KR100797761B1 - Wood type fire door - Google Patents

Abstract

A wood based fire door is provided to lower the cost of the door, and to enhance the fire resistance of the door by coupling fire proof material with a filling material space in step shapes and by coupling water contraction preventing groove and sills in step shapes. A heart wood(10) in a square frame shape, having inside formed of at least one filling material space, and a fire proof filling material(20) coupled to the filling material space. On an inner edge of the filling material space and an outer edge of the fire proof filling material, a water contraction preventing groove(12) and a water contraction preventing sill(29) are formed in step shapes. The cross section shape of water contraction groove and sill are in a shape of steps. A fire proof layer is disposed on front and back sides of the heart wood.

Description

Wood type fire door

1 is a simplified front view of a typical wood-based fire door,

2 and 3 is a side cross-sectional view of a conventional wood-based fire door,

4 and 5 is a cross-sectional side view of the wood-based fire door according to the invention,

Figure 6 is a side cross-sectional view showing the use of the wood-based fire door of Figures 4 and 5,

7 and 8 are side cross-sectional view showing another embodiment of the wood-based fire door according to the invention.

* Explanation of symbols for the main parts of the drawings

10: heartwood 11: outer heartwood

12: shrinkage preventing groove 13: inner core material

15: filling material space 17: heating foam

20: refractory filler 29: shrink prevention jaw

30: fiber board 40: decor sheet

50: door frame 60: flameproof layer

The present invention relates to a wood-based fire door, and more particularly to a wood-based fire door that is improved in the prevention of shrinkage and fire protection structure of the refractory filler.

Conventional indoor doors are mostly made of wood or synthetic resin materials, and indoor doors of such wood or synthetic resin materials are lost in a short time in the event of a fire, thereby preventing the indoor space from being protected from flame and smoke for a predetermined time.

Such conventional indoor doors do not significantly exceed the 30-minute fire resistance standard of KS-2268-1, which is a performance standard of domestic Euljong fire doors, and in fact, the fire role of the indoor door is meaningless in the event of a fire.

On the other hand, as the expansion of balconies of apartments, such as apartments, has become legal, the installation of separate evacuation spaces has become mandatory, and the fire protection performance of the doors installed in the evacuation spaces and indoors has a fireproof performance of 1 hour at 925 ° C. The performance standard of KS F-2268-1 was enacted.

Conventional fire doors satisfying the first type of fire protection performance are mostly steel fire doors, and some wood fire doors use aggregated flame retardant wood and expensive ceramic fireproof boards as fillers.

However, in the case of steel fire doors, there are problems in that they are applied to interiors or impart interior characteristics. In the case of wood-based fire doors using flame-retardant wood and ceramic fire boards, the thickness is very thick and the product price is high. There was a problem.

Thus, Japanese Patent Application Laid-Open No. 8-82166 discloses a wood-based fire door 101 that can be applied to slim and various interior designs and satisfies fire performance for one hour.

The wood-based fire door 101 is a frame-shaped wood core member 110 having a plurality of filling space 111, the first calcium silicate plate 120 is coupled to the filling space 111 of the core material 110 and And a pair of second calcium silicate plates 130 coupled to the front and back surfaces of the core 110 and the first calcium silicate plate 120 and the outer surfaces of both second calcium silicate plates 130. The interior plate 140 is configured.

The wood-based fire door 101 is made of a calcium silicate plate with excellent fire resistance to configure the fire door 101, so as to satisfy the fire protection criteria for 1 hour while maintaining a thin thickness of the fire door 101. In addition, by combining the interior plate 140 on the outer surface, it is possible to implement a variety of interior design.

By the way, in the conventional wood-based fire door 101, the core material 110 forming the frame of the fire door 101 is formed of wood for securing the strength for the door frame installation, the front and rear surfaces of the core material 110 The second calcium silicate plate 130 coupled to the electrode is inevitably formed relatively thin in consideration of an increase in the thickness of the fire door 101. As a result, the core material 110 is lost in a relatively fast time by the heat transmitted through the second calcium silicate plate 130 during a fire, and thus the fire resistance of the fire door 101 is greatly reduced.

In addition, in order to prevent the loss of the core member 110, since the fireproof member must be additionally provided on the circumferential surface of the core member 110, there is an inevitable problem of increasing thickness due to the addition of the fireproof member.

In addition, since a relatively expensive calcium silicate plate is provided in duplicate, there is a problem that the product price of the fire door 101 is formed at a high price.

On the other hand, the calcium silicate is characterized by having a slight shrinkage by heating, to be compressed to a high density in order to minimize the shrinkage when applied to the fire door 101 to produce the first and second calcium silicate plate 130.

However, such a calcium silicate plate is impossible to completely prevent shrinkage even if it is compressed to a high density in view of the characteristics of calcium silicate.

Accordingly, in the conventional wood-based fire door 101 when the first calcium silicate plate 120 is slightly contracted when a fire occurs, a gap is generated between the core material 110 and the first calcium silicate plate 120, There is a serious problem that smoke, heat and flames move into the room through the gap between the core member 110 and the first calcium silicate plate 120.

Accordingly, as shown in Figure 3, the inner circumferential end of the core member 110 forming the inner wall of the filling space 111 and the circumferential end of the first calcium silicate plate 120, the shrinkage preventing groove 113 and the concave-convex on the groove Even if the first calcium silicate plate 120 is slightly contracted by forming a shrinkage preventing jaw 123 on the upper surface, the core member 110 and the first calcium silicate plate 120 are formed by the shrinkage preventing groove 113 and the shrinkage preventing jaw 123. The gap of the liver was prevented from occurring.

However, in the conventional wood-based fire door 101 having a shrinkage preventing structure of the first calcium silicate plate 120, the structure of the shrinkage preventing groove 113 and the shrinkage preventing jaw 123 is formed of a groove and an uneven structure Because of this, there is a problem in that it is virtually impossible to couple the first calcium silicate plate 120 to the filling space 111 after assembling the core material 110. Accordingly, before assembling the core material 110, the first calcium silicate plate 120 is disposed at a position corresponding to the filling space 111, and then the core material 110 is assembled around the first calcium silicate plate 120. Since the assembly process of the fire door 101 is to be increased, there is a problem that productivity is lowered.

Accordingly, an object of the present invention is to provide a wood-based fire door that is excellent in fire resistance, can reduce the thickness and price of the product, and can be combined with various designs to meet the needs of the user.

In addition, to prevent the shrinkage of the refractory filler, and to simplify the assembly of the refractory filler to provide a wood-based fire door that can reduce the assembly process and improve the productivity.

The object is, according to the present invention, in the wood-based fire door having a rectangular frame-shaped core material is formed with at least one filler space in the inside, and a refractory filler coupled to the filler space, the inner side of the filler space and The outer side of the refractory filler is achieved by a wood-based fire door, characterized in that the shrinkage preventing groove and the shrinkage preventing jaw is formed in a stepped structure corresponding to each other.

Here, the cross-sectional shape of the shrinkage preventing groove and the shrinkage preventing jaw is preferably formed in a stepped cross-sectional shape.

In addition, it is effective that a flameproof layer is formed on the front and rear surfaces of the core material.

At this time, it is more preferable that the said flameproof layer is provided with a liquid flameproof liquid or a plate-shaped flameproof plate.

On the other hand, the core material is a rectangular frame-shaped outer core forming the outer base frame of the door, and at least one inside is arranged vertically and / or horizontally to the inner space of the outer core material partitioning the filler space into a plurality of spaces Has heartwood; It is more effective that the high density calcium silicate inorganic refractory material has a specific gravity of 0.80 to 0.90.

At this time, it is preferable that the heating foam is coupled to the outer circumferential surface of the outer core material.

The refractory filler is effectively provided with a calcium silicate plate having a specific gravity of 0.20 to 0.30 having a thickness and an area corresponding to the filler space.

In addition, it is more preferable to include a fiber board formed of a medium density fiber board (MDF) or a high density fiber board (HDF) bonded over the entire surface of the core material and the refractory filler.

At this time, it is more effective that the thickness of the bonded state of the core material and the fiber plate is 42 mm or less.

On the other hand, it is preferable to further include a pair of decorative sheets laminated on the outer surface of the both fibreboard.

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

4 and 5 is a side cross-sectional view of the wood-based fire door according to the present invention, Figure 6 is a side cross-sectional view showing the use of the wood-based fire door of Figures 4 and 5. As shown in these figures, the wood-based fire door (1) according to the present invention is a core material 10 forming the base frame and the filler space of the door, and the refractory filler 20 is filled in the filler space of the core material 10 ), A pair of fiberboards 30 coupled to front and rear surfaces of the core 10 and the refractory filler 20, and a pair of decor sheets 40 coupled to the outer surfaces of both fiberboards 30. .

The core 10 has a frame-shaped outer core 11 and an inner core 13 disposed vertically and / or horizontally in the outer core 11 to form a plurality of filler spaces. The core material 10 is manufactured by using a high density, high-temperature, high-strength, high-strength, lightweight, high-density calcium silicate inorganic refractory material, wherein the cross-sectional thickness of the calcium silicate inorganic refractory material has a specific gravity of 0.80 to 0.90 (about 30 mm). It is preferable to have a specific gravity of 0.85) in order to satisfy the fire resistance criteria of the above-mentioned Gapjong fire door.

On the other hand, the end closure sheet 19 is attached to the circumferential end of the outer core material 11 along the circumferential direction, wherein, at the circumferential end of the outer core material 11, a graphite foam sheet or a foamed flame retardant which is a heating foam 17 The sheets are joined. Preferably, graphite foam sheets are used. The heating foam 17 is compressed to a thickness of about 1.5 mm at room temperature, but when a fire occurs, foaming starts at a predetermined temperature and expands up to 10 times or more, whereby a fire door 1 and a fire door 1 are installed. Block the gap between the door frame 50 to be. As a result, it is possible to block the movement of the flame and the smoke in the gap between the fire door 1 and the door frame 50 at the time of fire.

In addition, the inner circumferential wall of the filler space formed in the core material 10 is formed with a shrinkage preventing groove 12 having a stepped cross-sectional shape. The shrinkage preventing groove 12 corresponds to the shrinkage preventing jaw 29 formed at the circumferential end of the refractory filler 20 to be described later.

The refractory filler 20 is provided in a plate shape having a thickness and an area corresponding to the filler space of the core 10 and is coupled to each filler space of the core 10. The refractory filler 20 is to use a high-density calcium silicate plate having high temperature resistance, heat resistance and high strength, wherein the calcium silicate plate has a thickness of about 30 mm corresponding to the thickness of the core material 10 and 0.20 to It is preferable to be manufactured to have a specific gravity of 0.30 (preferably a specific gravity of 0.25) in order to satisfy the fire resistance criteria of the above-mentioned AAA fire door.

At this time, at the circumferential end of the refractory filler 20, a shrinkage preventing jaw 29 is formed on the stepped section corresponding to the shrinkage preventing groove 12 of the core material 10. As a result, the refractory filler 20 is inserted into the filler space from the outside after the core 10 is assembled. Therefore, the refractory filler 20 is easily assembled.

Here, the shrinkage preventing grooves 12 of the core material 10 and the shrinkage preventing jaw 29 of the refractory filler 20 have a range in which the refractory filler 20 can be inserted into and withdrawn from the filler space of the core material 10 in a plan view. It may be variously changed including the structure.

The fiber board 30 is provided with at least one of a medium density fiber board (MDF) or a high density fiber board (HDF) having a thickness of about 6 mm corresponding to the entire area of the core material 10 and the fireproof filler 20, and the core material 10 and the fireproof filler 20 ) Is combined with the front and rear surfaces. The fiber board 30 is for diversifying the design of the fire door 1, and can easily emboss or engrav the desired design on the outer surface.

Here, the thickness of the fiber board 30 can be reduced by improving the heat shielding performance of the core material 10, for example, as shown in Figure 7, flame retardant between the front and rear surfaces of the core material 10 and the fiber board 30. By forming the layer 60 to improve the heat shielding performance to block the heat transmitted to the core material 10, the thickness of the fiber board 30 can be reduced to about 4.5mm as much as the heat shielding performance improved by the flameproof layer 60. . As a result, the fire door 1 can be further slimmed down. Here, the flame retardant layer 60 may be provided with a liquid flame retardant or a flame retardant plate such as a magnesium board.

Deco sheet 40 has an area corresponding to the area of the fibreboard 30, the outer surface is expressed in a variety of patterns and textures, such as wood pattern or wood texture. Thereby, the external appearance of the fire door 1 can be designed beautifully by various methods. In addition, the teco sheet can be combined with various designs of embossed or intaglio processed on the outer surface of the above-described fibreboard 30 to express the exterior design of the fire door 1 more beautifully.

As shown in FIG. 6, the fire-resistance performance of the wood-based fire door 1 according to the present invention having the above-described configuration is installed in the steel door frame 50. And blocked the heat, it was confirmed that excellent noise and insulation. That is, the wood-based fire door (1) according to the present invention by using the core material 10 and the refractory filler (20) made of calcium silicate-based refractory angle material, exhibits excellent fire resistance performance that exceeds the above-mentioned first grade fire prevention performance. .

In addition, the wood-based fire door (1) according to the present invention can significantly slim the thickness of the fire door (1) with a total thickness of about 42mm, calcium silicate-based refractory filler (20) and relatively inexpensive magnesium-based fireproof board By using (30), a wood fire door 1 having a low product price is provided.

In addition, since a variety of interior design is grafted, it provides a wood-based fire door (1) having a design that meets the needs of the user.

In particular, by forming the shrinkage preventing grooves 12 and the shrinkage preventing jaws 29 on the stepped cross-sections corresponding to each other so as to conform to the inner peripheral wall of the filler space of the core material 10 and the peripheral end of the refractory filler 20, fire occurrence Even if the core 10 is slightly contracted as shown by the virtual display line “A” of FIG. 5, a gap does not occur between the core 10 and the refractory filler 20. As a result, it is possible to block the movement of smoke and heat between the core material 10 and the refractory filler 20 when a fire occurs.

In addition, since the shrinkage preventing grooves 12 and the shrinkage preventing projections 29 are formed on the stepped cross-section, the refractory filler 20 is simply inserted into the filling material space from the outside after the assembly of the core material 10 is completed. Can be.

As described above, according to the present invention, there is provided a wood-based fire door which is excellent in fire resistance, can reduce the thickness and price of the product, and can be combined with a variety of designs to meet the needs of the user.

In addition, while preventing the shrinkage of the refractory filler, it is provided with a wood-based fire door that can simplify the assembly of the refractory filler to reduce the assembly process and improve productivity.

Claims (10)

In the wood-based fire door having a core of a rectangular frame shape formed inside of at least one filler space, and a refractory filler coupled to the filler space, Wood-based fire door, characterized in that the inner side of the filler space and the outer side of the refractory filler is formed with a shrinkage preventing groove and a shrinkage preventing jaw is formed in a step structure corresponding to each other. The method of claim 1, Cross-sectional shape of the shrinkage preventing groove and the shrinkage preventing jaw is wood-based fire door, characterized in that formed in the stepped cross-sectional shape. The method according to claim 1 or 2, Wood-based fire door, characterized in that the flame-proof layer is formed on the front and rear surfaces of the core material. The method of claim 3, The flameproof layer is a wood-based fire door, characterized in that provided with a liquid flameproof plate or a plate-shaped flameproof plate. The method of claim 1, The core member includes a rectangular core shaped outer core forming the outer base frame of the door and at least one inner core disposed vertically and / or horizontally in the inner space of the outer core to divide the filler space into a plurality of spaces. Has; The core material is a wood-based fire door, characterized in that formed of high density calcium silicate inorganic refractory material having a specific gravity of 0.80 to 0.90. The method of claim 5, Wood-based fire door, characterized in that the heating foam is coupled to the outer peripheral surface of the outer core material. The method of claim 6, The refractory filler is a wood-based fire door, characterized in that provided with a calcium silicate plate having a specific gravity of 0.20 to 0.30 having a thickness and an area corresponding to the filler space. The method of claim 7, wherein And a fiber board formed of a medium density fiber board (MDF) or a high density fiber board (HDF) bonded over the entire surface of the core material and the front and back surfaces of the refractory filler. The method of claim 8, The thickness of the bonded state of the core material and the fiberboard is wood-based fire door, characterized in that less than 42mm. The method of claim 9, A wood-based fire door, characterized in that it further comprises a pair of decor sheets laminated on the outer surface of the both fibreboard.

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