KR102075487B1 - Fire Door - Google Patents

Abstract

The present invention relates to a complex functional fire door preventing deformation of the fire door by shielding heat due to fire and, also, providing excellent performance such as airtightness, insulation, protection against wind, and prevention of dew condensation. According to the present invention, the complex functional fire door has a space inside where the front and rear plates are connected. An insulation material is filled in the space. The complex functional fire door comprises: the front plate having the shape of a rear side opening type box; the rear plate having the shape of a front side opening type box and installed at a fixed interval from the front plate; an inner frame connecting an edge circumference of the front plate and the rear plate; an insulation unit installed between the inner frame and a rear plate edge surface of the rear plate; and a packing installed on a packing connection surface of the insulation unit, wherein a first sealing is formed at an end on the front side of the packing and a second sealing is formed at an end on the rear side. The front plate has a front plate edge unit coupled to the inner frame by being bent toward the rear side, and the rear plate has the rear plate edge surface coupled to the inner frame by being bent toward the front side. The inner frame has: a front plate coupling unit coupled to the front plate edge unit; and a rear plate coupling unit coupled to the rear plate edge surface.

Description

Composite functional fire door

The present invention relates to a composite functional fire door having excellent performances such as airtightness, heat insulation, sound insulation, windbreak, heat shielding, condensation prevention, etc., while preventing the deformation of the fire door by shielding heat due to fire.

In general, the fire door is made of metal, the fire door is manufactured in the form of a square box, the intermediate material (such as honeycomb of paper material) is formed inside the box, the door frame is manufactured in the form of an outer open box, the inner side of the rear door of the fire door Steps are formed in which.

These fire doors are installed and used to prevent the movement and diffusion of high-temperature flames and toxic gases (hereinafter referred to as 'flames') in the event of a fire, and the front or rear of the fire doors may be Even if exposed to a fire for a long time there should be no deformation such as bending, door frame should also be free from deformation by flame.

By the way, the current fire door and door frame can achieve the above purpose and the blocking effect of the cold wind, but the insulation function to prevent the cold air transfer or conduction from the front to the rear direction is very insufficient, so the fire door or door frame in winter The problem of dew condensation on the back was caused.

In accordance with such a problem, various fire doors for preventing condensation have been proposed and implemented. In the fire door, there is a method of blocking the conduction of cold air by adopting a packing between the front and the rear of the fire door, and the method of using a mineral or a heat insulating material as an intermediate material.

However, due to the structural problem that the shape of the fire door using the packing must be firmly maintained, it is impossible to solve the condensation because the packing cannot be adopted throughout the front and rear boundary parts, and the fire door using the heat insulating material. Silver cannot prevent the conduction of cold air along the outer surface of the fire door, which also cannot prevent condensation.

Republic of Korea Utility Model Publication No. 20-2010-0004605 Republic of Korea Utility Model Registration Publication No. 20-0369797

The present invention is to solve the above problems, the object of the present invention is to provide a fire door that is excellent thermal insulation of the fire door is blocked mutual heat transfer between the front panel and the back plate.

It is another object of the present invention to provide a fire door that can prevent condensation due to excellent heat insulating performance.

The problem to be solved of the present invention is not limited to the above-mentioned problem. In addition, other technical problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

Complex functional fire door according to the present invention, the space is formed inside the combination of the front plate and the back plate, the fire door is filled with a heat insulating material in the space, the front plate of the rear open type; A rear panel of a front open box type disposed at a predetermined distance from the front panel; An inner frame connecting peripheral edges of the front and rear plates; A heat insulator which is employed between the rear plate edge of the rear plate and the inner frame; It is seated on the packing connection surface of the heat insulation, and comprises a packing in which the first sealing is formed at the front end and the second sealing is formed at the rear end, and the front plate is bent in the rear direction and fastened to the inner frame. Forming a front plate edge, the rear plate is bent in the front direction to form a rear plate edge fastened to the inner frame, the inner frame fastening portion and the back plate fastened to the front plate edge It is characterized in that to form a back plate fastening portion fastened to the edge surface.

The present invention has an excellent thermal insulation of the fire door by blocking the mutual heat transfer between the front plate and the back plate.

In addition, the present invention has the effect of blocking the condensation phenomenon occurring in the fire door due to the excellent heat insulating performance.

1 is a front view illustrating a state in which the complex functional fire door is installed in the door frame according to the present invention
Figure 2 is an exemplary view showing a cross-sectional view of the structure of the composite functional fire door according to the invention and the door frame in which the fire door is installed
3 is a partial cross-sectional perspective view and a partially enlarged cross-sectional perspective view illustrating an inner frame and a heat insulator according to the present invention;
4 is a partially enlarged cross-sectional perspective view illustrating a state in which a packing is added to the partially enlarged cross-sectional perspective view of FIG.
5 is an exemplary view showing in enlarged cross-sectional view the configuration of a composite functional fire door according to the present invention
6 is an exploded view illustrating the configuration of a composite functional fire door according to the present invention in a disassembled shear view;
7 is an exemplary view showing the operation of the composite functional fire door according to the present invention
Figure 8 is a side cross-sectional view showing another configuration of the composite functional fire door according to the present invention
Figure 9 is a cross-sectional view showing another configuration of the packing according to the present invention

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. However, in describing the preferred embodiments of the present invention in detail, when it is determined that the detailed description of the related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions. In addition, throughout the specification, when a part is connected to another part, this includes not only the case where it is directly connected, but also the case where it is indirectly connected by the other element in the middle. In addition, the inclusion of any component means that other components may be further included, unless specifically stated otherwise. The accompanying drawings of the present invention may exaggerate, reduce or omit each component or a specific part constituting the components for understanding of the invention. In the following description, the front direction, the width direction, and the width direction refer to the directions shown in FIGS. 1 and 2.

1 to 6, the composite functional fire door according to the present invention is rotatably installed in the door frame 700 to prevent the flame is transferred to the adjacent space in the event of a fire. The composite functional fire door according to the present invention has a space formed therein by the combination of the front plate 100 and the back plate 200, in the fire door is filled with the heat insulating material 600 in the space, the front panel of the open type back box type An inner frame connecting the periphery of the front panel 100 and the rear panel 200 of the front open box form at regular intervals from the front panel 100 and the front panel 100 and the rear panel 200. It comprises a 300 and the heat insulating hole 400 which is employed between the back plate edge surface 210 and the inner frame 300 of the back plate 200.

The front plate 100 is fastened with the inner frame 300 by a fastener B such as a piece, and the back plate 200 is also fastened with the inner frame 300 by a fastener B so that the front plate 100 is fastened. ) And the back plate 200 are arranged while maintaining a constant interval without being in contact with each other.

In the following description, the front plate 100, the rear plate 200, the inner frame 300, the heat insulator 500, and the heat insulator 600 will be described in detail with reference to the left portion of the cross section viewed from the upper direction.

The front plate 100 is a plate having a predetermined thickness and a rear shape is open. At the edge of the front plate 100 is formed a front plate edge portion 110 bent in the rear direction. The front plate edge portion 110 is the second front plate bent back bent in the direction of the center of the fire door at the end of the first front plate bent surface 111 bent in the rear direction and the first front plate bent surface 111. Face 112.

The front plate fastening hole 113 is formed in the second front plate bending surface 112, and the front plate fastening hole 113 is formed to protrude a predetermined distance in the front direction. The fastener B is connected to the front plate fastening hole 113, and the fastener B is fastened to the front plate fastening portion 310 of the inner frame 300 to allow the inner frame 300 and the front plate 100. ).

The front end portion of the front plate fastening hole 113 protruding in the front direction is in contact with the front plate fastening portion 310 of the inner frame 300, and by this contact the front plate fastening portion 310 and the second front plate. A front plate insulation space 114 is formed between the bent surfaces 112, and heat transfer between the front plate 100 and the inner frame 300 is minimized by the front plate insulation space 114.

The back plate 200 is a plate having a predetermined thickness and has an open shape in the front direction. The rear plate edge 210 is formed at the edge of the rear plate 200 is bent in the front direction, the rear plate edge 210 is formed with a back plate fastening hole 211. The back plate fastening hole 211 is formed to protrude a predetermined distance in the direction of the fire door center. A fastener B is connected to the back plate fastening hole 211, and the fastener B is fastened to the back plate fastening portion 320 of the inner frame 300 to be the inner frame 300 and the back plate 200. ).

Fireproof door center direction end portion of the back plate fastening hole 211 is in contact with the heat insulating opening 400, by the contact between the back plate fastening portion 320 and the heat insulating opening 400 is the back plate insulating space (212) The heat transfer between the rear plate 200 and the inner frame 300 is blocked by the rear plate insulation space 212 and the heat insulator 400.

The inner frame 300 has a back plate fastening portion 320 formed to be long in the width direction, a front plate fastening portion 310 formed to be long in the longitudinal direction at the front end of the back plate fastening portion 320, and the front plate. The second front plate fastening portion 311 is formed to be refracted in the front direction at the longitudinal end of the fastening portion 310.

The back plate fastening part 320 is coupled to the back plate 200 by fastening with the fastener B connected to the back plate fastening hole 211, and the front plate fastening part 310 is the front plate fastening hole 113 It is coupled to the fastener B connected to the through and coupled to the front plate 100. The second front plate fastening portion 311 prevents deformation of the front plate 100 and improves the rigidity of the fire door. The second front plate fastening portion 311 is formed so as not to contact the first front plate bending surface 111.

The heat insulating material 600 is formed of a material having high thermal insulation or heat resistance, including mineral wool. In the above description, the mineral wool is illustrated as the heat insulating material (GW), but the heat insulating material (GW) according to the present invention is a material having high thermal insulation or heat resistance, and is made of fiber, such as glass wool, rock wool, asbestos, or clay, magnesia, Polyporous ones such as cork, foamed plastic plates (foamable styrol, etc.), or ceramic-based ones such as refractory bricks, heat resistant blocks, and heat resistant tiles can be used. In the accompanying drawings, only the number is shown without the heat insulator 600 separately, but it is well known that the heat insulator is filled in the interior of the fire door, and thus the illustration of the detailed position of the heat insulator is omitted.

The rear plate fastening portion 320 of the inner frame 300 is formed with a thermal insulation hole 330. The heat insulation 330 blocks the heat conduction in the width direction of the inner frame 300 to further improve the insulation, heat shielding, condensation prevention, and fire protection performance of the fire door. The length of the thermal insulation hole 330 is not limited to the illustrated figure.

The heat insulation port 400 is disposed between the rear plate edge surface 210 and the rear plate fastening portion 320. The heat insulator 400 is disposed between the rear plate edge 210 and the rear plate fastening portion 320 to insulate between the rear plate 200 and the inner frame 300. The packing opening surface 410 is formed in the heat insulation port 400, and the packing 500 is seated on the packing connection surface 410.

5 and 6, the front end portion of the front plate fastening hole 113 of the front plate 100 is in contact with the front plate fastening portion 310 of the inner frame 300, the fastener (B) Is fastened to the heat of the front plate 100 is transferred to the front plate fastening portion 310 finely.

However, heat applied to the front plate fastening portion 310 through the front plate 100 is blocked by heat transfer by the heat insulation hole 330. In addition, a rear plate insulation space 212 and a heat insulating device 400 are disposed between the rear plate edge surface 210 of the rear plate 200 and the rear plate fastening portion 320 of the inner frame 300. Transfer of the heat applied through 100 to the backplane 200 is again blocked.

On the other hand, the heat of the back plate 200 is finely applied through the fastener (B) penetrating the back plate 200 and the back plate fastening portion 320 is the heat insulation hole 330 of the back plate fastening portion 320 Is blocked. Therefore, heat transmitted to the front plate 100 through the back plate 200 is blocked, and heat from the front plate 100 is also blocked from being transferred to the back plate 200.

The packing 500 includes a packing fixing piece 530 and a packing fastener 540. The packing 500 is composed of a first seal 510 formed at the front end and a second seal 520 formed at the rear end. The packing fixing piece 530 is a plate having a predetermined thickness, and is seated between the first sealing 510 and the second sealing 520, and the packing fastener 540 penetrates the packing fixing piece 530 and the packing 500. Is tightened.

With reference to Figure 7 looks at the operation of the fire door according to the present invention. Since the door frame 700 and the door frame packing 710 shown in FIG. 7 are well known technologies, detailed descriptions thereof will be omitted. The dashed-dotted line including the arrow shown in FIG. 7 shows the flow of air.

The minute heat applied to the front plate fastening portion 310 through the front plate 100 is blocked by heat transfer to the back plate fastening portion 320 by the heat insulating cabinet 330, the rear plate (by the heat insulation 400) Heat transfer to 200 is again interrupted.

In addition, the heat of the back plate 200 which is finely transmitted through the fastener B passing through the back plate 200 and the back plate fastening portion 320 is blocked by the heat insulation hole 330. Therefore, heat transmitted to the front plate 100 through the back plate 200 is blocked, and heat from the front plate 100 is also blocked from being transferred to the back plate 200.

The first sealing 510 blocks the flow of air moving in the direction of the back plate 200 in the front plate 100 direction, and the second sealing 520 moves in the front plate direction in the rear plate 200 direction. Shut off the flow of air.

The front plate edge portion 110 bends the flow of air moving between the door frame 700 and the front plate 100 to weaken the flow of air moving from the front plate 100 toward the first sealing 510, The first sealing 510 blocks the flow of air moving from the front plate 100 to the rear plate 200.

The first seal 510 and the second seal 520 contact the door frame 700 and again block the flow of air. The back plate 200 contacts the door frame packing 710 to block the flow of air moving between the back plate 200 and the door frame packing 710, and the second sealing 520 is the door frame packing 710 and the second It blocks the flow of air between the seals 520.

Therefore, the fire door according to the present invention blocks heat transfer between the front plate 100 and the back plate 200, and blocks the flow of air between the front plate 100 and the back plate 200 to provide excellent thermal insulation and dew condensation. Exert.

8 is a side cross-sectional view showing another configuration of the composite functional fire door according to the present invention. Referring to Figure 8 looks at another configuration of the composite functional fire door according to the present invention.

Another configuration of the composite functional fire door according to the present invention has the same configuration as the above-described composite functional fire door on the left side, the upper surface, and the right side, and only different surfaces. As shown in FIG. 8, in another configuration of the composite functional fire door according to the present invention, a first front plate bent surface 111 is formed on a bottom surface of the front plate 100, and the first front plate bent surface 111 is formed. The front plate fastening hole 113 is formed. That is, the configuration corresponding to the second front plate bent surface 112 is lost in the above-described configuration.

On the other hand, the lower surface of the inner frame 300 is formed longer than the length of the rear plate fastening portion 320 in the front direction compared to the left surface, the upper surface, the right surface, the upper portion at the front end of the rear plate fastening portion 320 The second front plate fastening portion 311 is refracted in the direction is formed. That is, the configuration corresponding to the front plate fastening portion 310 in the above-described configuration is lost.

The composite functional fire door of another configuration according to the present invention can maintain the performance of airtightness, heat insulation, sound insulation, windbreak, heat shield, condensation prevention, etc., while reducing the cost and simplifying the configuration compared to the composite functional fire door described above. In other words, it can pass certain performance tests (moon heat, condensation, etc.) specified in the fire door.

9 is a cross-sectional view showing another configuration of the packing according to the present invention. As shown in Figure 9, the other configuration of the packing according to the present invention is the same as the packing 500 described above, except that the first seal 510 is configured in a tubular shape.

In another configuration of the packing according to the present invention, the first seal 510 is configured to have a tube shape instead of a wing shape to more effectively block the flow of air moving between the front plate edge 110 and the door frame.

While the present invention has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various changes or modifications can be made within the spirit and scope of the present invention, and therefore, such changes or modifications. Will belong to the appended claims.

100: front panel 110: front panel edge portion
111: first front plate bending surface 112: second front plate bending surface
113: front plate fastening 114: front plate insulation space
200: rear plate 210: rear plate edge
211: rear plate fastening 212: rear plate insulation space
300: inner frame 310: front panel fastening
320: rear panel fastening part 311: second front panel fastening part
330: heat insulation 400: heat insulation
410: packing connection surface 500: packing
510: first seal 520: second seal
530: packing fixing 540: packing fastener
600: insulation material B: fastener
700: door frame 710: door frame packing

Claims (2)

In the fire door, the space is formed inside the combination of the front plate 100 and the back plate 200, the heat insulating material 600 is filled in the space,
A front plate 100 having a rear open box form;
A rear panel 200 having a front open box shape disposed at a predetermined distance from the front panel 100;
An inner frame 300 connecting the edges of the front plate 100 and the back plate 200;
A heat insulating tool 400 which is employed between the rear plate edge surface 210 and the inner frame 300 of the rear plate 200;
The packing 500 is seated on the packing connection surface 410 of the heat insulation port 400, the first sealing 510 is formed at the front end and the second sealing 520 is formed at the rear end. Make up,
The front plate 100 is bent in the rear direction to form a front plate edge portion 110 which is fastened to the inner frame 300, the back plate 200 is bent in the front direction and fastened to the inner frame 300 Forming a rear plate edge surface 210, the inner frame 300 having a front plate fastening portion 310 fastened to the front plate edge portion 110 and a rear plate edge surface 210 fastened to the rear plate edge surface 210. Composite functional fire door, characterized in that to form a plate fastening portion (320). delete

Images