KR102249002B1 - Assembly Structure of Fire Door - Google Patents

Abstract

The present invention relates to a fire door assembly structure consisting of an assembly of an inner panel and an outer panel, comprising assembling an outer panel including an outer surface of the fire door and an inner panel including an inner surface of the fire door, and on the inside of the four sides of the fire door A fire door assembly structure in which an edge reinforcing frame of C-shaped steel for reinforcing the fire door is inserted, and the outer panel is a first side of a square shape forming the outer surface of the fire door, and the outer panel is formed on the four sides of the first side. A second surface vertically formed in the first direction, which is the inner direction of the fire door, and extends vertically from the end of the second surface in a second direction parallel to the first surface, so that the gasket installed on the door frame is applied when the fire door is closed. Consisting of a third surface to be in close contact, and a fourth surface bent and extended vertically from the end of the third surface again in the first direction, and a first heat insulator to be inserted in close contact with the inner surface of the second surface, The inner panel is a fifth surface of a square shape forming the inner surface of the fire door, and extends vertically bent in a direction outside the fire door from four sides of the fifth surface, and wraps the fourth surface of the outer panel while surrounding the fourth surface. Consisting of a sixth surface assembled on the surface, and includes a second insulating material that is inserted in close contact between the fourth surface of the outer panel and the sixth surface of the inner panel, the fourth surface and the sixth surface, respectively It is installed to be spaced a certain distance from the facing fifth and third surfaces.

Description

Assembly Structure of Fire Door

The present invention relates to a fire door assembly structure composed of an assembly of an inner panel and an outer panel. In particular, the heat transferred through the inner panel and the outer panel of the fire door and through the reinforcing frame installed therebetween is efficiently and economical. It relates to a fire door assembly structure of a structure that can be blocked by.

The conventional fire door door structure is a structure in which an insulating material 31 is placed between the inner panel 14 and the outer panel 11, and an inner frame is installed as shown in FIG. 1, and the inner panel 14 The gasket contact surface 18 is formed at the corner of the outer panel 11 and the inner panel 14, and a gap G is formed with a certain width in the area where the outer panel 11 and the inner panel 14 are in close contact with each other. It is configured to block direct heat transfer. Therefore, the reinforcing material 21 installed on the inner side of the outer panel 11 is also prevented from contacting the inner panel 14 to increase the heat transfer blocking effect.

However, in this conventional structure, the edge ribs 12 of the outer panel and the edge ribs 15 of the inner panel that are assembled come into close contact with the outside air, so that part of the heat from the outside is directly transmitted despite the presence of the insulating material 31 to insulate. And there is a problem that the condensation performance is lowered.

In accordance with this awareness of the problem, it has come to develop a fire door door structure capable of minimizing the heat transmitted directly to the edge ribs of the inner panel through outside air by retreating the edge ribs of the inner panel as much as possible.

Registered Patent No. 10-2064271 (announcement on Jan. 13, 202)

An object of the present invention is to improve the structure for assembly between the outer panel and the inner panel constituting the fire door so that the gasket contact surface is formed at the edge of the outer panel so that heat transfer through the reinforcing frame can be effectively and economically blocked. It is to provide a fire door assembly structure of a new structure in which the edge ribs of the inner panel are retracted inward to the maximum. Other objects of the present invention can all be achieved by the detailed description of the present invention described with reference to the accompanying drawings.

In order to achieve this object, the present invention consists of assembling an outer panel including an outer surface of a fire door and an inner panel including an inner surface of the fire door, and is inserted into the inside of the four sides of the fire door to reinforce the fire door. -A fire door assembly structure in which an edge reinforcing frame of shaped steel is inserted, wherein the outer panel is a first side of a square shape forming an outer surface of the fire door, and from four sides of the first side to a first direction, which is an inner direction of the fire door. A second surface formed vertically, a third surface bent and extended vertically from the end of the second surface in a second direction parallel to the first surface to be in close contact with the gasket installed on the door frame when the fire door is closed, and the third surface Consisting of a fourth surface bent and extended vertically from the end of the third surface again in the first direction, and includes a first insulating material that is inserted in close contact with the inner surface of the second surface, and the inner panel forms the inner surface of the fire door It consists of a fifth surface having a rectangular shape, and a sixth surface that is vertically bent and extended from the four sides of the fifth surface in the outer direction of the fire door, and is assembled to the fourth surface while surrounding the fourth surface of the outer panel. And a second heat insulator inserted in close contact between the fourth surface of the outer panel and the sixth surface of the inner panel, wherein the fourth and sixth surfaces are opposite fifth and third surfaces, respectively It is installed a certain distance apart from.

In addition, in the present invention, the edge reinforcing frame includes an upper reinforcing frame for reinforcing the upper side, left and right reinforcing frames for reinforcing the left and right sides, and a lower reinforcing frame for reinforcing the lower side, and the second surface is an upper side of the fire door. And a 2-1 surface vertically bent and extended in the first direction from three sides of the first surface from left and right, and a 2-2 vertically bent and extended in the second direction from an end of the 2-1 surface. A surface and a second surface that extends vertically bent from the end of the second surface to the first direction, and the first insulating material includes the upper reinforcing frame, the left and right reinforcing frames, and the first insulator. It is closely inserted between the 2nd-3 sides of the 2nd side,
The first heat insulator is a basic heat insulating part and a first surface, a 2-1 surface, a 2-2 surface existing in the first space between the outer surface of the upper reinforcing frame and the left and right reinforcing frames and the 2-3 surface , And a stabilizing heat insulating part for further sealing the second space by being pushed into the second space defined between the planes parallel to the 2-3rd plane.

In addition, in the present invention, the second insulating material has a protruding shape for preventing contact to prevent the fifth surface from contacting the end of the fourth surface by being pushed into the gap between the end of the fourth surface and the fifth surface. Can be formed.

In addition, in the present invention, the lower reinforcing frame is installed a predetermined distance from the lower end of the fire door, the left and right reinforcing frames are installed between the lower reinforcing frame and the upper reinforcing frame, and the upper reinforcing frame and the lower reinforcing frame An intermediate reinforcing frame may be further installed therebetween.

In addition, in the present invention, a rectangular recessed area processed by a press embossing method is formed at the lower end of the first surface of the outer panel, and the lower reinforcing frame is seated on an upper support surface formed above the recessed area. It is fixed and is inserted into the recessed area further comprises a heat shielding member for blocking the transmission of cold air through the lower portion of the fire door, the first heat insulating material inserted into the lower end of the second surface of the outer panel is It is fixed by a lower fixing surface formed at the lower end, and the heat shielding member is processed by extrusion molding a heat-shielding resin, and a plurality of air pockets formed side by side in a horizontal direction may be formed.

According to the fire door assembly structure of the present invention, the edge ribs of the inner panel are formed to retreat to the inside as much as possible, and the heat of the outer panel is blocked by the inter-panel transfer heat blocking insulating material, so that the heat insulation and condensation prevention effect can be maximized.

In addition, as the assembly line formed by assembling the inner panel and the outer panel is retracted inward, the assembly line is not easily recognized by the user's eyes during the opening of the door, thereby providing an aesthetically pleasing feeling.

In addition, since the heat-insulating material of the outer panel itself is disposed inside the outer panel, it can be installed to extend over the entire width of the rim groove of the outer panel, thereby further maximizing heat insulation and condensation prevention effects.

1 is an example of a fire door of a conventional structure.
2 is a perspective view of a fire door to which a fire door assembly structure according to an embodiment of the present invention is applied,
Figure 3 is an exploded perspective view of Figure 2,
4 is a block diagram showing a fire door assembly structure according to an embodiment of the present invention,
5 is an enlarged perspective view of part B of FIG. 4,
6 is an enlarged perspective view of part A of FIG. 4 and an assembly process thereof,
7 is a side configuration diagram of a fire door assembly structure according to an embodiment of the present invention,
8 is a partial plan view of a fire door assembly structure according to another embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Terms or words used in the present specification and claims are not limited to a conventional or dictionary meaning and are not interpreted, but should be interpreted as meanings and concepts consistent with the technical matters of the present invention.

2 is a perspective view of a fire door to which a fire door assembly structure according to an embodiment of the present invention is applied, FIG. 3 is an exploded perspective view of FIG. 2, and FIG. 4 is a configuration showing a fire door assembly structure according to an embodiment of the present invention FIG. 5 is an enlarged perspective view of part B of FIG. 4, and FIG. 6 is an enlarged perspective view of part A of FIG. 4 and an assembly process thereof.

The present invention consists of an assembly of an outer panel 110 including an outer surface of the fire door and an inner panel 120 including an inner surface of the fire door, and is inserted into the inside of the four sides of the fire door to reinforce the fire door. As a fire door assembly structure in which the edge reinforcing frame 150 of the section steel is inserted, referring to FIGS. 5(b) and 6(a), the outer panel 110 includes a first side 112 and a second side 114 , A third side 116, and a fourth side 118. Typically, an intermediate stiffener 180 is inserted and installed in the vertical direction between the edge reinforcing frames 150, and in the case of the intermediate stiffener 180, it is in contact with the outer panel 110, but is installed spaced apart from the inner panel 120 to be installed inside and outside. There is no direct heat transfer between.

The first surface 112 is a surface that forms the outer surface of the fire door, has a normal rectangular shape, and is a region that directly receives external heat.

The second surface 114 is a surface formed vertically from four sides of the first surface 112 in a first direction, which is an inner direction of the fire door.

The third surface 116 is a gasket installed on the door frame 50 when the fire door is closed by bending and extending vertically from the end of the second surface 114 in a second direction parallel to the first surface 112 It adheres to (57) so that the space between the fire door and the door frame is sealed.

The fourth surface 118 is a surface extending vertically from the end of the third surface 116 in the first direction again to provide a rib for fastening to the inner panel 120.

In addition, the fire door assembly structure of the present invention includes a first insulating material 140 inserted in close contact with the inner surface of the second surface 114 of the outer panel 110. As described above, the first heat insulator 140 is a thermal insulation material for preventing the transmission of cold air from the outer panel itself, and is installed along the four sides of the fire door to block external cold air that can be transmitted through the four sides, thereby preventing the transmission of cold air from the outer panel itself. It is possible to prevent the formation of condensation in the.

That is, the cold air introduced to the first side 112 of the outer panel 110 of the fire door is posted through the second side 114 of the fire door or between the first side 112 and the third side 116 of the fire door. The cold air is transferred to the fourth surface 118 through the metal reinforcement frame 150, which is a heat transfer member, and the cold air delivered to the fourth surface 118 of the outer panel 110 is transmitted to the inner panel 120, which is shown in FIG. 1 Compared to the structure in which the reinforcement material 21 and the edge ribs 12 of the outer panel are in contact with each other to increase the amount of cold air transferred, the amount of cold air transfer can be reduced by separating the heat transfer path. There is an advantage.

In the present invention, since the reinforcing frame 150 is spaced apart from the edge of the fire door by the width of the first insulating material 140 and is isolated from the second surface 114, which is a cold air transmission path, the amount of cold air transmitted through the reinforcing frame 150 Becomes smaller.

In addition, in the conventional structure, the insulating material 31 is configured to have a smaller width than the reinforcing material 21, whereas in the present invention, the first insulating material 140 is configured to cover the entire width of the reinforcing frame 150, so reinforcement There is an advantage of minimizing the width of the heat transfer path through the frame 150.

And, as shown in the fire door assembly structure of the present invention, the inner panel 120 is composed of a fifth surface 122 and a sixth surface 124.

As shown in FIGS. 2 and 3, the fifth surface 122 is a surface having a normal rectangular shape forming the inner surface of the fire door, and the sixth surface 124 is on the four sides of the fifth surface 122. It is bent and extended vertically in the outer direction of the fire door, and is assembled with the fourth surface 118 while surrounding the fourth surface 118 of the outer panel 110.

In addition, the fire door assembly structure of the present invention includes a second insulating material 130 inserted in close contact between the fourth surface 118 of the outer panel 110 and the sixth surface 124 of the inner panel 120 do. The second heat insulator 130 is a heat shielding member for blocking the transmission path of cold air between the outer panel 110 and the inner panel 120, and the second heat insulator 130 is also installed along the four sides of the fire door. 1 In spite of the heat insulating material 140, the heat transferred to the third side 116 and the fourth side 118 is suppressed from being transferred to the inner panel 120.

And in the fire door assembly structure of the present invention, the fourth side 118 of the outer panel and the sixth side 124 of the inner panel 120 are the fifth side 122 of the inner panel and the third side of the outer panel, respectively. It is installed at a certain distance from (116) so that direct heat transfer between panels is blocked.

In the conventional structure, the heat insulating material 31 was used to prevent the cold air introduced into the outer panel from being transmitted to the inner panel, but also, the heat transfer path through the reinforcement material 21 and the outer panel 11 was not effectively prevented. , Measures were taken, such as adding more structures such as a condensation prevention panel to the surface of the inner panel. The present invention changes the bending structure of the outer panel 110 instead of installing such an additional panel, allows the inner panel to be installed, and adds the second insulating material 130 to the position where the outer panel and the inner panel are assembled, thereby overlapping the material. It provides the effect of lowering the manufacturing cost by simplifying the manufacturing process while eliminating the use.

8 is a partial plan view of a fire door assembly structure according to another embodiment of the present invention.

5 and 8, in the present invention, the edge reinforcing frame includes an upper reinforcing frame 152 for reinforcing the upper side, left and right reinforcing frames 156 for reinforcing the left and right sides, and a lower reinforcing frame for reinforcing the lower side. Including (154), wherein the first heat insulating material 140 is inserted in close contact between the upper reinforcing frame 152 and the left and right reinforcing frames 156 and the second surface 114, and the second surface 114 ) Is a 2-1 surface (114-1) vertically bent in the first direction from three sides of the first surface 112 from the upper and left and right sides of the fire door, and at the ends of the 2-1 surface. The second-second surface (114-2) bent and extended vertically in the second direction, and the second-third surface (114-3) vertically bent and extended again in the first direction from the end of the second-surface ), and the first heat insulating material 140 is a basic heat insulating part 142 present in the first space S1 between the outer surfaces of the upper reinforcing frame and the left and right reinforcing frames and the 2-3rd surfaces And the second space (S2) defined between the first surface, the 2-1 surface, the 2-2 surface, and the surface parallel to the 2-3 surface to further seal the second space (S2). It may include a stabilizing heat insulating portion 144 for the purpose.

In addition, in the present invention, the second insulating material 130 is pushed into the gap between the end of the fourth surface 118 and the fifth surface 122 so that the fifth surface 122 becomes the fourth surface 118 A first contact prevention protrusion shape 134 for preventing contact with the end of) may be further formed, and a second contact prevention for preventing the end of the sixth surface 124 from contacting the third surface 116 The protruding shape 136 may be further formed.

In addition, in the present invention, the lower reinforcing frame () is installed a predetermined distance from the lower end of the fire door, and the left and right reinforcing frames are installed between the lower reinforcing frame and the upper reinforcing frame, and the upper reinforcing frame and the lower An intermediate reinforcing frame may be further installed between the reinforcing frames.

7 is a side view of a fire door assembly structure according to an embodiment of the present invention. Referring to FIG. 7, in the present invention, a rectangular recessed area 220 processed by a press embossing method is formed at a lower end of the first surface of the outer panel, and an upper portion formed on the recessed area 220 is formed. The lower reinforcing frame 154 is seated and fixed on the support surface 222, and further includes a heat shielding member 210 for blocking transmission of cold air through the lower portion of the fire door by being inserted into the recessed area 220, , The first insulating material 140 inserted at the lower end of the second surface 114 of the outer panel 110 is fixed by a lower fixing surface 224 formed at the lower end of the recessed region 220, The heat shield member 210 is processed by extrusion molding a heat shielding resin, and a plurality of air pockets 225 formed parallel to each other in a horizontal direction may be formed.

That is, in FIG. 2, the lower reinforcing frame 154 is installed above a certain distance from the lower end of the fire door, which is generally cool air is accumulated under the fire door and less cold air is disposed at the top, so that the lower side of the fire door has heat transfer characteristics. This is to reduce the transmission of cold air through the metallic lower reinforcing frame, and the lower region (U) of the lower reinforcing frame is composed of a minimum amount of metallic material, and in addition to this, the heat shield member 210 is added to the bottom of the fire door. It is possible to minimize the amount of cold air delivered.

In addition, in the present invention, in order to block heat transfer through the metal locking device 55, the third insulating material 160 may be attached to the front and rear surfaces of the locking device.

When comparing the thermal imaging results of the heat insulation and airtightness comparison test results according to the embodiment of the present invention (an embodiment excluding the heat shield member) and the previous structure of Fig. 1, Fig. 9 of the embodiment of the present invention shows the previous structure. In 10, it can be seen that the cold air represented by purple appearing along the door gap has been significantly reduced.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and is not departing from the gist of the present invention claimed in the claims, and is generally used in the technical field to which the present invention pertains. Various modifications can be implemented by those with knowledge. In addition, matters that can be easily inferred from the accompanying drawings should be considered to be included in the content of the present invention even if they are not described in the detailed description, and various modifications are not individually understood from the technical spirit or prospect of the present invention. It won't work.

110: outer panel 120: inner panel
130: second insulating material 140: first insulating material
150: edge reinforcement frame 160: third insulation

Claims (5)

delete Fire door consisting of an assembly of an outer panel including the outer surface of the fire door and an inner panel including the inner surface of the fire door, and inserted inside the four sides of the fire door to reinforce the fire door with an edge reinforcing frame of C-shaped steel inserted As an assembly structure,
The outer panel includes a first surface of a square shape forming an outer surface of the fire door, a second surface formed perpendicularly to a first direction, which is an inner direction of the fire door, from four sides of the first surface, and the end of the second surface. A third surface that is bent and extended vertically in a second direction parallel to the first surface to be in close contact with the gasket installed on the door frame when the fire door is closed, and the end of the third surface is bent vertically again in the first direction. Consists of the fourth side,
Including a first insulating material that is inserted in close contact with the inner surface of the second surface,
The inner panel is a fifth surface of a square shape forming the inner surface of the fire door, and extends vertically bent in a direction outside the fire door from four sides of the fifth surface, and wraps the fourth surface of the outer panel while surrounding the fourth surface. It consists of a sixth side that is assembled on the side,
Including a second insulating material that is inserted in close contact between the fourth surface of the outer panel and the sixth surface of the inner panel,
The fourth and sixth surfaces are installed at a predetermined distance apart from the facing fifth and third surfaces, respectively,
The edge reinforcing frame includes an upper reinforcing frame for reinforcing an upper side, a left and right reinforcing frame for reinforcing the left and right sides, and a lower reinforcing frame for reinforcing the lower side,
The second surface is a 2-1 surface vertically bent and extended in the first direction from three sides of the first surface from the top and left and right sides of the fire door, and from the end of the second surface to the second direction. It is subdivided into a 2-2 surface bent vertically extended and a 2-3 surface vertically bent and extended again in the first direction from the end of the 2-2 surface,
The first insulating material is a fire door assembly structure, characterized in that in close contact between the upper reinforcing frame and the left and right reinforcing frames and the 2-3 surfaces of the second surface.
The method of claim 2,
The first heat insulator is a basic heat insulating part and a first surface, a 2-1 surface, a 2-2 surface existing in the first space between the outer surface of the upper reinforcing frame and the left and right reinforcing frames and the 2-3 surface And a stabilizing insulation part for further sealing the second space by pushing into a second space defined between planes parallel to the 2-3rd plane.
The method of claim 2,
The second heat insulating material is further formed with a protruding shape for preventing contact to prevent the fifth surface from contacting the end of the fourth surface by being pushed into the gap between the end of the fourth surface and the fifth surface. Fire door assembly structure.
The method of claim 2,
The lower reinforcing frame is installed a predetermined distance from the lower end of the fire door, and the left and right reinforcing frames are installed between the lower reinforcing frame and the upper reinforcing frame,
A fire door assembly structure, characterized in that an intermediate reinforcing frame is further installed between the upper reinforcing frame and the lower reinforcing frame.

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