KR102349022B1 - Fire protection door and its manufacturing method - Google Patents

Abstract

According to the present invention, one aspect of the present invention to achieve the above object may provide a prefabricated fire door having a thermal bridge prevention structure, comprising: a fire panel positioned on the indoor side and the outdoor side of the fire door, respectively; a side frame that is vertically coupled to the end of the fire panel at both left and right sides of the fire panel to form left and right frames of the fire door; a heat insulating member interposed between a coupling part of the fire panel and the side frame to block the thermal bridge between the indoor and outdoor fire panels; and a cover frame for forming upper and lower frames of the fire door by bolt-coupling upper and lower portions of the side frame, respectively, thereby capable of improving the durability of the fire door.

Description

A prefabricated fire door having a thermal bridge prevention structure and a manufacturing method thereof

The present invention relates to a prefabricated fire door having a thermal bridge prevention structure and a method for manufacturing the same, and more particularly, by combining a side frame and a cover frame between fire panels to improve the durability of the fire door, and at the same time, to a fire panel on the indoor and outdoor sides It relates to a prefabricated fire door having a thermal bridge preventing structure that prevents mutual thermal bridges, and a method for manufacturing the same.

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, protruding handles are installed on the front and rear surfaces of the door, respectively, so that the user holds the handle and tilts the door to open or close 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 a problem in that it cannot completely block the heat transmitted through the contact path between the panels, no matter how much insulating material is built in, because of its high thermal conductivity.

For example, the inflow of cold air through the thermal bridge between the outer plate and the inner plate, which is a metal plate, or heat loss of the inner plate, that is, the cooling of the inner plate is unavoidable. As a result, the condensation phenomenon in which water vapor condenses on the outer part of the door frame side of the inner plate occurs frequently, The condensation phenomenon of the outer part of the inner inner plate on the indoor side of the fire door is caused by the rapid cooling of the outer part of the inner plate due to the vigorous thermal bridge between the inner plate and the outer plate in direct contact, thereby increasing the gap between the indoor temperature and the inner plate surface temperature. There was a problem of accelerating corrosion and deterioration of fire doors and surrounding facilities in the long term as well as inconvenience.

Korean Patent Publication No. 10-2017-0022344 Korean Patent Registration No. 10-1705626 Korean Patent Publication No. 10-2013-0123530 Korea Registered Utility Model No. 20-0317333

The present invention has been devised to solve the above problems, and the purpose is to improve the durability of the fire door by combining the side frame and the cover frame between the fire panels, and at the same time, the phenomenon of thermal bridge between the fire panels on the indoor and outdoor sides. To provide a prefabricated fire door that prevents

Another object of the present invention is to provide a prefabricated fire door having a structure for preventing thermal bridges that enables rail-type fitting between a fire panel and a side frame.

According to an aspect of the present invention for achieving the above object, the fire protection panel is located on the indoor side and the outdoor side of the fire door, respectively;

a side frame that is vertically coupled to the end of the fire panel at both left and right sides of the fire panel to form left and right frames of the fire door;

a heat insulating member interposed between the coupling part of the fire panel and the side frame to block the thermal bridge between the indoor and outdoor fire panels; and

A prefabricated fire door having a thermal bridge prevention structure comprising a; a cover frame for forming upper and lower frames of the fire door by bolting the upper and lower portions of the side frame, respectively.

Here, the fire protection panel forms bent ends at both ends of the metal plate body, and the bent ends are formed by bending the ends of the metal plate body to have a "7"-shaped rail groove.

In addition, the bent end portion includes an overlapping portion for abutting the end of the fire panel in an inward direction for a predetermined section, a first bent portion bent to stand upright at the end of the overlapping portion in an orthogonal direction, and a fire panel at the end of the first bent portion. It characterized in that it comprises a second bent part bent outwardly, and a third bent part bent toward the fire panel side at the end of the second bent part.

In addition, the side frame is a metal linear material that is extruded in the longitudinal direction, and the bent ends of the fire panels are fitted in both corners of the body having a rectangular cross section, respectively, to form a rail guide groove to guide the rail coupling, It is characterized in that a fastening hole for bolting is formed in the center of the body.

In addition, the heat insulating member is characterized in that it is made of an engineering plastic material extruded in the longitudinal direction.

According to another aspect of the present invention, the step of fitting the insulating member to the guide groove of the side frame;

Assembling the side frame to which the heat insulating member is coupled in the vertical longitudinal direction from the left and right sides of the fire panel; and

There may be provided a method for manufacturing a prefabricated fire door having a thermal bridge preventing structure, comprising: bolting the cover frame to the upper and lower portions of the side frame.

The present invention as described above improves the durability of the fire door through the side frame and the cover frame coupled between the fire panels, and at the same time prevents the thermal bridge between the fire panels on the indoor side and the outdoor side, thereby solving the problem of condensation. has the effect of

In addition, the present invention can reduce the manufacturing time required to manufacture the fire door by manufacturing the rail-type fitting between the fire panel and the side frame, and simplify the manufacturing facility because the manufacturing process of the fire door is simplified. And it has the effect of reducing the manufacturing cost through miniaturization.

In addition, the present invention makes it easy to supply and manage parts by managing the main components of the fire door separately, and when a defect occurs in the manufacturing process or a failure occurs during use, only the relevant parts can be quickly replaced to solve the problem. have an effect

1 is an assembled perspective view showing a prefabricated fire door according to the present invention.
Figure 2 is an exploded perspective view showing a prefabricated fire door according to the present invention.
Figure 3 is a main perspective view showing a fire panel according to the present invention.
Figure 4 is a major perspective view showing a side frame according to the present invention.
Figure 5 is a main perspective view showing a heat insulating member according to the present invention.
6 is a perspective view showing a cover frame according to the present invention.
7 is a partial perspective view showing a modified embodiment of the cover frame according to the present invention.
8 to 10 are assembly process diagrams sequentially showing a method for manufacturing a fire door according to the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is an assembled perspective view showing a prefabricated fire door according to the present invention, and FIG. 2 is an exploded perspective view showing a prefabricated fire door according to the present invention.

1 and 2, the fire door according to the present invention is formed in a rectangular frame shape using a side frame 120 and a cover frame 140 between the fire panels 110 respectively located on the indoor side and the outdoor side of the fire door. As assembling, the side frame 120 and the cover frame 140 coupled between the fire panels 110 serve to improve the durability of the fire door, and the fire panel 110 on the indoor side and the outdoor side are thermally bridged with each other. Provides a thermal cross-blocking structure to prevent

At this time, the fire panel 110 and the side frame 120 are manufactured so that they can be fitted with a rail type, and the manufacturing time required to manufacture the fire door can be shortened through the rail coupling structure.

In addition, since the manufacturing process of the fire door is simplified, it has the effect that the manufacturing facility can be simplified and downsized.

In addition, by managing the main components of the fire door separately, it is easy to supply and manage parts, and when a defect occurs in the manufacturing process or a breakdown occurs during use, only the relevant parts can be quickly replaced to solve the problem. will have

First, the fire protection panel 110 of the present invention will be described with reference to FIG. 3 .

3 is a perspective view showing a fire protection panel according to the present invention, wherein the fire protection panel 110 of the present invention as shown has bent ends 111 at both ends of the metal plate body, respectively.

In this case, the bent end portion 111 is bent and molded to have a rail groove in the shape of a “7” at the end of the metal plate body, and a more detailed example of the bent end portion 111 will be described with reference to the drawings.

The bent end 111 of the present invention as shown in FIG. 3 is formed with an overlapping portion 111a that abuts the end of the fire panel 110 inward for a predetermined section, and is orthogonal to the end of the overlapping portion 111a. A first bent part 111b bent to stand up in the direction is formed, and a second bent part 111c bent outwardly from the fire panel 110 is formed at the end of the first bent part 111b, and the second bent part 111c is formed. A third bent part 111d bent toward the fire prevention panel 110 is formed at the end of the second bent part 111c.

The bending shape leading to the first bent part 111b, the second bent part 111c, and the third bent part 111d appears in a shape similar to the shape of the number "7", and the first bent part 111b, the first bent part 111b, The bent inner space of the second bent portion 111c and the third bent portion 111d becomes a rail groove to have a rail coupling structure with the side frame 120 .

The side frame 120 according to the present invention will be described with reference to FIG. 4 .

4 is a perspective view showing a side frame according to the present invention, as shown, the left and right frames of the fire door are rail-coupled to the ends of the fire panel 110 on the left and right sides of the fire panel 110 in the vertical direction. The side frame 120 forming the is shown.

The side frame 120 is a metal linear material extruded in the longitudinal direction, and the bent ends 111 of the fire panel 110 are inserted into both corners of the body having a rectangular cross section, respectively, to guide the rail coupling. A rail guide groove 121 is formed, and a fastening hole 122 for bolting is formed in the center of the body.

The side frame 120 may be made of a lightweight and durable aluminum alloy material.

At this time, the heat insulating member 130 is interposed between the coupling part of the fire panel 110 and the side frame 120 to block the thermal bridge between the indoor and outdoor fire panels 110 .

5 is a perspective view showing the heat insulating member according to the present invention, the heat insulating member 130 as shown may be made of an engineering plastic material extruded in the longitudinal direction.

Here, the engineering plastic refers to a high-performance plastic material that can replace metal and ceramic materials. It is a plastic product that has excellent strength and elasticity and can withstand high temperature conditions. It is lighter than metal and ceramic materials, which is advantageous for product weight reduction. In particular, based on the product's operating temperature of 100℃, products that are lower than that are classified as general-purpose plastics and high plastic materials are classified as engineering plastics.

The heat insulating member 130 according to the present invention may be made of super engineering plastic that can be used under conditions of 150° C. or higher.

In addition, the heat insulating member 130 may be a heat-resistant silicone material.

Then, the upper and lower frames of the fire door can be formed by bolting the upper and lower portions of the side frame 120 to the cover frame 140, respectively.

6 is a perspective view showing a cover frame according to the present invention, the cover frame 140 as shown has a fastening end 141 coupled with a bolt from an upper side of the side frame 120, and the fastening end 141 ) is formed as an insertion end 143 that is formed to protrude at a certain height from one side and is inserted by a certain height into the space between the fire panels 110 .

At this time, the through-holes 142 through which the bolt 150 penetrates are formed at both ends of the fastening end part 141 .

In addition, the cover frame 140 may be manufactured using an engineering plastic material having a thermal cross-blocking effect.

7 is a partial perspective view showing a modified embodiment of the cover frame according to the present invention. As shown, the cover frame 140 according to the present invention forms a metal body, and the outer surface thereof is combined with an insulating coating layer 144. Thus, it is possible to achieve thermal cross-cutting.

In this case, the heat insulating coating layer 144 may form a coating layer by applying a heat insulating material to the surface of the metal body, and may be coupled to the metal body by molding the heat insulating material as shown in FIG. 7 .

In addition, a thermal bridging phenomenon can be more effectively blocked by filling an insulating material (not shown) between the fire prevention panels 110 as described above.

The process of manufacturing the prefabricated fire door of the present invention as described above will be described with reference to FIGS. 8 to 10 .

8 to 10 are assembly process diagrams sequentially illustrating a method for manufacturing a fire door according to the present invention. First, as shown in FIG. 8 , the heat insulating member 130 is fitted into the guide groove 121 of the side frame 120 .

The heat insulating member 130 has a bent structure similar to that of the rail guide groove 121 of the side frame 120 , and is closely coupled along the inner surface of the rail guide groove 121 .

The heat insulating member 130 coupled to the side frame 120 can be slidably coupled and moved in the longitudinal direction, but it is not separated from the side frame 120 by the annular rail structure and maintains a solid coupling state.

Next, as shown in FIG. 9 , the side frame 120 to which the heat insulating member 130 is coupled is fitted and assembled in the vertical longitudinal direction at both left and right sides of the fire protection panel 110 .

At this time, frictional resistance is generated in the process in which the fire panel 110 is coupled to the rail, and the heat insulating member 130 serves to reduce the frictional resistance, so that the insertion can be made smoothly.

The fire panel 110 coupled to the side frame 120 can be slidably coupled and moved in the longitudinal direction, but it is not separated from the side frame 120 by the annular rail coupling structure and maintains a solid coupling state. .

Next, as shown in FIG. 10 , the cover frame 140 is bolted 150 to the upper and lower portions of the side frame 120 .

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person skilled in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention as claimed in the claims. It is of course possible to implement, and such modifications are intended to be within the scope of the claims.

110: fire panel 111: bent end
111a: overlapping portion 111b: first bent portion
111c: second bent part 111d: third bent part
120: side frame 121: rail guide groove
122: fastening hole 130: insulation member
140: cover frame 141: fastening end
142: through hole 143: insertion end
144: insulation coating layer 150: bolt

Claims (6)

a fire panel 110 positioned on the indoor side and the outdoor side of the fire door, respectively;
a side frame 120 that is vertically coupled to the end of the fire panel 110 at both left and right sides of the fire panel 110 to form left and right frames of the fire door;
a heat insulating member 130 interposed between the coupling portion of the fire panel 110 and the side frame 120 to block the thermal bridge between the indoor and outdoor fire panels 110 ;
a cover frame 140 for forming upper and lower frames of the fire door by bolting the upper and lower portions of the side frame 120, respectively;
including,
The fire protection panel 110 forms bent ends 111 at both ends of the metal plate body, respectively, and the bent ends 111 are bent and molded so that the ends of the metal plate body have a "7"-shaped rail groove,
The bent end portion 111 includes an overlapping portion 111a that abuts the end of the fire panel 110 inward for a predetermined section, and a first bent portion bent so as to be erected in an orthogonal direction at the end of the overlapping portion 111a ( 111b) and the second bent part 111c bent outwardly from the end of the first bent part 111b to the fire panel 110, and from the end of the second bent part 111c toward the fire panel 110 side A prefabricated fire door having a thermal bridge prevention structure, characterized in that it includes a third bent portion (111d) that is bent.
delete delete The method of claim 1,
The side frame 120 is a metal linear material that is extruded in the longitudinal direction, and the bent end 111 of the fire panel 110 is inserted into both side corners of the body having a rectangular cross section, respectively, to guide the rail coupling. A prefabricated fire door having a heat bridge preventing structure, characterized in that a rail guide groove (121) is formed, and a fastening hole (122) for bolting is formed in the center of the body.
The method of claim 1,
The heat insulating member 130 is a prefabricated fire door having a thermal bridge preventing structure, characterized in that it is made of engineering plastic material extruded in the longitudinal direction.
Fitting the heat insulating member 130 to the guide groove 121 of the side frame 120;
Assembling the side frame 120 to which the heat insulating member 130 is coupled in the vertical longitudinal direction from the left and right sides of the fire panel 110;
Bolting the cover frame 140 to the upper and lower portions of the side frame 120;
including,
The fire protection panel 110 forms bent ends 111 at both ends of the metal plate body, respectively, and the bent ends 111 are bent and molded so that the ends of the metal plate body have a "7"-shaped rail groove,
The bent end portion 111 includes an overlapping portion 111a that abuts the end of the fire panel 110 inward for a predetermined section, and a first bent portion bent so as to be erected in an orthogonal direction at the end of the overlapping portion 111a ( 111b) and the second bent part 111c bent outwardly from the end of the first bent part 111b to the fire panel 110, and from the end of the second bent part 111c toward the fire panel 110 side A method of manufacturing a prefabricated fire door having a thermal bridge prevention structure, characterized in that it includes a third bent portion (111d) to be bent.

Images