JP7565596B2 - Fire door - Google Patents

Description

The present invention relates to a fire door. More specifically, the present invention relates to a fire door that prevents damage to a door closer caused by high heat.

Hinged fire doors used in Japan are required to close automatically to ensure fire resistance, so door closers are used, but the door generally needs to be opened manually. Meanwhile, in recent years, to accommodate barrier-free access and prevent the spread of infectious diseases, there has been a growing need for fire doors that can be opened and closed automatically using non-contact switches or proximity sensors without touching the door with your hands. There are currently door closers that can open and close automatically, mainly overseas, but because they use flammable materials such as electrical boards and resins, there is a high possibility that the door closer itself will catch fire in the event of a fire.

Conventional fire door technologies include those disclosed in Patent Documents 1 and 2.
The door closer of Patent Document 1 prevents hydraulic oil from leaking from inside the door closer in the event of a fire from adhering to the hot door, and is configured as follows: The door closer includes a housing that is installed inside the door via a mounting plate and has an enclosed space filled with hydraulic oil, and is provided with a hydraulic oil drain path for discharging the hydraulic oil from the enclosed space when the housing becomes hot, and a storage tank for storing the hydraulic oil discharged from the hydraulic oil drain path to the outside of the housing. When hydraulic oil leaks from the door closer, the hydraulic oil is stored in the storage tank, so that it is possible to prevent the hydraulic oil from spreading to the fire and causing the fire to grow.

The fire door of Patent Document 2 is a fire door equipped with a concealed door closer, which collects hydraulic oil discharged from the door closer into the door body inside the door body without igniting flames at high temperatures, and is configured as follows. In the concealed door closer having a housing filled with hydraulic oil, the housing is located inside the door body, and an enclosing member is provided inside the door body to cover the sides and bottom of the housing. At least a portion of the inner surface of the enclosing member is provided with a thermally expandable fire-resistant member, and when the thermally expandable fire-resistant member expands within the internal space of the enclosing member due to the high temperature during a fire, it confines the hydraulic oil discharged from the housing within the internal space. This prevents the hydraulic oil from spreading to the fire and causing the fire to grow.

However, the conventional techniques of Patent Documents 1 and 2 are both intended to prevent the spread of damage when the door closer is heated to a high temperature.
Therefore, it is not possible to prevent damage to or fire from occurring to the door closer itself.

JP 2014-95215 A JP 2016-79779 A

In view of the above circumstances, the present invention aims to provide a fire door that can prevent damage and fire even if the door closer is exposed to high heat.

The fire door of the first invention is a fire door consisting of a door mounting frame fixed to a building and a door mounted to the door mounting frame so as to be freely opened and closed, a door closer is attached between the door mounting frame and the door, the door closer is an automatic opening and closing type equipped with an electric motor and an electric board whose main material is synthetic resin, a heat insulating material is placed on the door or the upper frame of the door mounting frame located between the closer body of the door closer and a heat source in the event of a fire, and a heat insulating material is placed on the upper frame of the door mounting frame or the door located between the rail mounting part of the door closer and the heat source in the event of a fire .
The fire door of the second invention is characterized in that, in the first invention, the insulation material is filled inside the upper frame of the door mounting frame and also filled in the internal space at the upper end of the door .
The fire door of the third invention is characterized in that, in the first invention, heat insulating material is arranged between the closer body or the rail mounting portion and the door mounting frame, and between the rail mounting portion or the closer body and the door.

According to the first invention, the heat insulating material between the heat source in the event of a fire and the door closer body or rail mounting part of the door closer reduces the amount of heat transferred to the door closer . This suppresses the temperature rise of the automatic door closer equipped with an electric motor or electric board that is vulnerable to heat, and prevents damage or fire from the door closer.
According to the second invention, the insulating material filled in the upper frame of the door mounting frame and the insulating material filled in the internal space at the upper end of the door reduce the amount of heat transferred from the flame heat source to the door closer, thereby suppressing the temperature rise of the door closer and preventing damage or fire from the door closer.
According to the third invention, the insulating material placed between the closer body or rail mounting portion and the door mounting frame, and between the rail mounting portion or the closer body and the door, respectively, reduces the amount of heat transferred from the flame heat source to the door closer, thereby suppressing the temperature rise of the door closer and preventing damage or fire from the door closer.

1 is a cross-sectional view of a fire door according to a first embodiment of the present invention. FIG. 5 is a cross-sectional view of a fire door according to a second embodiment of the present invention. FIG. 11 is a cross-sectional view of a fire door according to a third embodiment of the present invention. FIG. 11 is a cross-sectional view of a fire door according to a fourth embodiment of the present invention. FIG. 13 is a cross-sectional view of a fire door according to a fifth embodiment of the present invention. FIG. 13 is a cross-sectional view of a fire door according to a sixth embodiment of the present invention. FIG. 13 is a cross-sectional view of a fire door according to a seventh embodiment of the present invention. FIG. 13 is a cross-sectional view of a fire door according to an eighth embodiment of the present invention. 1 is a front view of an example of a fire door to which the present invention is applied. FIG. 10 is a perspective view of the fire door shown in FIG.

Next, an embodiment of the present invention will be described with reference to the drawings.
(Basic structure of fire doors)
First, the basic structure of a fire door will be described with reference to Figs.
The fire door D comprises a door mounting frame A fixed to a structural material of a building, a door B, and a door closer C for opening and closing the door B.

The door mounting frame A is a steel member consisting of left and right vertical frames 1, an upper frame 2, and a lower frame 3. This door mounting frame A is installed in walls and entrances that separate the inside and outside of a building. Partitions within a building include both fire compartment partitions and normal compartment partitions. Additionally, entrances include those located at the boundary between the inside and outside of a building, and those located at the boundary within the building.
Door B is attached to door mounting frame A so as to be able to open and close. Door B shown in the figure is made up of double-door doors 5, 5. Doors 5, 5 are attached to vertical frames 1, 1 by opening and closing fittings. The opening and closing fittings referred to in this invention include various fittings such as hinges that have two mounting plates attached to a single support shaft so as to be able to open and close freely, as well as hinges that use pivots.

For door B, various types other than those shown in the figure can be used without any particular restrictions. For example, the opening and closing type includes swing door types, and swing doors include both single and double swing doors. In terms of use, they include doors for people and goods to enter and exit, as well as doors for inspections where there is no need for people or goods to enter and exit. In terms of size, they include a variety of types, from large to small, depending on the use.

The fire door D of the present invention includes various types. For example, it includes both a constantly closed type and an occasional closing type. When the fire door D is a constantly closed type fire door, the door closer C keeps the fire door D closed at all times and automatically closes the fire door D after it is opened. When the fire door D is an occasional closing type fire door, the door closer C keeps the fire door D fully open at all times to open the passageway, and closes the fire door D in the event of a fire to prevent the fire from spreading. Furthermore, the fire door of the present invention can be used in various places, including places where it is opened and closed each time someone enters or exits.

A door closer C for controlling the opening and closing of the doors 5, 5 is attached between the upper edges of the doors 5, 5 and the upper frame 2 of the door mounting frame A.
The door closer C in this specification includes all known surface-type door closers. Therefore, it includes both manual and electric door closers. The activation means of the door closer includes those that are activated by pushing a switch button, as well as those that are activated by various authentication methods such as face recognition. The operator who activates the switch includes not only humans but also robots.

The housing of the door closer C is made of aluminum or iron. Inside the housing is built a mechanism for opening and closing the fire door D. This mechanism is composed of, for example, the closer body of the door closer C, a link or arm that connects the closer body to the door and the door frame, a biasing means such as a spring that extends the link or arm, and a speed controller that controls the opening and closing speed.
In addition, the speed controller incorporates a gasket such as an O-ring made of synthetic rubber to seal the hydraulic oil inside, and the speed control valve is made of synthetic resin. Door closers C that open and close automatically are equipped with an actuator such as an electric motor and an electric circuit board, and the electric circuit board is mainly made of synthetic resin. These gaskets, speed control valves, and electric circuit boards are easily damaged when exposed to high heat.

The first to eighth embodiments will be described below.
The door closers in each embodiment are designated by the reference symbols C1 to C8, but the reference symbol C will be used to refer comprehensively to all door closers.
First Embodiment
A fire door D according to a first embodiment will be described with reference to FIG.
The upper frame 2 of the door mounting frame A is a steel plate shaped member having a generally U-shaped cross section with an outer plate 21, an inner plate 22 and a lower plate 23. The doors 5, 5 are of an airtight structure in the same way as known steel door structures, with the outer and inner steel plates spaced apart by a few centimeters and closed off by a frame around the perimeter.

The door closer C1 comprises a door closer body 31, an arm 32 attached to protrude downward from the bottom surface of the door closer body 31, and a rail attachment part 33. A biasing means and a speed controller for the arm 32 are housed inside the door closer body 31. A rail that guides the rotational movement of the arm 32 is provided on the rail attachment part 33.
The door closer body 31 is attached to the outer plate 21 of the upper frame 2, and the rail mounting part 33 is attached to the upper end part of the door 5. An arm 32 is connected between the door closer body 31 and the rail mounting part 33. When the arm 32 is rotated by a biasing means or a speed controller in the door closer body 31, the doors 5, 5 are opened and closed.

In the fire door D of this embodiment, the inside of the upper frame 2 is filled with a heat insulating material 6. As the heat insulating material 6, any of known materials such as glass wool, rock wool, calcium silicate board, and heat foaming material can be used without any particular restrictions.
In Fig. 1, the right side of the fire door D is the inside side and the heated side. The left side is the outside side and the room side. In other words, the heat insulating material 6 is present between the heated side and the closer body 31 of the door closer C1.

In the embodiment of Figure 1, the presence of insulating material 6 between the heating source and the door closer C1 reduces the amount of heat transferred to the door closer body 31, suppressing the temperature rise of the door closer C1 and preventing damage or fire.

In this embodiment, a heat insulating material 9 may be further incorporated in the internal space of the upper end portion of the doors 5, 5. The heat insulating material 9 may be incorporated in a portion corresponding to the rail mounting portion 33 of the door closer C1.
By adding this insulating structure, the presence of the insulating material 9 between the heat source and the rail mounting portion 33 reduces the amount of heat transferred to the closer main body 31 via the rail mounting portion 33 and the arm 32, suppressing the temperature rise of the door closer C1 and preventing damage or fire.

Second Embodiment
A fire door according to a second embodiment will be described with reference to FIG.
The door closer C2 is composed of a closer body 31, a bracket 34, and a link 35. The link 35 is formed by connecting a body side arm 36 and a door side arm 37 with a pin. The closer body 31 and the bracket 34 are connected by the link 35 consisting of the body side arm 36 and the door side arm 37. When the link 35 is opened or closed by the biasing means or speed controller in the closer body 31, the doors 5, 5 are opened or closed.
The closer body 31 is attached to the outer panel 21 of the upper frame 2, and the bracket 34 is attached to the upper end portions of the doors 5,5.

In this embodiment, the heat insulating material 6 is filled inside the upper frame 2. In addition to this, this embodiment also includes a case in which a heat insulating material 9 is further built inside the upper end portions of the doors 5, 5.
In this embodiment, too, the presence of insulation materials 6, 9 between the heating source and the door closer C2 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C2 and preventing damage or fire.

Third Embodiment
A fire door according to a third embodiment will be described with reference to FIG.
The door closer C3 is composed of a closer body 31, a bracket 34, and a link 35. The link 35 is formed by connecting a body side arm 36 and a door side arm 37 with a pin. The closer body 31 and the bracket 34 are connected by the link 35 consisting of the body side arm 36 and the door side arm 37.

The closer body 31 is attached to the upper end of the doors 5, 5, and the bracket 34 is attached to the outer plate 21 of the upper frame 2. When the link 35 is opened or closed by the biasing means or speed controller in the closer body 31, the doors 5, 5 are opened or closed.

In this embodiment, a heat insulating material 6 is filled inside the upper frame 2. In addition, a heat insulating material 9 is also filled in the internal space of the upper end portion of the doors 5, 5.
In this embodiment, too, the presence of insulation materials 6, 9 between the heating source and the door closer C3 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C3 and preventing damage or fire.

(Fourth embodiment)
A fire door according to a fourth embodiment will be described with reference to FIG.
The door closer C4 comprises a closer body 31, a rail mounting portion 33, and an arm 32. A biasing means for the arm 32 and a speed controller are housed inside the closer body 31. A rail is provided in the rail mounting portion 33 to guide the pivoting motion of the arm 32. The arm 32 is connected between the closer body 31 and the rail mounting portion 33. When the arm 32 is pivoted by the biasing means and speed controller in the closer body 31, the doors 5, 5 are opened and closed.
The closer body 31 is attached to the upper end portions of the doors 5, 5, and the rail mounting portion 33 is attached to the outer panel 21 of the upper frame 2.

In this embodiment, a heat insulating material 6 is filled inside the upper frame 2. In addition to this, a heat insulating material 9 is also filled in the internal space of the upper end portion of the doors 5, 5.
In this embodiment, too, the presence of insulation materials 6, 9 between the heating source and the door closer C4 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C4 and preventing damage or fire.

Fifth Embodiment
Next, a fire door according to a fifth embodiment will be described with reference to FIG.
The door closer C5 comprises a door closer body 31, a rail mounting portion 33, and an arm 32. A biasing means and a speed controller for the arm 32 are housed inside the door closer body 31. A rail is provided on the rail mounting portion 33 to guide the pivoting movement of the arm 32. The arm 32 is connected between the door closer body 31 and the rail mounting portion 33.
When the arm 32 is rotated by a biasing means or a speed controller in the closer body 31, the doors 5, 5 are opened or closed.

The closer body 31 is attached to the outer panel 21 of the upper frame 2, and the rail mounting portion 33 is attached to the upper end portions of the doors 5, 5.
In this embodiment, an insulating material 7 is sandwiched and attached between the closer body 31 of the door closer C5 and the outer panel 21 of the upper frame 2 of the door mounting frame A, and an insulating material 8 is sandwiched and attached between the rail mounting portion 33 of the door closer C5 and the outer panel 51 of the doors 5, 5.

In this embodiment, the presence of insulating materials 7 and 8 between the heat source and the door closer C5 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C5 and preventing damage or fire.

The door closer C5 of this embodiment is attached to the outer surface of the door mounting frame A and door B, and is not designed to be built into the interior of the door mounting frame A, and is inherently susceptible to the effects of heat. However, by placing insulating material between the heat source and the door closer C5, damage to or fires caused by the door closer C5 can be prevented.

Furthermore, since the insulation material 7 is placed on the outer surface of the upper frame 2 and the insulation material 8 is attached to the outer surfaces of the doors 5, 5, no special members are required to hold the insulation materials.
The heat insulating material 7 is shielded from the flames by the upper frame 2 and does not come into direct contact with the flames.
In addition, the heat insulating material 8 is shielded from the flames by the doors 5, 5 and does not come into direct contact with the flames, so that the fire resistance time of the heat insulating materials 7, 8 is extended.

In the fire door D of this embodiment, the insulating materials 7 and 8 are provided between the door closer C5 and the fire heat source, so the amount of heat transferred from the flame to the door closer C5 is reduced, the temperature rise of the door closer C5 is suppressed, and damage or fire from the door closer C5 can be prevented.

Sixth Embodiment
A fire door according to a sixth embodiment will be described with reference to FIG.
The door closer C6 is composed of a closer body 31, a bracket 34, and a link 35. The link 35 is formed by connecting a body side arm 36 and a door side arm 37 with a pin. The closer body 31 and the bracket 34 are connected by the link 35 consisting of the body side arm 36 and the door side arm 37.
The closer body 31 is attached to the outer panel 21 of the upper frame 2, and the bracket 34 is attached to the upper end portions of the doors 5, 5.

In this embodiment, an insulating material 7 is sandwiched and attached between the closer body 31 of the door closer C6 and the outer panel 21 of the upper frame 2 of the door mounting frame A, and an insulating material 8 is sandwiched and attached between the bracket 34 of the door closer C6 and the outer panel 51 of the doors 5, 5.
In this embodiment, too, the presence of insulation materials 7, 8 between the heating source and the door closer C6 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C6 and preventing damage or fire.

Seventh Embodiment
A fire door according to the seventh embodiment will be described with reference to FIG.
The door closer C7 is composed of a closer body 31, a bracket 34, and a link 35. The link 35 is formed by connecting a body side arm 36 and a door side arm 37 with a pin. The closer body 31 and the bracket 34 are connected by the link 35 consisting of the body side arm 36 and the door side arm 37. When the link 35 is opened or closed by the biasing means or speed controller in the closer body 31, the doors 5, 5 are opened or closed.
The closer body 31 is attached to the upper end portions of the doors 5, 5, and the rail mounting portion 33 is attached to the outer panel 21 of the upper frame 2.

In this embodiment, an insulating material 7 is sandwiched and attached between the bracket 34 of the door closer C7 and the outer panel 21 of the upper frame 2 of the door mounting frame A, and an insulating material 8 is sandwiched and attached between the closer body 31 of the door closer C7 and the outer panels 51 of the doors 5, 5.
In this embodiment, too, the presence of insulation materials 7, 8 between the heating source and the door closer C7 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C7 and preventing damage or fire.

Eighth embodiment
A fire door according to an eighth embodiment will be described with reference to FIG.
The door closer C8 comprises a closer body 31, a rail mounting portion 33, and an arm 32. The arm 32 is connected between the closer body 31 and the rail mounting portion 33. When the arm 32 is rotated by a biasing means or a speed controller in the closer body 31, the doors 5, 5 are opened and closed.
The closer body 31 is attached to the upper end portions of the doors 5, 5, and the rail mounting portion 33 is attached to the outer panel 21 of the upper frame 2.

In this embodiment, an insulating material 8 is sandwiched and attached between the closer body 31 of the door closer C8 and the outer panel 51 of the doors 5, 5, and an insulating material 7 is sandwiched and attached between the rail mounting portion 33 of the door closer C8 and the outer panel 21 of the upper frame 2 of the door mounting frame A.
In this embodiment, too, the presence of insulation materials 7, 8 between the heating source and the door closer C8 reduces the amount of heat transferred to the closer body 31, suppressing the temperature rise of the door closer C8 and preventing damage or fire.

A Door mounting frame B Door C Door closer D Fire door 1 Vertical frame 2 Top frame 3 Bottom frame 5 Door 6 Insulation 7 Insulation 8 Insulation 9 Insulation 31 Door closer body 32 Arm 33 Rail mounting part 34 Bracket 35 Link

Claims (3)

A fire door comprising a door frame fixed to a building and a door attached to the door frame so as to be freely opened and closed,
A door closer is attached between the door mounting frame and the door,
The door closer is an automatic opening and closing type having an electric motor and an electric board whose main material is synthetic resin,
A heat insulating material is disposed on the upper frame of the door or the door mounting frame located between the door closer body of the door closer and a heat source in the event of a fire,
Furthermore, a heat insulating material is provided on the upper frame of the door mounting frame or on the door, which is located between the rail mounting portion of the door closer and a heat source in the event of a fire.
A fire door characterized by: The heat insulating material is filled inside the upper frame of the door mounting frame and also filled in the internal space at the upper end of the door.
2. The fire door according to claim 1. A heat insulating material is disposed between the closer body or the rail mounting portion and the door mounting frame, and between the rail mounting portion or the closer body and the door.
2. The fire door according to claim 1.