator; A nozzle for injecting the extinguishing agent pushed from the medicine chamber to the outside; And a thermosensitive operation module for controlling the operation of the trigger mechanism and the opening and closing of the pipeline between the chemical chamber and the nozzle.

Fire extinguishing system, inflator, triggering device, nozzle, thermal response module,

Description

Automatic Fire Extinguisher {A SELF-ACTING EXTINGUISHER}

The present invention relates to a fire extinguishing device that operates automatically in response to a rise in ambient temperature in the event of a fire, and more particularly, excludes electronic sensors and controllers that may be damaged or malfunction due to heat and operate the inflator through mechanical thermal response. The present invention relates to an automatic fire extinguishing device which controls the opening and closing of a fire extinguishing discharge pipe to improve the operation reliability required as a fire fighting article.

In general, it is desirable and required for buildings to have a fire extinguisher or the like in preparation for a fire. However, in the case of a general fire extinguisher, not only the user has to purchase a fire extinguisher separately, but also a user must operate the fire extinguisher to extinguish the extinguishing agent so that the user must take a risk in case of a fire and the fire extinguisher is difficult to access. Occurs, there is a problem that becomes useless when there is no one to operate.

Accordingly, an automatic fire extinguishing device for automatically extinguishing a fire extinguishing agent has been proposed. However, in the conventional automatic fire extinguishing device, an electrical temperature sensor is used to detect a fire and an operation unit and a controller for spraying an extinguishing agent are also electrically. Because it was operated structure, power supply means for this is indispensable in terms of manufacturing cost and maintenance, and in case of fire, electrical components and wiring may be damaged by high heat or flame, resulting in improper function, resulting in poor operation reliability. There is a problem.

On the other hand, the automatic fire extinguishing device can be arranged at any location in the room, but in this case occupies a space to inconvenient the human activity, it is often an obstacle to the surrounding aesthetics. Therefore, attempts have been made to install fire extinguishing devices in walls, ceilings, doors, etc. indoors. In this case, since the battery built in the power supply must be replaced at predetermined intervals, maintenance is more cumbersome. It must be.

The present invention is to solve the problems as described above, an object of the present invention is to provide an automatic fire extinguishing device to be made by the injection of the extinguishing agent through a change in physical properties and mechanical interlocking without the electrical control and operating structure.

According to the present invention for achieving the above object, the press body is installed to be movable inside and the main body is formed on both sides of the press body and the drug chamber and the pressure chamber, respectively; An inflator installed in the pressure chamber to rapidly increase the gas pressure in the pressure chamber through a chemical reaction or a physical change so that the extinguishing agent in the pharmaceutical chamber can be discharged to the outside; A trigger mechanism for operating the inflator; A nozzle for injecting the extinguishing agent pushed from the medicine chamber to the outside; And a thermosensitive operation module controlling the operation of the trigger mechanism and the opening and closing of the pipeline between the chemical chamber and the nozzle, wherein the thermosensitive operation module includes a module body having a stopper ball and a valve ball communicating with each other, and the inside of the stopper ball. A stopper which is installed to be movable in the stopper to support or release the triggering mechanism according to a position, and is coupled to the outside of the stopper hole to support the stopper, but at least a part of the heat is melted by a heat stopper when a fire occurs. A thermal plug for releasing the support of the trigger mechanism, and a valve which communicates or blocks the pipeline between the chemical chamber and the nozzle connected through the valve hole according to the position, which is composed of a separate member integrated with or supported by the stopper. An automatic fire extinguishing device is provided.

In the automatic fire extinguishing device of the present invention, the trigger mechanism is inserted into the inside of the module body through the shaft hole formed on one side of the stopper ball is installed to be movable in the axial direction and the movable rod formed with a stop to be fixed to the stopper And a spring for elastically supporting the movable rod toward the pressure chamber to release the inflator by moving the movable rod when the fixing by the stopper is released.

In this case, the lever may be connected to the movable rod so that the lever rotates in response to the movement of the movable rod to trigger the inflator.

In addition, the stopper is installed to be movable to the outside of the stopper ball in accordance with the operation of the thermal plug, the end is formed with a fixing portion protruding to the outside of the stopper ball to be located in the pressure chamber, the stopper is the It can be configured to support the trigger mechanism in the inoperative position by the fixing portion.

In this case, the trigger mechanism may have a structure provided with a striker rotatably installed in front of the fixed portion of the stopper, and a spring installed to apply a rotational force to the inflator side.

The thermal plug may be made of a structure coupled to the module body by a fastening and detachable fixing pin.

In addition, the thermal plug is made of a metal having a higher thermal conductivity than lead, a portion coupled to the module body may be made of lead or lead alloy.

The nozzle may be rotatably installed in the main body or the thermosensitive operation module, and may further include driving means for rotating the nozzle in association with the injection of the extinguishing agent.

In this case, the driving means is a spring and ratchet wheel coupled to the same rotation shaft, one side is connected to the eccentric position with respect to the rotation axis and the other side is connected to the nozzle and the rod to rotate the nozzle in accordance with the release of the spring, and It may be configured to include a nozzle stopper which is installed to be connected between the stopper and the ratchet in the nozzle stopper hole formed in communication with the stopper hole of the thermosensitive operation module to rotate or stop the nozzle according to the position of the stopper.

According to the present invention as described above has the following advantages.

(A) When the ambient temperature rises, the support force of the stopper by the thermal plug is released, the inflator is operated by the trigger mechanism and valve which is interlocked with the stopper, and the discharge pipe is opened to allow the extinguishing agent to be injected. No need of operating device and power supply, low manufacturing cost, easy maintenance, normal non-operating state of inflator and blocking of leakage of extinguishing agent are maintained firmly, and in case of fire, accurate operation is performed under bad conditions. The required operating reliability is significantly improved.

(B) A fire extinguishing device having various sizes and shapes suitable for the conditions of use may be provided by configuring a trigger mechanism in various structures such as an axially moving rod, a sisoso moving lever, and a rotary striker.

(C) By simplifying the structure by integrating the stopper and the valve, the manufacturing cost can be reduced and the product size can be downsized.

(D) If necessary, remove the fixing pin so that the support of the stopper by the thermal plug can be manually released. It can be used for the purpose.

(E) Fire extinguishing agent is sprayed when the nozzle is sprayed, the fire extinguishing agent is sprayed in a wider range of directions to more effectively extinguish the fire, and the rotation of the nozzle is also made by mechanical interlocking with the stopper to operate in the fire Reliability can be improved.

The objects, features and advantages of the present invention described above will become more apparent from the following detailed description. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are a perspective view and a front sectional view showing a first embodiment of the automatic fire extinguishing device according to the present invention.

As shown in the automatic fire extinguishing device of the present invention, the plate-shaped pressurizer 102 is installed to be movable therein, and the chemical chamber 103 and the pressure chamber 104 are respectively disposed on the upper and lower portions of the pressurizer 102. The formed body 100 and the inflator 108 installed inside the pressure chamber 104 to rapidly increase the gas pressure inside the pressure chamber 104 through chemical reactions or physical changes, and increase in temperature upon fire. A heat sensitive operation module 130 for operating the inflator 108 to open the pumping passage of the extinguishing agent while simultaneously extinguishing agent 10 inside the medicine chamber 103 is pushed to the outside; It is configured to include a nozzle 150 for spraying the extinguishing agent pumped from the drug chamber 103 through the outside.

In the illustrated embodiment, the main body 100 is illustrated as being formed in a flat enclosure so as to be suitable for installation in a door 1 or a wall, a ceiling, a floor, etc., but is not limited thereto. ) May be formed in any shape in which the pressurizer 102 of various types moves in accordance with the expansion of the pressure chamber 104 to pressurize the inside of the chemical chamber 103.

The inflator 108 may be made of a chemical reaction method that generates a large amount of gas by chemically reacting a lead-free chemical including sodium azide, similarly to a conventional air bag used as a safety device for a vehicle, and expands the compressor body. In order to increase the pressure of the gas inside the pressure chamber 104 by vaporizing or liquefiing the liquefied gas, it may be of a physical property change type.

3 is a detailed cross-sectional view of the thermal response operation module 130 is shown. When described with reference to this, the heat-sensitive operation module 130 is in the form of a block in which the shaft hole 139, the stopper ball 133, the valve hole 135 communicated with each other, preferably in a direction perpendicular to each other is formed. A module body 131 and a movable rod 110 inserted into the module body 131 through the shaft hole 139 to operate the inflator 108 according to the movement of the movable rod 110. A trigger mechanism, a stopper 121 installed inside the stopper ball 133 to fix the movable rod 110 to an upward position, and coupled to an outer side of an inlet of the stopper ball 133 to stop the stopper 121. Support the outer end, in the state of being supported by the stopper 121 in the thermal plug 138 and the inside of the valve hole 135 and the thermal plug 138 to allow the stopper 121 to move by melting part or all in the event of a fire The outlet pipes 101a and 101b connected to both sides of the valve hole 135 are installed according to the installed position. It is configured to include a valve 140 to disconnect or communicate. The contact portion of the movable rod 110 and the stopper 121 is formed with a stop portion 111 and a fixing portion 121a protruding or embedded in a corresponding shape so as to hook each other to provide a fixing force.

Preferably, a spring 122 is provided to elastically support the stopper 121 in a direction opposite to the movable rod 110. However, when the support by the thermal plug 138 is released without the spring 122, the movable rod is removed. The stopper 121 may be moved by an external movement force applied to the 110. For example, as described below, when the movable rod 110 is configured to receive a downward force by the spring 118, the inclined guide surface is formed on the stop portion 111 and the fixing portion 121a which are in contact with each other. One spring 118 may be configured such that the downward movement of the movable rod 110 and the outward movement of the stopper 121 is interlocked.

The trigger mechanism may be configured as an interlock mechanism having various structures so that an operation for the operation of the inflator 108 may be performed according to the type of the inflator 108. In the illustrated embodiment is provided with a spring 118 elastically supported to lower the movable rod 110 and a ball 119 provided to be close to the triggering portion of the inflator 108 in the lower portion of the movable rod 110. When the movable rod 110 is moved downward, the ball 119 has been exemplified a structure that hits the trigger 109 of the inflator 108.

The valve 140 may be formed in various structures for opening and closing the both side discharge pipe path (101a, 101b) connected through the valve hole 135 in accordance with the position of the stopper 121. For example, as shown, the discharge pipe (101a, 101b) connected to the medicine chamber 103 and the nozzle 150 are connected to the communication hole (136a. 136b) formed on both sides of the valve hole 135, respectively The valve body 140 may be installed between the communication holes 136a and 136b, and the valve stopper 128 may be installed to be connected between the stopper 121 and the valve body 140. Preferably, the valve stopper 128 or the valve body 140 is provided with a spring 129 for elastically supporting the stopper 121, the valve stopper 128 by the stopper 121 without such a spring 129 is provided. When the support is released, the valve body 140 may be moved to the open position by the pressure of the extinguishing agent flowing into the valve hole 135. In addition, the valve body 140 and the valve stopper 128 forming the valve 140 may be integrally formed.

The thermal plug 138 is made of a metal material (hereinafter referred to as "low-temperature molten metal") that is melted at a relatively low temperature such as lead or lead alloy, and is directly coupled to the module body 131 in various ways such as screwing. It may be, but illustrated a structure that is simply detachably coupled by the fixing pin (137).

In addition, the nozzle 150 is configured to be rotatable, and the drive unit is provided to rotate the nozzle 150 to widen the injection range of the extinguishing agent. In the illustrated embodiment, the ball-type nipple 153 is coupled to the end of the discharge passage (101a, 101b), the nozzle 150 is rotatably coupled to the nipple 153. Preferably, the nozzle 150 has a plurality of injection holes 151 formed in different directions.

The driving means of the nozzle 150 is the spring 161, the ratchet 163, the rotating plate 162 is installed on the same rotating shaft 164, the rod 169 coupled to the eccentric position of the rotating plate 162 is It is connected to the nozzle 150 has a structure in which the nozzle 150 is rotated as the spring 161 is released. In addition, a nozzle stopper ball 134 is formed in the module body 131 in a direction orthogonal to the stopper ball 133 and is connected between the stopper 121 and the ratchet 163 through the nozzle stopper ball 134. The nozzle stopper 126 is installed as much as possible. Preferably, a spring 127 is provided to elastically support the nozzle stopper 126 toward the stopper 121.

In the automatic fire extinguishing device of the present invention configured as described above, since the stopper 121 is normally supported by the thermal plug 138, the fixing portion 121a is inserted into the stop portion 111 of the movable rod 110. In addition, the movable rod 110, as well as the valve stopper 128 and the nozzle stopper 126, may stably maintain the position of the non-operating state as shown.

When the thermal plug 138 is melted due to a fire and the thermal plug 138 is melted, or if a person removes the fixing pin 137 in some cases, the stopper 121 is moved to the outside of the stopper hole 133. The support of the movable rod 110, the valve stopper 128, and the nozzle stopper 126 by the stopper 121 is released.

Accordingly, while the movable rod 110 is lowered by the spring 118, the ball 119 hits the inflator 108 to operate, thereby rapidly increasing the pressure in the pressure chamber 104 to pressurize the body. 102 applies a strong discharge pressure to the extinguishing agent 10 inside the chemical chamber 103. At the same time, since the valve 140 is retracted and the discharge pipes 101a and 101b connected to both sides of the valve hole 135 communicate with each other, the compressed extinguishing agent is delivered to the nozzle 150 and sprayed to the outside. In addition, since the fixing force applied to the ratchet 163 is released by the nozzle stopper 126, the rotational force by the spring 161 is transmitted through the rod 169 and the nozzle 150 is rotated.

As described above, in the fire extinguishing device of the present invention, the operation of the inflator 108 and the opening of the discharge pipes 101a and 101b are controlled by the mechanical interlocking operation of the thermosensitive operation module 130 according to the melting of the thermal plug 138. Because it is made to inject extinguishing agent, it does not need electric control and operation structure and power supply means, so manufacturing cost is reduced and maintenance is easy. There is no fear of failure or malfunction due to the above, and the operation reliability required as the fire extinguishing device is remarkably improved.

In addition, when formed in a flat enclosure or panel form as illustrated, it can be embedded in the door (1), wall, ceiling, etc., it is not necessary to have a separate fire extinguisher in the room, it is convenient and can reduce the space requirements, In particular, when embedded in the door (1) it can block or delay the spread of the flame more effectively in the entrance portion which is the passage of the flame when the fire occurs.

Moreover, when the fire occurs as described above, since the fixing by the nozzle stopper 126 is released and the nozzle 150 is rotated by the mechanical driving means such as the mainspring 161, the extinguishing agent is sprayed in various directions more widely to more effectively fire the fire. It is possible to extinguish, the rotation of the nozzle 150 is also made by a mechanical control structure, the operation reliability is improved in the event of a fire compared to the structure having an electrical control system.

4 and 5 are a perspective view and a front sectional view showing a second embodiment of the automatic fire extinguishing device according to the present invention, Figures 6 to 8 are perspective views showing the heat-sensitive operation module 130 in an assembled and disassembled state, respectively And cross section.

In the second embodiment shown, the inflator 108 is provided inside the main body 100 in which the pressure chamber 104 and the medicine chamber 103 are divided by the pressing body 102 similarly to the first embodiment. And, it is made of a structure provided with a thermosensitive operation module 130 and a nozzle 150 on the outside of the main body 100, the structure of the thermosensitive operation module 130 is simplified.

In addition, the present invention as shown in Figure 4 may be provided as a frame type fire extinguishing device. That is, through-holes 3 and 4 are formed in the frame 2 in which a display such as a picture or a picture is accommodated, and the heat-sensitive plug 138 and the nozzle 150 are exposed through the through-holes 3 and 4. The structure of the main body 100 and the heat-sensitive operation module 130 of the device is accommodated behind the display of the frame (2). Such a structure allows the user to easily mount the fire extinguishing device on the wall at the position required by the frame frame 2, thereby increasing the ease of use of the fire extinguishing device and making it possible to use the indoor space more efficiently without disturbing the indoor copper wire, There is also an advantage that can be obtained with the effect of improving the interior aesthetics.

The thermosensitive operation module 130 is the shaft hole 139, the stopper ball 133 and the valve body 135, the module body 131 is formed and the upper stop portion 111 is formed in the shaft hole 139 orthogonal to each other A movable rod 110 movably inserted into the module body 131 through a 139, a trigger mechanism for operating the inflator 108 according to the movement of the movable rod 110, and the stopper ball 133. Stopper 121 and a stopper 121 is installed in the state receiving the elastic force to the outside by the spring 122 and the fixing portion 121a is inserted into the stop portion 111 of the movable rod 110, the stopper ball The thermal plug 138 coupled to the inlet outside of the 133 to support the stopper 121 and installed in the valve hole 135 in a state in which the spring 129 receives elastic force in the direction of the stopper 121 by the spring 129. And a valve 140 supported by the stopper 121. Discharge pipe paths 101a and 101b are connected to both communication holes 136a and 136b of the valve hole 135, and the valve body 140 of the valve 140 is positioned between the communication holes 136a and 136b. It is configured to block or communicate both discharge pipe path (101a, 101b).

The thermal plug 138 may be made of a low-temperature molten metal as in the first embodiment described above, but only a part of the coupling portion such as a threaded portion coupled to the module body 131 is melted at low temperature for durability and light weight. It may be made of metal. Preferably, the center portion excluding the coupling portion is made of a relatively high thermal conductive material such as copper, and is configured to melt the coupling portion more quickly in case of fire.

The trigger mechanism includes a spring 118 for elastically supporting the movable rod 110 downward, a ball 119 movably installed at a position close to the trigger portion of the inflator 108, and one side of the movable rod 110. ) And the other side is composed of a lever 117 rotatably installed in a seesaw manner so that the ball 119 can be hit.

The fire extinguishing device configured as described above, when a fire occurs and the ambient temperature rises, the engaging portion of the thermal plug 138 is melted and the stopper 121 is moved outward by pushing the thermal plug 138 by the spring 122. The fixing of the movable rod 110 is released. Accordingly, the movable rod 110 is moved downward by the spring 118, the opposite side of the lever 117 connected to the movable rod 110 is raised while hitting the ball 119, the inflator 108 is operated, the inflator As the pressure chamber 104 is expanded by the 108, the extinguishing agent 10 of the chemical chamber 103 is pumped to the thermosensitive operation module 130 through the discharge conduits 101a and 101b. At the same time, since the support of the valve 140 by the stopper 121 is released, the valve 140 is retracted by the spring 129 so that the discharge pipe paths 101a and 101b on both sides communicate with each other. It is injected to the outside through the nozzle 150.

The fire extinguishing device of the present embodiment has a simple and robust support structure of the movable rod 110 and the valve 140 by the stopper 121, which is advantageous in miniaturization and manufacturing cost reduction, and improves the operational stability and thus the transportation or the like. Even if an impact is applied during installation, there is no risk of malfunction. In addition, since the inflator 108 can be disposed above the pressure chamber 104 by providing a lever-type triggering mechanism, there is an advantage that the overall size of the apparatus is further miniaturized.

Figure 9 shows a third embodiment of the present invention, the stopper 121 and the valve 140 is formed integrally, and the trigger mechanism is configured to operate in a rotational manner more compact and miniaturized thermal response operation module ( 130 is an example.

That is, the illustrated thermosensitive operation module 130 has a stopper ball 133 formed on both sides of the pressure chamber 104 and the outside in the module body 131, respectively, and a spring inside the stopper ball 133. The stopper 121 is installed in a state of being supported to receive an elastic force to the outside by the 122, and the thermal plug 138 supporting the stopper 121 inward is coupled to the outside of the inlet of the stopper hole 133. In addition, the valve 140 is integrally provided with the stopper 121 and connected to both sides of the medicine chamber 103 and the nozzle (not shown) on both sides of the valve hole 135 formed on the same line as the stopper hole 133. Communication holes 136a and 136b are formed so that both sides of the valve 140 are communicated or blocked. At the end of the pressure chamber 104 side of the stopper 121, a fixing part 121a protruding outside the stopper hole 133 is provided.

In the present embodiment, the trigger mechanism is a striker 149 installed to be rotated in front of the fixing portion 121a of the stopper 121 and a spring 118 installed to apply a rotational force to the inflator 108 side to the striker 149. Is provided, the striking machine 149 is supported in a state caught in the fixing portion (121a) of the stopper 121 has a structure that the rotation is limited.

In this fire extinguishing device of the present embodiment, when the support force of the thermal plug 138 is released by heat, the stopper 121 is pushed outward by the spring 122, whereby the fixing force by the stopper 121 is released. Therefore, the striker 149 rotates by the spring 118 to operate the inflator 108. At the same time, since the valve 140 of one side of the stopper 121 is moved to the open position, the extinguishing agent 10 of the chemical chamber 103 is pumped to the nozzle through the discharge pipe passages 101a and 101b and the communication holes 136a and 136b. It becomes possible.

The structure as described above, the stopper 121 and the valve 140 is integrally formed to simplify the structure, the trigger mechanism is made of a rotational structure and the inflator 108 is horizontally installed to facilitate downsizing, manufacturing cost Has the advantage of reducing the installation space.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

1 is a perspective view showing a first embodiment of an automatic fire extinguishing device according to the present invention.

2 is a front sectional view showing the first embodiment.

3 is a plan sectional view showing a thermosensitive operation module in the first embodiment.

Figure 4 is a perspective view showing a second embodiment of the automatic fire extinguishing device according to the present invention.

Fig. 5 is a front sectional view showing the second embodiment.

6 is a perspective view showing a thermosensitive operation module in the second embodiment.

Fig. 7 is an exploded perspective view showing the thermosensitive operation module of the second embodiment.

Fig. 8 is a plan sectional view showing the thermosensitive operation module of the second embodiment.

9 is a front sectional view showing a third embodiment of an automatic fire extinguishing device according to the present invention.

Claims (9)

A main body 100 having a pressing body 102 movable therein and having a medicine chamber 103 and a pressure chamber 104 formed at both sides of the pressing body 102; An inflator (108) installed in the pressure chamber (104) to rapidly increase the gas pressure in the pressure chamber (104) through a chemical reaction or physical change so that the extinguishing agent (10) of the chemical chamber (103) can be discharged to the outside; A trigger mechanism for operating the inflator 108; A nozzle 150 for spraying the extinguishing agent pumped from the medicine chamber 103 to the outside; And It includes a heat-sensitive operation module 130 for controlling the operation of the trigger mechanism and the opening and closing of the pipeline between the chemical chamber 103 and the nozzle 150, The thermosensitive operation module 130 is installed in the module body 131 and the stopper ball 133 and the valve ball 135 in communication with each other, the movable stopper ball 133 is installed in accordance with the position A stopper 121 for supporting or releasing the trigger mechanism so as to be suppressed to be operated and coupled to the outside of the stopper hole 133 to support the stopper 121, but at least part of the stopper 121 melts due to heat when a fire occurs. The thermal plug 138 for releasing the support of the trigger mechanism and a separate member integrally with the stopper 121 or supported by the stopper 121 are formed through the valve hole 135 depending on the position. An automatic fire extinguishing device comprising a valve (140) for communicating or blocking a conduit between the connected chemical chamber (103) and the nozzle (150). The method of claim 1, The trigger mechanism is inserted into the module body 131 through the shaft hole 139 formed at one side of the stopper hole 133 and is installed to be movable in the axial direction and stops to be caught and fixed to the stopper 121 ( The movable rod 110 having the 111 formed thereon and the movable rod 110 are elastically supported toward the pressure chamber 104 to release the fixing by the stopper 121 to move the movable rod 110 to the inflator 108. Automatic fire extinguishing device comprising a spring (118) to be triggered. The method of claim 2, The lever 117 is connected to the movable rod 110, the lever 117 is rotated in accordance with the movement of the movable rod 110 to trigger the inflator 108, characterized in that the automatic fire extinguishing device. The method of claim 1, The stopper 121 is installed to be movable to the outside of the stopper hole 133 according to the operation of the thermal plug 138, the end of the stopper hole 133 to be located in the pressure chamber 104 Fixing portion (121a) protruding to the outside is formed, the stopper 121 is an automatic fire extinguishing device, characterized in that to support the trigger mechanism in the non-operational position by the fixing portion (121a). The method of claim 4, wherein The trigger mechanism includes a striking machine 149 rotatably installed in front of the fixing part 121a of the stopper 121, and a spring 118 installed to apply the rotational force to the inflator 108 side to the striking machine 149. Automatic fire extinguishing device, characterized in that. The method of claim 1, The thermal plug 138 is an automatic fire extinguishing device, characterized in that coupled to the module body 131 by a fastening and detachable fixing pin (137). The method of claim 1, The thermal plug 138 is made of a metal having a higher thermal conductivity than lead, the automatic fire extinguishing device, characterized in that the portion coupled to the module body 131 is made of lead or lead alloy. The method according to any one of claims 1 to 7, The nozzle 150 is rotatably installed in the main body 100 or the thermosensitive operation module 130, the automatic fire extinguishing device further comprises a drive means for rotating the nozzle 150 in conjunction with the injection of the extinguishing agent. The method of claim 8, The driving means is a spring 161 and ratchet 163 coupled to the same rotation shaft 164, one side is connected to the position eccentric with respect to the rotation shaft 164 and the other side is connected to the nozzle 150, The stopper 121 and the ratchet are connected to the rod 169 for rotating the nozzle 150 and the nozzle stopper hole 134 formed in communication with the stopper hole 133 of the thermosensitive operation module 130 as the 161 is released. Automatic fire extinguishing device including a nozzle stopper 126 is installed to be connected between the (163) so that the nozzle 150 is rotated or stopped according to the position of the stopper (121).

Images