KR100932097B1 - Electrically-operating solid-aerosol automatic extinguisher including lateral outlet - Google Patents

Abstract

PURPOSE: An electrically operating solid aerosol automatic extinguisher is provided, which recognizes fire initially and suppresses fire effectively. CONSTITUTION: An electrically operating solid aerosol automatic extinguisher comprises an outer reservoir(317) which has a sealed cylinder shape and includes an lateral outlet(334) formed in one side; an inside reservoir(336) which is located in the outer reservoir and includes a perforated screen(326) in one side; a refrigerant(328) placed between the perforated screen and lateral outlet; a solid fire extinguishing agent generating aerosol in combustion; a igniting composition which burns the solid fire extinguishing agent; and an electrically operating ignition operation member.

Description

Electrically-operating solid-aerosol automatic extinguisher including lateral outlet

The present invention relates to an operating device for detecting a fire and operating an automatic fire extinguishing device. In particular, the present invention relates to an operating device for detecting a fire when a fire occurs and controlling the electric fire extinguishing device to operate by supplying a current to the fire extinguishing device.

In general, in the case of a fire, a fire caused by electricity accounts for a large part of the fire gun, and a fire occurs frequently due to a short circuit in an electrical outlet, a switch box, a light fixture, or an electronic product. In addition, if a fire occurs in an unattended or uninhabited area, the fire will progress to some extent after the upper time has elapsed since the fire has occurred and the temperature should rise and the smoke and flame should be activated so that a fire detector occurs and the fire extinguishing facility operates. Since it was mature, there were many difficulties in suppression.

In particular, most of the fire-extinguishing facilities are installed on the ceiling has a significant distance from the electrical equipment that is the ignition point of the fire, there was a problem that does not detect the fire early or the fire suppression is not properly made. Therefore, various researches have been made on automatic fire extinguishing apparatus so as to recognize the fire at an early stage to block the spread of the fire and extinguish the fire.

Conventional automatic fire extinguishers usually have a closed cylindrical shape and have a discharge port for discharging the extinguishing agent on a circular disk plate, which is mostly the lower surface. The size of an automatic fire extinguisher mounted in an electrical device such as an electrical wiring board is limited by the size of the mounted electrical device. Therefore, when the size of the electric device to be mounted is determined, the size of the automatic fire extinguisher to be mounted therein is also determined, and thus the discharge area of the extinguishing agent is also determined, which limits the performance of the conventional automatic fire extinguishing device.

On the other hand, the detonator of an automatic fire extinguisher uses two wires to supply an electrical signal to the initiator (as well as two more electrodes in direct contact with the initiator), even if there is an explosion of the initiator. The wires (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-circuited 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 can 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 has been made to solve the above problems of the prior art, has the following object.

The technical problem of the present invention is to provide an electric fire extinguishing device for side discharge that can effectively extinguish a fire by recognizing the fire at an early stage.

In addition, an object of the present invention is to provide an electrically operated automatic fire extinguishing device that can more easily and accurately check whether the detonator of the automatic fire extinguisher operation.

Automatic fire extinguishing device according to the present invention for solving the above problems, the outer storage container having a closed cylindrical shape and including a side discharge port formed on at least one side; An internal storage container located in the external storage container, the internal storage container including a perforated network on at least one side; A coolant interposed between the perforated network and the side outlet; A solid extinguishing agent inserted into the internal storage container to generate an aerosol of the extinguishing component upon combustion; Located on the top or bottom of the outer storage container, the igniter to ignite the solid extinguishing agent; And a ignition actuator for igniting the igniter.

The perforated network and the side outlet port preferably overlap each other.

The automatic fire extinguishing device may further include a mesh interposed between the coolant and the side outlet and having a mesh smaller than a hole size of the side outlet.

The mesh is preferably a stainless steel wire mesh.

The automatic fire extinguishing device may further include a thin film interposed between the side outlet and the mesh.

The thin film is adhesive and attached to the inner side outlet of the outer storage container, and is preferably a metal or resin thin plate.

The solid extinguishing agent may be a solid mixture including KNO ₃ , KClO ₄ , Ba (NO ₃ ) _2, and resins. In this case, preferably, the content of KNO ₃ is 27-42% by weight, the content of KClO ₄ is 28-43% by weight, the content of Ba (NO ₃ ) ₂ is 7-12% by weight and the content of the resins 16-25 wt%.

The coolant may be a solid mixture of at least one material selected from the group comprising MgCO ₃ , H ₃ BO ₂ , SiO ₂ and CaSO ₄ 2H ₂ O.

In the configuration of the ignition operation device, one end is electrically connected to the control unit, the other end is electrically connected to the detonator 200, and the detonator at the control unit generates an initiator signal for operating the detonator 200. In the cable assembly for an electric fire extinguishing device having at least a function of transmitting to the 200, the cable comprising at least two detonation wires (111, 112) which is a passage through which the detonation signal flows to operate the detonator 200 ( 110); 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 one embodiment of the present invention, the electric fire extinguishing device of the present invention includes a solid aerosol compound 340 for generating extinguishing gas by combustion; A coolant 328 for cooling the combustion heat of the extinguishing gas by the combustion of the solid aerosol compound 340; A main body 300 including the solid aerosol compound 340 and the coolant 328; 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.

In the automatic fire extinguishing device according to an embodiment of the present invention, since the aerosol of the extinguishing component is discharged to the side discharge port located on the side of the cylindrical automatic fire extinguishing device, the aerosol is effectively released to a larger space, so that the fire suppression is more effective and automatic. When designing and manufacturing the fire extinguishing device, by forming a discharge port on the side, the discharge area of the extinguishing gas can be freely controlled without being limited to the size of the electric device. This makes it possible to realize a very small, thin and long automatic fire extinguishing device.

In addition, according to the present invention, even if the wire used in the detonator is short-circuited by the fuse set of the cable assembly to open the circuit, even if the protection signal output of the control unit can be protected, the existing control unit or to solve the short circuit problem in the detonator Since the detonator only needs to replace the existing cable assembly, there is an effect that the short circuit problem in the detonator can be easily solved at a lower cost.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Rather, the embodiments introduced herein are provided to ensure that the disclosed subject matter is thorough and complete, and that the spirit of the present invention to those skilled in the art will fully convey.

The present invention operates the main body of the fire extinguishing device by transmitting the detonation signal to the detonator 200 when a fire signal is detected in the remote control unit (not shown in the drawing), to prevent the overcurrent flows to the control unit by a short circuit according to the operation. An electric fire extinguishing device. The automatic fire extinguishing device of the present invention includes a main body 300, the detonator 200 and the cable assembly 100.

1A is a cross-sectional view of an automatic fire extinguishing device according to an embodiment of the present invention. 1B is a cross-sectional view taken along line II ′ of FIG. 1A according to an example of the present invention.

1A and 1B, in the automatic fire extinguishing device main body 300 according to an embodiment of the present invention, an internal storage container 336 is inserted into a cylindrical external storage container 317. A plurality of discharge ports 334 are disposed at one side of the external storage container 317. The internal storage container 336 includes a perforated network 326 in a position overlapping the outlets 334. The internal storage container 336 contains a solid extinguishing agent 340 that generates an aerosol of the extinguishing component upon combustion. The solid extinguishing agent 340 is burned to generate a solid aerosol of the extinguishing component. An aerosol is referred to as an aerosol when particles in the solid or liquid state are present in the gas. The aerosol of the solid extinguishing component thus means that the solid extinguishing component particles are present in the gas. The solid extinguishing agent 340 may be a solid mixture including KNO ₃ , KClO ₄ , Ba (NO ₃ ) _2, and resins. In this case, preferably, the content of KNO ₃ is 27-42% by weight, the content of KClO ₄ is 28-43% by weight, the content of Ba (NO ₃ ) ₂ is 7-12% by weight and the content of the resins 16-25 wt%.

When the solid extinguishing agent 340 is burned, a solid extinguishing aerosol component containing a large amount of potassium (K) is generated. These ingredients are less harmful or harmless to the human body, do not cause significant damage to electronic equipment, are easy to handle residues after digestion, and are more environmentally friendly.

The solid extinguishing agent 340 is manganese dioxide, nickel oxide, copper oxide, iron oxide, surfactant, dibutyl phthalate, dibutyl sebazinat, acethenaglycerin, oleic acid, oleic acid, diamine dioleana lecithin, stearic acid, It may further include at least one selected from the group consisting of epoxide, unsaturated polyester resin, and rubber.

Specifically, the igniter 106 of the present invention may be a gunpowder composition including at least one selected from the group consisting of potassium nitrate, ammonium nitrate, charcoal, fuel oil, nitrogen oxides, perchlorates, saltpeter and sulfur.

Subsequently, a lower end portion 350 of the outer storage container 317 is located to seal the outer storage container 317 and to fix the inner storage container 336. An upper end cap 348 is positioned at an upper end of the external storage container 317 to seal the external storage container 317.

A coolant 328 is inserted between the perforated network 326 and the discharge port 334. The coolant 328 may be a solid mixture of at least one material selected from the group comprising MgCO ₃ , H ₃ BO ₂ , SiO _2, and CaSO ₄ 2H ₂ O. The coolant 328 may be in the form of, for example, spherical particles, as shown in FIG. 1A, thereby providing a space for gas to pass between the particles. The coolant 328 serves to cool the heat of combustion of the solid aerosol generated when the solid extinguishing agent 340 is burned. A mesh 322 having a mesh smaller than the size of particles of the outlet 334 and the coolant 328 is inserted between the coolant 328 and the outlet 334 so that the coolant 328 is discharged. Prevent escape through 334. The mesh 322 may be, for example, stainless steel wire mesh. The thin film 322 is inserted between the mesh 322 and the discharge port 334 to seal the moisture or foreign matter from entering. The thin film 322 may be, for example, a metal or resin thin plate.

On the other hand, there is a need for a detonator to burn the solid aerosol compound 340 in the event of a fire. The detonator is inserted and installed in the through part 311 of the main body, as shown in FIG. 1A, 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 controller to explode the initiator, ignite the igniter according to the explosion, and burn the solid aerosol compound 340 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 bi-metal switch 260 but also to the second terminal 202, and may include one end of the detonation signal (for example, a DC voltage or a ground voltage) when a fire occurs. Can be 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. Cable assembly 100 The sensor device may further include sensing wires 112 and 113 serving as a passage 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 and is 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.

The operation of the fire extinguishing device 300 for an automatic fire extinguishing device according to an embodiment of the present invention will be described.

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 340, which receives the heat of ignition from the igniter 240, is combusted, and the extinguishing gas generated while the solid aerosol compound 340 is combusted is cooled by the coolant 320 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 ignition agent 240, or the heat of combustion of the solid aerosol compound 340. 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 of the detonation wires 111 and 112, thereby disconnecting 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 an initiator signal. It is possible to prevent the part (the initiator signal output unit) from being broken.

And when solving the short circuit problem by improving the existing fire extinguishing device, according to the present invention, it is necessary to replace only the existing cable assembly without replacing the existing control unit or the detonator, so that the short circuit problem in the detonator There is an effect that can be easily solved at a low cost.

1A is a side view of a main body and a cable assembly of an electrically operated solid aerosol automatic fire extinguishing device according to an embodiment of the present invention.

1B is a cross-sectional view taken along line II ′ of FIG. 1A according to an example 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 invention.

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

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

Figure 6 shows the automatic fire extinguishing device according to an embodiment of the present invention is mounted in the switchboard to operate when a fire occurs.

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

31 Receptacle 32 Separator

33 Top cover 34 Bottom cover

34A ... Extinguishing 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 311 ... through

317 External storage containers 322 Thin film

326.Temp 328.Refrigerants

330 Mesh 334 Outlet

336 Internal Storage Container ... 338 Space

340.Solid aerosol compound 348.Top cap

350 bottom cap

Claims (10)

An outer storage container having a closed cylindrical shape and including a side outlet formed on at least one side thereof; An internal storage container located in the external storage container, the internal storage container including a perforated network on at least one side; A coolant interposed between the perforated network and the side outlet; A solid extinguishing agent inserted into the internal storage container to generate an aerosol of the extinguishing component upon combustion; Located on the top or bottom of the outer storage container, the igniter to ignite the solid extinguishing agent; And One end to ignite the igniter is electrically connected to the control unit and the other end is electrically operated ignition operation means electrically connected to the detonator; Solid aerosol automatic fire extinguishing device comprising a. The method of claim 1, The electrically operated ignition operation means, A cable assembly for an electric solid aerosol automatic fire extinguishing device having at least a function of transmitting a detonation signal for operating the detonator 200 from the controller to the detonator 200, A cable (110) including at least two or more initiator wires (111, 112) that serve as a passage through which the initiator signal flows to operate the initiator (200); And 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; Solid aerosol automatic fire extinguishing device comprising a. The method according to claim 1 or 2, And said perforated network and said side outlet are overlapped with each other. The method according to claim 1 or 2, And a mesh interposed between the coolant and the side outlet, the mesh having a mesh smaller than the pore size of the side outlet. The method of claim 4, wherein And said mesh is a stainless steel wire mesh. The method of claim 5, wherein Solid-state aerosol automatic fire extinguishing device further comprises a thin film interposed between the side outlet and the mesh. The method of claim 6, The thin film is a solid aerosol automatic fire extinguishing device, characterized in that the metal or resin thin plate. The method according to claim 1 or 2, The solid extinguishing agent is a solid aerosol automatic fire extinguishing device, characterized in that the solid mixture containing KNO ₃ , KClO ₄ , Ba (NO ₃ ) ₂ and resins. The method of claim 8, The content of KNO ₃ is 27 to 42% by weight, the content of KClO ₄ is 28 to 43% by weight, the content of Ba (NO ₃ ) ₂ is 7 to 12% by weight and the content of the resin is 16 to 25% by weight. Solid aerosol automatic fire extinguishing device, characterized in that%. The method according to claim 1 or 2, The coolant is a solid aerosol automatic fire extinguishing device, characterized in that one or two or more solid mixtures selected from the group consisting of MgCO ₃ , H ₃ BO ₂ , SiO ₂ and CaSO ₄ 2H ₂ O.

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