KR102156833B1 - Telecommunication box using Internet of Things - Google Patents

Abstract

The present invention relates to a communication terminal box using Internet of things. According to the present invention, the communication terminal box using Internet of things comprises: a box body having an internal accommodation space; a transparent acrylic plate; a fire-fighting tank in which carbon dioxide is compressed and stored; a hollow transfer pipe; a solenoid valve; a spray pipe; a spray nozzle; and a communication module. According to the present invention, communication equipment can be protected from a fire.

Description

Communication box using Internet of Things {Telecommunication box using Internet of Things}

The present invention relates to a communication terminal box, and in particular, to a communication terminal box utilizing the Internet of Things capable of protecting communication equipment embedded in an interior wall of a building from fire.

In general, a communication terminal box refers to an enclosure equipped with a door that can be opened and closed for maintenance by installing communication equipment that controls TV cables, Internet communication cables, telephone communication cables, and home network related communication cables, etc. do.

Such a communication terminal box is installed in the form of a case exposed to the outside or in the form of a concrete buried in the inner wall of the interior during construction or remodeling of a building, and the installation and maintenance of communication equipment is performed using the opening door opened to the outside. Is done.

On the other hand, a fire alarm system is installed in the building to reduce human damage in case of fire. Such a fire alarm system automatically detects a fire through a detector that detects heat, smoke, and flame generated by a fire, or when a predetermined transmitter is manipulated by a fire detector, an alarm device such as an alarm, a siren or an indicator light. It is a system that generates an alarm to the relevant person or occupant in the building.

In the conventional fire alarm system, since wired signal cables must be individually installed in a building, there is a problem that excessive installation costs are required.

In addition, the conventional fire alarm system simply outputs a fire signal detected by a detector through sound or light, and there is a problem in that it cannot prevent damage to the communication terminal box due to a fire.

Korean Registered Patent Publication No. 10-1504935 (announced on March 23, 2015)

The object of the present invention conceived to solve the above-described problem is that when a fire sensor detects a fire in a building, carbon dioxide is injected into the communication terminal box embedded in the interior wall of the building, so that external flames flow into the communication terminal box. It is to provide a communication terminal box using the Internet of Things that can protect the communication equipment accommodated in the communication terminal box from fire by blocking in advance.

In addition, the subject of the present invention is to prevent the inflow of flames into the communication terminal box by blocking the opening by unwinding the flame retardant film from the injection pipe installed in the opening of the communication terminal box when a fire occurs in the building, thereby preventing the communication equipment housed in the communication terminal box. It is to provide a communication terminal box using the Internet of Things that can protect from fire.

The present invention conceived to achieve the above object is a communication terminal box utilizing the Internet of Things, an internal accommodation space is provided, an opening with an open front is formed, a through hole is formed in the upper outer surface, and the internal accommodation Communication equipment is installed in the space, a box-shaped enclosure inserted into the interior of the buried space formed on the interior wall of the building, an acrylic plate made of a transparent material that is bolted to the front of the enclosure to shield the opening formed in the front of the enclosure, A fire-fighting tank installed inside the buried space where carbon dioxide is compressed and stored therein, and a hollow transfer pipe that receives carbon dioxide stored in the fire-fighting tank and transfers the carbon dioxide downward to the enclosure, and the end thereof is connected to a through hole formed in the enclosure , A solenoid valve that is provided in the transfer pipe to block the transfer of carbon dioxide, but interlocks with a fire sensor installed inside the building to enable the transfer of carbon dioxide, the inner upper part of the opening in a form that crosses the interior of the housing An injection pipe installed horizontally at one end and connected to a through hole formed in the enclosure to receive carbon dioxide transferred to the enclosure, and a plurality of installed along the outer diameter surface of the injection pipe to receive the carbon dioxide supplied to the injection pipe inside the enclosure And a communication module that wirelessly connects the spray nozzle spraying into the space and the fire sensor and the solenoid valve to wirelessly transmit a fire signal detected through the fire sensor to the solenoid valve.

Both ends of the injection pipe are rotatably coupled to the upper inner surface of the enclosure, one end connected to the through hole is opened and the other end is formed in a hollow shape, and the upper end is fixed to the outer diameter of the injection pipe. The flame-retardant membrane wound in the form of a roll on the outer diameter of the injection pipe in the state that the flame-retardant film wound on the injection pipe is mounted on the outside of the injection pipe in a form that encloses the flame-retardant film so that it is not unwound from the injection pipe, and an internal accommodation space is provided. , Includes a hollow air pack filled with powdered fire extinguishing agent inside the accommodation space, and when the air pack is melted and burned by heat above a certain temperature, the powder fire extinguishing agent filled inside flows to the outside and at the same time is wound around the injection pipe. The flame retardant film is unwound from the injection pipe to shield the opening.

At the lower end of the flame retardant film, a metal material having a conductive property is mounted, and a magnet is provided on the inner bottom surface of the enclosure, and when the flame retardant film is unwound from the spray pipe, the lower end of the flame retardant film is attached to the inner bottom surface of the enclosure by magnetic force. It is characterized by being.

A contact sensor interlocked with the solenoid valve is mounted on the inner bottom surface of the housing, and a contact signal detected by the contact sensor is wirelessly transmitted to the solenoid valve by wirelessly connecting the contact sensor and the solenoid valve through the communication module. , When the metal material of the flame retardant film attached to the inner bottom surface of the enclosure comes into contact with the contact sensor, the solenoid valve is opened and carbon dioxide is sprayed through the spray nozzle of the injection pipe, and the powder extinguishing agent discharged from the air pack It is characterized in that it diffuses into the interior accommodation space of.

In the present invention, when a fire sensor detects a fire in a building, carbon dioxide is sprayed into the interior of the enclosure installed inside the interior wall of the building, thereby preventing the inflow of external flames into the interior of the interior of the interior of the interior of the enclosure. There is an effect that can protect against.

In addition, in the present invention, when a fire occurs in a building, the flame retardant film is unwound from the injection pipe installed in the opening of the enclosure to shield the opening, thereby preventing the inflow of flame into the interior of the enclosure to protect the communication equipment contained inside the enclosure from fire. It can have an effect.

1 and 2 are exploded perspective views showing a communication terminal box utilizing the Internet of Things according to an embodiment of the present invention;
3 is a front sectional view showing a communication terminal box using the Internet of Things according to an embodiment of the present invention;
4 is a block diagram showing a connection relationship between the configuration of a communication terminal box using the Internet of Things according to an embodiment of the present invention;
5 to 7 are exemplary views showing a communication terminal box using the Internet of Things according to another embodiment of the present invention;
8 and 9 are partial cross-sectional views showing a communication terminal box using the Internet of Things according to another embodiment of the present invention;
10 is a block diagram showing a connection relationship between configurations of a communication terminal box using the Internet of Things according to another embodiment of the present invention.

Hereinafter, a preferred embodiment of a communication terminal box utilizing the Internet of Things according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are exploded perspective views illustrating a communication terminal box using the IoT according to an embodiment of the present invention, and FIG. 3 is a front cross-sectional view showing a communication terminal box using the IoT according to an embodiment of the present invention, and FIG. 4 is a block diagram showing a connection relationship between configurations of a communication terminal box using the IoT according to an embodiment of the present invention.

1 to 4, the communication terminal box using the Internet of Things according to a preferred embodiment of the present invention is a case 100, an acrylic plate 200, a fire tank 300, a transfer pipe 400, a solenoid It consists of components including the valve 500, the injection pipe 600, the injection nozzle 700, and the communication module 800, which will be described in detail as follows.

The enclosure 100 is formed in a rectangular box shape, and an internal accommodation space is provided so that the communication equipment T is accommodated therein. In addition, the enclosure 100 has an opening 110 with an open front, and a through hole 120 is formed on an outer upper surface thereof.

The enclosure 100 is inserted and installed inside the buried space H formed on the interior wall of the building. At this time, even if the housing 100 is buried in the buried space H, the inside of the housing 100 is exposed by the opening 110 formed in the front of the housing 100, so the communication installed in the interior receiving space of the housing 100 There is an advantage of easy maintenance of equipment (T).

The acrylic plate 200 is made of a transparent plastic material so that the operator can easily observe the communication equipment T accommodated in the interior of the housing 100 from the outside. In addition, each corner of the acrylic plate 200 to shield the opening 110 formed in the front of the enclosure 100 is detachably fastened to the front edge of the enclosure 100 through a bolt B.

The fire fighting tank 300 is a tank in which carbon dioxide is compressed and stored. In addition, liquefied carbon dioxide obtained by compressing and cooling carbon dioxide to about 20 atmospheres is stored therein and installed inside the buried space H.

At this time, the fire tank 300 is preferably installed inside the buried space (H) while seated on the outer upper surface of the enclosure (100).

The transfer pipe 400 is in the form of a hollow, connected to the fire tank 300 and receives the carbon dioxide vaporized from the liquefied carbon dioxide stored in the fire tank 300 and transfers the carbon dioxide downward to the housing 100, the end of which is It is connected to the through hole 120 formed in (100).

The solenoid valve 500 controls the movement of fluid by opening and closing the valve according to an electrical signal, and is provided in the transfer pipe 400 to block the transfer of carbon dioxide.

At this time, the solenoid valve 500 is controlled to be operated so as to enable the transfer of carbon dioxide by interlocking with the fire sensor 10 installed in the interior of the building, and the transfer of the carbon dioxide transferred through the transfer pipe 400 is normally However, when smoke or flame is detected by the fire sensor 10, the solenoid valve 500 is operated to enable the transfer of carbon dioxide through the transfer pipe 400.

Here, the solenoid valve 500 corresponding to the fire sensor 10 may be controlled by the controller 900.

The injection pipe 600 is installed horizontally on the inner upper side of the front opening 110 of the enclosure 100 in the form of a hollow crossing the interior of the enclosure 100. In other words, one end from the inside of the housing 100 is connected to the through hole 120 formed in the housing 100 to receive the carbon dioxide guided into the inside of the housing 100.

A plurality of injection nozzles 700 are mounted along the outer diameter surface of the injection pipe 600, and serve to inject carbon dioxide supplied to the injection pipe 600 into the interior receiving space of the housing 100 at high pressure.

The communication module 800 serves to wirelessly connect the fire sensor 10 and the solenoid valve 500 so that a fire signal detected through the fire sensor 10 is wirelessly transmitted to the solenoid valve 500. In other words, the communication module 800 may include a wireless transmitter provided in the fire sensor 10 and a wireless receiver provided in the controller 900 that controls the solenoid valve 500.

That is, when a fire such as smoke or flame is detected by the fire sensor 10, a fire signal is generated and a fire signal is transmitted through the wireless transmitter, and the fire signal is received by the wireless receiver and the solenoid valve 500 is opened. The carbon dioxide flowing into the injection pipe 600 is injected into the interior receiving space of the enclosure 100 through the injection nozzle 700, so that the communication equipment T installed inside the enclosure 100 is damaged due to fire. It can be prevented in advance.

In addition, the fire signal detected by the fire sensor 10 may be received by the user terminal 1000 through a wireless communication network and displayed on the user terminal 1000.

Meanwhile, the injection pipe 600 is rotatably coupled to the upper inner surface of the housing 100 at both ends in the form of a hollow. One end of the injection pipe 600 connected to the through hole 120 formed in the enclosure 100 so that carbon dioxide flows into the interior of the injection pipe 600 is opened, and the other end is closed.

5 to 7 are exemplary diagrams showing a communication terminal box using the IoT according to another embodiment of the present invention.

Referring to FIGS. 5 to 7, the configuration further includes a flame retardant film 610 wound in the form of a roll on the outer diameter of the injection pipe 600 with the upper end fixed to the outer diameter of the injection pipe 600 Can be.

In addition, the flame retardant film 610 wound around the spray pipe 600 is wrapped around the flame retardant film 610 so that it is not unwound from the spray pipe 600, and an air pack 620 made of vinyl is mounted on the outside of the spray pipe 600. ) Can be included.

Here, the air pack 620 is provided with an internal accommodation space in the form of a hollow, and a powder fire extinguishing agent (F) is filled in the interior of the accommodation space.

That is, when a fire occurs in the interior of the building, the acrylic plate 200 shielding the opening 110 formed in front of the enclosure 100 melts and burns due to high temperature, thereby exposing the interior of the enclosure 100 Will occur.

When the interior of the enclosure 100 is exposed in this way, the communication equipment T installed inside the enclosure 100 is damaged due to fire. To prevent this, when the air pack 620 is melted and burned by heat above a certain temperature, the interior As the powdered extinguishing agent (F) filled in is leaked to the outside, the powdered extinguishing agent (F) spreads inside the enclosure 100 to protect the communication equipment (T) housed in the enclosure 100 from fire and at the same time The flame retardant film 610 wound around 600 is unwound from the injection pipe 600 to shield the opening 110 formed in the front of the enclosure 100, and the flame enters the interior of the enclosure 100 through the opening 110 It blocks you from doing.

8 is a partial cross-sectional view showing a communication terminal box using the Internet of Things according to another embodiment of the present invention.

Referring to FIG. 8, a metal material 611 having a conductive property may be further mounted on the lower end of the flame retardant film 610.

And, on the inner bottom surface of the opening 110 of the housing 100, a magnet 130 is provided and the flame retardant film 610 in the injection pipe 600 due to the heavy metal material 611 mounted on the lower end of the flame retardant film 610 ) Is unwound, the lower end of the flame retardant film 610 is attached to the inner bottom surface of the enclosure 100 by magnetic force. Accordingly, the flame retardant film 610 completely shields the opening 110 formed in the front of the housing 100 to seal the housing 100.

9 is a partial cross-sectional view showing a communication terminal box using the IoT according to another embodiment of the present invention, and FIG. 10 is a block showing a connection relationship between the configuration of a communication terminal box using the IoT according to another embodiment of the present invention Is also.

9 and 10, a contact sensor 140 interlocking with the solenoid valve 500 may be further mounted on an inner bottom surface of the opening 110 of the enclosure 100.

In other words, a contact signal sensed by the contact sensor 140 is wirelessly transmitted to the solenoid valve 500 by wireless connection between the contact sensor 140 and the solenoid valve 500 through the communication module 800.

That is, the communication module 800 may include a wireless transmitter provided in the contact sensor 140 and a wireless receiver provided in the controller 900 that controls the solenoid valve 500.

That is, when the contact sensor 140 detects the contact of the metal material 611 of the flame retardant film 610, a contact signal is generated and a contact signal is transmitted through the wireless transmitter, and the contact signal is received by the wireless receiver to receive the solenoid valve. Carbon dioxide flowing into the interior of the spray pipe 600 by opening 500 is sprayed into the interior receiving space of the enclosure 100 through the spray nozzle 700.

In addition, a contact signal detected by the contact sensor 140 may be received by the user terminal 1000 through a wireless communication network and displayed on the user terminal 1000.

In other words, when the metal material 611 of the flame retardant film 610 attached to the inner bottom surface of the enclosure 100 comes into contact with the contact sensor 140, the solenoid valve 500 is opened and the spray nozzle of the spray pipe 600 As carbon dioxide is sprayed through 700, the powdered fire extinguishing agent F that flows out of the air pack 620 is diffused into the interior receiving space of the enclosure 100.

Here, the solenoid valve 500 corresponding to the contact sensor 140 may be controlled by the controller 900.

On the other hand, the controller 900, the fire signal detected by the fire sensor 10 installed in the interior of the building and the contact signal detected by the contact sensor 140 mounted on the inner floor surface of the housing 100, that is, two The solenoid valve 500 can be controlled to open only when a signal of is generated.

In the above, the present invention has been described based on a preferred embodiment, but the technical idea of the present invention is not limited thereto, and modifications or changes can be implemented within the scope described in the claims. It is obvious to the user, and such modifications or changes will fall within the scope of the attached claims.

10: fire breaker 100: enclosure
110: opening 120: through hole
130: magnet 140: contact sensor
200: acrylic plate 300: fire tank
400: transfer pipe 500: solenoid valve
600: injection pipe 610: flame retardant
611: metal material 620: air pack
700: spray nozzle 800: communication module
B: Bolt F: Powder fire extinguishing agent
H: Landfill space T: Communication equipment

Claims (4)

An internal accommodation space is provided, an opening with an open front is formed, a through hole is formed in the upper outer surface, and a communication device is installed in the internal accommodation space, and inserted into the interior of the buried space formed on the interior wall of the building. Box-shaped enclosure;
An acrylic plate made of a transparent material that is bolted to the front of the housing to shield the opening formed in the front of the housing;
A fire fighting tank installed inside the buried space and storing carbon dioxide compressed therein;
A hollow transfer pipe receiving the carbon dioxide stored in the fire fighting tank and transferring the carbon dioxide downward to the enclosure, the end of which is connected to a through hole formed in the enclosure;
A solenoid valve provided in the transfer pipe to block the transfer of carbon dioxide, but interlock with a fire sensor installed indoors of the building to enable transfer of carbon dioxide;
An injection pipe installed horizontally on the inner upper side of the opening in a form crossing the interior of the enclosure, and having one end connected to the through hole formed in the enclosure to receive carbon dioxide transferred to the enclosure;
A spray nozzle that is mounted along an outer diameter surface of the spray pipe to spray carbon dioxide supplied to the spray pipe into the interior receiving space of the enclosure; And
A communication module that wirelessly connects the fire sensor and the solenoid valve to wirelessly transmit a fire signal detected through the fire sensor to the solenoid valve; Including,
The injection pipe has both ends rotatably coupled to the upper inner surface of the enclosure, and one end connected to the through hole is opened and the other end is formed in a hollow shape,
The flame retardant film wound in the form of a roll on the outer diameter of the spray pipe while the upper end is fixed to the outer diameter of the spray pipe, and the flame retardant film wrapped around the flame retardant film so as not to be unwound from the spray pipe. A hollow air pack mounted, provided with an internal receiving space, and filled with a powder fire extinguishing agent in the receiving space; Including,
Internet of Things, characterized in that when the air pack is melted and burned by heat of a certain temperature or higher, the powder fire extinguishing agent filled therein is discharged to the outside and the flame retardant film wound around the injection pipe is unwound from the injection pipe to shield the opening. Communication terminal box using delete The method of claim 1,
At the lower end of the flame retardant film, a conductive metal material is mounted,
A communication terminal box using the Internet of Things, characterized in that a magnet is provided on the inner bottom surface of the enclosure so that when the flame retardant film is unwound from the injection pipe, the lower end of the flame retardant film is attached to the inner bottom surface of the enclosure by magnetic force. The method of claim 3,
On the inner bottom surface of the housing, a contact sensor interlocked with the solenoid valve; Is mounted,
The contact sensor and the solenoid valve are wirelessly connected through the communication module, and a contact signal detected by the contact sensor is wirelessly transmitted to the solenoid valve,
When the metal material of the flame retardant film attached to the inner bottom surface of the enclosure comes into contact with the contact sensor, the solenoid valve is opened and carbon dioxide is injected through the spray nozzle of the injection pipe, and the powder extinguishing agent flowing out of the air pack is A communication terminal box using the Internet of Things, characterized in that it spreads in the internal accommodation space.

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