KR20200054597A - Structure for Anti-Sweating of Fire Door - Google Patents

Abstract

The present invention is to provide an anti-condensation structure of a fire door to improve heat insulation performance and fire-protecting performance. An anti-condensation structure of a fire door according to one aspect of the present invention may include a case formed with an indoor plate and an outdoor plate, an insulation member filling inside the case, and a blocking member provided at the bottom of the insulation member to prevent condensation.

Description

Structure for Anti-Sweating of Fire Door}

The present invention relates to a condensation preventing structure of a fire door, and more particularly, to a condensation preventing structure of a fire door that can effectively prevent condensation by filling a heat insulating member inside the fire door and filling a blocking member at a lower portion vulnerable to condensation.

In general, fire doors made of metal are installed on the entrances of apartments, homes, and offices to prevent or block the spread of flames in the event of a fire, and these fire doors are provided with heat insulation, fire resistance, and sound absorption.

The fire door is rotatably mounted on a door frame for a fire door installed on a wall using a pivot hinge or hinge, and the door frame frame is also made of a metal plate.

Conventionally, in general, a structure in which a fire door is installed in a doorway of a building enables opening and closing of the fire door, fixing a door frame frame of a size surrounding the exterior to a wall forming a doorway of the building, and a hinge or hinge between the door frame frame and the fire door It is designed to open and close.

In addition, the function of absorbing and absorbing the shock noise generated when opening and closing the fire door and the gasket member of various types formed of urethane material are provided at the contact portion between the door frame frame and the fire door to block indoor and outdoor noise and heat transfer. Installed.

The structure of the fire door as described above has various structures suitable for installation purposes, but the present invention will be described with a structure generally known in the same industry.

When explaining the general structure of the fire door as described above, the fire door is formed of a metal plate having a certain thickness, which consists of an outer member constituting the front side and an inner member constituting the rear side, and the outer circumferential surfaces of the outer member and the inner member by press processing. By bending, the upper and lower surfaces and the left and right sides are provided with a border portion to close the circumference, and a certain space is provided between the outer and inner members.

In addition, inside the rim of the fire door, various types of reinforcing members are integrally formed by riveting to reinforce the strength so that hinges or hinges and door locks can be installed.

In order to prevent condensation, the interior space of the fire door is filled with a heat insulating material formed of a non-metallic inorganic material having heat insulation, fire resistance, and sound absorption.

Non-combustible refractory sheet, foamed resin, glass wool, urethane foam, etc. are used as the type of the insulating material. Recently, an insulating plate material made of a glass wool material, which is an inorganic material that is harmless to the human body, is mainly used to increase the insulating effect and increase the insulating material. In order to secure the strength, it is recompressed under pressure and installed inside the fire door.

However, filling the interior of the fire door with a filling material can complicate the manufacturing process, resulting in a high cost. In addition, even if the entire interior of the fire door is filled with heat insulating material, there is a problem in that condensation of the lower part cannot be prevented as the thermal bridge phenomenon is concentrated in the lower part of the fire door.

The present invention has been devised to solve the above problems, and an object of the present invention is to provide an anti-condensation structure of a fire door that can improve the heat insulation performance and the fire performance of the fire door.

Another object of the present invention is to provide a condensation preventing structure of a fire door that can prevent condensation by providing a blocking member at the bottom of the fire door with low thermal insulation performance.

The condensation prevention structure of the fire door according to an aspect of the present invention for achieving the above object is provided with a case formed of an indoor plate and an outdoor plate, an insulating member filled inside the case, and a lower end of the insulating member It may include a blocking member for preventing condensation.

The case includes a bending plate formed by bending to connect the edges of the indoor plate and the outdoor plate formed at different heights, a filling space formed at the same intervals as the width of the bending plate, and filling the insulating member, It is provided in the filling space may be provided with a ceramic pad to block the thermal bridge phenomenon of the position in contact with the heat insulating member and the case.

The heat insulating member is a filling material filled in the filling space, and is provided on top and bottom of the filling zone, respectively, and a non-combustible insulating material provided to contact the interior plate and the outdoor plate, respectively, and a stiffener surrounding a border of the filling material. , It may be provided in the corner portion of the filling material may be provided with a corner member to maintain the spacing of the non-combustible insulating material.

The stiffener is a joint surface in contact with a plurality of the non-combustible insulating material, a bending surface formed by bending vertically at one end of the bonding surface, and the case and the case as it is bent toward the filling material at the center of the bending surface. It may be provided with an insulating surface to reduce the bonding area with the blocking member.

The non-combustible insulation material is formed of one of a vacuum insulation material and a refractory insulation material of an inorganic material, and may include an upper non-combustible insulation material and a lower non-combustible insulation material provided on upper and lower portions of the filling material.

The blocking member is provided on the indoor side and the outdoor side, and includes a plurality of insulating reinforcements formed at different densities, and partition plates partitioning the insulating reinforcements of different densities by connecting the case and the edge reinforcement. can do.

The blocking member may be provided between the lower non-combustible insulating material by being divided by the edge reinforcement under the filling material.

According to the condensation preventing structure of the fire door according to the present invention, it is possible to prevent condensation from occurring as the blocking member is filled in the lower portion of the fire door.

And, by providing a vacuum insulation material, it is possible to secure more heat insulation.

1 is a perspective view showing a fire door according to an embodiment of the present invention.
Figure 2 is a cross-sectional view showing the fire door shown in Figure 1;
Figure 3 is a horizontal cross-sectional view showing a fire door according to an embodiment of the present invention.
Figure 4 is a cut perspective view showing the bottom of the fire door according to an embodiment of the present invention.
5 is a vertical cross-sectional view showing a fire door according to an embodiment of the present invention.

Hereinafter, a condensation prevention structure of a fire door according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing a fire door according to an embodiment of the present invention, FIG. 2 is a sectional view showing a fire door shown in FIG. 1, and FIG. 3 is a horizontal cross-sectional view showing a fire door according to an embodiment of the present invention.

1 to 3, the condensation preventing structure of the fire door according to an embodiment of the present invention includes a case 100 formed of an indoor plate 110 and an outdoor plate 120, and an inner side of the case 100 It is provided on the lower end of the heat insulating member 200 and the heat insulating member 200 is provided with a blocking member 300 for preventing condensation.

The case 100 is formed of a metal plate material having a predetermined thickness (1 to 2T), and includes an outdoor plate 120 forming a front surface and an interior plate 110 forming a rear surface in a state of maintaining a predetermined interval.

The outdoor plate 120 and the interior plate 110 may be hung on the door frame according to different heights, and the outdoor plate 120 and the outdoor plate 120 are connected to connect the outdoor plate 120 and the interior plate 110 of different heights. A bending plate 130 in which the outer circumferential surface of the interior plate 110 is bent by press processing is provided. At this time, the bending plate 130 is fixed to the outdoor plate 120 and the interior plate 110 by riveting or welding.

Bending plate 130 between the outdoor plate 120 and the interior plate 110 and the bending plate 130 by the bending plate 130 closing the circumference between the outdoor plate 120 and the interior plate 110 as described above It is formed at the same intervals as the width, and the filling space 140 having the same height as the outdoor board 120 and the indoor board 110 is formed to fill the heat insulating member 200.

In addition, the inside of the case 100 is provided with a ceramic pad 150 to prevent the heat bridge phenomenon at the position where the heat insulating member 200 and the case 100 are filled in the filling space 140 to prevent condensation from occurring. It can be prevented primarily.

The heat insulating member 200, which is press-molded in the same panel shape as the case 100 of a certain thickness, is integral with the inner surfaces of the outdoor plate 120 and the interior plate 110 by an adhesive in a state filled in the case 100. It is possible to maintain a stable state.

In addition, the insulating member 200 is inserted into the filling space 140 provided in the insulating member 200 by a forced fitting type, so that the adhesive is used, the outdoor plate 120 in contact with the front and rear surfaces of the insulating member 200 And by applying once to the inner surface of the interior plate 110, it is possible to simplify the adhesive coating operation, thereby improving workability.

Alternatively, the heat insulating member 200 is coupled to the inside of the case 100 in a corresponding size in consideration of the thickness, height, and length of the case 100, and the horizontal, vertical, and thickness of the case 100 are The same width as the heat insulating member 200 and the same length and depth as the depth of the space portion, and the thickness of the filling space 140 may be the same as the thickness or may be largely formed within 5% of the thickness.

Accordingly, when the heat insulating member 200 is inserted, the heat insulating member 200 inserted into the filling space 140 is firmly integrated with the case 100 without using an adhesive.

The insulation member 200 is provided at the filling material 210 filled in the filling space 140 and at the top and bottom of the filling table, respectively, and is in contact with the interior plate 110 and the outdoor plate 120, respectively. A non-combustible insulating material 220 provided to be provided, a frame reinforcement member 230 surrounding the rim of the filling material 210, and a corner member provided at a corner portion of the filling material 210 to maintain the distance between the non-combustible insulating material 220 It may be provided with (240).

The filling material 210 accommodated in the filling space 140 may select and use any one of known insulating materials such as a non-combustible refractory sheet, foamed resin, urethane foam, glass wool, and the like to secure heat insulation, fire resistance, and sound absorption. . And, to make the living environment more comfortable, inorganic glass wool materials can also be used.

In addition, the materials of these heat insulating members 200 are compressed under a predetermined pressure for a strength reinforcement effect, and are molded to a thickness and size suitable for the interior space of the case 100.

The non-combustible insulating material 220 is formed of one of a vacuum insulating material and a refractory insulating material of an inorganic material, and may include an upper non-combustible insulating material 221 and a lower non-combustible insulating material 222 provided on upper and lower portions of the filling material 210. have.

In addition, the lower non-combustible insulating material 222 provided on the lower portion of the non-combustible insulating material 220 may be formed to surround the blocking member 300 while being coupled to the indoor and outdoor sides of the filling material 210.

As described above, when the filling material 210 is filled from the inner top to the bottom of the case 100, the upper non-combustible insulating material 221 and the lower non-combustible insulating material 222 may be formed to surround the filling material 210, but in the present invention, In order to prevent the condensation phenomenon of the lower portion, a blocking member 300 is provided between the plurality of lower non-combustible insulating materials 222.

When the non-insulating insulating material 220 is formed of a vacuum insulating material, the core material is made of an organic material such as a polyurethane foam or an inorganic material such as glass fiber and silica and mineral wool, but recently the organic material is a fine but volatile organic gas. It is not used as it is confirmed to harm the surrounding environment because it is released, and a core material made of an inorganic material can be used to replace it.

In addition, the outer material of the non-combustible insulating material 220 may be made of a composite film in which several layers of films including a protective layer, a barrier layer, and a sealing layer are laminated, and the barrier layer maintains an internal vacuum level and external gas or water vapor. It acts as a block.

The non-insulating insulating material 220 has excellent thermal insulation performance of 0.007 W / mK or less, and an optimized effect can be obtained in terms of handling strength.

In this way, the non-insulating insulation material 220 is formed by being coupled to the indoor side and the outdoor side of the filling material 210, respectively, and as it is combined inside the case 100 by adhesive and interference fit, the wall is formed through the ceiling and floor surfaces of the building. Furnace heat conduction is made to reinforce the upper and lower parts of the fire door 10, which is vulnerable to condensation, and can significantly improve the fire resistance and heat insulation effect.

The stiffener 230 adjusts the width of the non-combustible insulating material 220, divides the filling material 210 and the case 100, surrounds a corner member 240, and covers the case 100 and the blocking member. Block and partition the thermal bridge with 300.

The edge stiffener 230 may be formed by bending a structure surrounding the corner member 240, a bonding surface 231 that is in contact with a plurality of the non-combustible insulating material 220, and one end of the bonding surface 231 Reduces the bonding area between the case 100 and the blocking member 300 as the bending surface 232 formed by bending in the vertical direction is bent from the center of the bending surface 232 toward the filling material 210. An insulating surface 233 may be provided.

The corner member 240 is installed only in a corner portion having a weak structural performance of the fire door 10 to reinforce strength and at the same time reduce weight.

The corner member 240 is accommodated inside the stiffener 230, one surface is formed so as to contact the end of the filler 210, the outside of the non-combustible insulating material 220 provided on the upper and lower portions of the filler 210, respectively Maintain the distance between the side and the interior.

4 is a cut-away perspective view showing the bottom of the fire door 10 according to an embodiment of the present invention, and FIG. 5 is a vertical cross-sectional view showing the fire door 10 according to an embodiment of the present invention.

As shown in Figures 4 to 5, the blocking member 300 according to an embodiment of the present invention is provided on the indoor side and the outdoor side, respectively, and a plurality of insulating reinforcements 310 formed with different densities, and As the case 100 and the corner member 240 are connected, a partition plate 320 for partitioning the heat insulating reinforcement materials 310 having different densities is provided.

Even if an insulating material is provided inside the fire door 10, condensation occurs due to a thermal bridge phenomenon occurring through the upper and lower portions. In particular, the performance of the heat insulating material inside the fire door 10 must be improved by the dew condensation occurring on the lower side, which may cause the manufacturing cost of the fire door 10 to increase, and also increase the weight of the fire door 10.

The blocking member 300 is provided under the fire door 10 where the thermal bridge phenomenon is intensively generated. At this time, the blocking member 300 is formed by being divided by the filling material 210 and the corner member 240 so as not to overlap with the filling material 210.

The thermal insulation reinforcement 310 may be provided on the outdoor side and the indoor side, respectively, and the density of the thermal insulation reinforcement 310 provided on the outdoor side and the indoor side may be different.

In general, thermal insulation materials have different performances depending on their density, and the higher the density, the higher the cost as the manufacturing process becomes more complicated. Therefore, a high-density insulation material cannot be used inside the fire door 10.

However, in the present invention, since the filling material 210 of the upper portion has a low probability of condensation, a low-density insulating material is used, but the blocking member 300 of the lower portion uses a high-density insulating material because of a high probability of condensation.

In addition, in order to more effectively block the occurrence of a thermal bridge phenomenon between the indoor side and the outdoor side, an insulating reinforcement material 310 having different densities is provided.

In addition, the partition plate 320 formed of a steel material, a synthetic resin, and a heat insulating material may be provided to partition each of the heat insulating reinforcing materials 310 to more effectively block the thermal bridge phenomenon.

At this time, the partition plate 320 may extend upward from a bent position of the bending plate 130 provided at the edge of the case 100 to the edge reinforcement 230 provided at the bottom of the filling material 210. have.

As described above, since the heat insulating member 200 and the blocking member 300 can be installed on the fire door 10, the weight of the fire door 10 is reduced, while the blocking member 300 is coupled to the lower portion of the filling material 210 to lower the thermal conductivity. , It can greatly improve the fireproofing and heat insulation effect and prevent condensation. In particular, since the weight of the fire door 10 can be lightened, other auxiliary materials (hinge or hinge) installed on the fire door 10 even if the fire door 10 is used for a long time Etc.).

In the above, the structure for preventing condensation of a fire door according to an embodiment of the present invention has been described, but the spirit of the present invention is not limited to the embodiments presented herein. And, those skilled in the art who understand the spirit of the present invention can easily propose other embodiments by adding, changing, deleting, adding, or the like components within the scope of the same spirit, but also within the scope of the present invention. Would say

10: fire door 100: case
110: indoor version 120: outdoor version
130: bending plate 140: filling space
150: ceramic pad 200: insulating member
210: filling material 220: non-insulating insulation material
221: upper non-combustible insulation 222: lower non-combustible insulation
230: frame reinforcement 231: joint surface
232: bent surface 233: insulating surface
240: corner member 300: blocking member
310: insulating reinforcement material 320: partition plate

Claims (7)

A case formed of an indoor plate and an outdoor plate,
An insulating member filled inside the case,
A condensation preventing structure of a fire door provided at a lower end of the heat insulating member and including a blocking member for preventing condensation.
According to claim 1,
The case is a bending plate formed by bending to connect the rim of the indoor plate and the outdoor plate formed at different heights,
A filling space formed at the same intervals as the width of the bent plate and filled with the heat insulating member,
A condensation preventing structure of a fire door, which is provided in the filling space and includes a ceramic pad that blocks a thermal bridge phenomenon at a position where the insulating member and the case are in contact.
According to claim 2,
The heat insulating member is a filling material filled in the filling space,
A non-combustible insulating material provided on upper and lower portions of the filling table, and provided to contact the indoor plate and the outdoor plate, respectively;
A border reinforcement that surrounds the border of the filling material,
A structure for preventing condensation of a fire door, characterized in that it has a corner member provided at a corner of the filling material to maintain a gap between the non-combustible insulating materials.
According to claim 3,
The rim reinforcement is a joint surface in contact with a plurality of the non-insulating insulation material,
A bending surface formed by bending vertically at one end of the bonding surface,
A structure for preventing condensation of a fire door, comprising a heat-insulating surface that reduces a bonding area between the case and the blocking member as it is bent from the center of the bent surface toward the filling material.
According to claim 3,
The non-combustible insulating material is formed of one of a vacuum insulating material and a refractory insulating material of an inorganic material, and the condensation preventing structure of the fire door is characterized by comprising an upper non-combustible insulating material and a lower non-combustible insulating material provided on the upper and lower portions of the filling material.
The method of claim 5,
The blocking member is provided on the indoor side and the outdoor side respectively, and a plurality of insulating reinforcements formed at different densities,
The condensation preventing structure of the fire door, characterized in that it comprises a partition plate for partitioning the insulating reinforcement of different densities by connecting the case and the frame reinforcement.
The method of claim 6,
The blocking member is condensation preventing structure of the fire door, characterized in that provided between the lower non-insulating insulating material is provided by the rim reinforcement under the filling material.

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