KR20190114071A - Automatic fire extinguisher, its manufacturing method and molded body - Google Patents

Abstract

Disclosed are an automatic fire extinguishing agent for initial fire extinguishing and a manufacturing method. According to the present invention, the automatic fire extinguishing agent for initial fire extinguishing comprises: a plurality of capsule fire extinguishing agents provided by encapsulating a fire extinguishing agent; a liquid fire extinguishing member mixed with the capsule fire extinguishing agents to apply the capsule fire extinguishing agents; and a thickener inputted to the fire extinguishing member to maintain the fire extinguishing member with predetermined viscosity.

Description

AUTOMATIC FIRE EXTINGUISHER, ITS MANUFACTURING METHOD AND MOLDED BODY}

The present invention relates to an automatic fire extinguishing agent for early fire extinguishing, a manufacturing method and a molded article, and more particularly, a short circuit in a closed enclosure such as a switchgear, a switchgear, a distribution board, a poor insulation, surface damage, overheating of terminals and contacts, The present invention relates to an automatic fire extinguishing agent, a manufacturing method, and a molded article for initial fire extinguishing which is automatically performed within a few seconds immediately after a fire occurs due to cracks and breakage of a support insulator, chemical deterioration, and physical change.

The switchgear, switchboard, distribution board, etc. is a device that is supplied with power and distributes power, most of which is composed of a closed enclosure.

In such a case, due to a short circuit, insulation failure, surface damage, overheating of terminals and contacts, cracks and breakage of support insulators, chemical degradation, physical changes, etc. Can lead to

According to the statistical analysis of electrical accidents of the Korea Electrical Safety Corporation, among the 803 fires in 2014, 363 fires in switchboards and distribution boards accounted for 45% of accidents in electrical installations, accounting for the highest proportion of electric fires. This is a neglected situation.

The reason for this is that there are devices such as a deterioration monitoring device, a heating sensor, and an infrared sensor for a switchboard, but there is a problem with post management such as a manpower for checking and monitoring a mechanical failure as well as an expensive equipment cost burden. Because the fire is rapidly spreading instantaneously, there is a phenomenon that the initial evolution does not occur due to a lot of fire progressing from detection to extinguishing, and thus is rejected by users.

In addition, there are various types of automatic fire extinguishing devices, but especially in switchboard and switchgear enclosures, transformers, low voltage, high voltage, extra high voltage switches, circuit breakers, uninterruptible power supplies, auxiliary power supplies, inverters, converters, automatic regulators, rectifiers, Dozens of electric devices such as control panels, condensers, and electric wires are densely packed, so it is impossible to install each electric device in a narrow space.

In order to solve such a problem, Korean Patent No. 10-1651658 discloses an automatic fire extinguisher and its manufacturing method. In this prior art, the extinguishing agent is applied to the fire detection member or epoxy resin mixture of the HFC-based fire extinguishing gas on the nonwoven fabric, and then hardens the extinguishing member to form an adhesive layer in the form of a double-sided tape on the back of the nonwoven fabric. It is effective when the inside of the enclosure is made of space, but inside the enclosure is filled with breakers, terminals, wires, etc., in case of fire at the lower part of the enclosure, the fire extinguisher pad with the heat on top is extinguished. It takes tens of seconds to reach the temperature for operation, which is not enough for early evolution.

In addition, small size distribution boards have some effects, but enclosures such as switchboards and switchboards are large.In the case of transformers and electrical equipment, the interior of the enclosure is full, so the heat of fire reaches the upper side after a considerable time. Fire extinguishing time is long and extinguishing action is caused by the production of fine gas. Therefore, if there is a certain distance or more (approximately 30cm), or if there are obstacles between electrical devices such as breakers between the fire department and the fire extinguishing pad, the extinguishing effect is rapidly increased. There is a disadvantage of deterioration.

In addition, there is paint or spray method, but inside the switchboard in use, the viscosity is thin, so it may flow down after construction and the coating thickness cannot be thickened, so it is not extinguishable at once, and when the flame proceeds to the second and third consecutively Since the extinguishing agent is thinned and the extinguishing agent is consumed due to the primary extinguishing action, there is a problem of low practicality.

In addition, since most of these methods use flame-retardant epoxy as a member, it is a two-component method that mixes the main material and the member (curing agent) before use and cures after several hours by chemical reaction after use. There are disadvantages.

In addition, the automatic fire extinguishing system switchboard disclosed in Korean Utility Model Registration No. 20-0484274 can store a large amount of extinguishing agent, which is more effective than the extinguishing agents described above. There is a disadvantage that the upper time must pass.

The above-described technical configuration is a background art for helping understanding of the present invention, and does not mean a conventional technology well known in the art.

Korean Registered Publication No. 10-1651658 (JD Industrial Co., Ltd.) 2016. 08. 22.

Fires in closed enclosures such as switchboards, switchboards, and distribution boards, which are not visible from the outside, can lead to large fires and cause large casualties that can result in personal injury due to explosion by compressed air.

In order to solve such a problem, an initial fire extinguishing should occur within a few seconds when a fire breaks out inside the switchboard enclosure to prevent the fire from progressing, and other electrical devices not related to the fire point should be free from damage caused by the extinguishing agent.

Including dozens of terminals interlocking dozens of electrical devices, including any leakage, defective insulation, surface damage, overheating of terminals and contacts, cracks and breaks of support insulators, chemical degradation, physical changes, etc. In order to place extinguishing agent that can extinguish within seconds without extinguishing device or apparatus, it should be possible to attach regardless of space, area, volume, device type, material, etc.

The fire extinguishing member should have high thermal conductivity or heat absorbing ability in order for fire extinguishing agent to be automatically operated by the contact temperature so that the fire heat can be conducted more quickly to the fire extinguishing agent cooled by the temperature decrease in winter.

The fire extinguishing member should be maintained at the desired thickness at the minimum distance from the expected point of ignition so that the user can adjust the thickness according to the location of use so that fire extinguishing is continuously performed even if the flame is repeated in the second and third times.

The fire extinguishing member is a one-component material capable of long-term storage, user convenience, and a simple manufacturing method, and provides an automatic fire extinguishing agent, a manufacturing method, and a molded article for the initial fire extinguishing requirement.

According to an aspect of the invention, a plurality of capsule extinguishing agent provided by encapsulating the extinguishing agent; A liquid extinguishing member mixed with the plurality of capsule extinguishing agents to apply the plurality of capsule extinguishing agents; And it may be provided to the automatic extinguishing agent for the initial fire comprising a thickener which is added to the extinguishing member to maintain the extinguishing member to a certain viscosity.

It may further include a thermally conductive additive added to the extinguishing member to guide the thermal conduction to the surface of the plurality of capsule extinguishing agent in the event of fire.

The fire extinguishing member may be added to the fire extinguishing member to further prevent the shape from being destroyed by heat. The plurality of capsule extinguishing agents may be provided in 9 to 12 layers.

The initial fire extinguishing agent may be stored and used in a storage tube.

In addition, according to another aspect of the present invention, by mixing a liquid extinguishing member in a plurality of capsule extinguishing agent and stirring the extinguishing member to be applied to the plurality of capsule extinguishing agent; Stirring by adding a thermally conductive additive and a flame retardant plasticizer to the extinguishing member; And a step of adding a thickener including silica to the extinguishing member to which the thermally conductive additive and the flame retardant plasticizer are added, and stirring the mixture until it reaches a predetermined viscosity.

Furthermore, according to another aspect of the present invention, there is provided a molded article of the initial extinguishing automatic fire extinguishing agent, characterized in that the initial extinguishing automatic extinguishing agent is provided by molding with a mold. Can be.

Embodiments of the present invention are capable of early extinguishing within seconds of a fire.

In addition, irrespective of the quantity of installation, all parts of the fire can be installed at a minimum distance, and there is no need for devices and devices for fire fighting operations.

Furthermore, there is no need for additional space or area for fire extinguishing equipment, and it can be installed in all parts at low cost, and can be installed by anyone simply and conveniently, and can be freely varied in width and thickness according to the type of equipment and the fire expectation range. It can be constructed.

1 is a view schematically showing a method for manufacturing an automatic fire extinguishing agent for an early fire according to an embodiment of the present invention.
Figure 2 is an enlarged view showing a state before mixing the capsule extinguishing agent applied to the automatic fire extinguishing agent for the initial embodiment of the present embodiment.
3 is a cross-sectional view of FIG. 2.
4 is a schematic state diagram of use of this embodiment.
Figure 5 is an exemplary view showing the use position of the present embodiment with an arrow.
Figure 6 is an embodiment of a molded body of the automatic fire extinguishing agent for the initial fire according to this embodiment.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a view schematically showing a method of manufacturing an automatic fire extinguishing agent for an initial fire extinguishing agent according to an embodiment of the present invention, and FIG. 2 is a state before mixing the capsule extinguishing agent applied to the initial fire extinguishing agent for the present embodiment. 3 is a cross-sectional view of FIG. 2, FIG. 4 is a schematic diagram illustrating a state of use of the present embodiment, and FIG. 5 is an exemplary diagram showing arrows of a use position of the present embodiment.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a view schematically showing a method for manufacturing an automatic fire extinguishing agent for an initial fire extinguishing agent according to an embodiment of the present invention, and FIG. 2 is a view showing a capsule extinguishing agent applied to an automatic fire extinguishing agent for an initial fire extinguishing agent of this embodiment. 3 is a cross-sectional view of FIG. 2, FIG. 4 is a schematic diagram illustrating a state of use of the present embodiment, and FIG. 5 is a diagram illustrating an example of a use position of the embodiment with arrows.

As shown in these figures, the initial fire extinguishing agent according to the present embodiment, a plurality of capsule extinguishing agent 10 provided by encapsulating the extinguishing agent and a plurality of capsules to apply a plurality of capsule extinguishing agent 10 A liquid extinguishing member 20 mixed with the extinguishing agent 10, a heat conductive additive added to the extinguishing member 20 to guide thermal conduction to the surfaces of the plurality of capsule extinguishing agents 10 during a fire, and a extinguishing member ( A flame retardant is added to 20) to prevent the extinguishing member 20 from being destroyed by heat, and a thickener is added to the extinguishing member 20 to maintain the extinguishing member 20 at a constant viscosity.

The plurality of capsule extinguishing agents 10 may be provided by encapsulating one selected from extinguishing medicines such as Novec 1230, HFC series, halon, inert gas, and CO ₂ .

In the present embodiment, the plurality of capsule extinguishing agents 10 may be inflated and destroyed at 80 to 120 degrees Celsius to extinguish gas by releasing extinguishing gas.

The extinguishing member 20 prevents wear of the plurality of capsule extinguishing agents 10 during production and use, prevents leakage of the extinguishing agent inside the capsule during long-term storage, and the plurality of capsule extinguishing agents 10 according to the use shape. It maintains the shape, and serves to adhere and fix the site.

Extinguishing member 20 in the present embodiment is excellent in adhesiveness, elasticity, elasticity, bendability, flexibility, etc., and can be selected from the liquid resin, such as water-soluble polyurethane or flame-retardant silicone, which is a liquid type and can be dried at room temperature.

The thermally conductive additive is for fast thermal conduction on the surface of the capsule extinguishing agent 10 in which the fire temperature is contained in the extinguishing member in case of fire. The thermally conductive additive is pulverized into high purity crystal silica or nano powder having good thermal conductivity. One kind can be selected from aluminum powder and the like.

The flame retardant plasticizer is an additive to prevent the extinguishing member 20 from being damaged or deformed by heat, and may be selected from chlorinated paraffins, phosphate esters, and the like.

The thickener may select one of fine crystal silica or aerosil-200 for thickening to reduce the flow rate of the liquid extinguishing member to maintain the shape in use.

This embodiment, as shown in Figure 4, can be stored and used in the storage tube 30, the storage tube 30 may be a known tubular container with good air blocking.

Hereinafter, the manufacturing method of the present embodiment will be briefly described.

First, in order to prevent wear of the plurality of capsule extinguishing agents 10 in the manufacturing process of the present embodiment, 50 to 30% by weight of the liquid extinguishing member 20 is mixed with 50 to 70% by weight of the plurality of capsule extinguishing agents 10. 20) is slowly stirred with a stirrer to be evenly applied to the entire capsule digestive agent (10).

5-10 wt% of each of the thermally conductive additive and the flame retardant plasticizer is added to the mixed weight ratio of the mixture, followed by stirring.

When used in the mixture described above, the applied shape is maintained without flowing down, and the viscosity becomes constant while stirring 3-10 wt% or more of silica (a kind of thickener) having no chemical change to cure. Slowly inject until

As described above, the mixed extinguishing agent mixture is injected into the storage tube 30 in the form of a toothpaste or a tube-type adhesive container, and sealed after packaging.

At this time, the theme of digestion is to use the encapsulated Novec 1230, produced by the US 3M company, which is known to be safe for the human body, has no pollution effect on other devices, emits no greenhouse gas, and is environmentally friendly. Can be.

At this time, the extinguishing member 20 can be used a water-soluble flame-retardant polyurethane liquid resin excellent in adhesion, good viscosity control.

In this case, the thermally conductive additive may use aluminum nanopowder without chemical change, and the flame retardant plasticizer may use chlorinated paraffins or phosphate esters.

In the present embodiment, the thickened silica may use 99.8% of silicon dioxide (sio2) as aerosol-200, which is a powder of 7-12 nm nano size.

And in the present embodiment, as shown in Figure 3, when applied to a thickness of 3mm capsule encapsulant 10 of about 9 to 12 layers can be arranged.

When the fire is in contact with the fire when the fire extinguishing member 20 is loosened by the heat to start the decomposition and the first to third layer capsule extinguishing agent 10 is destroyed, the initial fire is extinguished. When fire occurs in 2nd and 3rd time, fire extinguishing capsule arranged in 4 ~ 7 layers and 8 ~ 10 layers works. In the present embodiment, the thicker the thickness, the larger the number of fires can be extinguished early. Another expression is that when the initial fire is not extinguished and continuously fired, the extinguishing gas is continuously emitted until extinguishing. I can see it.

On the other hand, in this embodiment, as shown in Figure 4, after squeezing like a toothpaste on the use portion of the breaker 50 to dry at room temperature. When the automatic fire extinguishing agent of the present embodiment is applied to a large area, a fire extinguishing agent may be squeezed and rubbed with a ruler. Press it by hand and attach it.

And in Figure 5 the site of use of the embodiment is indicated by the arrow.

Experimental results of this embodiment are as follows.

After applying 3 g of the automatic fire extinguishing agent of the present embodiment to the wire 40 and turning on the lighter fire at a distance of 3 cm from the cured state, the fire was extinguished between 3 to 4 seconds in a room temperature of 18 degrees and 7 degrees in an outdoor temperature of 1 degree. Fire was extinguished between -10 seconds and later.

When the additive aluminum powder was added, the fire was extinguished between 1 and 2 seconds in a room temperature of 18 degrees, and fire was extinguished between 7 and 8 seconds in a room temperature of 1 degree.

This embodiment can be easily and effectively installed in the control box used for the mechanical equipment and the device or the power connection terminal area between the machine or the outdoor electrical equipment that can not be fire extinguishing.

As described above, the automatic fire extinguishing agent manufactured according to the present embodiment may be molded by a mold because of good viscosity, flexibility, moldability, and curability, and as shown in FIG. 6, for the wire molded body 60 or the breaker. Molding processing is possible depending on the shape of the use, such as the molded body 70, the molded body 80 for the battery of the smart device.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

10: capsule extinguishing agent
20: extinguishing member
30: storage tube
40: wires
50: breaker
60: wire molded body
70: molded body for breaker
80: molded body for battery

Claims (6)

A plurality of capsule extinguishing agents prepared by encapsulating a extinguishing agent;
A liquid extinguishing member mixed with the plurality of capsule extinguishing agents to apply the plurality of capsule extinguishing agents; And
The automatic fire extinguishing agent for the initial fire comprising a thickener is added to the extinguishing member to maintain the extinguishing member at a predetermined viscosity. The method according to claim 1,
The fire extinguishing agent for the initial fire extinguishing agent further comprises a heat conductive additive which is added to the extinguishing member and guides thermal conduction to the surfaces of the plurality of capsule extinguishing agents in case of fire. The method according to claim 2,
A flame retardant plasticizer added to the fire extinguishing member to prevent the fire extinguishing member from being destroyed by heat;
The plurality of capsule extinguishing agent is automatic fire extinguishing agent, characterized in that provided in 9 to 12 layers. The method according to claim 1,
The automatic fire extinguishing agent for the initial fire extinguishing, characterized in that it is stored and used in the storage tube. Mixing a liquid extinguishing member with a plurality of capsule extinguishing agents and stirring the extinguishing member with the plurality of capsule extinguishing agents;
Stirring by adding a thermally conductive additive and a flame retardant plasticizer to the extinguishing member; And
Method of producing an automatic fire extinguishing agent for the initial fire comprising the step of adding a thickener comprising silica to the extinguishing member to which the thermal conductive additive and the flame-retardant plasticizer is added until a certain viscosity. As a molded product of an early fire extinguishing agent,
A molded article of an initial fire extinguishing agent according to claim 1, wherein the initial fire extinguishing agent is prepared by molding with a mold.

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