JP7317658B2 - Sliding fire door - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sliding door type fire door installed in an opening such as an entrance of a structure such as a building.

Sliding fire doors are generally known as fire prevention equipment for preventing the spread of fire in the event of a fire. As a sliding door type fire door, a rail is arranged inside the door, and the door body is suspended from the rail via a door hanger and slides in the facing direction to open and close the opening of the frame. things are known. In case of fire, if the temperature inside the blind is increased or if it is directly exposed to flames, the rail will be deformed and the driving part of the automatic fire door will be damaged. is often made of a metal material with a high melting point such as mild steel.

In this type of fire door, for example, the one described in Patent Document 1 is known as one with improved fire resistance. The fire door described in Patent Document 1 is provided with a heat insulating material held by a holding member on the side surface of the open case, thereby suppressing the temperature rise inside the open case.

International Publication No. 2017/014193

By the way, in order to improve the design of the fire door, it has been proposed to use a metal material such as aluminum for the non-mesh case body. However, since the aluminum material has a lower melting point than the conventional steel material, the case body is likely to melt down in the event of a fire, increasing the possibility that the inside of the case will be directly exposed to the flame. In such a case, there is a concern that the door body may move due to deformation of the rail or damage to the drive unit, and the fire prevention performance may not be exhibited. Therefore, it is desired to improve the fire resistance of the fire door using a material with a low melting point for the non-mesh case body.

The present invention has been invented in order to solve the above problems. , wherein the blind includes a case body elongated in the left-right direction and having front and rear surface portions and an upper surface portion forming an installation space therein, and the door body is suspended in the installation space. In a sliding door type fire door provided with a rail portion for lowering and sliding movement, the case body is made of a metal material having a lower melting point than steel material, and inside the case body, from the front part of the case body A first reinforcing member is arranged at a position spaced rearward, and the first reinforcing member has a facing surface portion having a left-right width to form a front surface of the installation space, and the rail portion is the first reinforcing member. It is a sliding door type fire door that is attached to a case body via a material.
The invention according to claim 2 is the sliding door type fire door according to claim 1, wherein the first reinforcing member is made of a material having a melting point higher than that of the material of the case body.
The invention of claim 3 is the sliding door type fire door according to claim 1 or 2, characterized in that a fireproof material is disposed between the case body and the facing surface of the first reinforcing member. .
In the invention of claim 4, the case body is provided with a receiving portion with a gap at the rear of the front portion of the case body, and the rail portion is laminated with the first reinforcing member sandwiched therebetween. The sliding door type fire door according to any one of claims 1 to 3, characterized in that it is attached to the receiving part.
The invention according to claim 5 is the sliding door type fire door according to claim 4, wherein the receiving part is provided over the entire lateral direction of the case body.
According to the invention of claim 6, the upper end of the door body is recessed inside the mesh, and the first reinforcing member overlaps at least a part of the upper end of the door body in the front-rear direction. The sliding door type fire door according to any one of claims 1 to 5, characterized in that the lower end is extended.
In the invention according to claim 7, a door body reinforcing member made of a material having a higher melting point than the material of the upper end portion of the door body is disposed inside the upper end portion of the door body, and the door body reinforcing member comprises: 7. The sliding door type fire door according to claim 6, wherein the reinforcing member is not arranged in a portion overlapping with the first reinforcing member in the front-rear direction.
In the eighth aspect of the invention, a door body reinforcing member made of a material having a higher melting point than the material of the upper end portion of the door body is arranged inside the upper end portion of the door body, and the door body reinforcing member comprises: 7. The sliding door type fire door according to claim 6, characterized in that the reinforcing member is arranged up to a portion overlapping with the first reinforcing member in the front-rear direction.
According to the invention of claim 9, the first reinforcing member has an upper surface part covering at least a part of the upper part of the installation space. is the door.
According to the invention of claim 10, the door body is an automatic hanging door, a drive section for sliding the door body by automatic control is arranged in the installation space, and the first reinforcement 10. The sliding door type fire door according to claim 9, wherein the upper surface portion of the material covers at least a part of the upper portion of the driving portion.
The invention of claim 11 is the sliding door type fire door according to any one of claims 1 to 10, wherein the first reinforcing member has an upper end fixed to the upper surface of the case body. .
In the invention of claim 12, the upper surface of the case body has a recess to which the transom can be attached, and the upper surface of the first reinforcing member is fixed to the case body via the bottom surface of the recess. The sliding door type fire door according to claim 11, characterized by:
In the thirteenth aspect of the invention, the blind rear surface portion is composed of a cover member that can be opened to make the inside of the installation space visible, and the first reinforcing member and the cover member are separated from each other. The sliding door type fire door according to any one of claims 1 to 12, wherein the sliding door is connected and fixed inside by a fixing member.
According to the invention of claim 14, the first reinforcing member is made of a material having a lower thermal conductivity than the material of the case body. is.
The invention of claim 15 is the sliding door type fire door according to any one of claims 1 to 14, characterized in that the case body is made of an aluminum material, and the first reinforcing member is made of a steel material.
The invention of claim 16 is characterized in that the first reinforcing member is formed of a single plate-shaped elongated member that is elongated in the left-right direction of the case body. It is a sliding door type fire door.
The invention according to claim 17 is characterized in that the first reinforcing member is formed of a plurality of plate members having a left-right width provided with a gap in the left-right direction. 1. The sliding door type fire door according to 1.
In the eighteenth aspect of the invention, the lower end of the case body is formed with a supporting portion for supporting the upper end of a plate disposed so as to overlap the opened door body in the front-rear direction, and the supporting portion is formed at the lower end of the case body. The sliding door type fire door according to any one of claims 1 to 17, characterized in that one reinforcing member is fixed to the lower end.
In the invention of claim 19, the first reinforcing member has an extension portion extending from the lower end of the front surface facing the front surface of the case toward the rear surface of the case and covering the upper surface of the case support. 19. The sliding door type fire door according to claim 18, wherein the rail portion is formed in an L shape so as to abut against the front surface portion and the extension portion of the first reinforcing member.
According to the invention of claim 20, the extension part is formed in an inverted L shape with an extension rear end part for covering the rear surface part of the case support part. It is a traditional fire door.
The invention according to claim 21 is characterized in that the gap between the lower ends of the front and rear surfaces of the case body is closed over the entire width in the left-right direction by a thermally expandable fire-resistant material that expands upon receiving heat in the event of a fire. A sliding door type fire door according to any one of claims 1 to 20.
The invention of claim 22 is characterized in that the thermal expansion refractory material is provided at the lower end portion of the second reinforcing member provided at the rear surface portion of the case body and at the extending rear end portion of the first reinforcing member. The sliding door type fire door according to claim 21 quoting claim 20 .

According to the inventions of claims 1 and 2, even if the front surface of the case body is exposed to flames and melts, the first reinforcing member can prevent the installation space from being directly exposed to flames. At the same time, the deformation and displacement of the rail portion can be suppressed, and the fireproof performance of the fire door can be maintained. Furthermore, since a gap is formed between the case body and the first reinforcing member, heat insulation is improved.
According to the invention of claim 3, even if the front surface of the case body is exposed to flames and melted, the fireproof material prevents the first reinforcing material from being immediately exposed to flames. improve sexuality.
According to the inventions of Claims 4 and 5, it is possible to easily attach the case body to the first reinforcing member and the rail portion, to improve workability, and to suppress the influence of thermal expansion of the case body.
According to the inventions of claims 6 to 8, fire resistance in the vicinity of the upper end portion of the door body can be improved.
According to the inventions of claims 9 and 10, the inside of the installation space can also be protected from above.
According to the eleventh aspect of the invention, the first reinforcing member is attached and fixed to the case body side at the upper surface of the case body, which is less likely to be damaged by the heat of a fire. It is possible to prevent the member from falling off.
By adopting the invention of claim 12, it is possible to adopt a common case body regardless of the presence or absence of the transom part, while allowing the fixing part of the upper surface part of the first reinforcing member and the fixing part of the transom to be common in the concave part. Therefore, the structure can be simplified and the versatility can be enhanced.
According to the thirteenth aspect of the invention, it is possible to stabilize the fixation of the cover member and the fixation of the first reinforcing member.
According to the fourteenth aspect of the present invention, the thermal conductivity to the installation space is lowered, and the heat resistance is improved.
According to the fifteenth aspect of the present invention, it is possible to improve the fire resistance while improving the open design.
According to the inventions of claims 16 and 17, the rail portion is attached to the case body via the first reinforcing member in a state in which the rail portion has width in the left and right directions, so that the rail portion is firmly fixed to the case body side. will be possible.
According to the eighteenth aspect of the invention, the upper end portion of the plate material functioning as the end plate of the door case can be supported by the support portion provided in the case body, thereby simplifying the structure.
According to the nineteenth aspect of the invention, the rail portion is L-shaped, and the first reinforcing member covers the main body portion of the first reinforcing member and the upper surface portion of the support portion for supporting the plate material that becomes the end plate. Since it is in a seated state in contact with the extension part extending from the material body part, even if the support part falls off due to the heat of the fire, the rail part can be held by the first reinforcing material. As a result, the door body can be prevented from coming off early, and the heat resistance can be improved.
According to the twentieth aspect of the invention, the extending portion formed on the first reinforcing member is provided with an extending rear surface portion that covers the rear surface portion of the case support portion, thereby protecting the support portion and , the rail portion can be further protected.
According to the invention of claim 21, the gap between the lower ends of the front and rear surfaces of the case body is made of a thermally expandable fireproof material that expands upon receiving heat when a fire occurs. Since substantially the entire width in the left-right direction is blocked, including the part without the body, the fire resistance and fire resistance are improved.
According to the invention of claim 22, since the thermal expansion fireproof material is provided on the first and second reinforcing members, even if the lower end of the case body falls off due to heat in the event of a fire, the blocking function is maintained. It will be possible to demonstrate it continuously, and the fire resistance and fire resistance will be further improved.

1 is a front view of a fire door according to a first embodiment; FIG. FIG. 2 is a cross-sectional view taken along the line AA of FIG. 1; It is a longitudinal section showing an internal structure of a fire door concerning a first embodiment. (A) A case body, (B) It is a right side view of a 1st reinforcing member. It is an enlarged vertical cross-sectional view of the main part showing the internal structure of the fire door according to the first embodiment. (A) A modified example of the shape of the receiving part, (B) A cross-sectional view of a main part of a modified example in which a fireproof panel is arranged. (A) and (B) are cross-sectional views of essential parts of modified examples of how the first reinforcing member, the second reinforcing member, and the stile reinforcing member are overlapped. It is a front view of the fire door which concerns on 2nd embodiment. FIG. 8 is a cross-sectional view taken along the line BB of FIG. 7; It is a longitudinal cross-sectional view showing the internal structure of the fire door which concerns on 2nd embodiment. (A) and (B) show a double-opening door body according to the first embodiment in which the first reinforcing member is provided over the entire left and right width, and a third embodiment in which a plurality of reinforcing members are provided at intervals on the left and right. (C) and (D) show a schematic front view of the one-way swing door body of the first embodiment in which the first reinforcing member is provided over the entire width of the left and right, with a gap left and right. FIG. 11 shows a schematic front view of a third embodiment in which a plurality of devices are provided; It is an enlarged vertical cross-sectional view of the main part showing the internal structure of the fire door of the fourth embodiment. (A) and (B) are cross-sectional views of main parts showing a state in which a thermal expansion refractory material listens in a part with and without a door body in the fourth embodiment. It is an enlarged vertical cross-sectional view of the main part showing the internal structure of the fire door of the fifth embodiment. FIG. 11 is an enlarged vertical cross-sectional view of the main part showing the internal structure of the fire door of the sixth embodiment; (A), (B), and (C) are cross-sectional views showing the main part of the attachment structure of the thermal expansion refractory material. (A) and (B) are a fragmentary cross-sectional view and a fragmentary front view showing another mounting structure of the thermal expansion refractory material.

BEST MODE FOR CARRYING OUT THE INVENTION A first embodiment of the present invention will be described in detail below with reference to the drawings. 1 is a sliding door type fire door, which is provided at the opening of the frame. The fire door 1 has a pair of left and right drawable door bodies 2 that can slide in the left and right direction (viewing direction) to open and close the opening, and a door pocket that overlaps each door body 2 in the front and rear (viewing direction) when the opening is opened. A pair of left and right FIX parts 3 having a function as a fire door 1, and blinds provided on the upper end of each door body 2 and the FIX part 3 over the entire area in the left-right direction (the blinds 4 themselves constitute the "upper frame" of the fire door 1. Although there may be cases, in the present embodiment, the "upper frame" of the fire door 1 is configured integrally with an upper frame member 19, which will be described later.) 4 is provided. Further, the fire door 1 is of an automatic door type, and a driving portion 5 and a rail portion 6 elongated in the left-right direction are arranged in an installation space S inside the blind 4 . The door body 2 is suspended from the rail portion 6 via the door hanger 7 attached to the upper end portion, and is controlled to open and close the opening by sliding in the left and right direction based on the drive of the driving portion 5. It is Although the exterior side of the frame is described as the front side and the interior side as the rear side, this is for the sake of convenience and is not limited to this.
In this embodiment, the side on which the FIX section 3 is formed is defined as the front side, and the side without the FIX section 3 is defined as the rear side. It is for the convenience of being on the (outdoor) side, for example, it can be implemented even if the FIX section is provided on both the front and back sides, and it is of course not limited to the one of the present embodiment. .

The door body 2 is an automatic hanging door, and is constructed by surrounding heat-resistant glass 2a, which is a panel body, with a frame 2b made of an aluminum material. The four peripheral frames 2b are composed of an upper frame 8, a front side frame 9, a door bottom side frame 10 and a lower frame 11, respectively. A door hanger 7 having a hanger roller 7a is attached to the upper end of the upper frame 8, and the hanger roller 7a is slidably supported by the rail 6b of the rail portion 6 in the left-right direction, so that the door body 2 moves left and right. It is suspended so that it can slide in any direction.

The pair of door bodies 2 closes the opening by abutting the end portions of the door tip side frame 9. - 特許庁A concave opening 9a is provided in the vertical direction at the door leading end of the door leading side frame 9 of one of the door bodies 2 (the right side in this embodiment), while the door of the other (the left side) door body 2 is provided. A door end adapter 9b is attached to the door end portion of the front side frame 9. - 特許庁The tip end portion 9c of the door tip adapter 9b has a tapered trapezoidal shape, and protrudes from the door tip tip of the door tip side frame 9 to which it is attached. When the door body 2 is closed, the tip of the door end adapter 9b enters the recessed opening 9a of the door end side frame 9 of the other door body 2, so that a gap is not generated between the butted portions of the door bodies 2. is configured to

A lower frame 11 of the door body 2 is provided with a steady rest 2d protruding downward. The steady rest 2d is slidably inserted in the left-right direction into a groove of a guide rail G provided under the door body 2 so as to be slidable in the left-right direction, and movement in the front-rear direction is restricted. As a result, when the door body 2 suspended at the upper part slides left and right based on the drive of the drive part 5, the lower part of the door body 2 is prevented from swinging in the front-rear direction.

As will be described later, the upper frame 8 is assembled such that the upper end portion 8a enters the inside of the mesh 4 from the lower opening 4a of the mesh 4. As shown in FIG. A frame reinforcing member 2c made of mild steel and having a substantially U-shaped cross section is disposed inside the upper frame 8, the front frame 9, and the rear frame 10 along each facing surface. The frame reinforcing member 2c corresponds to a door body reinforcing member and is made of mild steel, which is a material with a higher melting point and lower thermal conductivity than the frame 2b made of aluminum. The fire resistance of is improved. Note that the frame reinforcing member 2c may also be arranged on the lower frame 11 in the same manner. Here, the frame reinforcing member 2c of the upper frame 8 is provided at a portion where the extending portion 20c of the first reinforcing member 20 arranged in the mesh 4 overlaps the upper frame 8 in the front-rear direction, as will be described later. not

The FIX part 3 is made of heat-resistant glass (corresponding to the "plate material" of the present invention) 3a. , and the other end thereof are inserted into vertical frames 14 provided at the left and right ends of the opening and fixed by sealing to form a configuration in which the four circumferences are surrounded. The door body 2 and the FIX section 3 are arranged with a positional deviation in the front-rear direction, and the FIX section 3 is configured to be positioned on the front side (outside of the frame). As a result, when the door body 2 slides left and right, when the opening is opened, the door body 2 and the heat-resistant glass 3a are overlapped back and forth. serves as a door case, and the heat-resistant glass 3a serves as a panel of the door case and is accommodated in the FIX portion 3.

A pair of vertical frames 14 provided opposite to the left and right ends of the opening of the frame serve as a vertically elongated groove-shaped insertion part for inserting and attaching each member. It has an insertion portion 14a, a second insertion portion 14b and a third insertion portion 14c. In the present embodiment, the left and right outer ends of the heat-resistant glass 3a of the FIX portion 3 are inserted into the first insertion portion 14a and sealed, while the second insertion portion 14b and the third insertion portion 14c are the second cover members, respectively. 14d and covered by a third cover member 14e. The second insertion portion 14b can be used to insert and fix heat-resistant glass or the like in the transom portion employed in a second embodiment described later. Further, the third insertion portion 14c can enable insertion of the door tip portion of the door body (the door tip adapter 9b of the present embodiment) in the case of a one-sided hinged door. Since the vertical frame 14 having such a structure can be employed in various structures, it has high versatility.

The door trailing stile 10 and the intermediate mullion 13 are designed to overlap each other in the front-rear direction when the door body 2 is in the closed position. The door tail side stile 10 is provided with a hook-shaped smoke return portion 10a extending from the door tail end toward the FIX section 3 side (outside). A smoke return portion 13a extending like a hook toward the side frame 10 (inner side) is provided. When the door body 2 is in the closed position, these smoke return parts 10a and 13a have a mutual shell structure so that flame and smoke do not pass between the door body 2 and the FIX part 3 in the event of a fire. are considered.

The mesh 4 has a case body 15 made of an aluminum material as an outer peripheral portion. The case body 15 has an installation space S for arranging the drive section 5 and the rail section 6 therein. The case body 15 includes a main body member 16 that forms the front surface of the blind 4, and a pressing edge member 17 that is attached to the front upper end of the main body 16 and forms the upper surface of the blind 4 together with the main body member 16. and a cover member 18 that forms the rear surface of the mulch 4 and is configured to be openable and closable so that the inside of the installation space S can be inspected. Further, the upper end of the case body 15 is fixed to an upper frame member 19 provided at the upper end of the opening.

The upper end portion of the main body member 16 has a stepped shape that is lower in the front and higher in the rear. Then, by attaching a letter-shaped rim member 17 in front of the stepped portion 16a forming the L-shaped stepped shape, the upper surface portion of the mesh 4 is formed, and the upper end center portion of the case body 15 is formed. A concave portion 15a is formed in a state of being positioned at . The stepped portion 16a serves as a screw receiving portion for screwing the upper surface portion 20a of the first reinforcing member 20 described later with a lower piece 16g via a screw 20f . When providing a part, it can also be used as a part for inserting and fixing the lower end part of the heat-resistant glass of the transom part. The upper frame member 19 is also provided with an upwardly recessed recess 19b at the same position as the recess 15a of the case body 15 in the front-rear direction. It can be fixed. That is, by adopting such a configuration, members having the same shape can be employed regardless of the presence or absence of the transom portion, so versatility is high.

The body member 16 has a front surface portion 16b forming the front surface of the mesh 4. As shown in FIG. A receiving portion 16c is formed inside the body member 16 so as to have a gap with the front surface portion 16b by being spaced rearward from the front surface portion 16b. The receiving portion 16c is provided over the entire left-right direction of the main body member 16 from the upper surface of the main body member 16 to the upper end portion of the support portion 16e, which will be described later. It functions as a screw receiving portion when the front surface portion 6a of the rail portion 6 is integrally screwed to the receiving portion 16c via the screws 6c. Further, by configuring the receiving portion 16c as described above, the hollow portion 16d is formed between the front portion 16b and the receiving portion 16c, so that the heat insulating property inside the mesh 4 is improved by the heat insulating effect of the air. . Furthermore, when the first reinforcing member 20 is screwed to the main body member 16, the screw 6c is hidden by the front surface portion 6a and is not exposed to the outside, so that the appearance is not impaired.

Further, in the present embodiment, the receiving portion 16c is provided over the entire width of the main body member 16 in the left-right direction, so that the first reinforcing member 20 and the rail portion 6 can be screwed at any position. Excellent in nature. In addition, the first reinforcing member 20 suppresses the influence of deformation due to thermal expansion of the case body 15, resulting in excellent fire resistance. On the other hand, if the screwing positions are predetermined, it is not necessary to provide the receiving portion 16c over the entire area, and as in the modification shown in FIG. A portion 16c may be provided.

The lower end of the main body member 16 has a recessed groove with an open bottom for inserting and fixing the upper end of the heat-resistant glass 3a of the FIX section 3 to the outside. A support portion 16e is provided for supporting the upper end portion of the heat-resistant glass 3a. On the other hand, the lower end portion of the main body member 16 is interrupted near the center of the mesh 4 in the front-rear direction, and the lower opening 4a serves as a gap between the cover member 18 forming the rear surface portion of the mesh 4 facing the rear side. is formed. By inserting the upper end 8a of the upper frame 8 of the door body 2 into the lower opening 4a, the upper end of the door body 2 overlaps with the mesh 4 with a gap therebetween.

A first reinforcing member 20 made of steel is arranged over the entire width in the left-right direction on the side of the front portion 16b in the main body member 16 . The first reinforcing member 20 includes an upper surface portion 20a, a front surface portion 20b (face portion) bent downward from the outer end of the upper surface portion 20a, and an extension portion 20c extending rearward from the lower end of the front surface portion 20b. , and an extended rear end portion 20d bent downward from the rear end of the extended portion 20c. As a result, the first reinforcing member 20 has a recessed shape that is open rearward, and the opening side serves as an arrangement space S for the blinds 4 . That is, the front surface of the installation space S is formed by the front surface portion 20 b of the first reinforcing member 20 .

The first reinforcing member 20 is made of steel, which has a higher melting point and lower thermal conductivity than the case body 15 made of aluminum. If the first reinforcing material 20 has a high melting point, the front part 16b and the support part 16e of the case body 15, which are susceptible to heat during a fire, melt when the fire door 1 is exposed to fire. Even so, the first reinforcing member 20 forming the front surface of the installation space S does not immediately melt, so direct exposure of the installation space S to flames can be suppressed. Moreover, due to the low thermal conductivity, it is possible to suppress the temperature rise in the installation space S in the event of a fire.

The upper surface portion 20a of the first reinforcing member 20 is bent rearward along the mounting portion 16f extending in the lateral direction of the main body member stepped portion 16a, and the tip thereof extends in the middle of the upper end side of the mesh 4 in the front-rear direction. However, the first reinforcing member 20 is bent upward from the rear end of the upper surface portion 20a so that the first reinforcing member 20 is formed by bending the vertical piece portion 16h of the main body member stepped portion 16a. , and reaches the vicinity of the upper end of the mesh 4 in a state facing the rear side. As a result, the upper portions of the drive section 5 and the rail section 6 arranged in the arrangement space S are covered with the first reinforcing member 20, thereby improving the fire resistance. Further, since the tip of the upper surface portion 20a reaches the vicinity of the upper end of the interior of the mesh 4, the vicinity of the upper end of the mesh 4 can be protected.

The front surface portion 20b of the first reinforcing member 20 abuts on the receiving portion 16c of the main body member 16 over the entire area, and is integrally screwed together with the front surface portion 6a of the rail portion 6 via the screws 6c as described above. It has become so. By attaching the front surface portion 20b to the receiving portion 16c spaced rearward from the front surface portion 16b of the main body member 16, the first reinforcing member 20 and the rail portion 6 can be stably fixed to the case body 15 and directly The presence of the hollow portion 16 d improves the heat insulation compared to the case where it is attached to the front portion 16 b of the main body member 16 .

The extending portion 20 c and the extending rear end portion 20 d of the first reinforcing member 20 are bent so as to contact the upper and rear surfaces of the support portion 16 e of the body member 16 . The tip (lower end) of the extended rear end portion 20d is configured to reach an intermediate position in the front-rear direction inside the lower end side of the interior of the mulch 4 . As a result, the vicinity of the lower end of the muth 4 can be protected by the first reinforcing member 20 . In the present embodiment, the upper and lower ends of the first reinforcing member 20 are both provided so as to reach the vicinity of the upper and lower ends inside the mesh 4. The first reinforcing member 20 may extend to the upper and lower ends of the inside of the mulch 4, although it is not provided so as to reach the end completely, in further consideration of fire resistance. The extending portion 20c of the first reinforcing member 20 is configured to reach the vicinity of the lower end inside the mesh 4, so that the upper end of the upper frame 8 of the door body 2 entered from the lower opening 4a of the mesh 4. Since the portion 8a and the first reinforcing member 20 are overlapped in the front-rear direction, the fire resistance of the upper end portion of the door body 2 is improved. In addition, it is possible to improve the fire resistance without arranging the frame reinforcing member 2c inside the upper end portion 8a of the upper frame 8. As shown in FIG.

A second reinforcing member 21 made of the same steel material as the first reinforcing member 20 is provided integrally over the entire area of the cover member 18 on the front side (surface on the installation space S side). The upper ends of the cover member 18 and the second reinforcing member 21 are integrally screwed and fixed to a mounting portion 16f provided at the rear side end portion of the upper portion of the main body member 16 via screws 21a.
On the other hand, between the cover member 18 and the lower ends of the second reinforcing member 21 and the extended rear end portion 20d of the first reinforcing member 20, as shown in FIG. It is screwed and fixed integrally via a screw 22a. When inspecting the installation space S, these screws are released, and the hook portion 18a provided at the upper end portion of the cover member 18 is pivotally supported by the mounting portion 16f, so that the cover member 18 moves backward. It is configured to be rotatable so that the rear of the blind 4 can be opened. Inspection and the like may be performed in this state, but by rotating the cover member 18 to a substantially horizontal position, the cover member 18 can be removed from the main body member 16, and the work must be performed after the cover member 18 has been completely removed. It is also possible to It should be noted that the cover member 18 may be detachable simply by unscrewing the cover member 18 instead of being rotatable.

The fixing member 22 is a member made of a metal material having one end bent downward and the other end bent upward to form a first bent surface 22a and a second bent surface 22b. attached to the part. The first bent surface 22a of the fixing member 22 abuts on the extension 20c of the first reinforcing member 20 and is screwed integrally with the extension 20c and the rear surface of the support portion 16e of the body member 16 that abuts thereon. ing. On the other hand, the second bent surface 22b of the fixing member 22 abuts on the lower end of the second reinforcing member 21 and is integrally screwed to the lower end of the cover member 18 from the rear surface side. By fixing the cover member 18 by bridging with the fixing member 22 in this manner, the cover member 18 can be stably fixed without shaking, and the extension portion 20c of the first reinforcing member 20 can also be stably fixed. It is possible to prevent the front and rear surfaces of the mulch 4 from being deformed toward the installation space S in the event of a fire. In addition, since the fixing member 22 is disposed above the abutting portion of the door body 2 at the center position in the left-right direction, consideration is given to avoiding problems such as contact with the door hanger 7 or the like when the door body 2 slides. ing.

In the installation space S, a drive section 5 and a rail section 6 for controlling the sliding movement of the door body 2 are arranged. The drive unit 5 is controlled to move the door body 2 in the opening direction by detecting the approach of a person or the like to the fire door 1 by a detection sensor (not shown). The driving part 5 in this embodiment is a general one configured to slide the door body 2 through the door hanger 7 connected to the chain by displacing the chain to which the power of the electric motor is transmitted. However, it is not limited to this, and can be set as appropriate.

The rail portion 6 is a member that is elongated in the left-right direction and has a substantially L shape when viewed from the side, and is arranged above each door body 2 . The front surface portion 6a of the rail portion 6 extending upward contacts the front surface portion 20b of the first reinforcing member 20, and is connected to the front surface portion 20b of the first reinforcing member 20 and the receiving portion 16c of the main body member 16 via the screw 6c. are fixed together with screws. The lower surface 6d of the rail portion 6 is in contact with the extending portion 20c of the first reinforcing member 20 from above, and the hanger roller 7a of the door hanger 7 slides on the rear end of the lower surface 6d. A rail 6b is provided for this purpose. Since the rail portion 6 is fixed to the first reinforcing member 20 in this way, if the case body 15 were to melt in the event of a fire, the rail portion 6 would be immediately deformed or displaced, and the door body would be deformed or displaced. 2 can be prevented from displacing and failing to exhibit fireproof performance. Members in the installation space S, such as the drive section 5 and the rail section, are arranged so as to be within the range of the upper and lower ends of the first reinforcing member 20 .

As a second modification of the present embodiment, as shown in FIG. 6B, a fireproof panel (fireproof material) 30 is arranged as a fireproof material in the hollow portion 16d formed in the mesh 4. good too. The fireproof panel 30 is a fireproof material made of calcium silicate, and has a hollow portion 16d formed by the front face portion 16b of the main body member 16, which is the front face of the case body 15, and the front face portion 20b of the first reinforcing member 20. distributed throughout the interior.

By arranging the fireproof panel 30 in the hollow portion 16d in this way, even if the front surface of the case body 15 melts, the first reinforcing member 20 and the installation space are not directly exposed to flames. Since it is possible to prevent it from being put away, it is possible to improve fire resistance. The fireproof panel 30 may be a single panel, or a plurality of panels may be juxtaposed. Moreover, although it is preferable to arrange the fireproof panel 30 over the entire hollow portion 16d, it is not necessarily limited to this.

In the first embodiment, as described above, the lower ends of the first reinforcing member 20 and the second reinforcing member 21 are arranged so as not to overlap the frame reinforcing member 2c arranged in the upper frame 8 in the front and rear. For example, as in the modifications shown in FIGS. 7A and 7B, by stacking the frame reinforcing member 2c and the first reinforcing member 20 and/or the second reinforcing member in front and behind, the fire resistance is further improved. It can also be assumed that In the modified example of FIG. 7A, both the lower ends of the first reinforcing member 20 (specifically, the extended rear end portion 20d) and the lower ends of the second reinforcing members 21 overlap the upper ends of the frame reinforcing members 2c. there is In addition, in the modification shown in FIG. 7B, the lower end of the second reinforcing member 21 and the frame reinforcing member 2c overlap, while the first reinforcing member 20 and the frame reinforcing member 2c do not overlap. However, since the lower end of the first reinforcing member 20 and the upper end of the stile reinforcing member 2c are arranged without a gap, the fire resistance of the upper end of the door body 2 is improved as a whole.

Next, a second embodiment of the invention will be described. As shown in FIGS. 8 to 10, a fire door 51 according to the second embodiment is obtained by adding a transom part 52 to the fire door 1 according to the first embodiment. Since the structure other than that related to the transom part 52 is the same as that of the first embodiment, the description is omitted, and the same reference numerals as those of the first embodiment are used.

The transom part 52 is positioned above the mesh 4 and surrounded on all sides by the upper frame member 19 , the mesh 4 and the left and right vertical frames 14 . The transom part 52 is divided into three parts by two intermediate mullions 53 positioned between them, and heat-resistant glass (transom plate, plate material) 54 is inserted and sealed in each part. In addition, the intermediate mullion 53 may not be arranged in the transom part, and one sheet of heat-resistant glass 54 may be arranged. . Further, the material to be fitted in the transom part 52 is not limited to heat-resistant glass, and various panels or the like can be used, but it is preferable to consider the fire resistance.

The heat-resistant glass 54 is sealed by inserting its upper end into the recess 19b of the upper frame member 19 and its lower end into the recess 15a of the case body 15 . Further, the end portion on the side of the intermediate mullion 53 is inserted into a concave portion 53a of the intermediate mullion 53 provided at the same position as the second insertion portion 14b of the vertical frame 14 in the front-rear direction and sealed.

The second insertion portion 14b of the vertical frame 14 is covered by the second cover member 14d at the lower portion of the mesh 4 in the same manner as in the first embodiment. Left and right outer ends of heat-resistant glass 54 of 52 are inserted and sealed. On the other hand, the first insertion portion 14a of the vertical frame 14 is covered with a first cover member 14f at the position of the transom portion 52 on the upper portion of the blind 4. As shown in FIG.

By adopting such a configuration, when making the fire door 51 having the transom 52, the recess 15a, which is a space for screwing the first reinforcing member 20, is used as an insertion and fixing portion for the lower end of the heat-resistant glass 54 of the transom 52. Therefore, the member of the mesh 4 can be used in common depending on whether the transom 52 is provided or not, so that versatility is high.

According to the embodiments of the present invention constructed as described above, the case body 15 is made of aluminum, which is a metal material having a lower melting point than steel, and the front surface portion 16b of the main body member 16 constituting the front surface of the mesh 4. A first reinforcing member 20 is arranged at a position spaced rearwardly from the first reinforcing member 20. The first reinforcing member 20 has a front surface portion 20b, which is a facing surface portion elongated in the left-right direction, so that the rail portion 6 is arranged. The rail portion 6 is attached to the receiving portion 16 c of the case body 15 via the first reinforcing member 20 . As a result, when a metal material having a melting point lower than that of steel is used as the material for the case body 15, even if the front surface of the case body 15 melts due to a fire, the inside of the installation space can be immediately restored. Since exposure to flame can be prevented and deformation and displacement of the rail portion 6 can be suppressed, the fireproof performance of the fire door 1 can be maintained.

Further, since the first reinforcing member 20 is made of a steel material that has a higher melting point than the aluminum material that is the material of the case body 15, the fire resistance of the mesh 4 can be further improved. In addition, since the steel material that is the material of the first reinforcing member 20 has a lower thermal conductivity than the aluminum material that is the material of the case body 15, it is possible to suppress the temperature rise in the installation space.

In addition, since the first reinforcing member 20 is spaced from the front surface portion 16b of the main body member 16, a hollow portion 16d can be formed between the front surface of the case body 15 and the first reinforcing member 20, resulting in an air insulation effect. improves fire resistance. Fire resistance can also be improved by disposing a fire-resistant panel 30 as a fire-resistant material in the hollow portion 16d.

Since the first reinforcing member 20 is attached to the case body 15 via a receiving portion 16c extending rearward from the front surface portion 16b of the main body member 16, which is the front surface of the case body 15, a hollow portion 16d is formed. When doing so, it can be made to be excellent in assembling property. Moreover, since the receiving portion 16c is provided over the entire front surface of the case body 15, the first reinforcing member 20 can be fixed at an arbitrary position, and the assembling property is excellent. can be suppressed and has excellent fire resistance.

The upper frame 8 of the door body 2 has its upper end 8a inserted inside the mesh 4, and part of it overlaps the extension 20c of the first reinforcing member 20 in the front and rear direction, so that the first reinforcing member 20 can protect the upper end of the door body 2 . In addition, the frame reinforcing member 2c corresponding to the door body reinforcing member is arranged inside the upper frame 8, but is arranged so as not to overlap with the first reinforcing member 20 in the front and rear. The fire resistance of the mesh 4 and the door body 2 can be improved without overlapping.

Since the first reinforcing member 20 has the upper surface portion 20a that partially covers the upper portion of the installation space S, fire resistance in the installation space S is improved. In addition, the driving part 5 is arranged in the installation space, and a part of the upper part of the driving part 5 is also covered with the upper surface part 20a of the first reinforcing member 20, so that the driving part 5 is protected in case of fire. be able to.

The case body 15 has a recess 15a at its upper end to which the transom part 52 can be attached. While the receiving portion of the reinforcing member 20 and the mounting portion of the transom portion 52 are shared, a common case body can be adopted regardless of the presence or absence of the transom portion, so the structure is simple and the versatility is high. can be

The rear surface of the mesh 4 is composed of a cover member 18 that can be opened so that the inside of the installation space can be visually recognized. Therefore, the fixation of the cover member 18 and the fixation of the first reinforcing member 20 can be stabilized.

Further, in this case, the upper end portion 20a of the first reinforcing member 20 is fixed to the upper surface portion of the case body 15. In order to form 15a, it is screwed to the mounting portion 16g of the stepped portion 16a formed in the main body member 16, but the upper end portion of the mesh 4 is close to the frame side (ceiling side), so the lower end side portion It is known that even if it is made of aluminum, it is less likely to melt and fall off even if it is made of aluminum. become. Since the upper surface portion 20a of the first reinforcing member 20 is screwed to the mounting portion 16g of the body member stepped portion 16a, the first reinforcing member 20 is prevented from falling off in the event of a fire. As a result, the door body 2 can be hung more reliably.

Moreover, in this case, since the first reinforcing member 20 is a single plate-shaped elongated member provided over almost the entire area of the mesh 4 in the vertical and horizontal directions, the fire resistance at the 4 parts of the mesh is improved. , the fire resistance can be improved, and in particular, the rail portion 6 can be protected in the installation space S formed in the blind 4, so that in the event of a fire, the rail portion 6 may fall off or otherwise be damaged. It is possible to prevent the door body 2 from falling off in an early stage.

Moreover, in this case, the rail portion 6 is in a seated state in which the front surface portion 6a contacts the front surface portion 20b of the first reinforcing member 20 and the lower surface portion 6d contacts the extending portion 20c of the first reinforcing member 20. In this state, even if the lower half of the body member 16 falls off due to the heat of a fire, the rail portion 6 can be supported by the first reinforcing member 20. As a result, fire resistance and fire resistance can be further improved.

In addition, a support portion 16e for supporting the upper end portion of the heat-resistant glass 3a provided in the FIX portion 3 is formed at the lower end portion of the main body member 16. The upper and rear surfaces of the support portion 16e are Since the extending portion 20c of the first reinforcing member 20 and the extending rear end portion 20d are in contact with each other, and the extending rear end portion 20d and the rear surface of the support portion 16e are fixed by screws 22a, the support portion 16e is The support provided by the first reinforcing member 20 is strengthened, and in the event of a fire, the support portion 16e can be prevented from falling off. As a result, early falling off of the heat-resistant glass 3e can be prevented, which contributes to the improvement of heat resistance and fire resistance. It will be possible.

In each of the above-described embodiments, the door body is a pair of right and left drawable doors. The present invention can also be applied to a manually opened/closed fire door that does not have a drive unit.

The present invention is of course not limited to the above-described embodiment. For example, the first reinforcing member 20 according to the above-described embodiment has In the double-opening type and the single-opening type, a wide one provided over substantially the entire area (left and right width) of the mesh 4 is adopted, but the third embodiment shown in FIGS. 11(B) and 11(D) As in the form of (1), the first reinforcing member 20 can be implemented by disposing a plurality of plate-shaped ones having a width in the left-right direction with a gap in the left-right direction.
Further, as in the fourth embodiment shown in FIGS. 12 and 13, the gap between the lower ends of the front and rear surfaces of the case body 15 is made of a thermally expandable refractory material (for example, Sekisui Chemical Co., Ltd.) that expands upon receiving heat during a fire. The thermal expansion fireproof material “Fi-Block (registered trademark)” 60 manufactured by the company covers the entire width in the left and right direction. The lower end portion of the second reinforcing member 21 and the extended rear end portion 20d of the first reinforcing member 20 are provided over the entire width in the left-right direction, and the door body 2 is closed by receiving heat at the time of fire occurrence. As for the parts, the space between the door body 2 and the lower ends of the second reinforcing members 21 and the extending rear end part 20d of the first reinforcing member 20 are closed, and in the FIX3 region where there is no door body 2, the second The space between the lower end portion of the second reinforcing member 21 and the extended rear end portion 20d of the first reinforcing member 20 may be closed, thereby further improving fire resistance and fire resistance. can.

As the main body member 16 for constituting the case body 15, there is no receiving portion 16c as in the fifth embodiment shown in FIG. As in the sixth embodiment, cooling fins 16i may be provided on the rear surface of the front surface portion 16b.

Furthermore, in the fourth embodiment, the thermal expansion refractory material 60 is attached to the door body 2 using chemical (physical) attachment means such as double-sided adhesive tape or adhesive. When a fire occurs and the mounting force is lost due to burning of such mounting means, the thermal expansion fireproof material 60 thermally expands and contacts the mating member. Consideration is made so that the thermal expansion refractory material 60 expanded by force) does not fall off, but the contact force can be reduced by mechanically attaching the thermal expansion refractory material 60 as shown in FIG. Even if it is weak, it is possible to prevent the thermal expansion refractory material 60 from coming off. Specifically, the thermal expansion refractory material 60 is fixed to the second reinforcing member 21 side through screws 61a together with a contact member 61 that is wide in the left-right direction (see FIG. 16A). The thermal expansion fireproof material 60 is sandwiched between the contact members 16 fixed to the second reinforcing member 21 through 31a (see FIG. 16(B)). Incidentally, the first reinforcing member 20 side can also be configured in the same manner.
In the fourth embodiment, as in the first embodiment, the lower end of the second reinforcing member 21 is fitted into and locked to the locking portion 18b formed on the lower end of the cover member 18. 16(A) and 16(B), the thermal expansion fireproof material 60 is attached to the second reinforcing member 21 locked to the locking portion 18b. 1, the locking portion 18b is configured to fit and lock even the lower end of the thermal expansion fireproof material 60, whereby the locking of the lower end of the thermal expansion fireproof material 60 becomes more reliable. 16(C) is configured such that the lower end of the second reinforcing member 21 is locked by the locking portion 18b as in the fourth embodiment. The thermal expansion refractory material 60 is sandwiched by a contact member 61 fixed via a screw 61b in a state of protruding from the engaging portion 18b. In this case, the contact member 61 normally covers most of the thermal expansion refractory material 60, and is constructed such that the contact member 61 is deformed by receiving the expansion force of the thermal expansion refractory material 60. In order to protect the thermal expansion refractory material 60 under normal conditions, the contact member 61 may be made of a material that deforms under expansion force, such as a foil material. preferable.
Further, in these devices, the thermal expansion refractory material 60 is supported by the laterally wide contact member 61, but the present invention is not limited to this. A thermal expansion refractory material 60 is provided with a plurality of contact members 61 each having a narrow triangular plate shape (thin plate-like, bar-like, and needle-like shapes are further set as such a shape) at intervals. Therefore, it is possible to implement a configuration in which the support is provided in a comb shape.
Further, when the thermal expansion refractory material 60 is provided, in the above-described embodiment, it is provided on the side of the blind 4, but it may be provided on the door body 2 side. The portion where the door body 2 is located does not have the thermal expansion fire-resistant material 60, and the other portions are configured to have the thermal expansion fire-resistant material 60 provided on the side of the blind 4 as in the above-described embodiment. can be done.
Also, regarding the first reinforcing member 20, when attaching the thermal expansion refractory member 60 to a plurality of the first reinforcing members 20 that are provided at intervals as shown in FIGS. In this case, the fireproof function of the thermal expansion refractory material 60 is exhibited except for the part where the case body 15 fell off due to fire and the sealing collapsed. It will be.

INDUSTRIAL APPLICABILITY The present invention can be used in the field of sliding door type fire doors provided as fire prevention equipment.

1 fire door 2 door body 2c frame reinforcement (door body reinforcement)
3 FIX part 4 No mesh 5 Driving part 6 Rail part 7 Door hanger 8 Upper frame 8a Upper end part 15 Case body 15a Recessed part 16 Main body member 16b Front part 16c Receiving part 16d Hollow part 18 Cover member 20 First reinforcing member 20a Upper surface part 20b Front part (face part)
20c extension
21 second reinforcing member 22 fixing member 30 fireproof panel (fireproof material)
S Installation space

Claims (22)

a door body that can be slid in the left-right direction;
and a mesh provided on the upper part of the door body,
The mesh has a case body elongated in the left-right direction and having front and rear surface portions and an upper surface portion forming an arrangement space inside,
A sliding door type fire door in which a rail portion for suspending and sliding the door body is arranged in the installation space,
The case body is made of a metal material having a melting point lower than that of steel,
A first reinforcing member is arranged inside the case body at a position spaced rearward from the front surface of the case body,
The first reinforcing member forms a front surface of the installation space by having a side surface portion with a left-right width,
A sliding door type fire door, wherein the rail portion is attached to the case body via the first reinforcing member. 2. The sliding door type fire door according to claim 1, wherein said first reinforcing member is made of a material having a higher melting point than the material of said case body. 3. The sliding door type fire door according to claim 1, wherein a fireproof material is arranged between the case body and the facing surface portion of the first reinforcing member. The case body is provided with a receiving portion with a gap at the rear of the front portion of the case body, and the rail portion is attached to the receiving portion in a laminated state with the first reinforcing member sandwiched therebetween. The sliding door type fire door according to any one of claims 1 to 3, characterized in that: 5. The sliding door type fire door according to claim 4, wherein the receiving portion is provided over the entire lateral direction of the case body. The upper end of the door body is inserted into the mesh, and the first reinforcing member has a lower end extending forward and backward so as to overlap at least a part of the upper end of the door body. The sliding door type fire door according to any one of claims 1 to 5, characterized in that: A door body reinforcing member made of a material having a higher melting point than the material of the upper end of the door body is disposed inside the upper end portion of the door body, and the door body reinforcing member is disposed in front of and behind the first reinforcing member. 7. The sliding door type fire door according to claim 6, wherein the sliding door type fire door is not disposed in a portion overlapping with the . A door body reinforcing member made of a material having a higher melting point than the material of the upper end of the door body is disposed inside the upper end portion of the door body, and the door body reinforcing member is disposed in front of and behind the first reinforcing member. 7. The sliding door type fire door according to claim 6, characterized in that the sliding door type fire door is arranged to a portion overlapping with the . The sliding door type fire door according to any one of claims 1 to 8, wherein the first reinforcing member has an upper surface portion covering at least a portion of the upper portion of the installation space. The door body is an automatic hanging door, a drive unit for sliding the door body by automatic control is arranged in the installation space, and the upper surface part of the first reinforcing member is the above-mentioned 10. The sliding door type fire door according to claim 9, wherein at least a part of the upper part of the driving part is covered. 11. The sliding door type fire door according to any one of claims 1 to 10, wherein the upper end of the first reinforcing member is fixed to the upper surface of the case body. 4. The upper surface of the case body has a recess to which the transom can be attached, and the upper surface of the first reinforcing member is fixed to the case body via the bottom surface of the recess. 12. The sliding door type fire door according to 11. The rear face portion of the mesh is configured by an openable cover member so as to make the inside of the installation space visible, and the first reinforcing member and the cover member are connected and fixed inside the mesh by a fixing member. The sliding door type fire door according to any one of claims 1 to 12, characterized in that The sliding door type fire door according to any one of claims 1 to 13, wherein the first reinforcing member is made of a material having a lower thermal conductivity than the material of the case body. The sliding door type fire door according to any one of claims 1 to 14, wherein the case body is made of aluminum, and the first reinforcing member is made of steel. The sliding door type fire door according to any one of claims 1 to 15, wherein the first reinforcing member is formed of a single plate-shaped elongated member that is elongated in the lateral direction of the case body. The sliding door type fire protection according to any one of claims 1 to 15, wherein the first reinforcing member is formed of a plurality of plate members having a left-right width provided with a gap in the left-right direction. door. A support portion is formed at the lower end of the case body for supporting the upper end of the plate material arranged to overlap the opened door body, and the support portion is provided at the lower end of the first reinforcing member. The sliding door type fire door according to any one of claims 1 to 17, characterized in that it is fixed. The first reinforcing member is formed with an extending portion extending from the lower end of the front surface facing the front surface of the case toward the rear surface of the case and covering the upper surface of the case support. 19. The sliding door type fire door according to claim 18, wherein the first reinforcing member is L-shaped to abut against the front face and the extension of the first reinforcing member. 20. The sliding door type fire door according to claim 19, wherein the extending portion is formed in an inverted L shape with a rear end portion of the extending portion for covering the rear surface portion of the case support portion. 21. The gap between the lower ends of the front and rear surfaces of the case body is closed over the entire width in the left-right direction by a thermally expandable fire-resistant material that expands upon receiving heat in the event of a fire. 1. The sliding door type fire door according to 1. Cite claim 20, wherein the thermal expansion refractory material is provided at the lower end portion of the second reinforcing member provided at the rear surface portion of the case body and at the extending rear end portion of the first reinforcing member. The sliding door type fire door according to claim 21 .

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