KR102592886B1 - Thermal deformation prevention structure fire door - Google Patents

Abstract

The present invention includes a front steel plate disposed inside the blocked space; a rear steel plate spaced apart from the front steel plate and disposed on the outside of the space to be abutted and blocked; A horizontal upper piece and both sides of the upper piece are vertically bent to form a side piece, and both ends of the side piece are bent inward at a right angle to form a bottom piece that is horizontal with the upper piece. The end of the side piece is welded to the front steel plate to form a side piece. A front steel plate reinforcement plate that is integrated with the front steel plate and whose upper piece is not connected to the inner surface of the rear steel plate but is in close contact with it; A horizontal upper piece and both sides of the upper piece are vertically bent to form a side piece, and both ends of the side piece are bent inward at a right angle to form a bottom piece that is horizontal with the upper piece. The end of the side piece is welded to the rear steel plate to form a side piece. It relates to a fire door with a heat deformation prevention structure, characterized in that it includes a rear steel plate reinforcement plate that is integrally coupled with the rear steel plate and whose upper piece is not coupled to the inner surface of the front steel plate but is in close contact with it.

Description

Thermal deformation prevention structure fire door}

The present invention relates to a fire door, and to a fire door with a thermal deformation prevention structure that can maintain its original shape for a long time without being distorted even at high temperatures.

Fire doors are installed at entrances and exits of houses, apartments, factories, offices, etc. to block the spread of fire and flames in the event of a fire and to block the inflow of smoke. Like general entrance doors, fire doors are hinged to the door frame, but they must be durable against conditions such as combustion, melting, cracking, thermal decomposition, and deterioration. They must remain connected to the door frame even under strong heat during a fire, preventing fire. It must also be durable against distortion to prevent spread as much as possible.

When distortion occurs, a gap is created between the door frame and the frame, or in the case of a double door, between the fire door and the fire door, and flame or smoke flows in through the gap, causing the fire door to lose its function. The cause of distortion is structural defects, but more than that, when a fire occurs, high heat is applied to a fire door made of steel plate, causing thermal deformation. All steel sheets undergo thermal deformation when heat is applied, and it is common to slow down thermal deformation as much as possible by forming a reinforcing structure in the fire door.

According to the performance standards for fire doors according to the Building Act of the Republic of Korea (enforced on August 7, 2021), 60-minute+ fire doors must be able to block smoke and flames for more than 60 minutes and block heat for more than 30 minutes. do. A 60-minute fire door must block smoke and flames for more than 60 minutes. A 30-minute fire door must block smoke and flames for at least 30 minutes but less than 60 minutes.

Likewise, the Korean building code stipulates that the time a fire door can block smoke and flames is 30 to 60 minutes, but the standards are increasingly being strengthened. In addition, the longer a fire door can block smoke or flames, the better. However, due to the nature of the steel plate, which is the material of the fire door, thermal deformation occurs at high temperatures, so there is bound to be a limit to the blocking time.

If you increase the thickness of the steel plate of a fire door, the time it takes to deform even when heated will be extended. However, due to various conditions, standards for the thickness of the steel plate are set in the building code, so deformation must be prevented as much as possible without changing the thickness of the steel plate.

Looking at the conventional fire door structure developed with this in mind, although it varies depending on the structure and size of the building, as shown in Figures 1 to 4, a front steel plate is installed on the front of the outer frame with a width of 30 to 80 mm. Weld it together and weld the back steel plate on the back. The front and back steel plates are steel plates with a thickness of approximately 1 to 2 mm.

A steel plate reinforcement plate is added between the front and back steel plates to prevent deformation or thermal deformation due to external force or pressure. That is, several steel plate reinforcement plates are added in the longitudinal direction of the front steel plate and spot welded at regular intervals, and several steel plate reinforcement plates are also added in the longitudinal direction of the rear steel plate and spot welded at regular intervals, and then the front and rear of the outer frame are The outer frame and the front and back steel plates are joined by welding by butting the front and back steel plates at intervals.

Looking at the structure of the steel plate reinforcement, both ends of the steel plate reinforcement are bent to form an upper piece (11) and a side piece (12), and only one side of the bent portion is welded to the front or rear steel plate, and the other side is welded to the front or rear steel plate. They are butted together rather than welded. This is because the internal space is closed when the front and rear steel plates are welded to the outer frame, so the space is narrow and it is difficult to join the steel plate reinforcement plates there by welding. Therefore, steel plate reinforcement plates are spaced at regular intervals between the front steel plate and the rear steel plate. Since one side of the bent part is first welded and joined so that it butts against each other, the bent part on the one side that is not welded is in a state of being butted to the inner surface without being integrally joined to the opposing front or back steel plate. The space between the steel plate reinforcement plates is filled with mineral wool, a fireproof material, to block heat movement from the inside to the outside or from the outside to the inside of the fire door.

When a fire door as described above is installed in a door frame, and a fire occurs inside the fire door and flames are applied to the front steel plate, distortion stress is generated in the front steel plate due to heat. At this time, the outer frame and steel plate reinforcement resist the front steel plate from being twisted. This delays the distortion of the front steel plate and the entire fire door. When the front steel plate is twisted, the stress is applied to the bent portion of the steel plate reinforcement plate, and the stress applied to the bent portion is ultimately applied to the upper piece 11. Since the twisting stress applied to the upper piece through the bent portion (side piece) is not distributed to the side piece 12, only the structural strength of the bent portion (side piece) and the upper piece 11 serves as a force to resist the twisting stress. Therefore, if steel sheets with the same physical properties are used, only the difference in size or thickness between the side piece 12 and the top piece 11 can determine the time to resist twisting stress. In other words, if the thickness of the steel plate reinforcement is relatively thin, the time to resist twisting stress becomes shorter, and if the thickness of the steel plate reinforcement is relatively thick, the time to resist twisting stress becomes longer. In addition, heat is applied to the steel plate reinforcement over time, so if the heat applied to the steel plate is not blocked, the steel plate will inevitably be easily deformed by torsional stress.

Increasing the number of steel plate reinforcements can extend the time to resist torsional stress, but since the structure of the fire door becomes more complex and steel plate reinforcements also serve as a means of transferring heat, increasing the number of steel plate reinforcements increases the time to resist torsional stress. Increasing it is not efficient and has limitations.

Registered Patent No. 10-1985631 Registered Patent No. 10-1942861 Registered Patent No. 10-1977044 Registered Patent No. 10-1977047 Registered Patent No. 10-1883978 Registered Patent No. 10-1923643

The present invention is intended to solve the problems described above, by modifying the shape and connection method of the steel plate reinforcement to disperse the torsional stress applied to the steel plate reinforcement, and to prevent heat transfer to the steel plate reinforcement in the event of a fire. We want to delay as much as possible the deformation of the fire door due to heat.

In order to achieve the above object, the present invention provides a fire door installed in the door frame of a building opening to protect life and property by opening and closing while blocking a specific space from fire, comprising: a front steel plate disposed inside the blocked space; a rear steel plate spaced apart from the front steel plate and disposed on the outside of the space to be abutted and blocked; A horizontal upper piece and both sides of the upper piece are vertically bent to form a side piece, and both ends of the side piece are bent inward at a right angle to form a bottom piece that is horizontal with the upper piece. The end of the side piece is welded to the front steel plate to form a side piece. A front steel plate reinforcement plate that is integrated with the front steel plate and whose upper piece is not connected to the inner surface of the rear steel plate but is in close contact with it; A horizontal upper piece and both sides of the upper piece are vertically bent to form a side piece, and both ends of the side piece are bent inward at a right angle to form a bottom piece that is horizontal with the upper piece. The end of the side piece is welded to the rear steel plate to form a side piece. A fire door with an anti-thermal deformation structure is provided, which includes a rear steel plate reinforcement plate that is integrally coupled with the rear steel plate and whose upper piece is not coupled to the inner surface of the front steel plate but is in close contact with it.

In addition, in order to achieve the above purpose, a fire door is installed on the door frame of a building opening to protect life and property by opening and closing while blocking a specific space from fire, including a front steel plate disposed inside the blocked space; a rear steel plate spaced apart from the front steel plate and disposed on the outside of the space to be abutted and blocked; A horizontal upper piece and both sides of the upper piece are vertically bent to form a side piece, and both ends of the side piece are bent inward at a right angle to form a bottom piece that is horizontal with the upper piece. The end of the side piece is welded to the front steel plate to form a side piece. A front steel plate reinforcement plate that is integrated with the front steel plate and whose upper piece is not connected to the inner surface of the rear steel plate but is in close contact with it; A horizontal upper piece and both sides of the upper piece are vertically bent to form a side piece, and both ends of the side piece are bent inward at a right angle to form a bottom piece that is horizontal with the upper piece. The end of the side piece is welded to the rear steel plate to form a side piece. A rear steel plate reinforcement plate that is integrated with the rear steel plate and whose upper piece is not combined with the inner surface of the front steel plate but is in close contact with it; It is formed with an upper support piece and a side support piece so as to be in close contact with the inside of the front and rear steel plate reinforcement plates and the inside of the upper and side pieces. The upper support piece is in close contact with the bottom of the upper piece and the side support plate is in close contact with the inside of the side piece. A bottom support piece bent at a right angle inward is formed at the end of the support plate, and the bottom support piece is seated on the upper surface of the bottom piece. A horizontal support piece bent at a right angle outward is formed at the end of the bottom support piece, and the horizontal support piece is at the end of the bottom piece. A fire door with an anti-thermal deformation structure is provided, which includes a reinforced cardboard support plate that is in close contact with the floor and resists deformation in the horizontal direction when the bottom piece is deformed in the horizontal direction.

In addition, between the front steel plate reinforcement plate, the rear steel plate reinforcement plate, and the reinforced plate support plate, an insulating material is installed to block the heat transmitted to the reinforced plate support plate through the front steel plate and the front steel plate reinforcement plate, thereby delaying the distortion of the reinforced plate support plate as it softens due to heat. Provides a fire door with a thermal deformation prevention structure that is characterized by being installed.

According to the present invention, when a fire occurs inside a fire door and the fire door made of steel plate is heated, a gap is created between the fire door and the door frame on which the fire door is installed, and the flame or smoke inevitably flows into the outside of the fire door. When the fire door is heated by a flame, the front steel plate reinforcement plate and the rear steel plate reinforcement plate formed between the front steel plate and the rear steel plate are structured to resist the distortion stress and disperse the stress when distortion occurs. As the time for this to occur is significantly delayed, the time for a gap to appear between the fire door and the door frame due to smoke is also delayed significantly. In other words, the time for a conventional fire door to withstand a flame without being distorted was 40 to 45 minutes, but the present invention can last for 60 to 70 minutes, delaying the time a gap is created between the fire door and the door frame by a flame by more than 20 minutes. It has been done.

As the time for the gap between the fire door and the door frame to develop is longer than that of existing fire doors, flames and smoke flowing through the gap are extinguished, thereby reducing casualties outside the fire door. In other words, by increasing the golden time, casualties from fire and property damage from water can be greatly reduced.

In addition, the reinforcement plate support plate formed on the inside of the front steel plate reinforcement plate and the rear steel plate reinforcement plate double prevents distortion of the front steel plate and the rear steel plate, thereby further delaying the time for deformation (distortion) of the fire door to occur. Thermal deformation of the fire door can be delayed for a longer period by blocking the heat transmitted to the reinforced plate support plate by the insulation material sandwiched between the front steel plate reinforcement plate and the rear plate reinforcement plate and the reinforced plate support plate.

Figure 1 shows the structure of a conventional fire door.
Figure 2 is a plan cross-sectional view of a conventional fire door.
Figure 3 shows the steel plate reinforcement of a conventional fire door.
Figure 4 shows a steel plate reinforcement plate combined with a conventional fire door.
Figure 5 is a plan cross-sectional view of a double-opening fire door according to an embodiment of the present invention.
Figure 6 is a steel plate reinforcement plate of a fire door according to an embodiment of the present invention.
Figure 7 is a plan cross-sectional view of a steel plate reinforcement plate coupled to a fire door according to an embodiment of the present invention.
Figure 8 shows a steel plate reinforcement plate combined with a fire door according to an embodiment of the present invention.
Figure 9 is a steel plate reinforcement plate of a fire door according to another embodiment of the present invention.
Figure 10 is a cross-sectional plan view of a steel plate reinforcement plate coupled to a fire door according to another embodiment of the present invention.
Figure 11 shows a steel plate reinforcement plate combined with a fire door according to another embodiment of the present invention.

An embodiment of the present invention will be described in detail with reference to the attached drawings as follows.

As shown in Figures 5 to 8, the fire door according to an embodiment of the present invention is installed on the door frame in the form of a double door that opens on both sides based on the center. The fire door is a structure in which a front steel plate (100) and a rear steel plate (200) of the same shape are joined together at intervals. The front steel plate (100) and the rear steel plate (200) are made of galvanized KS steel sheets with a thickness of 0.8 mm. ) are joined against each other with a space between them so that the thickness of the fire door is 40mm.

A reinforcing plate is welded between the front steel plate 100 and the rear steel plate 200 to reinforce structural strength. The reinforcing plate coupled to the front steel plate 100 is connected to the front steel plate reinforcing plate 110 and the rear steel plate 200. The combined reinforcing plate is called the rear steel plate reinforcing plate (210).

When the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 are joined against each other so that the front steel plate 100 and the rear steel plate 200 form a certain width, it is difficult to weld them due to space constraints, so the front steel plate (100) ) and the rear steel plate 200, the front steel plate reinforcement plate 110 is coupled to the front steel plate 100, and the rear steel plate reinforcement plate 210 is coupled to the rear steel plate 200. The thickness of the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 is set to match the width between the front steel plate 100 and the rear steel plate 200, so the front steel plate reinforcement plate 110 is attached to the front steel plate 100. ) is combined, and the rear steel plate reinforcement plate 210 is coupled to the rear steel plate 200. When the front steel plate 100 and the rear steel plate 200 are joined together, the end of the front steel plate reinforcement plate 110 is the rear steel plate. It is in close contact with the inner surface of the front steel plate 100, and the end of the rear steel plate reinforcement plate 210 is in close contact with the inner surface of the front steel plate 100.

In the process of combining the front steel plate reinforcement plate 110 to the front steel plate 100, first, several front steel plate reinforcement plates 110 in the form of a grid with both sides bent are provided. The front steel plate reinforcement plate 110 is bent at right angles on both sides. The unbent middle portion is the upper piece 112, and the side bent vertically from the upper piece 112 is the side piece 114. The height of the side piece 114 is the same as the gap between the front steel plate 100 and the rear steel plate 200. That is, when the front steel plate 100 and the rear steel plate 200 are joined to each other, the end of the side piece 114 of the front steel plate reinforcement plate 110 coupled to the front steel plate 100 is exactly adhered to the inner surface of the rear steel plate 200. It is formed so that it can be interviewed. The end of the side piece 114 is bent inward at a right angle to form a bottom piece 116. The bottom piece 116 functions to distribute the twisting stress applied to the side piece 114 to the back steel plate 200 by increasing the area where the end of the side piece is in contact with the back steel plate 200.

With the upper piece 112 of the front steel plate reinforcement plate 110 placed in close contact with the inner surface of the front steel plate 110, both side pieces 114 are spot welded to the front steel plate 110 at regular intervals.

A number of front steel plate reinforcement plates 110 are coupled to the front steel plate 100 at regular intervals. The number of front steel plate reinforcement plates 110 combined varies depending on the width of the front steel plate 110, which determines the width of the fire door. Approximately 2 to 4 are combined.

The process of joining the rear steel plate reinforcement plate 210 to the rear steel plate 200 is the same as the process of joining the front steel plate reinforcement plate 110 to the front steel plate 100, and the form and function are the same as those of the front steel plate 100. do. In addition, the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 are formed at intersections at regular intervals from each other. In other words, if the entire fire door has four front steel plate reinforcement plates and four rear steel plate reinforcement plates, they are formed in this way: front steel plate reinforcement plate - rear steel plate reinforcement plate - front steel plate reinforcement plate - rear steel plate reinforcement plate.

The empty space between the front steel plate 100 and the rear steel plate 200 is filled with mineral wool, a non-combustible material. Mineral wool is manufactured based on inorganic ore with non-flammable properties and is resistant to fire as it does not burn. In other words, mineral wool is a material that has already been proven to have excellent insulation and thermal insulation performance by blocking the movement of heat energy.

A frame (F) with both sides bent is placed between both ends of the front steel plate (100) and the rear steel plate (200) and welded to the front steel plate (100) and the rear steel plate (200) to form the front steel plate (100) and the rear steel plate (200). These are combined into one piece, and the frame (F) becomes the outer border of the fire door.

A fire door formed by a pair of doors (two doors) has a gap between the doors, so to close the gap, it is designed so that some parts overlap when the fire door is closed. The front steel plate (100) is the outside of the fire door. At one end of the front steel plate (100), an overlap plate (R) with a width of 20 to 40 mm is formed by bending the end, and at one end of the rear steel plate (200) corresponding to the inside of the fire door, the end of the rear steel plate (200) is formed. By bending, an overlapping plate (R) with a width of 20 to 40 mm is formed. Therefore, when a fire door formed of two doors is closed and horizontal in a plane, the overlap plate (R) formed on the front steel plate 100 overlaps the end of the front steel plate 100 of the opposite fire door, and the overlap plate formed on the rear steel plate 200 The overlapping plate (R) overlaps the end of the rear steel plate 200 of the opposite fire door and is sealed without a gap.

The completed fire door is fixed to the door frame installed in the opening. A door frame made by bending a steel plate is fixed to the opening where the fire door is installed, and the fire door is joined so that it can be opened and closed using several stainless steel hinges (H). The gap between the fire door and the door frame is sealed with a flame retardant gasket (G) to prevent flames from penetrating in the event of a fire.

The operation of the fire door according to the present invention configured as described above will be described as follows. If a fire breaks out inside a fire door, the flame heats the fire door.

Since fire doors are made of steel plates, if exposed to flame for more than a certain period of time, they soften at high heat and cause thermal deformation. The heat applied to the front steel plate 100 by the flame distorts the front steel plate 100 over time. In particular, in the event of a fire, the flame does not apply uniform heat to the front steel plate, so distortion is bound to become more severe. When the front steel plate 100 is twisted, the front steel plate 100 resists being twisted by the frame (F) that forms the border of the fire door. However, since the flame applies heat to the entire fire door including the frame, there is a time difference and it eventually becomes distorted. do. The front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 resist and delay the distortion of the front steel plate 100.

Looking at the process by which the front steel plate reinforcement plate 100 resists distortion, first, a distortion stress is applied to the upper piece 112 by the front steel plate 100. The twisting stress applied to the upper piece 112 is distributed over the entire surface of the upper piece 112 and is distributed to the side pieces formed on both sides of the upper piece 112. That is, the twisting stress applied to the upper piece 112 is distributed to the two side pieces 114, and the ends of the side pieces 114 are supported by the rear steel plate 200 together with the bottom piece 116, so the upper piece 112 is distorted. This is resisted by the two side pieces 114 supported on the rear steel plate 200.

Therefore, even if one of the two side pieces 114 cannot overcome the thermal stress transmitted by the flame and is deformed (twisted), the other side piece 114 prevents the upper piece 112 from being deformed. Since the back steel plate 200 is blocked by the front steel plate 100, heat and flame are not applied directly, so the softening time due to heat is delayed compared to the front steel plate, thereby delaying the distortion of the side piece supported on the back steel plate 200. there is.

Since both the front steel plate 100 and the rear steel plate 200 are steel plates that cannot help but transmit heat, the fire door is continuously applied by a fire occurring inside the fire door, eventually causing distortion of the fire door, but the front steel plate reinforcement plate (110) ), the distortion is delayed, and in particular, the distortion stress is distributed to the side pieces 114 formed on both sides of the front steel plate reinforcement plate 110, and both side pieces 114 are rear steel plates (which have relatively less heat transfer than the front steel plate). 200), it is possible to delay the entire fire door from being twisted by flame for a long time.

As a result of the experiment, compared to the existing fire door, flame was sprayed on the front steel plate (100) from the inside of the fire door and tested under the same conditions. As a result, distortion occurred and the flow of flame and smoke to the other side of the fire door was delayed for more than 20 minutes. In other words, when the existing reinforcing plate was applied, the time for the fire door to twist and flame or smoke to flow into the other side was 40 to 45 minutes on average, but when the reinforcing plate according to the present invention was applied, the distortion was prevented for 60 to 70 minutes on average. As a result, the inflow time of flame or smoke was delayed accordingly.

Another embodiment of the present invention will be described as follows. As shown in Figures 9 to 11, the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 are formed between the front steel plate 100 and the rear steel plate 200, but the front steel plate reinforcement plate (110) and the rear steel plate reinforcement plate (210) are formed in double form. That is, a reinforcing plate support plate 310 is formed inside the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210, respectively. Since the reinforced plate support plate 310 formed on the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 has the same shape and has the same function, the reinforced plate support plate 310 formed on the inside of the front steel plate reinforcement plate 110 It only explains.

A reinforced plate support plate 310 composed of an upper support piece 312 and a side support piece 314 is formed inside the front steel plate reinforcement plate 110 so as to be in close contact with the inner surfaces of the top piece 112 and the side piece 114. That is, the upper support piece 312 is in close contact with the bottom of the upper piece 112, and the side support plate 314 is in close contact with the inside of the side piece 114. A bottom support piece 316 bent inward at a right angle is formed at the end of the side support plate 314, and the bottom support piece 316 is seated on the upper surface of the bottom piece 116. Additionally, a horizontal support piece 318 bent outward at a right angle is formed at an end of the bottom support piece 316. The horizontal support piece 318 is in close contact with the end of the bottom piece 116 and resists deformation in the horizontal direction when the bottom piece 116 is deformed in the horizontal direction.

An insulation material 410 is formed between the front steel plate reinforcement plate (1100), the rear steel plate reinforcement plate 210, and the reinforcement plate support plate 310. The insulation material 410 is made by processing mineral wool, a non-combustible material, to a thickness of 2 mm or less, and It is sandwiched between the steel plate reinforcement plate 110 and the reinforcement plate support plate 310 and functions to delay as much as possible the transfer of heat from the front steel plate reinforcement plate 110 to the reinforcement plate support plate 310. The insulating material 410 prevents heat transfer. Since it has a delaying function, you can use fiberglass or other non-combustible insulation materials.

The empty space between the front steel plate 100 and the rear steel plate 200 is filled with mineral wool, which is a non-combustible filler. Mineral wool is manufactured based on inorganic ore with non-flammable properties and is resistant to fire as it does not burn. In other words, mineral wool is a material that has already been proven to have excellent insulation and thermal insulation performance by blocking the movement of heat energy.

The completed fire door is fixed to the door frame installed in the opening. A door frame made by bending a steel plate is fixed to the opening where the fire door is installed, and the fire door is joined so that it can be opened and closed using several stainless steel hinges. The gap between the fire door and the door frame is sealed with a flame retardant gasket to prevent flames from penetrating in the event of a fire.

The operation of another embodiment of the present invention as described above will be described as follows.

Since fire doors are made of steel plates, thermal deformation occurs when exposed to flame for more than a certain period of time. The heat applied to the front steel plate by the flame causes the front steel plate 100 to soften and distort over time. When the front steel plate 100 is twisted, the front steel plate 100 resists being twisted by the frame (F) forming the border of the fire door. In addition, the front steel plate reinforcement plate 210 and the reinforcement plate support plate 310 resist distortion of the front steel plate 100.

Looking at the process of resistance of the front steel plate reinforcement plate 110 and the reinforcement plate support plate 310 when the front steel plate 100 is twisted, first, the front steel plate 100 is softened by a flame, causing thermal deformation and twisting. When the front steel plate 100 is distorted, a distortion stress is applied to the upper piece 112 of the front steel plate reinforcement plate 110 formed integrally with the front steel plate 100, and the twisting stress applied to the upper piece 112 is that of the upper piece 112. As it is distributed over the entire surface, it is distributed while being transmitted to the side pieces 114 formed on both sides of the upper piece 112. That is, the twisting stress applied to the upper piece 112 is distributed to the two side pieces 114, and the ends of the side pieces 114 are supported on the rear steel plate 200 through the bottom piece 116, preventing the upper piece 112 from being distorted. Resistance is provided by two side pieces 114 supported on the rear steel plate 200. Therefore, even if one of the two side pieces 114 cannot overcome the thermal stress transmitted by the flame and is deformed (twisted), the other side piece prevents the upper piece from being deformed.

When the front steel plate reinforcement plate 110 is deformed, twisting stress due to thermal stress is applied to the reinforced plate support plate 310, and the insulation material 410 sandwiched between the front steel plate reinforcement plate 110 and the reinforced plate support plate 310 By blocking the heat, the heat applied to the reinforced plate support plate 310 is delayed. Therefore, even if the front steel plate reinforcement plate 110 cannot withstand thermal stress and is distorted, it resists the distortion for a relatively longer period of time.

When a twisting stress is applied to the upper support piece 312 of the reinforcing plate support plate 310 combined with the front steel plate reinforcement plate 110, the upper support piece 312 resists the distortion and a twisting stress is applied to the side support pieces 314 on both sides. dispersed. In addition, the upper support piece 312, the side support piece 314, and the bottom support piece 316 of the reinforcing plate support plate 310 are in close contact with the inner surface of the front steel plate reinforcing plate 110, so if the reinforcing plate support plate 310 is not distorted, The front steel plate reinforcement plate 110 is also not distorted. In addition, the vertical support piece 318 of the reinforcing plate support plate 310 prevents the bottom piece 116 of the front steel plate reinforcing plate 110 from being deformed inward, so that the deformation of the front steel plate reinforcing plate 110 lasts longer. It can be delayed. In particular, the insulation material 410 has weak structural strength, but blocks heat transferred to the reinforced plate support plate 310 through the front steel plate reinforcement plate 110, thereby further delaying the deformation (twisting) of the reinforcement plate support plate 310. You can.

The function of the rear steel plate reinforcement plate 210 is the same as that of the front steel plate reinforcement plate 110, and the structure and function of the reinforcement plate support plate 310 formed inside the rear steel plate reinforcement plate 210 are also similar to those of the front steel plate reinforcement plate 110. ) Since the structure and function of the reinforcing plate support plate 310 formed on the inside are the same, description of its operation is omitted.

If the deformation of the front steel plate reinforcement plate 110, the rear steel plate reinforcement plate 210, and the reinforcement plate support plate 310 is delayed, the deformation of the front steel plate 100 coupled thereto is delayed, ultimately delaying the deformation of the fire door. If the deformation (twisting) of the fire door is delayed, the gap between the door frame and the fire door edge and the overlap between the left and right fire doors and the fire door are delayed, causing the gap caused by distortion to spread, causing the flame or smoke from the fire inside the fire door to spread to the other side of the fire door. The inflow time is greatly delayed. Therefore, the golden time to protect property and life after a conflict breaks out is greatly extended.

100: Front steel plate 110: Front steel plate reinforcement plate
112: upper section 114: side section
116: bottom part
200: rear steel plate 210: rear steel plate reinforcement plate
212: upper section 214: side section
216: bottom part
310: Reinforcement plate support plate 312: Upper support piece
314: side support piece 316: floor support piece
312: Horizontal support piece
410: insulation material

Claims (3)

delete In the fire door installed in the door frame of the building opening to protect life and property by opening and closing while blocking a specific space from fire,
A front steel plate (100) disposed inside the blocked space;
A rear steel plate 200 spaced apart from the front steel plate 100 and disposed on the outside of the blocked space;
A horizontal upper piece 112 and both sides of the upper piece are vertically bent to form a side piece 114, and both ends of the side piece are bent inward at a right angle to form a bottom piece 116 that is horizontal with the upper piece. A front steel plate reinforcement plate (110) whose end is welded to the front steel plate (100) to be integrally coupled with the front steel plate, and whose upper piece (112) is not coupled to the inner surface of the rear steel plate but is in close contact with it;
A horizontal upper piece 212 and both sides of the upper piece are vertically bent to form a side piece 214, and both ends of the side piece are bent inward at a right angle to form a bottom piece 216 that is horizontal with the upper piece. The end of (214) is welded to the rear steel plate 200 to be integrated with the rear steel plate 200, and the upper piece 212 is not coupled to the inner surface of the front steel plate 100, but is in close contact with the rear steel plate reinforcement plate ( 210);
The front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 are formed with an upper support piece 312 and a side support piece 314 so as to be in close contact with the inside of the upper and side pieces, and the bottom surfaces of the upper pieces 112 and 212. An upper support piece 312 is in close contact with the side pieces 114 and 214, and a side support plate 314 is in close contact with the inside of the side pieces 114 and 214. A bottom support piece 316 is formed at the end of the side support plate 314 and is bent inward at a right angle. The piece 316 is seated on the upper surface of the bottom piece 116, and a horizontal support piece 318 bent outward at a right angle is formed at the end of the bottom support piece 316, and the horizontal support piece 318 is attached to the bottom. A fire door with an anti-thermal deformation structure comprising a reinforcing plate support plate (310) that is in close contact with the ends of the pieces (116, 216) and resists deformation in the horizontal direction when the bottom piece (116) is deformed in the horizontal direction. According to paragraph 2,
Between the front steel plate reinforcement plate 110 and the rear steel plate reinforcement plate 210 and the reinforcement plate support plate 310, heat is transferred to the reinforcement plate support plate 310 through the front steel plate 100 and the front steel plate reinforcement plate 110. A fire door with a thermal deformation prevention structure, characterized in that an insulating material 410 is inserted to block this and delay the reinforcement plate 310 from being softened and distorted by heat.

Images