KR200447025Y1 - Electric Solid Aerosol Automatic Fire Extinguisher - Google Patents

Abstract

The present invention provides an electric solid aerosol automatic fire extinguishing device that can protect the control unit even if the electric wires used to explode the initiator 230 in the electric fire extinguishing device are short-circuited. Its purpose is to.

In order to achieve the object of the present invention, the detonator 200 of the present invention, the initiator exploded by the detonator signal received from the control unit 230; A ignition agent 240 ignited by the explosion of the initiator 230; It characterized in that it comprises a bimetal switch 260 is the contact is switched by the ambient temperature rise.

In addition, the cable assembly 100 of the present invention, one end is electrically connected to the control unit and the other end is electrically connected to the detonator 200, the detonator signal for operating the detonator 200, the control unit The cable 110 having at least a function of transmitting to the detonator 200, including at least two detonation wires (111, 112) which is a passage through which the detonation signal for operating the detonator 200 flows; ); And a fuse set 130 installed in at least one of the two or more initiator wires 111 and 112 and performing a function of blocking a circuit when an overcurrent flows.

Fire Extinguisher, Solid Aerosol, Detonator, Fuse, Bimetal

Description

ELECTRICAL OPERATING-TYPE SOLID AEROSOL AUTOMATIC EXTINGUISHER}

The present invention relates to an electric solid aerosol automatic fire extinguishing device, and more particularly, the detonator is operated by receiving an electrical signal from the control unit, the solid aerosol compound is combusted by the operation of the detonator, the combustion of the solid aerosol compound An electric solid aerosol automatic fire extinguishing device for extinguishing a fire by a gas. In addition, the present invention transmits a signal relating to the operation of the detonator to the control unit so that the control unit can check whether the detonator is in operation, and the electric solid aerosol can automatically protect the control unit even if an electrical short occurs in the detonator. It relates to a fire extinguishing device.

Fire extinguishers are used to extinguish a fire at an early stage. Fires are classified into general fires, oil fires, electric fires, and metal fires according to their characteristics. The fire is extinguished, and these fire extinguishers are further divided into powder fire extinguishers, carbon dioxide fire extinguishers and halon fire extinguishers according to the extinguishing agent charged therein.

The fire extinguisher is also classified into a manual fire extinguisher and an automatic fire extinguisher.

Manual fire extinguishers are the most commonly seen fire extinguishers that pull out the safety pins and hold the lever by hand to inject extinguishing agents. An automatic fire extinguisher is a fire extinguisher that detects heat or smoke and automatically releases a fire extinguishing agent to extinguish a fire.

Automatic fire extinguishers are divided into mechanical and electrical systems, which operate by raising heat by attaching a heat-operated device and releasing extinguishing agents to extinguish a fire. Electricity senses heat or smoke and releases fire extinguishing agent by electric signal method to extinguish fire.

Meanwhile, the inventors of the present invention have devised an electric solid aerosol automatic fire extinguishing apparatus using a solid aerosol compound as a fire extinguishing agent. {These designs may not be known yet. It consists of an initiator and a main body. The controller generates an electrical signal and transmits it to the detonator when a fire occurs. The detonator is for providing the heat of ignition by receiving the electrical signal. In the detonator, the detonator is exploded by the electric signal received from the controller, and the igniter is ignited by the explosion. The solid aerosol compound and the coolant are separately contained in the main body, and the solid aerosol compound of the main body initiates combustion by ignition of the igniter, releasing extinguishing gas (in the form of an aerosol), and the extinguishing gas passes through the coolant. The heat of combustion is cooled and the extinguishing gas is released to the outside.

On the other hand, in the initiator, two wires are used to supply an electrical signal to the initiator (as well as two electrodes may be used directly in contact with the initiator), and even if there is an explosion of the initiator, Or electrodes, hereinafter simply referred to as wires) should be spaced apart from each other, but the wires may flow in their original position and short-circuit by the explosion of the initiator. In addition, a housing made of a metallic material is used for the detonator, and the electric wires may contact the housing and short-circuit by the explosion of the detonator. However, the control unit has a detonation signal output unit for outputting an electrical signal for operating the detonator, and the short circuit has a problem of damaging the detonation signal output unit of the control unit.

And the control unit needs to check whether the operation of the detonator or the main body of the remote. Information on whether such an action can be reported to a higher system through the control unit, it is possible to provide more useful information to the administrator. However, a device or method for simply and accurately confirming whether the detonator or the main body is operated has not been presented.

The present invention is designed to solve the above conventional problems.

The object of the present invention is to provide an electric solid aerosol automatic fire extinguishing device that can protect the control unit even if the wire used to explode the initiator in the electric solid aerosol automatic fire extinguishing device.

In addition, the present invention has an object to provide an electrical fire extinguishing device that can more easily and accurately check whether the detonator operation.

According to an aspect of the present invention, the present invention, one end is electrically connected to the control unit and the other end is electrically connected to the detonator 200, the detonator signal for operating the detonator 200, the control unit In the cable assembly for an electric solid aerosol automatic fire extinguishing device having at least a function of transferring from the detonator 200 to the detonator 200, at least two detonation wires that are passages through which the detonation signal for operating the detonator 200 flows ( Cables 110 including 111 and 112; It is characterized in that it comprises a fuse set 130 is installed on at least one of the two or more initiator wires (111, 112), the function of blocking the circuit when the overcurrent flows.

According to an aspect of the present invention, the electric solid aerosol automatic fire extinguishing device of the present invention, the solid aerosol compound (10) for generating a fire extinguishing gas by combustion; A coolant (20) spaced apart from the solid aerosol compound (310) and cooling combustion heat by combustion of the solid aerosol compound (10); A main body 300 including a space part 70 for separating the solid aerosol compound 10 and the coolant 20; An initiator 230 exploded by the initiator signal received from the controller; A ignition agent 240 ignited by the explosion of the initiator 230; And a bimetal switch 260 in which the contact is switched by an increase in ambient temperature, and at least the initiator 200 is introduced into the main body 300.

According to the present invention, even if the wires used in the initiator are short-circuited, the fuse set of the cable assembly opens the circuit, thereby protecting the initiator signal output of the controller.

Further, according to the present invention, in order to solve the short circuit problem in the detonator, the existing control unit or the detonator only needs to replace the existing cable assembly without having to replace the short circuit problem in the detonator. There is an effect that can be solved.

In addition, according to the present invention, by configuring a bimetal switch in the detonator and using it to sense the temperature rise of the detonator, there is an effect that can easily and accurately determine whether the detonator operation.

In addition, according to the present invention, by using the common wire and the sensing wire in common, there is an effect that the configuration of the cable assembly is simplified.

In addition, according to the present invention, by screwing the detonator and the cable assembly, there is an effect of easy coupling and separation of the detonator and the cable assembly.

In addition, according to the present invention, by forming a heat insulating cloth to surround the top and side of the solid aerosol compound, the heat generated during the combustion of the solid aerosol compound is not transferred to the surroundings there is an effect that can prevent the secondary fire.

In addition, according to the present invention, by cooling the extinguishing gas generated during the combustion of the solid aerosol compound with a coolant, it is possible to lower the temperature of the extinguishing gas to prevent the secondary fire by the extinguishing gas.

Further, according to the present invention, potassium nitrate (KN0 ₃₎ or potassium chlorate by using a solid aerosol compound containing at least one selected from (KClO _4), O in the digestion gas is combustible substance ^-, H ^+, OH ^-, etc. Combination prevents the combustibles from burning anymore, and because the extinguishing gas is not combined with oxygen in the air, the oxygen at the fire site remains as it is, and the effect of solving the problem of depletion of oxygen due to the extinguishing gas at the fire site is solved. There is.

Hereinafter will be described in more detail through the accompanying drawings showing an embodiment of the present invention.

1 is a view showing an electric solid aerosol automatic fire extinguishing device according to an embodiment of the present invention.

The present invention operates a main body of the fire extinguishing device by transmitting the detonation signal to the detonator 200 when a fire signal is detected from a remote control unit (not shown in the drawing), which prevents an overcurrent from flowing to the control unit by a short circuit according to the operation. Electric fire extinguisher. Fire extinguishing device of the present invention includes a main body 300, the detonator 200 and the cable assembly (100).

The main body 300 includes a solid aerosol compound 10 that generates extinguishing gas by combustion; A coolant 20 spaced apart from the solid aerosol compound 310 and cooling the combustion heat by combustion of the solid aerosol compound 10; And a space part 70 for separating the solid aerosol compound 10 and the coolant 20.

As shown in FIG. 1, the main body 300 is formed of a double-walled cylindrical upper and lower portions, is made of a metal resistant to corrosion, and the inside of the wall is filled with a heat insulating cloth 60. Maintain insulation.

The heat insulation cloth 60 is made of a non-combustible heat insulating material having excellent heat insulating performance and heat resistance, so that the solid aerosol compound 10 is ignited so that the high temperature heat generated thereby does not escape to the outside and cause another fire.

Inside the cylindrical body 300, the heat insulation cloth 60, the solid aerosol compound 10, the upper diaphragm 50A, the separator tube 32, the intermediate diaphragm 50B, the coolant 20, and the lower partition plate from the upper part ( 50C), the auxiliary seating stand 32A and the lower cover 34 are sequentially seated, and these components are formed by the latching jaw A formed by bending the upper and lower ends of the main body 300 inward. ) Is fixed inside, and the upper cover 33 is installed on the upper and sealed by the outside, whereby the locking jaw (A) is placed in the main body 300 all the components and then cover the upper cover 33 I then formed bending.

The heat insulation cloth 60 is formed to surround the top of the solid aerosol compound 10 and the side of the solid aerosol compound 10.

The heat insulation cloth 60 is installed not only inside the wall of the main body 300 but also inside the upper part of the main body 300, and a material of the same material as that of being filled into the inside of the wall of the main body 300 is used, which will be described later. The heat generated while the aerosol compound 10 is burned is blocked from being discharged to the upper portion of the main body 300. According to the present invention, by forming a heat insulating cloth to surround the top and side of the solid aerosol compound 10, the heat generated during the combustion of the solid aerosol compound is not transferred to the surroundings there is an effect that can prevent the secondary fire. .

Solid aerosol (exists in solid state and produces solid particulates on combustion) Compound 10 is thick cylindrical and the solid aerosol compound 10 is selected from potassium nitrate (KN0 ₃ ) or potassium chlorate (KClO ₄ ). When the ignition agent 240 of the detonator 200, which will be described below, is prepared to include at least one, it is ignited, whereby the solid aerosol compound 10 enters the digestion gas containing potassium (K) ions (the hyeongtaeyi C) is generated and this when the extinguishing gas is discharged from the main body 30, the digestion gas is O in the combustible material so that the continued up ^fuels so that it is not combustible material further combustion by engaging as ^-, H ^+, OH It blocks combustion and does not combine with oxygen in the air, so the oxygen at the fire site remains intact, allowing people who may remain at the fire site to breathe. This eliminates the risk of choking.

Meanwhile, the diaphragm 50 having a plurality of through-holes 51 formed in the main body 300 is horizontally arranged into three upper, middle, and lower portions, and the upper diaphragm 50A is positioned below the solid aerosol compound 10. The gas discharged when the solid aerosol compound 10 is combusted is discharged downward through the plurality of through holes 51, and the middle diaphragm 50B is formed by a pipe-shaped separation pipe 32 whose upper and lower portions are opened. Located in the lower portion of the space portion 70 to induce the combustion gas discharged to the space portion 70 to flow into the coolant 20 installed in the lower portion, the bottom plate (50C) is located at the bottom of the coolant 20 While supporting the function to discharge the combustion gas passing through the coolant 20 to the outside of the main body.

A separation pipe 52 having a predetermined height is installed between the upper diaphragm 50A and the intermediate diaphragm 50B positioned above the coolant 20. Thus, a space portion having a predetermined height is provided between the diaphragms 50. 70 forms, whereby a large amount of combustion gas is produced at once, providing a space in which the combustion gas that can not escape through the coolant 20 can remain, while at the same time the flame of the solid aerosol compound 10 is directly directed to the coolant. The coolant 20 is protected by preventing contact.

The coolant 20 is filled in the space formed by the middle diaphragm 50B and the lower diaphragm 50C, and the coolant 20 is magnesium hydroxide (Mg (OH) ₂ ), sodium carbonate (Na ₂ CO ₃ ), Combustion of solid aerosol compound 10 as a solid compound comprising at least one selected from boric acid (H ₃ BO ₃ ), potassium chlorate (KClO ₄ ), potassium nitrate (KN0 ₃ ) and calcium carbonate (CaCO ₃ , CaCO ₄ ) In order to cool the high temperature combustion (digestion) gas generated by the low temperature, when the high temperature extinguishing gas is discharged to prevent the secondary fire may occur by this high temperature extinguishing gas.

The lower diaphragm 50C is installed in the lower part of the coolant 20, and this lower diaphragm 50C is supported by the pipe-shaped auxiliary seating stand 32A whose upper and lower parts which have a predetermined height are opened, and this auxiliary seating stand ( 32A is again supported by the lower cover 34, so that a space having a predetermined height is formed between the lower plate 50C and the lower cover 34. As shown in FIG.

Unlike the upper cover 33, the lower cover 34 is provided with a plurality of extinguishing gas discharge holes 34A, through which the extinguishing gas is discharged to the outside of the main body.

On the other hand, there is a need for a detonator to burn the solid aerosol compound 10 in the event of a fire. The detonator is inserted into the penetrating portion 11 of the main body as shown in FIG. 1, and FIG.

The detonator 200 includes a detonator 230 exploded by the detonator signal received from the control unit; A ignition agent 240 ignited by the explosion of the initiator 230; And a bimetal switch 260 for outputting a detection signal by switching the contact point due to an increase in ambient temperature, and at least the firing agent 240 is introduced into the main body 300.

The detonator 200 receives the detonator signal from the control unit to explode the initiator, ignite the igniter according to the explosion, and burn the solid aerosol compound 10 by the heat of ignition of the igniter.

The detonator 200 may include a wire for transmitting the detonator signal to the initiator 230 and a wire for transmitting the detection signal from the bimetal switch 260.

The initiator 230 is connected to the first terminal 201 by the first terminal input line 211 and also to the second terminal 202 by the second terminal input line 212. The bimetal switch 260 is connected to the second terminal 202 by a second terminal output line 213, and is connected to the third terminal 203 by a third terminal output line 214.

In the event of a fire, a DC voltage may be applied through the first terminal 201 and the second terminal 202, and the DC voltage is, for example, 24V DC.

In addition, the first terminal input line 211, the second terminal input line 212, the second terminal output line 213, and the third terminal output line 214 may be formed of a heat resistant wire that is resistant to heat. .

The bimetal switch 260 is to switch the contact when the ambient temperature rises above a certain temperature, the external material may be made of a ceramic material to be protected from heat (flame). One end of the bimetal switch 260 is connected to the second terminal 202 by the second terminal output line 213, and is connected to the third terminal 203 by the third terminal output line 214. By monitoring the voltage between the terminal 202 and the third terminal 203, it is possible to know whether the bimetal switch 260 is switched. In detail, the second terminal output line 213 is not only connected to the bimetal switch 260 but also to the second terminal 202, and may be one end (eg, a DC voltage or a ground voltage) of the detonation signal when a fire occurs. Is supplied). The third terminal output line 214 is connected to the other end of the bimetal switch 260. Therefore, if the voltage between the third terminal output line 214 and the second terminal output line 213 is monitored, it is possible to know whether the contact point of the bimetal switch 260 is in contact or not, and whether the change is made in time. You will also know.

3 and 4 show a side view and a separated view of the cable assembly, respectively.

Cable assembly 100, one end is electrically connected to the control unit and the other end is electrically connected to the detonator 200, the detonator signal for operating the detonator 200 from the detonator ( A cable (110) having at least a function of transmitting to the at least two and including at least two detonation wires (111, 112) which is a passage through which the detonation signal for operating the detonator 200 flows; It is installed on at least one of the two or more initiator wires (111, 112) of the wire (111, 112), and includes a fuse set 130 for performing a function to block the circuit when the overcurrent flows.

The cable assembly 100 may further include sensing wires 112 and 113 serving as passages through which a detection signal indicating whether the detonator 200 is operated.

In FIG. 4, one strand 112 of the sensing wires 112 and 113 and one strand 112 of the initiator wires 111 and 112 are commonly used. The wire denoted by reference numeral 112 is both an initiator wire and a detection wire.

The coupling nut 121 has a female thread and is screwed with the input / output connector 220 of the detonator 200. The plug 122 is installed in the coupling nut 121 to be coupled to the input / output connector 220 of the detonator 200, and has a male screw portion coupled to the connector 13. The connecting body 123 has a female screw portion and a male screw portion, the female screw portion is screwed with the plug 122, and the male screw portion is screwed with the clamp 125. The bushing 124 abuts on the end of the connecting body 123 and prevents bending of the cable 110. The clamp 125 has a bushing 124 inserted therein, and the bushing 124 is fixed to abut the end of the connecting body 123 while being screwed with the connecting body 123 having a female threaded portion.

The cable 110 is installed through the coupling nut 121, the connecting member 123, the bushing 124 and the clamp 125, one end is connected to the plug 122, the other end is It is connected to the signal input / output terminal of the controller.

The cable 110 is a passage through which at least two or more initiator wires 111 and 112 which are a passage through which the amplification signal for operating the aerator 200 flows, and a detection signal indicating whether the aerator 200 is operated. The sensing wires 112 and 113 may be included. In FIG. 4, one strand 112 of the sensing wires 112 and 113 and one strand 112 of the initiator wires 111 and 112 are used as common wires.

The fuse set 130 is installed on at least one of the wires 111 and 112 to prevent the flow of overcurrent.

5 is an exploded cross-sectional view of the fuse set.

The fuse set 130 includes a fuse 131, a female fuse case 132, a male fuse case 133, and springs 134 and 135.

The female fuse case 132 has a female screw portion and is screwed into the male fuse case 133 having a male screw portion engaged with the female screw portion. A fuse 131 is installed between the female fuse case 132 and the male fuse case 133, and springs 134 and 135 are respectively installed in the female fuse case 132 and the male fuse case 133. The fuse 131 is elastically supported.

Look at the operation of the present invention made as described above

When the detonation signal is transmitted from the controller to the detonator 200 through the cable assembly 100, the detonator 230 of the detonator 200 is detonated and the igniter 240 is ignited by the detonator. In addition, the solid aerosol compound 10 that receives the heat of ignition from the igniter 240 is combusted, and the extinguishing gas generated while the solid aerosol compound 10 is combusted is cooled by the coolant 20 and discharged. Extinguish fire by extinguishing gas. At this time, in the inside of the detonator 200, the temperature around the bimetal switch 260 is increased due to the heat caused by the explosion of the initiator 230, the heat of ignition of the igniter 240, or the heat of combustion of the solid aerosol compound 10. Will rise. Therefore, the contact of the bimetal switch 260 is switched so that the detection signal indicating that the ignition is normally performed through the second terminal 202 and the third terminal 203 can be transmitted to the controller.

Here, due to the shock and heat caused by the explosion of the initiator 230, the heat caused by the ignition of the igniter 240, the wire used in the initiator may be short-circuited or the wire may be attached to the housing 210 to short-circuit. have. Assuming that such a short circuit occurs, the detonation wire 111, the first terminal 201, the first terminal input line 211, the second terminal input line 212, the second terminal 202 and the detonation wire 112 Overcurrent flows in a closed circuit composed of However, according to the present invention, the fuse set 130 is installed in at least one or more of the initiator wires (111, 112), thereby breaking the circuit. {Although FIG. 3 illustrates that the fuse set 130 is installed on the initiator wire 111 of reference numeral 111, it may be installed on the initiator wire 112 of reference numeral 112.} Therefore, the controller outputs the initiator signal. It is possible to prevent the portion (detonation signal output section) from being broken.

And to solve the above short circuit problem by improving the existing fire extinguishing device, according to the present invention, since only the existing cable assembly need to be replaced without replacing the existing control unit or the detonator, the short circuit problem in the detonator There is an effect that can be easily solved at a low cost.

1 is a side cross-sectional view of a main body and a cable assembly of an electric solid aerosol automatic fire extinguishing device according to an embodiment of the present invention.

2 is a cross-sectional view of the detonator according to the present invention.

3 is a side view of the cable assembly according to the present invention.

4 is an exploded view of the cable assembly according to the present invention.

5 is an exploded cross-sectional view of the fuse set.

** Description of symbols for the main parts of the drawing **

10.Solid aerosol compound 11 ... through

20 Coolant 31 Receptacle

32 Separator 33 Top cover

34 Lower cover 34 A Extinguishing gas outlet

50 ... plate 51 ... through hole

60 ... insulation 70

100 ... cable assembly 110 ... cable

121 ... Coupling nut 122 ... Plug

123 ... Connector 124 ... Bushing

125 Clamp 130 Fuseset

200 ... Detonator 210 ... Housing

211 ... 1st terminal input line 212 ... 2nd terminal input line

213 ... 3rd terminal input wire 220 ... I / O connector

230 ... Initiator 240 ... Ignition Agent

250 ... insulation material 260 ... bimetal switch

300 ... body

Claims (12)

One end is electrically connected to the control unit and the other end is electrically connected to the detonator 200, and a function of transmitting a detonator signal for operating the detonator 200 from the control unit to the detonator 200. A cable assembly for an electric solid aerosol automatic fire extinguishing device having at least A cable 110 including at least two initiator wires 111 and 112 serving as a passage through which the initiator signal flows to operate the initiator 200; A fuse set installed on at least one of the two or more initiator wires 111 and 112 and having a function of blocking a circuit when an overcurrent flows; Cable assembly for an electric solid aerosol automatic fire extinguishing device comprising a. The method according to claim 1, The cable 110, The cable assembly for an electric solid aerosol automatic fire extinguishing device, characterized in that it further comprises a sensing wire (112, 113) that is a passage through which a detection signal indicating whether the detonator 200 is operating. The method according to claim 2, The cable assembly for an electric solid aerosol automatic fire extinguishing device, characterized in that one strand of the sensing wires (112, 113) and one strand of the initiator wires (111,112) are used in common. The method according to claim 1, The fuse set 130, An female fuse case 132 having a female thread portion; A male fuse case 133 having a male screw portion engaged with the female screw portion and coupled to the female fuse case 132; A fuse 131 inserted between the female fuse case 132 and the male fuse case 133 and elastically supported by springs 134 and 135; Cable assembly for an electric solid aerosol automatic fire extinguishing device comprising a. The method according to claim 1, A coupling nut 121 screwed to the detonator 200; A plug 122 installed in the coupling nut 121 and coupled to the detonator 200; A connector 123 screwed to the plug 122; A bushing 124 installed in the connection body 123 and preventing bending of the cable 110; A clamp 125 screwed to the connecting member 123 and preventing separation of the bushing 124; Cable assembly for an electric solid aerosol automatic fire extinguishing device further comprising. A solid aerosol compound 10 which produces an extinguishing gas by combustion; A coolant 20 spaced apart from the solid aerosol compound 310 and cooling the combustion heat by combustion of the solid aerosol compound 10; A main body 300 including a space part 70 for separating the solid aerosol compound 10 and the coolant 20; An initiator 230 exploded by the initiator signal received from the controller; A ignition agent 240 ignited by the explosion of the initiator 230; An initiator 200 including a bimetal switch 260 in which a contact is switched by an increase in ambient temperature, and at least the firing agent 240 is introduced into the body 300; Electric solid aerosol automatic fire extinguishing device comprising a. The method according to claim 6, And a fuse set 110 that cuts off a circuit when an overcurrent flows through the wire through which the detonation signal flows, and electrically connects the detonator 200 and the control unit to transmit at least the detonation signal. ; Electric solid aerosol automatic fire extinguishing device further comprises. The method according to claim 6, The main body 300, Electrical solid aerosol automatic fire extinguishing device, characterized in that it further comprises a heat insulating cloth (60) formed to surround the top and side of the solid aerosol compound (10). The method according to claim 6, A detection signal indicating whether the detonator 200 is operated by being electrically connected to at least two or more detonators wires 111 and 112 serving as a passage through which the detonator signal flows, and the bimetal switch 260 of the detonator 200. Cable 110 including the sensing wires 112, 113 to be a passage through which; The cable assembly 100 further comprises a; fuse set 110 to cut off the circuit when the overcurrent flows through the wire through which the detonation signal flows, An electric solid aerosol automatic fire extinguishing device, characterized in that one strand of the sensing wires (112, 113) and one strand of the initiator wires (111,112) are used in common. The method according to claim 6 The detonator 200, Wires 211 and 212 for transmitting the detonation signal to the initiator 230 and wires 213 and 214 electrically connected to the bimetal switch 260 to transmit a detection signal indicating whether the detonator 200 is operated. Electric solid aerosol automatic fire extinguishing device further comprises. The method according to claim 6, The coolant 20 is magnesium hydroxide (Mg (OH) ₂ ), sodium carbonate (Na ₂ CO ₃ ), boric acid (H ₃ BO ₃ ), potassium chlorate (KClO ₄ ), potassium nitrate (KN0 ₃ ), calcium carbonate (CaCO ₃ , CaCO ₄ ) The electric solid aerosol automatic fire extinguishing apparatus, characterized in that the solid compound containing at least one selected from. The method according to claim 6, The solid aerosol compound (10), An electric solid aerosol automatic fire extinguishing device comprising at least one selected from potassium nitrate (KN0 ₃ ) or potassium chlorate (KClO ₄ ).

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