JP2020159123A - Fire door - Google Patents

Abstract

To restrain heat from being transmitted from a heating surface side to a non-heating surface side through a door body.SOLUTION: A fire door is made up of an aggregate including four-circumferential frames (frames 3, 4, 5, 6, 4', 5'), surface members 20 and 21 fixed to the four-circumferential frames 3 to 6, and a refractory core material which fills a space surrounded by the surface members 20 and 21. The refractory core material includes a main refractory core material (blocks 8A to 8D) provided in a portion surrounded by the four-circumferential frames, and heat absorbing layers a1 and a2 are provided on the front surface of the main refractory core material (blocks 8A to 8D).SELECTED DRAWING: Figure 3

Description

The present invention relates to a fire door.

In recent years, fire doors are not limited to fire-prevention performance, but there is a tendency that heat-shielding performance is required to prevent heat transfer from the fire side to the non-fire side, which is harmful during evacuation.

A fire door is composed of a door body and a door frame. Generally, the structure of the door body is composed of a surface material, a force bone and a middle bone, and the force bone is fixed to the surface material in four directions in the height direction. The middle bones extending in the width direction are provided at equal intervals in the width direction. Furthermore, in order to impart heat shielding performance, it is conceivable to fill the inside of the door body with a heat insulating material or a fireproof material as a core material, but the surface material, the reinforced bone, and the middle bone are made of metal (typically steel). Therefore, if the temperature on the fire side rises, the heat on the fire side may be transferred to the non-fire side by radiation, convection, and conduction through the door body itself. As a result, combustible materials on the non-fire side that have received heat may ignite and the fire may spread, or the heat of the fire door itself may obstruct the passage of the evacuation route. The fire door described in Patent Document 1 uses a heat insulating material containing a porous material and free water to ensure heat insulating properties in the event of a fire. With this means, heat transfer from the fire side to the non-fire side depends on a core material (insulation material) having a special structure.
JP 2016-166503

An object of the present invention is to suppress heat transfer from the heated surface side to the non-heated surface side through the door body.

The technical means adopted by the present invention to solve such a problem is
Aggregate including a four-circle frame and
The surface material fixed to the four-circle frame and
The refractory core material filled in the space surrounded by the surface material and
Consists of
The refractory core material includes a main refractory core material provided in a portion surrounded by the four-circumferential frame.
A heat absorbing layer is provided on the finding surface of the main refractory core material.
It is a fire door.

In one embodiment, the endothermic layer is formed of an endothermic material that exhibits an endothermic effect upon heating.
In one embodiment, the endothermic material is an endothermic paint, and the endothermic layer is formed by the applied endothermic paint.
In one embodiment, the endothermic material contains aluminum hydroxide.
In one embodiment, the main refractory core material and the surface material are in contact with each other via a heat absorbing layer.
In one embodiment, the main refractory core material comprises a fire resistant heat insulating material.
In one embodiment, the insulation is rock wool.

In one embodiment, the main refractory core material is formed of two or more plate-shaped refractory materials in multiple layers, and the finding surfaces of the refractory materials are in contact with each other or close to each other via a heat absorbing layer.
In one embodiment, the plate-shaped refractory material is rock wool.
In one embodiment, a heat absorbing layer is provided on a part or all of the prospective surface of the main refractory core material.

In one embodiment, the main refractory core material is provided in a plurality of stages in the height direction of the door body, and the aggregate includes a middle and horizontal frame provided between the plurality of main refractory core materials.
By providing the middle and horizontal frames, it is possible to prevent the main refractory core material filled inside the door body from falling off and creating a gap above the inside of the door body. If a gap is created above the inside of the door body, hot air may convection and cause a temperature rise on the non-fire side.
In one embodiment, the aggregate includes a medium vertical frame provided on the door end side of the door body, and the main refractory core material is an upper frame, a lower frame, and a door tail side vertical frame of the four-circumferential frame. , It is provided in a portion surrounded by the middle and vertical frames.
In one aspect, such portions are vertically partitioned by a horizontal frame, and the main refractory core material is provided in a plurality of stages in the height direction of the door body.

In one embodiment, the refractory core material includes an inner refractory core material filled inside the aggregate, and an endothermic layer is provided between the inner refractory core material and the inner surface of the aggregate, and the inner refractory core material is provided. The core material and the inner surface of the aggregate are in contact with each other via a heat absorbing layer.
In one embodiment, a heat absorbing layer is formed on the prospective surface of the main refractory core material, and the prospective surface of the main refractory core material is the bone filled with the inner refractory core material via the heat absorbing layer. It is in contact with the expected surface of the material.
In one embodiment, the inner refractory core material comprises a refractory heat insulating material.
In one embodiment, the insulation is rock wool.

In one embodiment, the refractory core material comprises an outer refractory core material located between the found surface of the aggregate and the surface material.
In one embodiment, the outer refractory core material is a calcium silicate plate.
In one embodiment, a lock is built in the door end side portion of the fire door, and between the found surface of the aggregate forming the door end side vertical frame of the four-circle frame and the surface material. The outer fire-resistant core material on the door end side, which is located, extends beyond the finding surface to the center side of the door body, and extends so as to be located between the installation position of the lock and the surface material.

In one embodiment, the outer fireproof core material is located above and below the lock, and the door end side internal fireproof core material is provided between the outer fireproof core material on the door end side.
In one embodiment, the door end side internal refractory core material comprises a central first element (for example, rock wool) and a second element (calcium silicate plate) provided so as to sandwich the first element. The first element and the second element are in contact with each other via a heat absorbing layer, and the second element is in contact with the outer refractory core material.

In the fire door according to the present invention, by providing the endothermic layer on the finding surface of the main fire-resistant core material provided in the portion surrounded by the four-circumferential frame, the heat absorption reaction due to the heat at the time of fire causes the fire door to be non-heated from the heating surface side. It is possible to suppress the transfer of heat to the heating surface side through the door body.

In the fire door according to the present invention, by further providing an endothermic layer located on the contact surface of each element constituting the door body, an endothermic reaction due to heat at the time of a fire causes an endothermic reaction from the heated surface side to the non-heated surface side. It is possible to suppress the transfer of heat through each element.

It is a front view which looked at the door device from the outdoor side. FIG. 5 is a vertical sectional view taken along the line AA of the door device according to FIG. It is a BB vertical sectional view of the door device which concerns on FIG. It is a CC cross-sectional view of the door device which concerns on FIG. It is an enlarged view of the door end side part of FIG. It is a DD cross-sectional view of the door device which concerns on FIG. It is a figure which shows the aggregate which filled with the 2nd refractory core material, and the block of the 3rd refractory core material. It is a figure which shows the 1st refractory core material. It is a figure which shows the 4th refractory core material. It is a model diagram showing the heat-shielding effect of the heat-absorbing layer in the first fire-resistant core material having a multi-layer structure. The left figure is a model in which a heat-absorbing layer is provided at the boundary of each layer, and the right figure is on the surface of the first fire-resistant core material. Only the model provided with the endothermic layer is shown.

[A] Overall Configuration of Door Device FIG. 1 is a front view of the door device according to the embodiment as viewed from the outdoor side, and the door device is a vertically rectangular door frame 1 and an opening formed by the door frame 1. It consists of a door body 2 that opens and closes the part. In the present embodiment, the door body 2 is a heat shield door or a fire door, and the door device is installed in an opening where fire prevention performance is required.

The door frame 1 is formed in a vertical rectangular shape from the upper frame 10, the lower frame 11, the door tip side vertical frame 12, and the door tail side vertical frame 13. The upper frame 10, the door end side vertical frame 12, and the door tail side vertical frame 13 are formed with grooves that open toward the open side of the door body 2 in three directions, and the grooves are made of airtight rubber. An upper airtight member S1 (see FIG. 3), a door end side airtight member S2, and a door tail side airtight member S3 (see FIG. 5) are provided. S3 is the door stop on three sides. When the opening is fully closed, the upper surface, the lower surface, the door end side prospective surface, and the door tail side prospective surface of the door body 2 in the closed posture are the upper frame 10, the lower frame 11, the door end side vertical frame 12, and the door tail side, respectively. It is close to the prospective surface of the vertical frame 13, and the peripheral portions of the three sides (door end side portion, door tail side portion, upper portion) of the door body 2 are the upper airtight member S1, the door end side airtight member S2, and the door tail. It comes into contact with the side airtight member S3.

The door body 2 according to the present embodiment includes a metal aggregate including a four-circumferential frame, a first metal surface material 20 and a second surface material 21 fixed to the four-circumferential frame, and a first surface. It is composed of a refractory core material filled in a space surrounded by the material 20 and the second surface material 21. The refractory core material according to the present embodiment is a first refractory core material or a main refractory core material (blocks 8A to 8D made of rock wool RW1 to 3) and a second refractory core that occupy the largest volume in the internal space of the door body 2. Materials (rock wool RW4 to RW7, RW12, RW13 filled in the internal space of each aggregate), third refractory core material (arranged between each aggregate and the first surface material 20 and the second surface material 21). The refractory core material 7A to 7L) and the fourth refractory core material (blocks 14A to 14D composed of rock wool RW8 to RW11 and the refractory core materials 7E'and 7F') are included.

The aggregates are an upper frame 3, a lower frame 4, a door end side vertical frame 5, a door tail side vertical frame 6, and one vertical center provided on the door end side of the door body 2 that forms a four-circle frame. It is composed of a bone, that is, a middle vertical frame 5', and three horizontal middle bones, that is, a middle horizontal frame 4'provided in a space between the middle vertical frame 5'and the door tail side vertical frame 6. Locks (1st lock 24, 2nd lock 25, 3rd lock 26) are housed at a predetermined height in the space between the door end side vertical frame 5 and the middle vertical frame 5'.

The first surface material 20 is formed by bending a thin steel plate, and has a main surface portion 200 forming an outdoor side finding surface of the door body 2 and an upper side 201 formed by bending a peripheral portion of the main surface portion 200. , The lower side 202, the first side side 203 on the door end side, and the second side side 204 on the door end side. In the following description, the main surface portion 200 of the first surface material 20 constituting the door body 2 as one component of the door body 2 is referred to as a first finding surface 200.

The second surface material 21 is formed by bending a thin steel plate, and has a main surface portion 210 forming an indoor side finding surface of the door body 2 and an upper side 211 formed by bending a peripheral portion of the main surface portion 210. , The lower side 212, the first side side 213 on the door tip side, and the second side side 214 on the door tail side. In the following description, the main surface portion 210 of the second surface material 21 constituting the door body 2 as one component of the door body 2 is referred to as a second finding surface 210.

The upper side 201 of the first surface material 20 and the upper side 211 of the second surface material 21 are fixed to the upper frame 3 (upper surface portion 32), and the upper side 201 of the first surface material 20 and the upper side 211 of the second surface material 21 The upper surface of the door body 2 is formed from the door body 2, and the lower side 202 of the first surface material 20 and the lower side 212 of the second surface material 21 are fixed to the lower frame 4 (lower surface portion 42), and the first surface material 20 The lower surface of the door body 2 is formed from the lower side 202 and the lower side 212 of the second surface material 21, and the first side side 203 of the first surface material 20 and the first side side 213 of the second surface material 21 are doors. It is fixed to the front side vertical frame 5 (expected surface portion 52), and the door end side prospective surface of the door body 2 is formed from the first side side 203 of the first surface material 20 and the first side side 213 of the second surface material 21. The second side side 204 of the first surface material 20 and the second side side 214 of the second surface material 21 are fixed to the door tail side vertical frame 6 (expected surface portion 62), and the first surface is formed. A door tail side prospective surface of the door body 2 is formed from the second side side 204 of the material 20 and the second side side 214 of the second surface material 21.

As shown in FIG. 1, the door body 2 is rotatably supported by the door tail side vertical frame 13 of the door frame 1 by a hinge 22 provided on the door tail side portion. On the door end side of the outdoor side finding surface (first finding surface 200 of the first surface material 20) and the indoor side finding surface (second finding surface 210 of the second surface material 21) of the door body 2. A handle 23 (the handle on the indoor side finding surface is not shown) is provided. The first lock 24 is built in the door end side portion of the door body 2 located in the middle in the height direction. Further, the second lock 25 is built in the upper part of the door end side portion of the door body 2, and the third lock 26 is built in the third lock 26 located in the lower part.

The first lock 24 has a predetermined thickness (expected dimension) and a predetermined width (finding dimension), and includes a lock case 240 having a front view shape, and a latch and a dead bolt built in the lock case 240. A strike of the first lock 24 is provided at a predetermined height of the prospective surface 120 (see FIG. 4A) of the door end side vertical frame 12 of the door frame 1. The latch protrudes from the door end side finding surface of the door body 2 by the urging means, locks on the latch receiving hole of the strike, maintains the closed posture of the door body 2, and protrudes in conjunction with the rotation operation of the handle 23. The latch is retracted into the door end side prospective surface of the door body 2 to unlock the locked state, thereby opening the door body 2. The dead bolt is a dead strike due to the rotation of the operation knob (not shown) provided on the indoor side finding surface of the door body 2 and the rotation of the key inserted into the key hole 241 provided on the outdoor side finding surface. It is designed to take a locking posture and a releasing posture with respect to the bolt receiving hole.

The second lock 25 has a predetermined thickness (expected dimension) and a predetermined width (finding dimension), and includes a front view-shaped lock case 250 and a latch built in the lock case 250. Not prepared. The third lock 26 has a predetermined thickness (expected dimension) and a predetermined width (finding dimension), and includes a front view-shaped lock case 260 and a latch built in the lock case 260. Not prepared. In the present embodiment, the lock case 240 of the first lock 24, the lock case 250 of the second lock 25, and the lock case 260 of the third lock 26 have the same thickness (expected dimension) and width (finding dimension). There is. A strike of the latch of the second lock 25 is provided in the upper portion of the prospective surface of the vertical frame 12 on the door end side of the door frame 1, and a strike of the latch of the third lock 26 is provided in the lower portion. The latches of the second lock 25 and the third lock 26 project from the door end side mitsuke surface of the door body 2 by urging means and are locked to the latch receiving hole of the strike to maintain the closed posture of the door body 2. .. In the present embodiment, the door body 2 is locked to the door end side vertical frame 12 of the door frame 1 by latches at three points in the height direction when the opening is fully closed, so that the door body 2 is heated by the heat of a fire. Warpage is prevented as much as possible, and an unfavorable gap in fire prevention, smoke prevention, and heat insulation is prevented from being formed between the door body 2 and the door frame 1.

The rotation of the handle 23 and the operations of the latch of the first lock 24, the latch of the second lock 25, and the latch of the third lock 26 are linked, and when the door body 2 is closed, the handle 23 in the horizontal posture is lowered. The latch of the first lock 24, the latch of the second lock 25, and the latch of the third lock 26, which are in the locking posture (protruding posture) with respect to the latch receiving hole, are on the door end side of the door body 2. It moves in the direction of retracting into the finding surface and becomes the release posture (retract posture). Therefore, when the door body 2 is in the closed posture, the three latches in the protruding posture are interlocked with the rotation operation of the handle 23. The door body 2 is opened by simultaneously retracting it into the door end side finding surface of the door body 2 and unlocking the locked state.

More specifically, the first lock 24 and the second lock 25 and the first lock 24 and the third lock 26 are interlocked and connected by a rod (not shown) extending in the door body 2 in a vertical posture. The latch in the locked posture becomes the released posture in conjunction with the downward or upward movement of the rod. Such a so-called three-point latch lock is disclosed in, for example, Japanese Patent Application Laid-Open No. 2013-722179 and Japanese Patent Application Laid-Open No. 2013-249644, and refer to the description of these documents for a specific example of interlocking configuration of a rod and a latch. can do. In the present embodiment, a total of three tablets, the first lock 24 having a dead bolt and a latch, the second lock 25 having only a latch, and the third lock 26, are used, but only one of the first lock 24 is used. It may be a lock, or four or more locks may be adopted.

On the upper surface, lower surface, door end side prospective surface, and door tail side prospective surface of the door body 2, between the upper side 201 of the first surface material 20 and the upper side 211 of the second surface material 21, the lower side of the first surface material 20 Between 202 and the lower side 212 of the second surface material 21, between the first side side 203 of the first surface material 20 and the first side side 213 of the second surface material 21, the second side of the first surface material 20 A thermal expansion fireproof member 16 (shown as represented by FIG. 4A) is provided so as to straddle between the side 204 and the second side side 214 of the second surface material 21, and a screw 17 (FIG. 4 (A)) is provided. ) Is fixed to the upper surface 32 of the upper frame 3 together with the upper sides 201 and 211, and fixed to the lower surface 42 of the lower frame 4 together with the lower sides 202 and 212, and the first side side 203 on the door end side. It is fixed to the prospective surface portion 52 of the door end side vertical frame 5 together with 213, and is fixed to the prospective surface portion 62 of the door tail side vertical frame 6 together with the second side sides 204 and 214 on the door tail side. In the event of a fire, the thermal expansion refractory member 16 foams and expands due to the heat of the fire, so that the upper surface of the door body 2, the door end side prospective surface, the door tail side prospective surface, the upper frame 10 of the door frame 1, and the door The gap between the front vertical frame 12 and the door end vertical frame 13 is closed.

The door body 2 according to the present embodiment has a heat-insulating refractory core material in the internal space in order to suppress heat transfer from the heated surface side to the non-heated surface side through the surface material or aggregate. Is filled. The refractory core material according to the present embodiment includes an upper frame 3, a lower frame 4, a middle and horizontal frame 4'in the internal space of the door body 2 surrounded by the first surface material 20 and the second surface material 21. A first refractory core material (block 8A made of rock wool RW1 to RW3) located in a space surrounded by the middle vertical frame 5'and the door tail side vertical frame 6 and provided over almost the entire thickness of the door body 2. ~ 8D) and each aggregate (upper frame 3, lower frame 4, door tip side vertical frame 5, door tail side vertical frame 6, middle vertical frame 5', middle horizontal frame 4') 2 Refractory core materials (rock wool RW4 to RW7, RW12, RW13) and each aggregate (upper frame 3, lower frame 4, door front side vertical frame 5, door tail side vertical frame 6, middle vertical frame 5', middle With the third refractory core material 7 (7A to 7L) provided between the found surface of the horizontal frame 4') and the main surface portion 200 of the first surface material 20 and the main surface portion 210 of the second surface material 21. , Located in the space between the door end side vertical frame 5 and the middle vertical frame 5', the third refractory core material 7 (7E, 7F) and the first lock 24, the second lock 25, and the third lock 26 It is composed of a fourth refractory core material (blocks 14A to 14D composed of 7E', 7F', RW8 to RW11) provided between them.

The first refractory core material is prepared as block 8A, block 8B, block 8C, and block 8D assembled from rock wool RW1 to RW3. Each aggregate (upper frame 3, lower frame 4, door tail side vertical frame 6, middle vertical frame 5', middle horizontal frame) filled with the second refractory core material (rock wool RW4, RW5, RW7, RW12 to RW13) Blocks 9A to 9E are prepared by assembling 4') and the third refractory core material 7 (excluding 7A to 7L, 7E, and 7F), respectively. The fourth refractory core material is prepared as blocks 14A to 14D assembled from RW8 to RW11, 7E', 7F', and the door end side vertical frame 5 filled with rock wool RW6, the third refractory core material (7E, 7F), the first lock 24, the second lock 25, and the third lock 26 are provided in the internal space of the door end side portion (finding width corresponding to the lock) of the door body 2.

In the fire door according to the present embodiment, as described in detail below, the heat absorbing layers a1 to the finding surfaces of the rock wool RW1 to RW3 of the first fireproof core material provided in the portion surrounded by the four-circumferential frame. By providing a6, it is possible to prevent heat from being transmitted from the heated surface side to the non-heated surface side through the door body due to the endothermic reaction caused by heat during a fire. Further, by providing the endothermic layers a7 to a16 located on the contact surface of each element constituting the core material of the door body, each element is moved from the heated surface side to the non-heated surface side by the endothermic reaction due to the heat at the time of fire. It suppresses the transfer of heat through the door.

[B] Aggregate Filled with Second Refractory Core Material The aggregate of the door body 2 according to the present embodiment includes an upper frame 3, a lower frame 4, a door end side vertical frame 5, and a door tail side vertical frame 6. It is composed of four rounds of refractory, a vertical middle bone or middle vertical frame 5'located on the door end side of the door body 2, and a horizontal middle bone or middle horizontal frame and 4'. Each aggregate or frame 3 to 6, 5'4'is a long member made of metal (typically made of steel) and has a U-shaped cross section, and rock wool is used as a heat insulating material in the concave internal space. RW4 to RW7, RW12, and RW13 are filled. Rock wool RW4 to RW7, RW12, and RW13 form a second refractory core material. Hereinafter, the configuration of the aggregate filled with the second refractory core material will be described in detail with reference mainly to FIG.

The upper frame 3 of the door body 2 is formed in a U-shape in cross section from the first finding surface portion 30, the second finding surface portion 31, and the upper surface portion 32. Rock wool RW4 as a filler is filled in the recess formed from the first finding surface portion 30, the second finding surface portion 31, and the upper surface portion 32. The surface of the rock wool RW4 is coated with a heat absorbing paint except for the lower surface, and heat absorbing layers a11, a12, and a13 are formed between the inner surface of the upper frame 3 and the rock wool RW 4, and the upper frame 3 The rock wool RW4 is in contact with the inner surface of the rock wool RW4 via the heat absorbing layers a11, a12, and a13.

The lower frame 4 of the door body 2 is formed in a U-shape in cross section from the first finding surface portion 40, the second finding surface portion 41, and the lower surface portion 42. Rock wool RW5 as a filler is filled in the recess formed from the first finding surface portion 40, the second finding surface portion 41, and the lower surface portion 42. The surface of the rock wool RW 4 is coated with a heat absorbing paint except for the upper surface, and heat absorbing layers a11, a12, and a13 are formed between the inner surface of the lower frame 4 and the rock wool RW 5, and the lower frame 4 The rock wool RW5 is in contact with the inner surface of the rock wool RW5 via the heat absorbing layers a11, a12, and a13.

The door end side vertical frame 5 of the door body 2 is formed in a U-shape in cross section from the first finding surface portion 50, the second finding surface portion 51, and the prospective surface portion 52. Rock wool RW6 as a filler is filled in the recess formed from the first finding surface portion 50, the second finding surface portion 51, and the prospective surface portion 52. The surface of the rock wool RW6 is coated with a heat absorbing paint except for the prospective surface on the door end side, and the heat absorbing layers a11, a12, and a13 (Fig.) Between the inner surface of the vertical frame 5 on the door end side and the rock wool RW6. 6 is used), and the inner surface of the door end side vertical frame 5 and the rock wool RW6 are in contact with each other via the heat absorbing layers a11, a12, and a13. The first finding surface portion 50 of the door end side vertical frame 5 and the predetermined portion of the second finding surface portion 51 in the height direction are cut out to receive the lock cases 240, 250, 260, and correspond to the lock. The internal space is not filled with rock wool RW6. In the present embodiment, the upper and lower ends of the prospective surface portion 52 of the door end side vertical frame 5 are the upper extension piece and the lower extension piece beyond the upper and lower ends of the first finding surface portion 50 and the second finding surface portion 51, respectively. Pieces (not shown) are formed, which are located on the door end side end face of the upper frame 3 and the door end side end face of the lower frame 4, respectively, and are located on the door end side end face of the rock wool RW4 and the door end side of the rock wool RW5, respectively. Closely opposed or in contact with the end face on the door end side.

The door tail side vertical frame 6 of the door body 2 is formed in a U-shape in cross section from the first finding surface portion 60, the second finding surface portion 61, and the prospective surface portion 62. Rock wool RW7 as a filler is filled in the recess formed from the first finding surface portion 60, the second finding surface portion 61, and the prospective surface portion 62. The surface of the rock wool RW7 is coated with a heat absorbing paint except for the prospective surface on the door end side, and heat absorbing layers a11, a12, and a13 are formed between the inner surface of the vertical frame 6 on the door tail side and the rock wool RW7. The inner surface of the door tail side vertical frame 6 and the rock wool RW7 are in contact with each other via the heat absorbing layers a11, a12, and a13. In the present embodiment, the upper and lower ends of the prospective surface portion 62 of the door tail side vertical frame 6 are the upper extension piece and the lower extension piece beyond the upper and lower ends of the first finding surface portion 60 and the second finding surface portion 61, respectively. Pieces (not shown) are formed, which are located on the door butt side end face of the upper frame 3 and the door butt side end face of the lower frame 4, respectively, and of the rock wool RW4 door butt side end face and the rock wool RW5 Closely opposed or in contact with the end face on the door tail side.

The middle vertical frame 5'is formed in a U-shape in cross section from the first finding surface portion 50', the second finding surface portion 51', and the prospective surface portion 52'. Rock wool RW12 as a filler is filled in the recess formed from the first finding surface portion 50', the second finding surface portion 51', and the prospective surface portion 52'. The surface of the rock wool RW12 is coated with a heat absorbing paint except for the prospective surface on the door end side, and heat absorbing layers a11, a12, and a13 are formed between the inner surface of the middle vertical frame 5'and the rock wool RW12. The inner surface of the middle vertical frame 5'and the rock wool RW12 are in contact with each other via the heat absorbing layers a11, a12, and a13.

The middle horizontal frame 4'is formed in a U-shape in cross section from the first finding surface portion 40', the second finding surface portion 41', and the lower surface portion 42'. Rock wool RW13 as a filler is filled in the recess formed from the first finding surface portion 40', the second finding surface portion 41', and the lower surface portion 42'. The surface of the rock wool RW13 is coated with a heat absorbing paint except for the upper surface, and the heat absorbing layers a11, a12, and a13 are coated between the inner surface of the inner horizontal frame 4'and the rock wool RW13. The inner surface of the horizontal frame 4'and the rock wool RW13 are in contact with each other via the heat absorbing layers a11, a12, and a13.

The endothermic material (heat-absorbing coating material in this embodiment) forming the heat-absorbing layers a11, a12, and a13 is a substance that exhibits a heat-absorbing action by heating, and is, for example, a coating material containing aluminum hydroxide as a heat-absorbing substance. Such an endothermic substance is disclosed in, for example, Japanese Patent Application Laid-Open No. 2014-88277. Aggregates (frames 3 to 6, 5', 4 of the door body 2 due to the endothermic effect associated with the endothermic reaction of the heat absorbing layers a11, a12, and a13 by being exposed to the high temperature at the time of fire by heating at the time of fire. ´) and the temperature rise around them can be suppressed.

By filling the internal space of the aggregate (frames 3 to 6, 5'4') of the door body 2 with the second refractory core material (rock wool RW4 to RW7, RW12, RW13), the aggregate (frames 3 to 3 to 6, 5', 4') suppresses heat transfer due to convection from one finding surface to the other finding surface. In the present embodiment, rock wool RW4 to RW7, RW12, and RW13, which are fire-resistant heat insulating materials, are disclosed as the second refractory core material, but the material of the second refractory core material is not limited to rock wool. For example, it may be glass wool or plaster.

[C] Third refractory core material In the present embodiment, the expected dimensions of the four-circumferential frame forming the ribs, that is, the upper frame 3, the lower frame 4, the door end side vertical frame 5, and the door tail side vertical frame 6. The expected dimension is smaller than the expected dimension (thickness) of the door body 2, and is between the first surface material 20 and the four-circumferential frame, and between the second surface material 21 and the four-circumferential frame. , Plate-shaped third refractory core materials 7A to 7H are provided. By sandwiching the third refractory core materials 7A to 7H between the metal first surface material 20, the second surface material 21, and the metal four-circumferential frame, the door body 2 is sandwiched from one finding surface to the other. The heat transfer to the found surface of the door is suppressed.

The expected dimensions of the middle vertical frame 5'and the middle horizontal frame 4'that form the middle bone are smaller than the expected dimensions (thickness) of the door body 2, and the first surface material 20 and the middle vertical frame 5 A plate-shaped third refractory core material 7I to 7L is provided between the second surface material 21 and the middle vertical frame 5'and the middle horizontal frame 4'. By sandwiching the third refractory core materials 7I to 7L between the first surface material 20 and the second surface material 21 made of metal and the middle vertical frame 5'and the middle horizontal frame 4', one view of the door body 2 is seen. Heat transfer from the surface to the other surface is suppressed.

In the present embodiment, the third refractory core material 7 is formed of a calcium silicate plate (typically primed), but the material of the third refractory core material 7 is not limited and has heat shielding properties. Other non-combustible materials provided may be adopted. As such a nonflammable refractory material, gypsum board, fiber reinforced cement board and the like can be exemplified. The second refractory core material 7 according to the present embodiment will be described in detail below.

The third refractory core materials 7A to 7L are formed between the first surface material 20 and the second surface material 21 of the door body 2 and the found surface of each aggregate (frames 3 to 6, 5', 4'). It is provided in a position. In the present embodiment, the third refractory core material 7 is a refractory core material 7A provided between the first surface material 20 and the upper frame 3, and a refractory core provided between the second surface material 21 and the upper frame 3. Material 7B, refractory core material 7C provided between the first surface material 20 and the lower frame 4, refractory core material 7D provided between the second surface material 21 and the lower frame 4, first surface material 20 and the door. The refractory core material 7E provided between the front vertical frame 5 and the refractory core 7F provided between the second surface material 21 and the door end vertical frame 5, the first surface material 20 and the door tail side vertical frame Between the refractory core material 7G provided between the first surface material 20 and the middle vertical frame 5', the refractory core material 7H provided between the second surface material 21 and the door tail side vertical frame 6. The refractory core material 7I provided, the refractory core material 7J provided between the second surface material 21 and the middle vertical frame 5', and the refractory core material 7K provided between the first surface material 20 and the middle horizontal frame 4'. , A refractory core material 7L provided between the second surface material 21 and the middle horizontal frame 4'.

The third fireproof core materials 7A to 7L include a first finding surface and a second finding surface extending in the width direction or the height direction of the door body 2, and four peripheral end faces, that is, upper surface, lower surface, and length direction. It is a long plate body consisting of an end face at one end and an end face at one end in the length direction. In the present embodiment, the refractory core materials 7A, 7B, 7C, and 7D have the same shape and the same cross-sectional shape, and the refractory core materials 7G, 7H, 7I, and 7J have the same shape and the same cross-sectional shape. The refractory core materials 7K and 7L have the same shape and the same cross-sectional shape. The refractory core materials 7E and 7F have the same shape and dimensions, and are slightly smaller than the refractory core materials 7A, 7B, 7C, 7D, 7G, 7H, 7I, 7J, 7K, and 7L (thickness). It has become. The refractory core materials 7A to 7L sandwich each aggregate (upper frame 3, lower frame 4, door tip side vertical frame 5, door tail side vertical frame 6, middle vertical frame 5', middle horizontal frame 4'). It is provided so as to be located on both side finding surfaces, the first finding surface contacts the first finding surface 200 of the door body 2, and the second finding surface contacts the finding surface of each aggregate. Hereinafter, a more specific description will be given.

The height dimensions and found dimensions (width dimensions) of the fire-resistant core materials 7A and 7B are the same as the height dimensions and found dimensions of the upper frame 3, and the first finding surface of the fire-resistant core materials 7A is the door body 2. The first finding surface of the fireproof core material 7B is in contact with the first finding surface portion 30 of the upper frame 3, and the first finding surface of the fireproof core material 7B is the second finding surface of the door body 2. It is in contact with the surface 210, and the second finding surface is in contact with the second finding surface portion 31 of the upper frame 3.

The height dimensions and found dimensions (width dimensions) of the fire-resistant core materials 7C and 7D are the same as the height dimensions and found dimensions of the lower frame 4, and the first found surface of the fire-resistant core materials 7C is the door body 2. The first finding surface of the fireproof core material 7D is in contact with the first finding surface portion 40 of the lower frame 4, and the first finding surface of the fireproof core material 7D is the second finding surface of the door body 2. It is in contact with the surface 210, and the second finding surface is in contact with the second finding surface portion 41 of the lower frame 4.

The height dimensions of the refractory core materials 7E and 7F are the same as the height dimensions of the door end side vertical frame 5, but the found dimensions of the refractory core materials 7E and 7F are the found dimensions of the door end side vertical frame 5. Greater than. The first finding surface of the fireproof core material 7E contacts the first finding surface 200 of the door body 2, the second finding surface contacts the first finding surface portion 50 of the door end side vertical frame 5, and the fireproof core The first finding surface of the material 7F is in contact with the second finding surface 210 of the door body 2, and the second finding surface is in contact with the second finding surface portion 51 of the door end side vertical frame 5.

The found dimensions and height dimensions of the fire-resistant core materials 7G and 7H are the same as the found dimensions and height dimensions of the door tail side vertical frame 6, and the first finding surface of the fire-resistant core material 7G is the second door body 2. The first finding surface is in contact with the first finding surface 200, the second finding surface is in contact with the first finding surface portion 60 of the door tail side vertical frame 6, and the first finding surface of the fireproof core material 7H is the second sight of the door body 2. It is in contact with the attached surface 210, and the second finding surface is in contact with the second finding surface portion 61 of the door tail side vertical frame 6.

The found dimensions and height dimensions of the fire-resistant core materials 7I and 7J are the same as the found dimensions and height dimensions of the middle and vertical frame 5', and the first found surface of the fire-resistant core material 7I is the second door body 2. The first finding surface of the fireproof core material 7J is in contact with the first finding surface of the middle vertical frame 5', and the first finding surface of the fireproof core material 7J is in contact with the first finding surface of the door body 2. It is in contact with the attached surface 210, and the second finding surface is in contact with the second finding surface portion 51'of the middle vertical frame 5'.

The height dimensions and found dimensions of the fire-resistant core materials 7K and 7L are the same as the height dimensions and found dimensions of the middle and horizontal frame 4', and the first finding surface of the fire-resistant core material 7K is the second door body 2. The 1st finding surface is in contact with the 1st finding surface 200, the 2nd finding surface is in contact with the 1st finding surface portion 40'of the middle horizontal frame 4', and the 1st finding surface of the fireproof core material 7L is the 2nd sight of the door body 2. It is in contact with the attached surface 210, and the second finding surface is in contact with the second finding surface portion 41'of the middle horizontal frame 4'.

[D] Block composed of an aggregate filled with a second refractory core material and a third refractory core material In this embodiment, an upper frame 3 and a refractory core material 7A, 7B form an upper block 9A, and a lower frame 4 The lower block 9B is formed from the refractory core materials 7C and 7D, the door tail side vertical frame 6 and the refractory core material 7G, 7H form the door tail side block 9C, and the middle vertical frame 5'and the refractory core material. The middle vertical block 9D on the door end side is formed from 7I and 7J, and a plurality of middle and horizontal blocks 9E are formed from the middle horizontal frame 4'and the refractory core materials 7K and 7L. By forming such blocks 9A to 9E, the assembly efficiency of the door body 2 can be improved. As used herein, the term "block" means a mass in which a plurality of elements are integrated prior to the assembly of the door body 2. The aggregate filled with the second refractory core material and the third refractory core material are integrated by an adhesive means (for example, a double-sided adhesive tape or an adhesive) to form a block. As shown in FIG. 6, the blocks 9A to 9E are long rectangular parallelepipeds having finding surfaces 90 and 91, prospective surfaces 92 and 93, and end surfaces 94 and 95 in the longitudinal direction.

The upper surface of the refractory core material 7A, the upper surface of the refractory core material 7B, and the upper surface portion 32 of the upper frame 3 form the upper surface (expected surface 92) of the block 9A. The lower surface of the refractory core material 7A, the lower surface of the refractory core material 7B, the lower end of the first finding surface portion 30 of the upper frame 3, the lower end of the second finding surface portion 31 of the upper frame 3, and the lock filled in the upper frame 3. The lower surface (expected surface 93) of the block 9A is formed from the lower surface of the wool RW4. Door end surface of the refractory core material 7A on the door end side, door end surface of the refractory core material 7B on the door end side, and a door in the length direction of the upper frame 3 (first finding surface portion 30, second finding surface portion 31, and upper surface portion 32). The door end side prospective surface (length direction end surface 94) of the block 9A is formed from the front end surface, and the door end side end surface of the rock wool RW4 filled in the upper frame 3 is the door end side prospective surface of the block 9A. It is located in the vicinity of. Doors in the length direction of the door tail side end face of the fireproof core material 7A, the door tail side end face of the fireproof core material 7B, and the upper frame 3 (first finding surface portion 30, second finding surface portion 31, and upper surface portion 32). The door butt side prospective surface (length direction end surface 95) of the block 9A is formed from the buttock side end surface, and the door butt side end surface of the rock wool RW4 filled in the upper frame 3 is the door butt side prospective surface of the block 9A. It is located in the vicinity of. When the upper extension piece is not provided at the upper ends of the door end side vertical frame 5 and the door end side vertical frame 6, the door end side end surface and the door end side end surface of the rock wool RW4 are the door ends of the block 9A, respectively. It may coincide with the side prospective surface (length direction end surface 94) and the door tail side prospective surface (length direction end surface 95) (FIG. 6).

The upper surface of the refractory core material 7C, the upper surface of the refractory core material 7D, the upper end of the first finding surface portion 40 of the lower frame 4, the upper end of the second finding surface portion 41 of the lower frame 4, and the lock filled in the lower frame 4. The upper surface (expected surface 93) of the block 9B is formed from the upper surface of the wool RW5. The lower surface of the refractory core material 7C, the lower surface of the refractory core material 7D, and the lower surface portion 42 of the lower frame 4 form the lower surface (expected surface 92) of the block 9B. Door end surface of refractory core material 7C, door end side end surface of refractory core material 7D, door in the length direction of lower frame 4 (first finding surface portion 40, second finding surface portion 41, lower surface portion 42) The door end side prospective surface (length direction end surface 94) of the block 9B is formed from the front end surface, and the door end side end surface of the rock wool RW5 filled in the lower frame 4 is the door end side prospective surface of the block 9B. It is located in the vicinity of. Door tail side end face of fireproof core material 7C, door tail side end face of fireproof core material 7D, door in the length direction of lower frame 4 (first found surface portion 40, second found surface portion 41, lower surface portion 42) The door butt side prospective surface (length direction end surface 95) of the block 9B is formed from the buttock side end surface, and the door butt side end surface of the rock wool RW5 filled in the lower frame 4 is the door butt side prospective surface of the block 9B. It is located in the vicinity of. When the lower extension piece is not provided at the lower ends of the door end side vertical frame 5 and the door end side vertical frame 6, the door end side end face and the door end side end face of the rock wool RW5 are block 9B doors, respectively. It may coincide with the front side prospective surface (length direction end surface 94) and the door tail side prospective surface (length direction end surface 95) (FIG. 6).

The end face of the fireproof core material 7G on the door end side, the end face of the fireproof core material 7H on the door end side, the end face of the first finding surface portion 60 of the vertical frame 6 on the door tail side, and the second view of the vertical frame 6 on the door tail side. The door end side end surface (expected surface 93) of the block 9C is formed from the door end side end surface of the attached surface portion 61 and the door end side end surface of the rock wool RW7 filled in the door tail side vertical frame 6. The door butt side end surface of the refractory core material 7G, the door butt side end surface of the fire proof core material 7H, and the door butt side prospect surface (expected surface 92) of the block 9C are formed from the prospect surface portion 62 of the door butt side vertical frame 6. The upper surface of the fire-resistant core material 7G, the upper surface of the fire-resistant core material 7H, the upper end of the door tail side vertical frame 6 (first finding surface portion 60, second finding surface portion 61, and prospective surface portion 62) in the height direction, and a lock. The upper end surface (length direction end surface 94) of the block 9C is formed from the upper end surface of the wool RW7. The lower surface of the fire-resistant core material 7G, the lower surface of the fire-resistant core material 7H, the lower end of the door tail side vertical frame 6 (first finding surface portion 60, second finding surface portion 61, and prospective surface portion 62) in the height direction, and a lock. The lower end surface (length direction end surface 95) of the block 9C is formed from the lower end surface of the wool RW7.

The door butt side end face of the fireproof core material 7I, the door butt side end face of the fireproof core material 7J, the door butt side end of the first finding surface portion 50'of the middle vertical frame 5', and the second finding of the middle vertical frame 5'. The door tail side end surface (expected surface 93) of the block 9D is formed from the door tail side end surface of the surface portion 51'and the door tail side end surface of the rock wool RW12 filled in the middle vertical frame 5'. The door end side end face of the refractory core material 7I, the door end side end face of the refractory core material 7J, and the door end side prospective surface (expected surface 92) of the block 9D are formed from the prospective surface portion 52'of the middle vertical frame 5'. The upper surface of the fire-resistant core material 7I, the upper surface of the fire-resistant core material 7J, and the upper end of the middle vertical frame 5'(first finding surface portion 50', second finding surface portion 51', and prospective surface portion 52') in the height direction. , The upper end surface (length direction end surface 94) of the block 9D is formed from the upper end surface of the rock wool RW12. The lower surface of the fire-resistant core material 7I, the lower surface of the fire-resistant core material 7J, and the lower end of the middle vertical frame 5'(first finding surface portion 50', second finding surface portion 51', and prospective surface portion 52') in the height direction. , The lower end surface (length direction end surface 95) of the block 9D is formed from the lower end surface of the rock wool RW12. A heat absorbing layer a16 is formed on the door end side prospective surface of the block 9D (see FIGS. 4 and 5). The heat absorbing layer a16 is formed by applying a heat absorbing paint to the prospective surface of the block 9D on the door end side.

The upper surface of the refractory core material 7K, the upper surface of the refractory core material 7L, the upper end of the first finding surface portion 40'of the middle horizontal frame 4', the upper end of the second finding surface portion 41' of the middle horizontal frame 4', and the middle horizontal The upper surface (expected surface 93) of the block 9E is formed from the upper surface of the rock wool RW13 filled in the frame 4'. The lower surface of the refractory core material 7K, the lower surface of the refractory core material 7L, and the lower surface portion 42'of the middle and horizontal frame 4'form the lower surface of the block 9E (expected surface 92). The end face of the fireproof core material 7K on the door end side, the end face of the fireproof core material 7L on the door end side, and the middle horizontal frame 4'(the first finding surface portion 40', the second finding surface portion 41', and the lower surface portion 42'). A door end side prospective surface (length direction end surface 94) of the block 9E is formed from the door end side end surface in the length direction and the door end side end surface of the rock wool RW13. Door tail side end face of fireproof core material 7K, door tail side end face of fireproof core material 7L, middle horizontal frame 4'(first found surface portion 40', second found surface portion 41', lower surface portion 42') A door tail side prospective surface (length direction end surface 95) of the block 9E is formed from the door tail side end surface in the length direction and the door tail side end surface of the rock wool RW13.

The vertical frame 5 on the door end side and the refractory core materials 7E and 7F are not fixed in advance prior to the assembly of the door body 2. In the door end side vertical frame 5 filled with rock wool RW6, the door tail side end of the first finding surface portion 50 of the door front side vertical frame 5 and the second finding surface portion 51 of the door end side vertical frame 5 The door tail side prospective surface is formed from the door tail side end and the rock wool RW6 filled in the door end side vertical frame 5, and the first finding surface portion 50, the second finding surface portion 51, and the prospective surface portion 52 are formed. The upper end surface is formed from the upper end surface in the height direction of the rock wool RW6 and the upper end surface of the rock wool RW6, and the lower end surface of the first finding surface portion 50, the second finding surface portion 51, the lower end surface portion 52 in the height direction, and the rock wool RW6. The lower end surface is formed from the lower end surface. The vertical frame 5 on the door end side and only one of the refractory core materials 7E and 7F (for example, the refractory core material 7E) may be fixed in advance to form a block.

[E] First Refractory Core Material The first refractory core material is prepared as blocks 8A to 8D formed by assembling rock wool RW1 to RW3. In FIG. 7, blocks 8A to 8D are collectively indicated by “8”. The space surrounded by the first surface material 20, the second surface material 21, the upper frame 3, the lower frame 4, the middle vertical frame 5', and the door tail side vertical frame 6 of the door body 2 is different in the space. It is divided into four spaces by three horizontal frames 4'extending horizontally at a height, and each of the divided spaces is filled with blocks 8A, 8B, 8C, and 8D. In the present embodiment, the blocks 8A to 8C have the same shape and dimensions, and the block 8D is a low-profile block having only a height dimension different from that of the blocks 8A to 8C. In addition, blocks 8A to 8D may be formed from equal blocks.

The configuration of the first refractory core material will be described with reference to FIG. The block 8 has a multi-layered structure by superimposing the finding surfaces of three plate-shaped rock wools RW1, RW2, and RW3. That is, the block 8 according to the present embodiment has a multi-layer structure composed of a first layer made of rock wool RW1, a second layer made of rock wool RW2, and a third layer made of rock wool RW3.

As shown in FIG. 7, the blocks 8A to 8C are provided with six surfaces: a first finding surface 80, a second finding surface 81, an upper surface 82, a lower surface 83, a door end side surface 84, and a door tail side side surface 85. It is a rectangular parallelepiped, and heat-absorbing paint is applied to the outer surfaces of the six surfaces, and heat-absorbing layers a1, a2, and a7 to a10 are formed. In the present embodiment, the rock wool RW1, RW2, and RW3 are each coated with the heat absorbing paint on six surfaces, and the block 8 is formed by superimposing the rock wool RW1, RW2, and RW3 coated with the heat absorbing paint on the entire surface. The found surfaces of the rock wool RW1 and the rock wool RW2 and the found surfaces of the rock wool RW2 and the rock wool RW3 overlap each other via the heat absorbing layers a3 and a4 and the heat absorbing layers a5 and a6, respectively.

Specifically, a heat absorbing layer a1 is formed on the first finding surface 80 of the block 8, and a heat absorbing layer a2 is formed on the second finding surface 81, and the rock wool RW1 and the rock wool RW2 are formed. Heat absorbing layers a3 and a4 are formed at the boundary, heat absorbing layers a5 and a6 are formed at the boundary between the rock wool RW2 and the rock wool RW3, and the heat absorbing layers a7 are formed on the upper surface 82 and the lower surface. A heat absorbing layer a8 is formed on the 83, a heat absorbing layer a9 is formed on the door end side side surface 84, and a heat absorbing layer a10 is formed on the door end side side surface 85.

The first finding surface 80 of the block 8 is in contact with the first finding surface of the door body 2 (main surface portion 200 of the first surface material 20) via the heat absorbing layer a1, and the second finding surface of the block 8 is found. The surface 81 is in contact with the second finding surface (main surface portion 210 of the second surface material 21) of the door body 2 via the heat absorbing layer a2. Inside the block 8, heat absorbing layers a3 and a4 and heat absorbing layers a5 and a6 are formed at intervals in the expected direction (thickness direction) of the door body 2.

FIG. 9 shows a model diagram showing the heat shielding effect of the heat absorbing layer in the first refractory core material having a multi-layer structure. The figure on the left shows a model in which a heat absorbing layer is provided at the boundary of each layer, the figure on the right shows a model in which a heat absorbing layer is provided only on the surface of the first fireproof core material, and in each figure, the left side is the fire side (heat receiving side). It is a conceptual diagram of the temperature gradient with the right side as the non-fire side. In the figure on the left, heat absorbing layers a1 and a2 are formed on the outer finding surface of the multilayer structure, and further, the first layer (RW1) and the second layer (RW2), the second layer (RW2) and the third layer. (RW3) are adjacent to each other via the heat absorbing layers a3 and a4 and the heat absorbing layers a5 and a6, respectively. In the figure on the right, heat absorbing layers a1'and a2' are formed on the outer finding surface of the multilayer structure, and the first layer (RW1'), the second layer (RW2'), and the second layer (RW2') are formed. The third layer (RW3') is in direct contact with each other. The first layer (RW1), the second layer (RW2), the third layer (RW3) of the model in the left figure, the first layer (RW1'), the second layer (RW2'), and the third layer of the model in the right figure. (RW3') has the same thickness, and the temperature decrease gradient in each layer (RW1, RW2, RW3, RW1', RW2', RW3') does not depend on the layer position (fire side or non-fire side). It is virtually the same. The endothermic layers a1 to a6 have the same thickness, and a1 + a3 + a4 = a1'and a2 + a5 + a6 = a2'. Here, since the endothermic material forming the heat absorbing layer exhibits an endothermic reaction at, for example, 200 degrees or more, assuming that the temperature on the non-fire side is about 200 degrees, the temperature in the heat absorbing layer a2'of the model on the right is lowered. The gradient is relatively small. On the other hand, in the model shown on the left, the temperature decrease gradient can be increased in each layer (particularly, the heat absorbing layers a3 to a6, which are intermediate layers) due to the endothermic effect of the endothermic layer. It is believed that the rate of heat transfer can be delayed.

The block 8A constituting the first refractory core material includes the first surface material 20, the second surface material 21, the upper frame 3, the middle vertical frame 5', the door tail side vertical frame 6, and the middle and horizontal sides of the door body 2. The space surrounded by the frame 4'is filled. The first finding surface 80 of the block 8A is in contact with the first finding surface of the door body 2 (main surface portion 200 of the first surface material 20) via the heat absorbing layer a1, and the second finding surface of the block 8A is found. The surface 81 is in contact with the second finding surface (main surface portion 210 of the second surface material 21) of the door body 2 via the heat absorbing layer a2. Between the first finding surface (heat absorbing layer a1) and the second finding surface (heat absorbing layer a2) of the block 8A, rock wool RW1, heat absorbing layers a3, a4, and rock wool RW2 as fire-resistant heat insulating materials. , The heat absorbing layers a5 and a6, and the rock wool RW3 are formed in multiple layers, and exert a heat shielding effect between the first finding surface 200 and the second finding surface 210 of the door body 2.

The upper surface of the block 8A is in contact with the lower surface of the block 9A via the endothermic layer a7, the lower surface of the block 8A is in contact with the upper surface of the block 9E via the endothermic layer a8, and the end surface on the door end side of the block 8A is. The door tail side prospective surface of the block 9D is in contact with the endothermic surface of the block 9D via the endothermic layer a9, and the door tail side end surface of the block 8A is in contact with the door end side prospective surface of the block 9C via the endothermic layer a10.

The blocks 8B and 8C constituting the first refractory core material are the first surface material 20 and the second surface material 21 of the door body 2, the middle vertical frame 5', the door tail side vertical frame 6, and two middle and horizontal blocks. The space surrounded by the frame 4'is filled. The first finding surface 80 of the blocks 8B and 8C is in contact with the first finding surface of the door body 2 (main surface portion 200 of the first surface material 20) via the heat absorbing layer a1 and is in contact with the first finding surface of the blocks 8B and 8C. The second finding surface 81 is in contact with the second finding surface of the door body 2 (main surface portion 210 of the second surface material 21) via the heat absorbing layer a2. Between the first finding surface (heat absorbing layer a1) and the second finding surface (heat absorbing layer a2) of the blocks 8B and 8C, rock wool RW1, heat absorbing layers a3, a4, and lock as a fire-resistant heat insulating material. Wool RW2, heat absorbing layers a5 and a6, and rock wool RW3 are provided to provide a heat shielding effect between the first finding surface 200 and the second finding surface 210 of the door body 2.

The upper surfaces of the blocks 8B and 8C are in contact with the lower surface of the block 9E via the heat absorbing layer a7, and the lower surfaces of the blocks 8B and 8C are in contact with the upper surface of the block 9E via the heat absorbing layer a8. The door end side of the block 9D is in contact with the door end side prospective surface of the block 9D via the endothermic layer a9, and the door end side end faces of the blocks 8B and 8C are in contact with the door end side prospective surface of the block 9C via the endothermic layer a10. Are in contact.

The block 8D constituting the first refractory core material includes the first surface material 20 and the second surface material 21, the middle vertical frame 5', the door tail side vertical frame 6, the middle horizontal frame 4', and the door body 2. The space surrounded by the lower frame 4 is filled. The first finding surface 80 of the block 8D is in contact with the first finding surface of the door body 2 (main surface portion 200 of the first surface material 20) via the heat absorbing layer a1, and the second finding surface of the block 8D is found. The surface 81 is in contact with the second finding surface (main surface portion 210 of the second surface material 21) of the door body 2 via the heat absorbing layer a2. Between the first finding surface (heat absorbing layer a1) and the second finding surface (heat absorbing layer a2) of the block 8D, rock wool RW1, heat absorbing layers a3, a4, and rock wool RW2 as fire-resistant heat insulating materials. , The heat absorbing layers a5 and a6, and the rock wool RW3 are provided, and exert a heat shielding effect between the first finding surface 200 and the second finding surface 210 of the door body 2.

The upper surface of the block 8D is in contact with the lower surface of the block 9E via the endothermic layer a7, the lower surface of the block 8D is in contact with the upper surface of the block 9B via the endothermic layer a8, and the end surface of the block 8D on the door end side is The door tail side prospective surface of the block 9D is in contact with the endothermic surface of the block 9D via the endothermic layer a9, and the door tail side end surface of the block 8D is in contact with the door end side prospective surface of the block 9C via the endothermic layer a10.

[F] Fourth refractory core material The fourth refractory core material is prepared as blocks 14A to 14D assembled from RW8 to RW11, 7E'and 7F'. In FIG. 8, blocks 14A to 14D are collectively indicated by “14”. As shown in FIG. 8, the fourth refractory core material (blocks 14A to 14D) includes a first finding surface 140, a second finding surface 141, an upper surface 142, a lower surface 143, a door end side end surface 144, and a door tail side end surface. It is a plate-shaped block provided with 145. In the present embodiment, the refractory core materials 7E'and 7F' are calcium silicate plates, but the refractory core materials 7E'and 7F' may be formed from rock wool having a heat absorbing layer on the outer surface, for example.

The fourth refractory core material is composed of rock wool RW8 to RW11, which are plate-shaped bodies in the center in the thickness direction, and fire-resistant core materials 7E'and 7F' provided so as to sandwich the plate-shaped body, and has a plate shape. A heat absorbing layer a14 is formed between the first finding surface of the body and the finding surface of the refractory core material 7E', and the second finding surface of the plate-shaped body and the finding surface of the refractory core material 7F' A heat absorbing layer a15 is formed between them.

In the fourth refractory core material (blocks 14A to 14D), the first finding surface 140 is in contact with the finding surface inside the refractory core material 7E, and the second finding surface 141 is found inside the refractory core material 7F. The door end side 144 abuts on the surface, and the door end side end surface 144 abuts on the door tail side prospective surface of the door end side vertical frame 5 filled with rock wool RW6, and the door tail side end surface 145 is a door of refractory core materials 7E and 7F. It is flush with the end face on the buttock side and comes into contact with the prospective surface on the door end side of the block 9D via the heat absorbing layer a16.

The found dimensions (width dimensions) and expected dimensions (thickness) of the fourth fireproof core material (blocks 14A to 14D) are substantially the same as the found dimensions and the expected dimensions of the storage space of the lock cases 240, 250, 260. , Blocks 14A to 14D are arranged above and below the lock cases 240, 250 and 260 in the internal space of the door end side portion (the width corresponding to the lock) of the door body 2. Further, the expected dimensions of the fourth refractory core material (blocks 14A to 14D) are the expected dimensions of the door end side vertical frame 5 (in this embodiment, the expected dimensions of the other frames 3, 4, 6, 4', 5'. Slightly larger than). Hereinafter, a more specific description will be given.

In the internal space of the door end side portion (finding width corresponding to the lock) of the door body 2, the block 14A includes an upper frame 3, a door end side vertical frame 5, a middle vertical frame 5', and refractory core materials 7E and 7F. It is provided in a space surrounded by the upper surface of the second lock 25. The upper surface of the block 14A is flush with the upper surfaces of the refractory core materials 7E and 7F, and is in contact with the upper surface of the refractory core materials 7E and 7F and the lower surface of the block 9A, and the lower surface of the block 14A is the second lock. It is in contact with the upper surface of the case 250, the first finding surface 140 of the block 14A is in contact with the finding surface of the refractory core material 7E, and the second finding surface 141 of the block 14A is the refractory core material 7F. The door end side prospective surface 144 of the block 14A is in contact with the door tail side prospective surface of the door end side vertical frame 5 filled with rock wool RW6, and is in contact with the door end side prospective surface of the block 14A. The tail side prospective surface 145 comes into contact with the door end side prospective surface of the block 9D via the heat absorbing layer a16 together with the door tail side end faces of the refractory core materials 7E and 7F.

The block 14B has a door end side vertical frame 5, a middle vertical frame 5', a refractory core material 7E, 7F, and a second lock 25 in the internal space of the door end side portion (finding width corresponding to the lock) of the door body 2. It is provided in a space surrounded by the lower surface of the first lock 24 and the upper surface of the first lock 24. The upper surface of the block 14B is in contact with the lower surface of the second lock case 250, the lower surface of the block 14B is in contact with the upper surface of the first lock case 240, and the first finding surface 140 of the block 14B is a refractory core. The second finding surface 141 of the block 14B is in contact with the finding surface of the refractory core material 7F, and the door end side prospect surface 144 of the block 14B is a rock wool. The door end side vertical frame 5 filled with RW6 is in contact with the door tail side prospective surface, and the door tail side prospective surface 145 of the block 14B is a heat absorbing layer a16 together with the refractory core materials 7E and 7F. It comes into contact with the door end side prospective surface of the block 9D via.

The block 14C has a door end side vertical frame 5, a middle vertical frame 5', a fireproof core material 7E, 7F, and a first lock 24 in the internal space of the door end side portion (finding width corresponding to the lock) of the door body 2. It is provided in a space surrounded by the lower surface of the third lock 26 and the upper surface of the third lock 26. The upper surface of the block 14C is in contact with the lower surface of the first lock case 240, the lower surface of the block 14C is in contact with the upper surface of the third lock case 260, and the first finding surface 140 of the block 14C is a fireproof core. The second finding surface 141 of the block 14C is in contact with the finding surface of the fireproof core material 7F, and the door end side prospect surface 144 of the block 14C is a rock wool. The door end side vertical frame 5 filled with RW6 is in contact with the door tail side prospective surface, and the door tail side prospective surface 145 of the block 14C is a heat absorbing layer a16 together with the fireproof core materials 7E and 7F. It abuts on the door end side prospective surface of the block 9D via.

In the internal space of the door end side portion (finding width corresponding to the lock) of the door body 2, the block 14D has a lower frame 4, a door end side vertical frame 5, a middle vertical frame 5'fireproof core material 7E, 7F, and a third. It is provided in a space surrounded by the lower surface of the three tablets 26. The upper surface of the block 14D is in contact with the lower surface of the third lock case 260, and the lower surface of the block 14D is flush with the lower surfaces of the refractory core materials 7E and 7F, and blocks together with the lower surfaces of the refractory core materials 7E and 7F. It is in contact with the upper surface of 9B, the first finding surface 140 of the block 14D is in contact with the finding surface of the refractory core material 7E, and the second finding surface 141 of the block 14D is of the refractory core material 7F. The door end side prospective surface 144 of the block 14D is in contact with the door end side prospective surface of the door end side vertical frame 5 filled with rock wool RW6, and is in contact with the door end side prospective surface of the block 14D. The side prospective surface 145 abuts on the door end side prospective surface of the block 9D via the heat absorbing layer a16 together with the door tail side end faces of the refractory core materials 7E and 7F.

[G] Manufacturing Method of Door Body A manufacturing method of the door body 2 will be described. 1st surface material 20, 2nd surface material 21, blocks 8A to 8D, blocks 9A to 9E, blocks 14A to 14D, door end side vertical frame 5, fireproof core material 7E, 7F, 1st lock 24, 2nd lock 25 , A lock consisting of a third lock 26 and a rod (not shown) is prepared.

Blocks 8A to 8D are prepared by laminating plate-shaped rock wools RW1 to RW3 coated with an endothermic paint on the outer surface. In blocks 8A to 8D, heat absorbing layers a1 to a10 are formed on the outer surfaces and boundary surfaces of the plate-shaped rock wool RW1 to RW3.

Rock wool RW4 with heat absorbing paint applied to three sides in the internal space of the upper frame 3, the lower frame 4, the door end side vertical frame 5, the door tail side vertical frame 6, the middle vertical frame 5', and the middle horizontal frame 4'. By filling the internal space with RW7, RW12, and RW13, the inner space is filled with rock wool RW4 to RW7, RW12, and RW13. Upper frame 3, lower frame 4, door end side vertical frame 5, door tail side vertical frame 6, middle Prepare a vertical frame 5'and a middle and horizontal frame 4'. The heat absorbing layer a11 is between the inner surfaces of the upper frame 3, the lower frame 4, the door end side vertical frame 5, the door tail side vertical frame 6, the middle vertical frame 5', and the middle horizontal frame 4'and the RW4 to RW7, RW12, and RW13. ~ A13 is formed.

Prior to assembling the door body 2, the thermal expansion refractory member 16 is attached to the outer surface of the upper surface portion 32 of the upper frame 3, the outer surface of the lower surface portion 42 of the lower frame 4, the outer surface of the prospective surface portion 52 of the door end side vertical frame 5, and the door. It is attached to the outer surface of the prospective surface portion 62 of the buttock side vertical frame 6. The thermal expansion refractory member 16 is a long tape-shaped member having a predetermined width and provided with an adhesive layer.

Upper frame 3, lower frame 4, door tail side vertical frame 6, middle vertical frame 5', middle horizontal frame 4', and refractory core materials 7A, 7B, filled with rock wool RW4, RW5, RW7, RW12, RW13. Blocks 9A to 9E are formed by adhering the refractory core materials 7C and 7D, the refractory core materials 7G and 7H, the refractory core materials 7I and 7J, and the refractory core materials 7K and 7L.

(1) The main surface portion 200 of the first surface material 20 is placed on a flat surface such as a floor surface. At this time, the back surface of the main surface portion 200 of the first surface material 20 faces upward, and the upper side 201, the lower side 202, the first side side 203, and the second side side 204 stand up vertically.

(2) Blocks 9A, 9B, blocks 9C, and refractory core material 7E are placed around the back surface of the main surface portion 200 of the first surface material 20 in a four-circumferential manner.

(3) Blocks 9D and 9E are placed on a predetermined portion on the back surface of the main surface portion 200 of the first surface material 20.

(4) On the back surface of the main surface portion 200 of the first surface material 20, the block 8A is placed in the area surrounded by the blocks 9A, 9C, 9D, and 9E, and the upper and lower blocks 9E, 9C, and 9D are placed. Block 8B is placed in the area surrounded by, block 8C is placed in the area surrounded by upper and lower blocks 9E, block 9C, and block 9D, and is surrounded by blocks 9E, block 9C, block 9D, and block 9B. The block 8D is placed in the area.

(5) The vertical frame 5 on the door end side is placed on the refractory core material 7E. The first lock 24, the second lock 25, and the third lock 26 are provided at predetermined positions of the door end side vertical frame 5, the block 14A is provided between the block 9A and the second lock 25, and the first lock 24 and the second lock are provided. A block 14B is provided between 25, a block 14C is provided between the first lock 24 and the third lock 26, and a block 14D is provided between the third lock and the block 9B. Set the rods on the blocks 14B and 14C.

(6) The refractory core material 7F is placed on the door end side vertical frame 5 and the blocks 14A to 14D of the door end side portion of the door body.

(7) With the thermal expansion refractory member 16 sandwiched between the upper side 201 of the first surface material 20 and the upper surface 32 of the upper frame 3, the upper side 201 is fixed to the upper surface 32 using screws 17. With the thermal expansion refractory member 16 sandwiched between the lower side 202 of the first surface material 20 and the lower surface 42 of the lower frame 4, the lower side 202 is fixed to the lower surface 42 using screws 17. With the thermal expansion refractory member 16 sandwiched between the first side side 203 of the first surface material 20 and the prospective surface portion 52 of the door end side vertical frame 5, a screw 17 is used to form the first side side 203 on the prospective surface portion 52. Fix it. With the thermal expansion refractory member 16 sandwiched between the second side side 204 of the first surface material 20 and the prospective surface portion 62 of the door tail side vertical frame 6, a screw 17 is used on the prospective surface portion 62 of the second side side 204. Fix it. This screw fixing may be performed when the four circumferences of the block 9A, the block 9B, the block 9C, and the door end side vertical frame 5 are installed.

(8) Cover the second surface material 21. The back surface of the main surface portion 210 of the second surface material 21 comes into contact with the found surfaces of the blocks 9A, 9B, block 9C, block 9D, block 9E, blocks 8A to 8D, and the refractory core material 7F, and the upper side 211 and the lower side 212 , The inner surfaces of the first side side 213 and the second side side 214 come into contact with or approach the prospective surfaces of the blocks 9A, 9B, and 9C, and the end surface of the refractory core material 7F on the door end side.

(9) The upper side 211 is fixed to the upper surface 32 by using a screw 17 with the thermal expansion refractory member 16 sandwiched between the upper side 211 of the second surface material 21 and the upper surface 32 of the upper frame 3. With the thermal expansion refractory member 16 sandwiched between the lower side 212 of the second surface material 21 and the lower surface 42 of the lower frame 4, the lower side 212 is fixed to the lower surface 42 using screws 17. With the thermal expansion refractory member 16 sandwiched between the first side side 213 of the second surface material 21 and the prospective surface portion 52 of the door end side vertical frame 5, a screw 17 is used to form the first side side 213 on the prospective surface portion 52. Fix it. With the thermal expansion refractory member 16 sandwiched between the second side side 214 of the second surface material 21 and the prospective surface portion 62 of the door tail side vertical frame 6, a screw 17 is used on the prospective surface portion 62 of the second side side 214. Fix it.

As described above, the door body 2 includes the first surface material 20, the second surface material 21, blocks 8A to 8D, blocks 9A to 9E, blocks 14A to 14D, the door end side vertical frame 5, fireproof core materials 7E, 7F, and the like. It is manufactured by assembling a lock consisting of a first lock 24, a second lock 25, a third lock 26 and a rod (not shown), but the order of each step is not limited to the above order. It will be understood by those skilled in the art that the order of the steps of the parts may be changed. Further, it will be understood by those skilled in the art that in each step, the surfaces to which the elements come into contact with each other may be appropriately adhered with an adhesive or the like. In the present embodiment, the work efficiency at the time of assembly is improved by preparing blocks 8A to 8D, blocks 9A to 9E, and blocks 14A to 14D, but each element is assembled without preparing these blocks. The door body 2 may be manufactured.

[H] Fireproof structure of door device In the door body 2 assembled in this way, the fireproof core materials 7A, 7C, 7G, 7I, and 7K of blocks 9A to 9E are found on the inner surface of the first finding surface 200. The surface and the heat absorbing layers a1 of the blocks 8A to 8D are in contact with each other, and the fireproof core materials 7B, 7D, 7H, 7J, and 7L of the blocks 9A to 9E are located on the inner surface of the second finding surface 210. The endothermic layers a2 of 8A to 8D are in contact with each other. As described above, the blocks 8A to 8D have a multi-layer structure of rock wool RW1 to RW3, and endothermic layers a3 and a4 and endothermic layers a5 and a6 are formed at the boundaries of each layer. Further, as described below, by forming an endothermic layer on the contact surface of each element to reduce the heat transfer efficiency between the elements, heat is transferred from the heated surface side to the non-heated surface side through the door body. Suppress that.

The upper end surface of the door end side vertical frame 5, the upper end surfaces of the refractory core materials 7E and 7F, the upper surface of the block 14A, and the upper surface of the block 9D are in contact with the door end side portion of the lower surface of the upper block 9A. The upper surface of the block 9C is in contact with the door tail side portion of the lower surface, and the upper surface of the block 8A is in contact with the lower surface of the block 9A via the heat absorbing layer a7. The internal space of the upper frame 3 forming the block 9A is filled with rock wool RW4 via the heat absorbing layers a11 to a13.

The lower end surface of the door end side vertical frame 5, the lower end surfaces of the refractory core materials 7E and 7F, the lower surface of the block 14D, and the lower surface of the block 9D are in contact with the door end side portion of the upper surface of the lower block 9B, and the block 9B The lower surface of the block 9C is in contact with the door tail side portion of the upper surface of the block 9B, and the lower surface of the block 8D is in contact with the upper surface of the block 9B via the heat absorbing layer a8. The internal space of the lower frame 4 forming the block 9B is filled with rock wool RW5 via the heat absorbing layers a11 to a13.

The door end side prospective surfaces of blocks 8A to 8D are in contact with the door end side prospective surface of the block 9C on the door tail side via the heat absorbing layer a10, and the door tail side end faces of the block 9E are in contact with each other. There is. The internal space of the upper frame 3 forming the block 9C is filled with rock wool RW7 via the heat absorbing layers a11 to a13. The internal space of the inner horizontal frame 4'forming the block 9E is filled with rock wool RW13 via the heat absorbing layers a11 to a13.

The door end side prospective surfaces of blocks 8A to 8D are in contact with the door end side prospective surface of the block 9D via the heat absorbing layer a9, and the door end side end surface of the block 9E is in contact with the door end side prospective surface. The door end side prospective surfaces of the blocks 14A to 14D and the door tail side end surfaces of the refractory core materials 7E and 7F are in contact with the door end side prospective surface of the block 9D via the heat absorbing layer a16. The internal space of the middle vertical frame 5'forming the block 9D is filled with rock wool RW12 via the heat absorbing layers a11 to a13.

The door end side prospective surface of the door end side vertical frame 5 filled with rock wool RW6 is in contact with the door end side prospective surface of blocks 14A to 14D, and the first found surface portion 50 of the door end side vertical frame 5 The refractory core material 7E is in contact with the second finding surface portion 51, and the refractory core material 7F is in contact with the second finding surface portion 51.

In the present embodiment, the first surface material 20, the second surface material 21, blocks 8A to 8D, blocks 9A to 9E, blocks 14A to 14D, the door end side vertical frame 5, and the fireproof core material, which are the components of the door body 2, are used. In 7E and 7F, the door body 2 is formed by appropriately contacting or contacting the elements with each other, but there are cases where the door bodies 2 may be close to each other to the extent that the heat shielding performance of the door body 2 is not affected. Is understood by those skilled in the art, in which case "contact", "contact" can be replaced with "proximity".

Further, if a fire breaks out when the door body 2 is in the fully closed position, the thermal expansion fireproof member 16 provided on the prospective surface of the door body 2 in a four-circle shape foams and expands, so that the upper surface of the door body 2 The gap between the door-end side prospective surface and the door-end side prospective surface and the door frame 1 upper frame 10, the door-end side vertical frame 12, and the door-end side vertical frame 13 is closed to block the indoor and outdoor flames. It is designed to prevent the flow of doors and smoke.

1 Door frame 2 Door body 20 1st surface material 200 Main surface part, 1st found surface 21 2nd surface material 210 Main surface part, 2nd found surface 24 1st lock 25 2nd lock 26 3rd lock 3 Upper frame 4 Lower frame 5 Door-side vertical frame 6 Door-side vertical frame 4'Middle-horizontal frame 5'Middle-vertical frame 7A-7L 3rd refractory core material (outer refractory core material)
7E', 7F' refractory core material (outer refractory core material on the door end side, 4th refractory core material)
8 (8A-8D) block (1st refractory core material), main refractory core material 9A-9E block 14A-14D block (4th refractory core material)
RW1 to RW3 rock wool (first refractory core material), main refractory core material, plate-shaped refractory material RW4 to RW7, RW12, RW13 rock wool (inner refractory core material, second refractory core material)
RW8 to RW11 Rock wool (4th refractory core material)
a1 to a15 endothermic layer

Claims (7)

Aggregate including a four-circle frame and
The surface material fixed to the four-circle frame and
The refractory core material filled in the space surrounded by the surface material and
Consists of
The refractory core material includes a main refractory core material provided in a portion surrounded by the four-circumferential frame.
A heat absorbing layer is provided on the finding surface of the main refractory core material.
Fire door. The main refractory core material is formed in multiple layers from two or more plate-shaped refractory materials, and the finding surfaces of the refractory materials are in contact with each other or close to each other via a heat absorbing layer.
The fire door according to claim 1. A heat absorbing layer is provided on a part or all of the prospective surface of the main refractory core material.
The fire door according to any one of claims 1 and 2. The main refractory core material is provided in a plurality of stages in the height direction of the door body, and the aggregate includes a middle and horizontal frame provided between the plurality of main refractory core materials.
The fire door according to any one of claims 1 to 3. The aggregate includes a middle vertical frame provided on the door end side of the door body, and the main refractory core material includes an upper frame, a lower frame, a door tail side vertical frame, and the middle vertical frame of the four-circumferential frame. It is provided in the area surrounded by
The fire door according to any one of claims 1 to 4. The refractory core material includes an inner refractory core material filled inside the aggregate, a heat absorbing layer is provided between the inner refractory core material and the inner surface of the aggregate, and the inner refractory core material and the bone. The inner surface of the material is in contact with the endothermic layer,
The fire door according to any one of claims 1 to 5. The refractory core material includes an outer refractory core material located between the found surface of the aggregate and the surface material.
The fire door according to any one of claims 1 to 6.

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