KR102050635B1 - Fire door frame coupling structure of multiple layer - Google Patents

Abstract

The present invention relates to a multi-structure fire door frame coupling structure, more specifically through a structure that can greatly improve the bearing capacity and strength of the edge side portion of the fire door, to improve the sealing properties for the entire fire door and thereby through the fire It is to improve the blocking effect and prevent fire spread.
In particular, the present invention does not constitute a separate support, but through the folding and bending process of the edge of the front panel and the rear panel of the fire door, by combining the two or more layers of the combination to improve the bearing capacity and strength, compression Bending and torsional stresses, which are represented by the sum of stress and tensile stress, can be improved and deformation of the fire door due to external forces can be minimized.
Therefore, it is possible to improve the reliability and competitiveness in the field of fire doors and fire door reinforcement structures, in particular the corner reinforcement structure of the frame for fire doors, as well as similar or related fields.

Description

Fire door frame coupling structure of multiple layer

The present invention relates to a multi-structure fire door frame coupling structure, and more specifically, through a structure that can greatly improve the bearing capacity and strength of the edge side of the fire door, improve the sealing properties for the entire fire door and thereby through the fire in case of fire It is to improve the blocking effect and prevent fire spread.

In particular, the present invention does not constitute a separate support, but through the folding and bending process of the edge of the front panel and the rear panel of the fire door, by combining the two or more layers of the combination to improve the bearing capacity and strength, compression The present invention relates to a multiple door structure combined with a fire door frame that can improve bending stress and torsion stress represented by the sum of stress and tensile stress and minimize deformation of the fire door by external forces.

Fire doors are designed to block and delay the spread of flames and smoke in the event of a fire. Unlike general doors, fire doors are considered to be most important, and are mainly made of metal in consideration of fire resistance and manufacturing cost.

In particular, in order to be able to withstand various shocks from the outside, various types of reinforcement structures are applied to the part where the key cylinder is mounted, the hinge part to which the hinge is attached, and the corner part of the fire door.

For example, Republic of Korea Patent Publication No. 10-0954551, the following prior art document 'Firing edge edge of the frame frame for mounting around the fire door' (hereinafter referred to as 'prior art 1') and Republic of Korea Patent Publication No. 10- 0823367 'Welded window frame connection structure with edge reinforcement connecting structure, window structure using the same and its manufacturing method' (hereinafter referred to as 'prior art 2') is used to connect the corners of the frame forming the appearance of the fire door. Technology.

In the case of the prior art 1, the fastener is to be fitted to the fitting groove of the frame to be in close contact with the partition wall, and then to connect the two neighboring frames through the bolt coupling, the fastener in the structure is simply connecting the two frames. It can be seen.

In case of the prior art 2, a separate frame reinforcement is configured at the corners, but the manufacturing process is very cumbersome, such as forming an opening at the edge of the frame and additionally combining the cover to install the frame reinforcement. Able to know.

On the other hand, looking at the structure of the frame shown in the prior art, it can be easily seen that the frame is produced by extrusion molding.

However, extrusion is a method mainly used for processing materials that are easily deformed by heat such as synthetic resin or aluminum (including alloy), and these materials are not suitable for use as fire doors that must withstand high temperatures generated in a fire.

As described above, the fire doors are mainly made of metal, and the metal panel is mainly manufactured through a roll forming process. Therefore, it is impossible to manufacture a frame of the same type as the prior arts. There is also a limit to the application of the reinforcement structure shown in the prior art.

Republic of Korea Patent Publication No. 10-0954551 'Edge fixing device of the edge frame for mounting the circumference of the fire door' Republic of Korea Patent Publication No. 10-0823367 'Welded window frame connection structure having a corner reinforcement connection structure, window structure using the same and its manufacturing method'

In order to solve the above problems, the present invention through the structure that can greatly improve the bearing capacity and strength of the edge side of the fire door, to improve the sealing performance for the whole fire door, thereby improving the flame shielding effect in the event of fire and fire An object of the present invention is to provide a multi-structure fire door frame coupling structure that can prevent diffusion.

At this time, the present invention can form a reinforcement structure using only the panel of the metal constituting the fire door, without using a separate reinforcing member, etc., while the process can be easily processed by a roll forming process, An object of the present invention is to provide a multi-structure fire door frame coupling structure capable of providing sufficient bearing capacity and strength.

In particular, the present invention does not constitute a separate support, but through the folding and bending process of the edge of the front panel and the rear panel of the fire door, by combining the two or more layers of the combination to improve the bearing capacity and strength, compression The purpose of the present invention is to provide a multi-structure fire door frame coupling structure that can improve the bending stress and torsion stress represented by the sum of stress and tensile stress and minimize the deformation of the fire door by external forces.

In order to achieve the above object, a multi-structure fire door frame coupling structure according to the present invention, in the coupling structure of the fire door frame is configured so that the edges of the front panel and the rear panel constituting the fire door, the front panel and Any one of the rear panel is configured to be stacked in a layered structure, the step portion extending from at least a portion of the edge of the panel surface portion forming a fire door; And a reinforcement support part configured to be stacked in a layered structure and extending from the stepped part to be coupled to the other of the front panel and the rear panel.

In addition, at least one of the stepped portion and the reinforcement support part may be formed to be folded so that the edge of any one of the front panel and the rear panel in close contact.

The stepped part may include: a first bent part bent in one direction from the panel surface part; And a second bent part bent in one direction from the first bent part. The reinforcement support part may be bent in another direction from the second bent part.

In addition, the stepped portion and the reinforcing support portion is composed of a double structure of the outer and the inner side, the stepped portion, the first outer bent surface formed on the outside of the first bent portion and the second outer side formed on the outside of the second bent portion The bent surface extends sequentially from the panel surface portion and is connected to the reinforcing support portion, wherein the second inner bending surface configured inside the second bending portion and the first inner bending surface configured inside the first bending portion are , May be sequentially extended from the reinforcement support.

In addition, the reinforcing support portion may be of a double structure folded so that the outer reinforcing surface extending from the second outer bent surface and the inner reinforcing surface extending from the second inner bent surface is in close contact.

In addition, the other one of the front panel and the rear panel, the reinforcing connecting portion coupled to the reinforcing support may be formed extending at least part of the edge of the panel surface.

In addition, the reinforcing connector may be formed of a multi-layer folded structure formed to be in close contact by folding the edge of the panel surface portion a plurality of times.

In addition, the reinforcing connection portion, the edge of the panel surface portion can be formed to be in close contact by folding a plurality of times by the equal folding (Equal folding) method.

In addition, the reinforcing connection portion may be formed to be in close contact by folding the edge of the panel surface portion in a half folding (Half folding) method.

In addition, the reinforcing connection portion is bent from the panel surface portion is formed extending, the end portion may be coupled in surface contact with the outer side of the reinforcement support portion to be in close contact with the second outer bent surface.

By means of the above solution, the present invention can be easily manufactured by simplifying the structure and manufacturing process of the fire door by forming a reinforcement structure using only the panel of the metal material constituting the fire door, without using a separate reinforcing member or the like. There is an advantage that it can.

In particular, the present invention has the advantage that by forming the shape of the coupling portion of the front panel and the rear panel by a roll forming process, it is easy to process and still obtain sufficient support and strength.

Through this, the present invention has the advantage of improving the sealing performance of the whole fire door through a simple structure and process that can greatly improve the bearing capacity and strength of the edge side of the fire door.

Thus, the present invention has the effect of improving the flame shielding effect and prevent fire spreading effectively when a fire occurs.

More specifically, the present invention does not constitute a reinforcing member such as a separate support, but through the folding and bending process for the edges of the front panel and the rear panel, by combining the coupling portion in two or more layers of support force and strength There is an advantage that can be improved.

As a result, the present invention has the effect of improving the bending stress and torsional stress, which is represented by the sum of the compressive stress and the tensile stress, to minimize the deformation of the fire door by external force.

Therefore, it is possible to improve the reliability and competitiveness in the field of fire doors and fire door reinforcement structures, in particular the corner reinforcement structure of the frame for fire doors, as well as similar or related fields.

1 is a view for explaining an embodiment of a multi-structure fire door frame coupling structure according to the present invention.
FIG. 2 is a diagram illustrating each configuration of the front panel shown in FIG. 1.
3 to 5 are views for explaining a processing method of the front panel shown in FIG.
FIG. 6 is a view illustrating each configuration of the rear panel shown in FIG. 1.

An example of a multi-structure fire door frame coupling structure according to the present invention can be applied in various ways, hereinafter with reference to the accompanying drawings will be described the most preferred embodiment.

1 is a view for explaining an embodiment of a multi-structure fire door frame coupling structure according to the present invention.

Referring to FIG. 1, the fire door A may be configured such that the edges of the front panel 100 and the rear panel 200 constituting the fire door A are coupled to each other, and the front panel 100 and the rear panel 200. In the inner space between the) a heat resistant material and a fire resistant material of various materials can be configured.

On the other hand, the fire door (A) is installed to be hinged to the fire door frame (F), the edge portion of the handle (not shown) of the fire door (A) in the process of closing the fire door (A) is a fire door frame (F) Impact may occur when hitting.

In other words, when the fire door (A) is closed, a significant impact may occur on the 'a' portion of the edge of the fire door (A) in close contact with the fire door frame (F), the impact may be transmitted to the 'b' portion connected thereto have.

When the deformation or damage occurs at the edge of the fire door (A) due to such an impact, a gap may occur in the state in which the fire door (A) is closed, which results in inferior sealing of both sides of the fire door (A). Fires in a space can cause dangerous situations, such as exposing one side to a flame or spreading a fire.

Therefore, the present invention is intended to solve the above-described problems by improving the structural strength of the 'a' portion and the 'b' portion as shown in FIG.

In general, in order to prepare for such an impact, a separate reinforcement or reinforcing structure is applied, but in the present invention, the front panel 100 and the rear panel (as shown in FIG. It is intended to improve the strength of the part by the processing method of 200).

Here, it is shown that the fire door (A) to which the frame coupling structure of the present invention is applied is formed to have a shape that is in close contact with the fire door frame (F) in multiple stages in order to increase the sealing property on both sides of the fire door (A). Of course, the shape of the fire door frame (F) corresponding to the edge shape of the fire door (A) is not limited to Figure 1, it can be variously modified according to the needs of those skilled in the art.

Thus, the present invention will be described with respect to the fire door (A) is closed so that the shape of the fire door frame (F) is in close contact with the fire door frame (F) of various shapes in multiple stages.

In addition, the shapes of the front panel 100 and the rear panel 200 shown in FIG. 1 are not necessarily determined, and the shapes of the front panel 100 and the rear panel 200 are formed opposite to each other, or the front panel 100. The shape of the rear panel 200 and the shape of the same may be configured to have a structure in which the front and rear surfaces are symmetrical.

However, in order to easily describe the technical features of the present invention, the shape of the front panel 100 and the rear panel 200 will be described as an example as shown in FIG. 1, and the front panel 100 and It is to be considered that the shape of the rear panel 200 may be mutually substituted or the same.

FIG. 2 is a diagram illustrating each configuration of the front panel shown in FIG. 1.

Referring to FIG. 2, the front panel 100 has a stepped portion corresponding to a portion 'a' of FIG. 1 at the edge of the panel surface portion 110 based on the panel surface portion 110 constituting the front surface of the fire door A. FIG. 120 and the reinforcement support part 130 corresponding to the 'b' portion is formed.

The stepped part 120 is formed to extend from at least a part of the edge of the panel surface part 100 forming the fire door A, and is configured to be stacked in an inner and outer layered structure as shown in FIG. 2.

The reinforcement support 130 is formed to extend from the stepped portion 120 to be coupled to be connected to the rear panel 200, which is also configured to be stacked in an inner and outer lap structure as shown in FIG. 2.

In other words, the stepped part 120 and the reinforcement support part 130 shown in FIG. 2 may be formed in a double structure that is folded and formed so that the edge of the front panel 100 is in close contact.

As shown in FIG. 1, the stepped part 120 is formed to protrude into the fire door frame F, and may include a first bent part 121 and a second bent part 122.

The first bent portion 121 is formed to be bent in one direction from the panel surface portion 110, and the first outer bent surface 131a formed on the outside of the dual structure and the first inner bent surface 121b formed on the inner side. ) May be included.

The second bent portion 122 is formed by being bent in one direction from the first bent portion 121, the second outer bent surface 122a formed on the outside of the dual structure and the second inner bent surface formed on the inside. 122b).

As a result, the step portion 120 is formed by extending the first outer bent surface (121a) formed on the outside of the first bent portion 121 is bent from the panel surface portion 110, the second bent portion 122 The second outer bent surface 122a configured at the outside may be bent and extended from the first outer bent surface 121a.

In addition, the second inner bent surface 122b configured inside the second bent part 122 of the stepped part 120 is bent from the reinforcing support part 130 and extended to be in close contact with the second outer bent surface 122a. The first inner bent surface 121b of the first bent portion 121 may be bent from the second inner bent surface 122b and extended to closely contact the first outer bent surface 121a.

In addition, as shown in FIG. 2, the panel support surface (not shown) which is bent and extended from the first inner bent surface 121b may be configured to be in close contact with the panel surface portion 110.

As a result, by including a stepped portion 120 and the reinforcement support 130 in a double-layered dual structure up to the edge portion of the panel surface portion 110, to strengthen the bonding force with the rear panel 200, the fire door (A) It can greatly improve the structural strength to counteract the external force generated during the use of.

The reinforcement support part 130 is formed to be bent in the other direction from the second bent part 122, and the outer reinforcing surface 130a and the second inner bent surface 122b extending from the second outer bent surface 122a described above. The extended inner reinforcing surface 130b may be formed in a folded double structure to be in close contact.

Hereinafter, the process of forming each component of the front panel 100 will be described.

3 to 5 are views for explaining a processing method of the front panel shown in FIG.

First, the processing method to be described below will be described as processing by using a roll forming process as described above, can be changed to the same or similar processing method as the roll forming process according to the needs of those skilled in the art, such a processing method is physical It is not limited to a processing method.

As shown in FIG. 3, when the flat panel surface portion 110 is supplied as a raw material, the edge 111 of the panel surface portion 110 may be folded and adhered to form a folded portion 111a by being processed in a double structure. The stepped portion 120 and the reinforcement support 130 may be formed by roll forming the folded portion 111a of the edge processed in a double structure as described above.

In more detail, as shown in FIG. 4, after bending the edge of the folded portion 111a to form the reinforcement support part 130, the stepped part ( By forming the second bent portion 122 of 120 and bending again in the corresponding direction to form the first bent portion 121 of the stepped portion 120, the stepped portion 120 and the reinforcement support 130 may be formed. Can be.

Alternatively, as shown in FIG. 5, after bending the center inner portion (the right direction in FIG. 5) of the folded portion 111a, the portion having a predetermined height is bent again to form the first bent portion 121. The edge portion of the folded portion 111a may be bent in the opposite direction to form the second bent portion 122 and the reinforcement support 130.

In the above, the front panel 100 has been described in detail. Hereinafter, the rear panel 200 coupled to the front panel 100 will be described in detail.

FIG. 6 is a view illustrating each configuration of the rear panel shown in FIG. 1.

Referring to Figure 6, the fire door (A) having a coupling structure of the present invention may form a reinforcing connector 220 in the rear panel 200 is coupled to the front panel 100.

The reinforcing connection part 220 is a part coupled to the reinforcing support part 130 of the front panel 100 and may be extended by bending a part of the edge of the panel surface part 220 of the rear panel 200.

At this time, the reinforcing connection part 220 may be folded into a plurality of times to be in close contact with a part of the bent edge, it may be formed in a multi-layer folded structure consisting of a layered structure.

For example, the reinforcing connection part 220 may form an equal folding part 221 by folding the edges of the panel surface part 220 at equal intervals as shown in FIG. 6 (a). A method of folding a plurality of times at equal intervals to form a close contact is called an equal folding method.

As another example, the reinforcing connection part 220 may form a half folding part 222 by sequentially folding the edges of the panel surface part half by half as shown in FIG. 6 (b). Half-folding is a method in which the part is repeatedly folded to form a close contact.

As described above, when the reinforcement connection part 220 of the rear panel 200 is formed in a layered structure by an equal folding method or a half folding method, as shown in part 'b' of FIG. The reinforcing support portion 130 of the front panel 100 and the reinforcing connection portion 220 of the rear panel 200 may be coupled to the second outer bent surface 122a of the panel 100. At this time, the coupling of the reinforcement support 130 and the reinforcement connection 220 may be made by various methods such as welding, riveting, of course.

As a result, the reinforcing connector 220 may be in surface contact with the outer reinforcing surface 130a which is the outer side of the reinforcing support 130 and may be coupled to the reinforcing support 130 while being in linear contact with the second outer bent surface 122b. have.

Therefore, the fire door (A) having a coupling structure of the present invention is a 'a' portion protruding from the fire door frame (F), 'a' is connected to the front panel 100 and the rear panel 200 ' The structural strength of the b ′ part can be greatly improved.

In addition, by not using a separate reinforcing member, such as to improve the structural strength, it is possible to simplify the process and to improve the work efficiency, and to improve the productivity of the product and reduce the manufacturing cost have.

The fire door frame coupling structure of the multi-structure according to the present invention has been described above. Such a technical configuration of the present invention will be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood in all respects as illustrative and not restrictive.

A: Fire door
100: front panel
110: panel surface 111: edge
120: stepped portion
121: first bending part
121a: first inner bent surface 121b: first inner bent surface
122: second bending part
122a: second outer bent surface 122b: second inner bent surface
130: reinforcement support
130a: outer reinforcement surface 130b: inner reinforcement surface
200: rear panel
210: panel surface portion
220: reinforcement connection
221: equal folding 222: half folding

Claims (10)

In the joining structure of the fire door frame is configured such that the edges of the front panel and the rear panel constituting the fire door are coupled to each other,
Any one of the front panel and the rear panel,
A stepped portion configured to be stacked in a layered structure and extending from at least a portion of an edge of the panel surface portion forming the fire door; And
It is configured to be stacked in a layered structure, extending from the stepped portion is reinforced support portion coupled to the other of the front panel and the rear panel; includes,
At least one of the stepped portion and the reinforcement support portion,
Consists of a dual structure folded and formed so as to close the edge of any one of the front panel and the rear panel,
The stepped portion,
A first bent portion bent in one direction from the panel surface portion; And
And a second bending portion bent in one direction from the first bending portion.
The reinforcement support part,
Is bent from one side in the other direction from the second bent portion,
The stepped portion and the reinforcing support portion is composed of a double structure of the outer and inner,
The stepped portion,
The first outer bent surface configured to the outside of the first bent portion and the second outer bent surface configured to the outside of the second bent portion are sequentially formed from the panel surface portion is connected to the reinforcement support portion,
The second inner bent surface formed inside the second bent portion and the first inner bent surface formed inside the first bent portion are sequentially formed from the reinforcement support portion,
The reinforcement support part,
Consists of a double structure folded so that the outer reinforcing surface extending from the second outer bent surface and the inner reinforcing surface extending from the second inner bent surface is in close contact,
The other of the front panel and the rear panel,
The reinforcing connection portion coupled with the reinforcing support portion extends from at least some of the edges of the panel surface portion,
The reinforcing connection portion,
It is a multi-layer folding structure formed to be in close contact with the edge of the panel surface portion a plurality of times,
The reinforcing connection portion,
It is bent and extended from the panel surface portion, the end portion is coupled to the outer surface of the reinforcing support portion to be in close contact with the second outer bent surface,
The edges of the panel surface are folded to closely contact each other to form a reinforcement support by bending the edge of the folded portion formed by a double structure, and then bent in a direction opposite to the direction in which the reinforcement support is bent to form a second bent portion of the stepped portion. And the stepped portion and the reinforcing support portion are formed by bending the plate again to form the first bent portion of the stepped portion.
In the joining structure of the fire door frame is configured such that the edges of the front panel and the rear panel constituting the fire door are coupled to each other,
Any one of the front panel and the rear panel,
A stepped portion configured to be stacked in a layered structure and extending from at least a portion of an edge of the panel surface portion forming the fire door; And
It is configured to be stacked in a layered structure, extending from the stepped portion is reinforced support portion coupled to the other of the front panel and the rear panel; includes,
At least one of the stepped portion and the reinforcement support portion,
Consists of a dual structure folded and formed so as to close the edge of any one of the front panel and the rear panel,
The stepped portion,
A first bent portion bent in one direction from the panel surface portion; And
And a second bending portion bent in one direction from the first bending portion.
The reinforcement support part,
Is bent from one side in the other direction from the second bent portion,
The stepped portion and the reinforcing support portion is composed of a double structure of the outer and inner,
The stepped portion,
The first outer bent surface configured to the outside of the first bent portion and the second outer bent surface configured to the outside of the second bent portion are sequentially formed from the panel surface portion is connected to the reinforcement support portion,
The second inner bent surface formed inside the second bent portion and the first inner bent surface formed inside the first bent portion are sequentially formed from the reinforcement support portion,
The reinforcement support part,
Consists of a double structure folded so that the outer reinforcing surface extending from the second outer bent surface and the inner reinforcing surface extending from the second inner bent surface is in close contact,
The other of the front panel and the rear panel,
The reinforcing connection portion coupled with the reinforcing support portion extends from at least some of the edges of the panel surface portion,
The reinforcing connection portion,
It is a multi-layer folding structure formed to be in close contact with the edge of the panel surface portion a plurality of times,
The reinforcing connection portion,
It is bent and extended from the panel surface portion, the end portion is coupled to the outer surface of the reinforcing support portion to be in close contact with the second outer bent surface,
The edges of the panel surface are folded to closely contact each other, and the center inner portion of the folded portion formed by the double structure is bent, and then a portion of a predetermined height is bent again to form a first bent portion, and then the edge portion of the folded portion is bent in the opposite direction. A multi-structure fire door frame coupling structure, characterized in that the second bent portion and the reinforcing support portion formed.
The method according to claim 1 or 2,
The reinforcing connection portion,
Multi-structured fire door frame coupling structure characterized in that the edge of the panel surface portion is formed to be in close contact by folding a number of times by the equal folding (Equal folding) method.
The method according to claim 1 or 2,
The reinforcing connection portion,
Multi-structured fire door frame coupling structure characterized in that the edge formed in the panel side by folding the half folding (Half folding). delete delete delete delete delete delete

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