KR101951918B1 - Heat insulation function improve fireproof door - Google Patents

Abstract

The present invention relates to a fire door with improved heat shielding function. For this purpose, the bending is performed while sequentially connecting the third side wall, the first step surface, and the fourth side wall on the front, left, and bottom of the door front of the fire door. And a stepped structure formed by bending forming while sequentially connecting the fifth side wall and the second step surface on the right side of the front surface of the door, to drastically improve the high temperature blocking function of the fire door against the flame. There is.
In the present invention for realizing this, in the fire door which improved the heat shielding function in which the fire door 2 is installed in the door frame 4 so that a door can be opened and closed by a hinge, the fire door 2 is the front door 30 and the door. ; A third side wall 32 and a first step surface 34 connected to upper, left and lower sides of the door front surface 30 and sequentially bent; A fourth side wall 36 extending and formed on the first step surface 34 and being bent; A fifth side wall (38) formed vertically while being connected over the right side of the third side wall (32) and the first step surface (34) and the right side of the fourth side wall (36); A second step surface 40 extending to an end of the fifth side wall 38 and connected to a right side of the fourth side wall 36; A door rear surface 42 connected to an end portion of the fourth side wall 36; And first, second and third door packings 45, 46 and 48 installed on the first and second stepped surfaces 34 and 40 and the fourth side wall 36, respectively.

Description

Heat insulation function improve fireproof door

The present invention relates to a fire door with improved heat shielding function. More specifically, the fire door is formed by sequentially connecting the third side wall, the first step surface, and the fourth side wall to the upper, left, and lower sides of the front door. It is intended to improve the high-temperature blocking function of the fire door to the flame by forming the bent, forming a step formed by bending bending while connecting the fifth side wall and the second step surface on the right side of the front door.

In addition, by installing a heat shield block filled with mineral wool in a semi-vacuum state while filling a fireproof filler inside the fire door, and simultaneously coating an eco-diatom layer on the inner surface of the heat shield block, the heat of the flame is transferred to the eco-diatom layer. It is related to a fire door that improves the heat shield function to significantly improve the heat shield efficiency of the fire door by being sequentially blocked by a refractory filler and mineral wool in a semi-vacuum state.

In general, fire doors are installed in the entrance walls of apartments, homes, and offices together with door frames. These fire doors and door frames effectively block outdoor noise and air flow. And the like.

Such a fire door is in a situation in which structural improvement measures are required to effectively prevent heat condensation.

Meanwhile, KR 20-0360568 Y1 2004.08.20. Looking at the "structure of the fire door" in Figure 1, the door frame 20 constituting the entrance door to the wall of the building first fixed in a rectangular shape, the fire door 10 is coupled to the door frame 20 by a hinge 30 It is installed to open and close.

The fire door 10 is cut into a metal plate and then assembled or welded with rivets or screws to form a door, in which case a passage is formed by a gap between the unsafely welded weld and a gap between the rivet and the screw.

Therefore, the indoor air and the outdoor air pass through the gap formed in the process of manufacturing the fire door 10 as described above, the condensation occurs in the fire door 10 due to the temperature difference between the indoor and outdoor, thereby Corrosion occurs in the fire door (10) has a problem.

In addition, there is a problem that the flame and soot generated during the fire passes through the gap formed in the fire door 10 to act as a secondary fire occurrence factor.

The present invention has been made to solve the problems of the prior art as described above, the object is as follows.

First, forming the bending bending while connecting the third side wall, the first step surface and the fourth side wall in order on the front, left, and bottom of the front door of the fire door, and the fifth side wall and the second end on the right side of the front door The construction of a stepped structure formed by bending forming while connecting the jaw surface is realized in a semi-vacuum state, which is intended to drastically improve the high temperature blocking function of the fire door to flame.

Second, by installing a heat shielding block filled with mineral wool while filling a fireproof filler inside the fire door, and simultaneously coating an eco-diatom layer on the inner surface of the heat shielding block, the heat of the flame is transferred to the eco-diatom layer, the fireproof filler and the mineral By sequentially blocking by wool, etc., it is to significantly improve the heat shielding efficiency of the fire door.

The present invention, first, the fire door (2) is installed on the door frame (4) installed in the doorway so as to be opened and closed by a hinge, the door frame (4) and the main packing 28 and the position in contact with the fire door (2) In the fire door which improved the heat shield function in which the frame packing a, b (26, 27) is installed,

The fire door 2 includes a front door 30 formed in a rectangular shape;

A third side wall 32 and a first step surface 34 connected to upper, left and lower sides of the door front surface 30 and sequentially bent;

A fourth side wall 36 extending and formed on the first step surface 34 and being bent;

It is formed vertically while being connected over the right side of the third side wall 32 and the first stepped face 34 and the right side of the fourth side wall 36, and is simultaneously connected to the right side of the front door 30. A fifth side wall 38 being formed;

A second step surface (40) which is formed at an end of the fifth side wall (38) and is bent outwardly and is connected to the right side of the fourth side wall (36);

A door rear surface 42 connected to an end portion of the fourth side wall 36 and disposed in parallel with the door front surface 30;

And first, second and third door packings 45, 46 and 48 installed on the first and second stepped surfaces 34 and 40 and the fourth side wall 36, respectively.

Second, the heat shield block 50 is installed inside the fire door 2 to block high heat, and the inner surface of the heat shield block 50 is coated with an eco-diatom layer 52 having a function for blocking high heat, The front and rear of the heat shield block 50 is characterized in that the plurality of protrusions 54 are formed to protrude at equal intervals.

Third, between the inner space of the fire door (2) and the heat shield block 50 is characterized in that the refractory filler (58) made of any one material selected from mineral wool, glass wool, honeycomb heat insulating material.

The effects of the present invention are as follows.

First, the fire door 2 is formed by bending the third side wall 32, the first step surface 34, and the fourth side wall 36 sequentially on the upper, left, and lower sides of the front door 30. And the fifth side wall 38 and the second step surface 40 are sequentially formed on the right side of the door front surface 30, and are formed in a stepped bending form. High heat shielding function is significantly improved.

Second, the fire door (2) is filled with a refractory filler (58) inside the heat shield block 50 is filled in the mineral wool 60 in a semi-vacuum state, at the same time the eco-diatom layer ( 52) is coated, so the heat of the flame is sequentially blocked by the eco-diatom layer 52 of the heat shield block 50 and the refractory filler (58) and mineral wool (60), the fire door (2) Heat shielding efficiency) is significantly improved.

1 is a state in which a conventional fire door is installed in the door frame.
2 is a state in which the fire door is an embodiment of the present invention installed on the door frame.
3 is a state in which the fire door is an embodiment of the present invention opened in the door frame.
Figure 4 is an exploded perspective view of the fire door which is an embodiment of the present invention.
Figure 5 is installed another embodiment of the heat shield block in the fire door which is an embodiment of the present invention
State diagram.

Fire door (2) of the present invention is coupled to the hinge (6) to the door frame (4) located in the doorway of the apartment, house, office, etc., which is installed to open and close, the fire door (2) due to the flame at the time of fire It prevents high heat and soot from moving indoors or outdoors, and also prevents condensation caused by temperature difference between indoors and outdoors of a building.

The metal door frame 4 installed as described above is installed in a rectangular shape between the entrance wall 8 of the building, as shown in Figures 2 to 4, the door frame 4 is the front frame 10 From the first side wall 12 and the frame stepped surface a (14) and the second side wall (16) and the main packing groove 18 is formed in a structure that is formed by bending forming.

In this case, a part of the first side wall 12, the frame stepped surface a 14 and the second side wall 16 are disposed on the upper, lower, and left sides of the door frame 4, and the door frame 4 The first a side wall 20 is vertically disposed on the right side, and the frame end jaw surface b 22 is connected to the end of the first a side wall 20 to be bent and connected to the second side wall 16. .

In addition, the frame packing a (26) is inserted into the packing groove (24) formed in an ohmic (Ω) shape on the frame stepped surface a (14) located on the upper, lower, and left sides of the door frame (4). The frame packing b (27) is inserted into the frame groove (22) located on the right side of the door frame (4) and is disposed toward the rear side of the frame packing b (27). The main packing 28 is inserted into the groove 18.

Subsequently, a rectangular front door 30 is formed on the metal fire door 2 in the same rectangular shape as the door frame 4, and the upper, left, and lower sides of the front door 30 are formed. The third side wall 32 and the first step face 34 are sequentially formed by bending forming, and the end of the first step face 34 is formed by bending the fourth side wall 36 integrally. Is formed.

In this case, the fifth side wall 38 is vertically formed while being connected to the right side of the third side wall 32 and the first stepped face 34 and the right side of the fourth side wall 36. The fifth side wall 38 is formed to be bent while being connected to the right side of the front door 30.

In addition, the second end face 40 extends to the end of the fifth side wall 38 and is formed to be folded outwardly, and the end of the second end face 40 is formed on the fourth side wall 36. It is connected to the end of the fourth side wall 36, the door rear surface 42 is connected to form the bending and at the same time disposed parallel to the door front (30).

The fire door 2 as described above is formed in a step shape as a whole when viewed from the plane, and thus becomes a structure that can effectively block the heat and noise of the flame.

Packing grooves 44 are formed in the first and second stepped surfaces 34 and 40 and the fourth and fifth side walls 36 and 38 of the fire door 2, which are configured as described above, and the first stepped surface 34. The first door packing 45 is inserted into and installed in the packing groove 44 formed in the second hole, and the second door packing 46 is formed in the packing groove 44 formed over the fourth and fifth side walls 36 and 38. Is inserted and installed, the third door packing 48 is inserted into the packing groove 44 formed in the second step surface 40 is installed.

At this time, the packing groove 44 of the fourth side wall 36 and the fifth side wall 38 is installed inside the inner frame type to prevent the twist of the fire door.

Subsequently, one side of the hinge 6 is screwed to the fifth side wall 38 constituting the fire door 2, and the other side of the hinge 6 is the first side wall 20 of the door frame 4. Screwed).

The main packing 28, the frame packing a, b (26, 27), the first, second, third door packing (45, 46, 48) and the like installed as described above are formed of a rubber or urethane material.

On the other hand, inside the fire door (2) is installed a heat blocking block 50 for high heat, the heat blocking block 50 is formed in a hollow rectangular shape while having a blocking function against high heat eco-diatom layer 52 The inner surface is coated, and a plurality of protrusions 54 are formed at the front and rear of the heat shield block 50 at equal intervals, and the fixing groove 56 is concave along the circumference of the heat shield block 50. Is formed.

The protruding portion of the packing groove 44 into which the second door packing 46 of the fire door 2 is inserted is inserted into the fixing groove 56, so that the heat blocking block 50 is fixed inside the fire door 2. It will be installed.

In addition, between the inner space of the fire door 2 and the heat shield block 50 is filled with a refractory filler 58 made of any one material selected from the heat insulating material of mineral wool, glass wool, honeycomb, the heat shield block 50 Inside it is filled with mineral wool (60) having a high temperature blocking function or to fill the glass wool.

Referring to the operation of the present invention configured as described above are as follows.

First, when the fire door 2 is in the closed state in the door frame 4, the first door packing 45 installed on the first step surface 34 of the fire door 2 is the frame end surface of the door frame 4 The second door packing 46, which is in close contact with a (14) and is provided over the fourth and fifth side walls 36 and 38 of the fire door 2, has the second side wall 16 of the door frame 4. ) And the first door side wall 20 is in close contact with each other, and the third door packing 48 installed on the second step surface 40 located on the right side of the fire door 2 is located on the right side of the door frame 4. It is in close contact with the frame stepped surface b (22) located.

In addition, the frame packing a (26) installed on the frame step surface a (14) of the door frame (4) is in close contact with the first step surface 34 of the fire door (2), The frame packing b 27 installed on the frame stepped surface b 22 located on the right side is in close contact with the second stepped surface 40 located on the right side of the fire door 2, and the main packing ( 28 is in close contact with the door back 42 of the fire door (2).

As described above, when the fire caused by the fire reaches the door rear surface 42 of the fire door 2 in the state where the fire door 2 is closed, the fireproof filler 58 and the heat shield block installed inside the fire door 2 The ecodiatom layer 52 and the mineral wool 60 or the glass wool constituting the 50 block the high heat of the flame. Therefore, the area located on the opposite side of the fire door 2 away from the fire zone is separated from the high heat of the flame. safe.

Unlike the above, when heat and noise reach the fire door 2 from the outside, the heat and noise are primarily blocked by the main packing 28 in contact with the door back 42 of the fire door 2, and the main packing. Part of the noise and heat passing through the door 28 is the second door packing 46 in contact with the second side wall 16 of the door frame 4 and the third door packing in contact with the frame stepped surface b 22. The second block is blocked by (48), and the noise passing through the second and third door packing (46, 48) after the frame packing a (26) in contact with the first step surface 34 of the fire door (1) Is blocked by the frame packing b 27 in contact with the second step surface 40, and some noise passing through the frame packings a, b (26, 27) thereafter is the frame step surface a of the door frame 4. It is blocked by the first door packing 45 in contact with 14 and the second door packing 46 in contact with the first side wall 20.

Moreover, the fire door 2 is formed in a step shape as a whole when viewed from the plane, it effectively blocks the heat and noise of the flame.

As a result, the temperature of the room is not affected by the outdoor temperature by the fire door 2, and condensation which may occur due to the difference between the indoor and outdoor temperatures is prevented, and the fire door 2 and the door frame made of metal are prevented. Corrosion does not occur in (4).

In addition, the main packing 28, the frame packing a, b (26, 27) and the first, second, third door packing (45, 46, 48) and the like installed as described above to mitigate the noise between the floors, By blocking the hot air flow it is possible to prevent secondary fires.

Subsequently, when the fire door 2 in the closed state is opened as described above, the door 6 is rotated about the hinge axis of the hinge 6 and exits to the door frame 4 to be opened.

At this time, the door back 42 is spaced apart from the main packing 28, and at the same time, the first, second, and third door packings 45, 46, and 48 installed on the fire door 2 are separated from the door frame 4. The first and second stepped surfaces 34 and 40 of the fire door 2 are spaced apart from the frame packings a and b (26 and 27).

Therefore, the fire door 2 is in an open state, so that the indoor air and the outdoor air communicate with each other through the doorway.

Meanwhile, another embodiment of the heat shield block 50 constituting the present invention will be described with reference to FIG. 5.

First, the heat blocking block 50 is formed in a box-shaped recessed body 64 is formed with a flange 62 around the upper end, the cover 66 is in close contact with the open upper portion of the body 64 At the same time, the outer peripheral surface of the cover 66 is fixed to the flange 62 is integrated by a hamming operation.

At this time, the inside of the heat shield block 50 is in a semi-vacuum state.

A plurality of protrusions 54 are formed to protrude at equal intervals on the front and rear of the heat shield block 50 is configured as described above, and the mineral wool 60 or glass wool having a high heat shielding function inside the heat shield block 50. Will be filled.

Although the preferred embodiments of the present invention as described above in detail by the accompanying drawings, the present invention is not limited to the embodiments described herein, those skilled in the art having ordinary skill in the art Various modifications and variations can be made without departing from the scope.

2: fire door 4: door frame
6: hinge 8: wall
10: frame front 12: first side wall
14: frame stepped surface a 16: second side wall
18: main packing groove 20: first side wall
22: Frame stepped surface b 24, 25, 44: Packing groove
26: frame packing a 27: frame packing b
28: main packing 30: front door
32: third side wall 34: first step surface
36: fourth side wall 38: fifth side wall
40: second step surface 42: door back
45: first door packing 46: second door packing
48: third door packing 50: heat shield
52: eco-diatom layer 54: protrusion
56: fixed groove 58: refractory filler
60: mineral wool 62: flange
64: body 66: cover

Claims (7)

The fire door 2 is hingedly installed on the door frame 4 installed at the doorway, and the main door 28 and the frame packing a, b are installed at the position where the door 2 is in contact with the door frame 4. In the fire door which improved the heat shield function in which (26,27) is installed,
The fire door 2 includes a front door 30 formed in a rectangular shape;
A third side wall 32 and a first step surface 34 connected to upper, left and lower sides of the door front surface 30 and sequentially bent;
A fourth side wall 36 extending and formed on the first step surface 34 and being bent;
It is formed vertically while being connected over the right side of the third side wall 32 and the first stepped face 34 and the right side of the fourth side wall 36, and is simultaneously connected to the right side of the front door 30. A fifth side wall 38 being formed;
A second step surface (40) which is formed at an end of the fifth side wall (38) and is bent outwardly and is connected to the right side of the fourth side wall (36);
A door rear surface 42 connected to an end portion of the fourth side wall 36 and disposed in parallel with the door front surface 30;
And first, second and third door packings 45, 46 and 48 installed on the first and second step surfaces 34 and 40 and the fourth side wall 36, respectively.
Inside the fire door (2) is installed a heat shield block 50 for blocking high heat,
The inner surface of the heat shield block 50 is coated with an eco-diatom layer 52 having a blocking function against high heat,
The front and rear of the heat shield block 50, the plurality of protrusions 54, the fire door to improve the heat shield function, characterized in that the protrusion formed at equal intervals. delete The method of claim 1,
Between the inner space of the fire door (2) and the heat shield block (50) to improve the heat shield function, characterized in that the refractory filler (58) made of any one material selected from the heat insulating material of mineral wool, glass wool, honeycomb. Fire doors. The method according to claim 1 or 3,
Inside the heat shield block 50 is a fire door with improved heat shield function, characterized in that the mineral wool (60) or glass wool having a high heat blocking function is filled. The method of claim 1,
The concave fixing groove 56 is formed along the side circumferential surface of the heat shield block 50,
By inserting a protruding portion of the packing groove 44 into which the second door packing 46 of the fire door 2 is inserted into the fixing groove 56,
The heat shield with improved heat shield function, characterized in that the heat shield block 50 is fixed inside the fire door (2). The method of claim 4, wherein
The heat shield block 50 is formed in a box-shaped recessed body 64 formed with a flange 62 around the upper end,
The cover 66 is located in close contact with the open upper portion of the body 64, the circumferential surface is integral to the flange 62 by a hamming operation,
Inside the heat shield block 50 is a fire door with improved heat shield function, characterized in that the semi-vacuum state.





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