KR102379871B1 - Fire door for apartment house - Google Patents

Abstract

The present invention relates to a fire door for an apartment house, wherein the fire door can be safely operated. Moreover, the fire door comprises: a ceramic pipe buried along a wall surface; a door frame for forming a frame moving path; a fire door for allowing cold air to be sprayed to the door frame; a hinge axis; a door temperature sensor for checking a temperature; and a controller for controlling a temperature and intensity of the cold air.

Description

Fire door for apartment house

The present invention relates to a fire door for an apartment house, and more particularly, when a fire occurs, depending on the temperature applied to the fire door, the cold air supplied through a ceramic pipe to the inside of the door frame and the fire door, respectively, and the fire by double or triple insulation It relates to a fire door for an apartment house that can provide a safer shelter while preventing the spread and damage of

In general, fire doors allow people to pass through, but they are designed to prevent the penetration of flames in case of fire, and play an important role in preventing fire damage.

These fire doors are very important facilities to minimize the spread of flames in case of a fire and secure an evacuation route, and inspection is mandatory at regular intervals.

In general, a fire door is a structure such as an entrance door or an emergency door installed to prevent a fire from spreading to the other side in a house, apartment, factory, office, or prefabricated temporary building.

Most of such fire doors include a rectangular door frame installed through a wall, and a door in which one side is coupled to the door frame by a coupling means such as one or more hinges while being sandwiched between the door frames.

In addition, each protruding handle is installed on the front and rear surfaces of the door, so that the user holds the handle and opens or closes the door by flipping it.

In addition, either the front or rear side of the door has a protruding sill along the edge to cover the space between the door frame and the neighboring door frame when the door is closed. The door can only be tilted in one direction.

The door frame and the fire door including the door are made of a heat-resistant metal material so that deformation or loss due to fire does not occur.

In addition, the fire door has a built-in insulating material inside in order to perform the same insulating function as a general window when it is not a fire.

However, a fire door made of metal has high thermal conductivity, so there is a limit in blocking the heat transmitted through the contact path between the panels, no matter how much insulating material is embedded inside.

In addition, insulation materials are vulnerable to high temperatures, so they are easily lost and deformed in case of fire. .

In order to solve the problem of heat conduction between panels of the fireproof door, a separate frame construction has to be carried out in the past, and the entire door and door frame have to be completely replaced.

Therefore, there is a need for a fire door having a structure that can secure excellent airtight performance in ordinary times, and is strong against high temperatures and has excellent heat shielding properties, especially in case of fire.

In the fire door of Registered Patent No. 2181203 (November 16, 2020), in a configuration consisting of a door frame, a door, an upper pin hinge, and a lower pin hinge, heat conduction between the panels of the fire door or door frame is blocked to ensure thermal insulation performance, In the event of a fire, it is possible to block the rapid and large amount of gas leaking from the combustion of the insulating material inside the door.

That is, the door inner panel and the outer panel are spaced apart, with a heat insulating material interposed therebetween, and a double insulation structure having a heat-shielding perforation is applied to the door frame side in a double packing method. It is designed to effectively block heat.

However, the fire door in the prior art has a problem in that it is very difficult to manufacture as well as have a limit in insulation.

(Document 1) Registered Patent No. 10-2181203 (Document 2) Registered Patent No. 10-1705626

Accordingly, the present invention is to solve the above problems, and the present invention is to make the heat applied to the door cooled by the cold air of the air conditioner passing through the inside of the door when a fire occurs, thereby making the evacuation space more secure with a safer evacuation through the fire door. Its main purpose is to provide a fire door for an apartment house that can be safely protected.

Another object of the present invention is to provide a fire door for an apartment house in which the supply speed of cold air from an air conditioner is automatically adjusted according to the temperature of the heat delivered to the door.

A fire door for an apartment house according to the present invention for achieving the above object includes: a ceramic pipe for supplying cool air from an air conditioner while being buried along a wall; a door frame having a ceramic pipe connected to the upper part, and forming a mold movement path so that cold air circulates therein to the lower surface through the upper surface and both sides; An inner panel and an outer panel that are rotatably supported at an upper end and a lower end of the door frame from one side and are spaced apart from each other by a predetermined width, a heat-resistant plate joined to inner surfaces of the inner panel and the outer panel, and the inner panel; A central diaphragm provided between the outer panels to separate the inner and outer spaces, and the space between the heat-resistant plate and the central diaphragm are separated in multiple stages in a vertical direction, and each separated space is alternately communicated between the opposite ends and a guide diaphragm forming a cooling passage so that cold air can move downward in a zigzag shape from the top, and the heat-resistant plate, the central diaphragm, and the guide diaphragm are made of a non-combustible and heat-insulating material coupled to each other, the inner panel and the outer panel On the side surface of which the periphery is bent to a certain width, the inner panel and the outer panel are spaced apart by a certain width between the bent ends of the outer panel, and heat transfer between the panels is blocked by the guide diaphragm on the outside, and a certain width between the ends of the panels on both sides The exposed side surface is covered by the guide diaphragm, and fine spray holes are formed at regular intervals along the side surface of the guide diaphragm so that the cold air flowing through the internal cooling passage is sprayed onto the door frame. ; The fire door is rotatably supported with respect to the door frame, and the center is vertically penetrated, and the upper shaft is partially inserted into the upper surface side frame movement path of the door frame and the upper side cooling passage of the fire door, The lower shaft is a hinge shaft that is partially inserted into the lower side cooling passage of the fire door and the lower surface side frame movement path of the door frame to supply and discharge cold air from the air conditioner to the fire door; a door temperature sensor to be installed on an inner panel and an outer panel of the fire door, respectively, to check each temperature when a fire occurs; It is configured as a controller to automatically operate the air conditioner at a temperature higher than a certain temperature according to the temperature detected by the door temperature sensor, and to adjust the temperature and intensity of cold air according to the detected temperature change.

A first cold air distributor is formed in a portion where the upper shaft of the hinge shaft of the fire door is connected, so that the cold air is selectively supplied to the inner panel or the outer panel side by the controller or can be simultaneously supplied.

A second cold air distributor is formed on the lower surface of the door frame so that the cold air collected from the frame movement path of the door frame and the cooling passage of the fire door is discharged to the fire generating space by the controller.

As described above, by the fire door for apartment houses according to the present invention, when a fire occurs, the cold air generated from the air conditioner that automatically operates the heat applied to the fire door is supplied to the fire door together with the door frame so that it is forcibly cooled. With evacuation, the fire door can be operated more safely.

In addition, the present invention enables the fire to be extinguished more quickly by preventing the spread of fire through the fire door at its source.

1 is a front sectional view illustrating a schematic configuration of a fire door for an apartment house according to the present invention;
2 is a side cross-sectional view of a fire door for an apartment house according to the present invention;
3 is a partially enlarged perspective view illustrating a side surface of a fire door for an apartment house according to the present invention;
4 is an enlarged cross-sectional view illustrating a configuration for forming a first cold air distributor in a fire door for an apartment house according to the present invention;
5 is an enlarged cross-sectional view illustrating a configuration for forming a second cold air distributor in a fire door for an apartment house according to the present invention;
6 is an operation state diagram for cooling the door frame and the fire door by the movement of cold air by the fire door for an apartment house according to the present invention;
7 is an operational state diagram illustrating an operation structure for cooling the door frame through a cooling passage and a fine spray hole formed in the fire door in the fire door for an apartment house according to the present invention;

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily carry out the present invention.

The scope of the present invention should not be construed as being limited by the embodiments described herein.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the description of the embodiments, the same reference numerals are assigned to the same components, and in some cases, the descriptions of the same reference numerals will be omitted.

1 is a front cross-sectional view illustrating a schematic configuration of a fire door for an apartment house according to the present invention, and FIG. 2 is a side cross-sectional view of a fire door for an apartment house according to the present invention.

As illustrated, the present invention is largely composed of a ceramic pipe 10 , a door frame 20 , a fire door 30 , a hinge shaft 40 , a door temperature sensor 50 , and a controller 60 .

The ceramic pipe 10 is a configuration that allows the cold air generated from the air conditioner (not shown) to flow safely, and is buried along the wall. One end is connected to the cold air supply port of the air conditioner, and the other end is the door frame 20 . is connected to the top of

The air conditioner in the present invention is most preferably formed as a system air conditioner, and may be supplied with cold air from such a general air conditioner, but may be provided separately so that cold air is supplied.

The door frame 20 connected to the ceramic pipe 10 includes an upper surface 21 , a lower surface 22 and both sides 23 , and the ceramic pipe 10 is connected to one side of the upper surface 21 , and , so that the mold movement path 24 is formed from the upper surface 21 together with the upper surface 21 to the lower surface 22 through the both sides 23 and the cold air supplied through the ceramic pipe 10 is the door frame It allows the door frame 20 to be cooled while flowing inside the 20 .

When there is no lower surface 22 of the door frame 20, the cooling passages 24 are formed only from the upper surface 21 to both sides.

A fire door 30 is pivotally supported on the door frame 20 to be rotatable from one side.

The fire door 30 is composed of an inner panel 31 and an outer panel 32 that are spaced apart from the outside by a predetermined width, and the inner surface of the inner panel 31 and the outer panel 32 has an inner surface of a predetermined thickness, respectively. Central diaphragms 34 are provided in parallel to each other so that the heat plates 33 are joined, and the inner space is divided so that a space of a certain width is formed on both sides between the heat-resistant plates 33 on both sides, and these central diaphragms ( Between the heat-resistant plates 33 and the central diaphragm 34 on both sides of the space on both sides of 34), the guide diaphragm 35 forming the cooling passage 36 in a zigzag shape gradually moving downward in one direction between both sides is mutually coupled. make it possible

At this time, the outer peripheral ends of the inner panel 31 and the outer panel 32 are bent in a direction opposite to each other by a predetermined width, and a predetermined width is spaced between the bent ends of both sides, and the spaced between the bent ends The side surface 37 of the fire door 30 is formed by being covered with the guide diaphragm 35 .

Accordingly, the fire door 30 is formed externally by the inner panel 31, the outer panel 32, and the outer side surface 37, and the inside is formed by the heat-resistant plates 33 on both sides and the heat-resistant plate 33 ) and the central diaphragm 34 that bisects the space between the central diaphragm 34 and the heat-resistant plates 33 on both sides around the central diaphragm 34 in a vertical direction, while each separated space is at the opposite end It is configured such that the guide diaphragm 35 forming the cooling passage 36 is integrally coupled to each other so that the cold air can move downward in a zigzag shape from the upper portion to alternately communicate.

At this time, it is most preferable that the heat-resistant plate 33 , the central diaphragm 34 , and the guide diaphragm 35 forming the inside are made of a non-combustible and heat-insulating material such as ceramic.

The heat-resisting plates 33 on both sides perform an insulating function to prevent heat due to fire generated inside or outside the fire door 30 from being transferred to the opposite side, and at the same time, the central partition plate 34 is re-attached from the inside. The insulation is made so that two to three layers of insulation are made, and the cooling passages 36 that allow the cooling air of the air conditioner to move to both sides are formed by the guide diaphragms 35 .

However, along the side surfaces 37 of the bent surfaces of the inner panel 31 and the outer panel 32 on both sides and the guide diaphragm 35 provided between the bent ends, as shown in FIG. 3, internal cooling The fine jetting holes 38 that pass through the passage 36 are formed at regular intervals, so that cold air is sprayed through the fine jetting holes 38 to the inner surfaces of the door frames 20 facing each other.

The fire door 30 has an upper end and a lower end of one side to be rotatably supported by the door frame 20 , and a hinge shaft 40 is provided as a means for pivoting in this way.

The hinge shaft 40 is composed of an upper shaft 41 and a lower shaft 42 , and the upper shaft 41 is the upper side of the upper surface side frame movement path 24 of the door frame 20 and the upper side of the fire door 30 . Each part is provided to be inserted into the cooling passage 36, and the lower shaft 42 is the lower side cooling passage 36 of the fire door 30 and the lower surface 22 side of the door frame 20 side frame movement path ( 24) is formed to be partially inserted.

The upper shaft 41 and the lower shaft 42 of the hinge shaft 40 have the center vertically penetrating, respectively, so that cold air flowing in through the frame movement path 24 on the upper surface 21 side of the door frame 20 is provided. It is moved to the frame movement path 24 on the lower surface 22 side of the door frame 20 through the cooling passage 36 of the fire door 30 .

In addition, the door temperature sensor 50 is provided on the inner panel 31 and the outer panel 32 of the fire door 30 to check the temperature transmitted to each panel when a fire occurs, respectively.

It is more preferable that the door temperature sensor 50 is formed inside the fire door 30 to check the temperatures of the inner panel 31 and the outer panel 32 .

In this way, the controller 60 is provided to control the temperature and intensity of cold air sent from the air conditioner while automatically operating the air conditioner at a temperature higher than a certain temperature according to the temperature sensed by the door temperature sensor 50 .

On the other hand, in the present invention, the first cold air distributor 70 is provided at the portion where the upper shaft 41 of the hinge shaft 40 of the fire door 30 is connected, as shown in FIG. The cold air may be selectively supplied to the inner panel 31 or the outer panel 32 side of the door 30 or may be supplied simultaneously.

In addition, the second cold air distributor 80 is formed on the lower surface 22 of the door frame 20 as shown in FIG. 5 to cool the frame movement path 24 of the door frame 20 and the fire door 30 . The cold air collected from the passage 36 may be discharged to the space where the fire occurred by the controller 60 .

The operation and effect of the fire door structure for a fire door for an apartment house of the present invention according to the configuration as described above will be described in more detail as follows.

The present invention is configured to be applied as an entrance door or emergency door installed to prevent the spread of fire in a building.

According to the present invention, the temperature signal detected from the door temperature sensor 50 formed on the inner panel 31 and the outer panel 32 of the fire door 30 is checked by the controller 60 and the air conditioner is automatically activated only when the temperature is higher than the set temperature. make it run

When the air conditioner is driven, cold air is generated, and the cold air is supplied through the ceramic pipe 10 formed along the wall surface.

At this time, the air conditioner changes the temperature of the cold air and the discharge rate of the cold air according to the temperature sensed by the door temperature sensor 50 .

That is, as the temperature sensed by the door temperature sensor 50 increases, the cold air temperature is gradually lowered, and the cold air discharge rate is made faster.

Cold air generated from the air conditioner flows into the upper surface 21 of the door frame 20 through the ceramic pipe 10 as shown in FIG. 6 , and through the frame movement path 24 of the door frame 20 , the door frame The door frame 20 is cooled while moving to the lower surface 22 through both sides 23 of the 20 .

In addition, cold air is supplied to the fire door 30 from the upper surface 21 of the door frame 20 through the upper shaft 41 of the hinge shaft 40 .

The fire door 30 has cooling passages 36 formed on both sides with respect to the central diaphragm 34 as in FIG. 2, so that cold air is selectively or simultaneously supplied through the cooling passages 36 on both sides. The fire door 30 is forced to cool.

However, the fire door 30 is already provided with heat-resistant plates 33 on both sides of the inside, and a central diaphragm 34 is provided at the center, so that double or triple heat insulation is achieved. Even if the heat of the fire is in contact with one side of the , it is possible to prevent the heat from being transmitted to the other side at all.

In particular, as shown in FIG. 7 , cold air moving through the cooling passage 36 of the fire door 30 is sprayed to the side surface 37 through the fine injection hole 38 and the door frame facing the side surface 37 . Cold air is sprayed on the surface of (20) so that the mold moving path 24 is double cooled with cold air passing through the mold moving path 24.

In this way, the fire door 30 is cooled by the movement of cold air through the double or triple insulation and cooling passage 36 together with the door frame 20, thereby preventing the spread of fire in the event of a fire. Not only can it be provided, but it also has the effect of preventing deformation or damage to the fire door due to thermal contact.

As such, the present invention is not limited to the described embodiments, and it is apparent to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Accordingly, it should be said that such modifications or variations are included in the claims of the present invention.

10: ceramic piping
20: door frame
21: upper surface 22: lower surface
23: both sides 24: frame moving path
30: fire door
31: inner panel 32: outer panel
33: heat-resistant plate 34: central diaphragm
35: guide plate 36: cooling passage
37: side surface 38: fine injection hole
40: hinge shaft
41: upper shaft 42: lower shaft
50: door temperature sensor
60: controller
70: first cold air distributor
80: second cold air distributor

Claims (3)

A ceramic pipe 10 that is buried along the wall to supply cold air from the air conditioner; The ceramic pipe 10 is connected to the upper part, and the door frame 20 forms a mold movement path 24 so that cold air circulates therein to the lower surface 22 through the upper surface 21 and both side surfaces 23;
The inner panel 31 and the outer panel 32, the inner panel 31 and the outer panel 32 are rotatably supported at the upper end and the lower end of the door frame 20 from one side and are provided to be spaced apart by a predetermined width. ), a heat-resistant plate 33 joined to the inner surface of the central diaphragm 34 provided between the inner panel 31 and the outer panel 32 to separate inner and outer spaces, and the heat-resistant plate 33 ) and the central diaphragm 34 are separated in multiple stages in the vertical direction, and each separated space is alternately communicated between the opposite ends of the cooling passage 36 so that cold air can move downward in a zigzag shape from the top. consists of a guide diaphragm 37 forming On the side surface 37 of the panel 32 bent to a predetermined width, the inner panel 31 and the bent end of the outer panel 32 are spaced apart by a predetermined width by the outer guide partition plate 35 . The heat transfer between the two sides is blocked, and the side surfaces 37 exposed to a predetermined width between the ends of the panels on both sides are covered by the guide partition plates 35 while being constant along the side surfaces 37 of the guide partition plates 35 . a fire door 30 for spraying the cold air flowing through the internal cooling passage 36 to the door frame 20 by forming fine injection holes 38 at intervals;
The fire door 30 is rotatably supported with respect to the door frame 20 and the center is vertically penetrated, and the upper shaft 41 moves the frame on the upper surface 21 side of the door frame 20 . A portion is respectively inserted into the furnace 24 and the upper cooling passage 36 of the fire door 30 , and the lower shaft 42 is connected to the lower cooling passage 36 of the fire door 30 and the door frame. a hinge shaft 40 for supplying and discharging cold air from the air conditioner to the fire door 30 while being partially inserted into the frame movement path 34 on the lower surface 22 side of (20);
a door temperature sensor 50 for checking each temperature when a fire occurs by being installed on the inner panel 31 and the outer panel 32 of the fire door 30, respectively;
a controller 60 for automatically operating the air conditioner above a certain temperature according to the temperature detected by the door temperature sensor 50 and adjusting the temperature and intensity of cold air according to the detected temperature change;
Fire doors for apartment houses made of
The method according to claim 1,
A fire door for an apartment house in which a first cold air distributor is formed in a portion where the upper shaft of the hinge shaft of the fire door is connected, so that the cold air is selectively supplied to the inner panel or the outer panel side by the controller or at the same time.
The method according to claim 1,
A fire door for an apartment house for discharging the cold air collected from the frame movement path of the door frame and the cooling path of the fire door to the fire generating space by the controller by forming a second cold air distributor on the lower surface of the door frame.

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