JP7564751B2 - Panel structure with improved fire resistance - Google Patents

Description

The present invention relates to a panel structure with improved fire resistance, and in a typical embodiment, to a fire resistance structure and panel structure for an overhead door.

Overhead doors are known that open and close an opening with a shutter curtain made up of multiple panels connected in the height direction. With overhead doors, when the opening is fully closed, both ends of the shutter curtain in the width direction are received in side frames erected on the left and right sides of the width direction of the opening, but there is a gap between both ends of the shutter curtain in the width direction and the side frames across the entire height of the opening, and in the event of a fire, there is a risk that flames will pass through this gap and spread from the fire side (outside the room) to the non-fire side (inside the room).

Traditionally, fireproof overhead doors have been designed to provide fireproofing material (thermally expandable fire-resistant material) on the widthwise ends of the exterior facing surface of each panel and on the inner surface of the side frames to maintain fireproofing performance in the height direction at both ends of the width of the opening when the opening is fully closed, and a blocking body is provided at the lower end of the bottom section to minimize the formation of gaps (see Patent Document 1).

However, in the case of aluminum hollow panels, the visible surface of the panel may melt over time during a fire, and the high-temperature, high-pressure air from the flames may pass through the inside of the panel and flow from both widthwise ends into the side frame, creating an updraft that escapes to the top of the internal space of the side frame. The guide rollers protruding from both widthwise ends of the panel are located in the path of this updraft, and there is a risk that the hot air from the updraft may ignite the lubricant on the guide rollers, causing a fire inside the room.

Furthermore, guide rollers are protruding from the lower portions of both widthwise ends of the bottom section, but the heat of a fire may cause the lubricant in the guide rollers to flow down the roller shaft, which could become a source of fire.
JP2009-235691

The present invention aims to provide a panel structure that can solve the latter problem.

The technical means adopted in the present invention are:
The panel body,
Guide rollers protruding from both ends of the panel body in the width direction;
It consists of:
The shaft portion of the guide roller is inserted into the shaft insertion portion inside the panel body,
A space is formed around the shaft portion, and a thermally expandable fire-resistant member is provided inside the panel body facing the space.
It is a panel structure with improved fire resistance.

In one aspect, the panel body is a body of a bottom section of an overhead door;
The guide roller is provided protruding from the lower end portion of the bottom section.

In one embodiment, a bottom closing member is provided at the lower end of the panel body,
The upper end of the bottom closing member is located inside the panel main body,
The thermally expandable refractory member is disposed at an upper end of the bottom closure member.

In one embodiment, the panel body is a hollow aluminum panel body having open projections at both ends in the width direction,
Metal end covers are provided at both widthwise ends of the panel body so as to close the projection portions,
The end cover has an inner surface provided with a thermally expandable refractory member,
The end cover laterally closes the space around the shaft.
In one embodiment, the end cover is formed with an opening through which the shaft portion of the guide roller is inserted.

Typically, the panel body is the body of the bottom section of an overhead door, but may also be the body of the mid-section of an overhead door.
The panel structure according to the present invention is not limited to panels (sections) of overhead doors, but can also be adopted, for example, in the structure of panels of panel shutters.

The present invention comprises a panel body and guide rollers protruding from both widthwise ends of the panel body, the shaft of the guide roller being inserted into a shaft insertion section inside the panel body, and a space being formed around the shaft. By providing a heat-expanding fire-resistant member inside the panel body facing the space, in the event of a fire, the space is blocked by the heat-expanding fire-resistant member which foams when heated, suppressing the outflow of lubricant along the shaft of the guide roller, and preventing the outbreak of fire (to the side affected by the fire) from the panel (typically the bottom section of an overhead door). In addition, the foamed heat-expanding fire-resistant member blocks the space, blocking the air layer around the shaft of the guide roller, suppressing heat transfer to the shaft in the event of a fire.

FIG. 2 is a side view of the overhead door according to the embodiment, in which the overhead door is in a fully closed position. The upper figure is a front view of the overhead door in a fully closed position as seen from the second side (inside the garage), and the lower figure is a plan view. FIG. 2 is a cross-sectional view of FIG. 1 . 4A is a front view of the shutter curtain from the second side, and a side view of the shutter curtain. FIG. FIG. 5 is a partially enlarged view of the front view of FIG. 4 . FIG. 5 is a partial enlarged view of the side view of FIG. 4 . FIG. 2 is a partial enlarged view of the upper portion of FIG. 1 . FIG. 4 is a partial enlarged view of the right side portion of FIG. 3 . The upper figure is a front view of the intermediate panel as viewed from the second side, and the lower figure is a front view of the intermediate panel as viewed from the first side. FIG. 10 is a partially enlarged view of the upper part of FIG. FIG. FIG. 13 shows an end cover for a middle panel having a thermally expandable fire-resistant member fixed thereto. 11A and 11B are diagrams illustrating the fixing of a thermally expandable fire-resistant member to an end cover for an intermediate panel. 4A and 4B are side views of a panel body of an intermediate panel and diagrams showing a method of connecting the intermediate panel. This shows the bottom section (without the guide rollers attached), with the upper figure being a front view seen from the second side and the lower figure being a front view seen from the first side. 11 shows the bottom section (with guide rollers attached), with the upper figure being a front view seen from the second side and the lower figure being a front view seen from the first side. FIG. 13 is a side view of the bottom section (without the guide rollers attached). FIG. 13 is a side view of the bottom section (with guide rollers attached). FIG. 13 shows an end cover for the bottom section having a thermally expandable refractory member secured thereto. The left figure shows a bottom closing member and a bottom airtight material (two-dot chain line), and the right figure shows the bottom closing member. FIG. 17 is a partially enlarged view of the lower part of FIG. The left figure is a partial side view showing the lower end portion of the bottom section, and the right figure shows the state in which the thermally expandable fire-resistant member has expanded and foamed in the left figure. The top section is shown, with the upper figure being a front view seen from the second side, the lower figure being a front view seen from the first side, and the right figure being a side view. FIG. 13 shows an end cover for the top section having a thermally expandable refractory member secured thereto.

[A] Overall structure of overhead door Fig. 1 is a side view of an overhead door in a fully closed position, the upper figure of Fig. 2 is a front view of the overhead door in a fully closed position as seen from the inside of the room, and the lower figure is a plan view. The overhead door is equipped with a door body or shutter curtain 1 that opens and closes an opening, and both ends of the shutter curtain 1 in the width direction are guided by a guide rail 2 and raised and lowered to open and close the opening. The overhead door of this embodiment is a garage door installed at the opening of a garage, and the opening is formed from the left and right side walls W1 and W2 and the underside of the upper wall W3. The garage door of this embodiment is also a fireproof type.

The guide rail 2 is located on the left and right side walls W1, W2 at both ends of the width of the opening, and consists of a first section (vertical section) 20 that extends in the height direction of the opening, a curved second section 21 that extends rearward from above the first section 20 toward the inside of the room (inside the garage), and a third section 22 that is supported from the ceiling surface and extends rearward from behind the second section 21 along the ceiling surface CL.

2 and 3, the left and right side walls W1 and W2 are provided with side frames 3 extending in the height direction, and the side frames 3 have a U-shaped cross section formed by opposing first and second sides 30 and 31 and a bottom side 32. The first portion (vertical portion) 20 of the guide rail 2 is attached to the bottom side 32 of the side frame 3. That is, the first portion (vertical portion) 20 of the guide rail 2 is located within the side frame 3 and attached to the bottom side 32 of the side frame 3. The front end of the first side 30 is bent and formed as a front edge 300, and a fin 301 is attached to the front edge 300 along the height direction. The front edge 310 is bent and formed at the tip of the second side 31. As shown in the upper diagram of FIG. 2, the upper end portion of the second side 31 on the indoor side (garage interior side) of the side frame 3 according to this embodiment does not extend to the upper end of the first part 20 of the guide rail 2, and the upper end portion of the first part 20 of the guide rail 2 is exposed on the indoor side. As shown in FIG. 8, the side frame 3 in this embodiment is formed from multiple components, but how to form the side frame 3 is a matter that can be appropriately determined by a person skilled in the art.

The overhead door door body or shutter curtain 1 is composed of multiple horizontally rectangular panels or sections 4, 5, and 6 connected together so that they can rotate vertically. More specifically, as shown in FIG. 4, the shutter curtain 1 is composed of the uppermost panel or top section 6, the lowermost panel or bottom section 5, and multiple intermediate panels or intermediate sections 4 located between the top section 6 and the bottom section 5. In this embodiment, the main body of each of the sections 4, 5, and 6 is formed from an aluminum profile. Note that in this specification, the terms section and panel are used interchangeably and can be read interchangeably if necessary.

As shown in FIG. 4, guide rollers 7 are protruding from both ends of each section 4, 5, 6 in the width direction, and the shutter curtain 1 is raised and lowered along the guide rails 2 by the guide rollers 7 at both ends in the width direction being guided by the left and right guide rails 2. When the opening is fully closed, both ends of the shutter curtain 1 in the width direction are located inside the side frame 3, and the guide rollers 7 are located at the first portion (vertical portion) 20 of the guide rails 2, so that the shutter curtain 1 is in a vertical position, and the lower end of the shutter curtain 1 touches the ground GL to close the opening. From the fully closed state, the guide rollers 7 at both ends of the shutter curtain 1 in the vertical position are pulled up to a nearly horizontal position at the third portion 22, and the shutter curtain 1 is in a position extending laterally along the ceiling of the indoor space, and the opening is fully open.

As shown in the upper diagram of Figure 2, a rotating shaft 10 is provided above the opening, extending horizontally in the width direction of the opening. The rotating shaft 10 is equipped with a balance spring 10a, and one end of a winding wire (not shown) is fixed to a drum 10b journaled at both ends of the rotating shaft 10. The other end of the winding wire is connected to both left and right ends of the lower end of the shutter curtain 1, and the force of the balance spring in the winding direction urges the shutter curtain 1, which is in the fully closed position, in the opening direction (upward).

The overhead door in this embodiment is electrically operated, and the electric opening and closing mechanism comprises an opening/closing machine M, a trolley rail TR, and an arm 11 connected to the second surface 61, which is the interior side portion of the top section 6, and the upper end of the arm 11 is movable on the trolley rail TR. The opening/closing machine M moves the connecting arm 11 to start the top section 6, thereby moving the shutter curtain 1, which is in a fully closed position, along the garage ceiling.

[B] Panel Structure [B-1] Middle Section or Intermediate Panel The configuration of the middle section or intermediate panel 4 according to this embodiment will be described. In this specification, unless otherwise specified, the middle section or intermediate panel 4 will be referred to as "panel 4" for explanation.

The upper figure in Figure 9 is a front view of the panel 4 seen from the second side, and the lower figure is a front view of the panel 4 seen from the first side. Figure 11 is a side view of the panel 4. Figure 14 is a side view of the panel body 4'. The panel 4 is composed of a hollow aluminum body 4' with open end faces or projections at both widthwise ends, steel end covers 8 provided at both widthwise ends of the panel body 4' to close the projections, and a thermally expandable fire-resistant member 9 provided on the inner surface of the end covers 8.

As shown in Figure 14, the panel body 4' is a hollow aluminum profile formed to include a first surface 40, a second surface 41, an upper surface 42, a rising piece 43, an upper connecting portion 44, a lower connecting portion 45 integrally formed with the lower surface 45', and internal intermediate edges 48, 49. The panel body 4' according to this embodiment includes three hollow portions 4A, 4B, and 4C extending in the width direction, and in the projection portion of the panel body 4', both widthwise ends of the hollow portions 4A, 4B, and 4C are open. In other words, the projection portion of the panel body 4' is formed by the widthwise end faces of the first surface 40, the second surface 41, the upper surface 42, and the lower surface 45', and the openings at the widthwise ends of the hollow portions 4A, 4B, and 4C. In the illustrated embodiment, the internal space of the panel body 4' has three hollows 4A, 4B, and 4C defined by intermediate edges 48 and 49, but the number of hollows in the hollow panel body 4' is not limited, and it may have one hollow or two hollows, for example.

The first surface 40 on the first side of the panel body 4' and the second surface 41 on the second side form the facing surfaces of the panel 4, and in this embodiment, when the shutter curtain 1 is in the fully closed position, the first surface 40 is the outside facing surface facing the outside of the room, and the second surface 41 is the inside facing surface facing the inside of the room (inside the garage). As shown in the lower diagram of FIG. 9, a thin, plate-shaped thermal expansion fire-resistant member 400 is fixed to both ends of the width direction of the first surface 40 (the surface located on the outside of the room when the opening is fully closed) of the panel body 4' over the entire height. When the opening is fully closed, the thermal expansion fire-resistant member 400 provided at both ends of the width direction of the first surface 40 of the panel body 4' faces the inner surface of the first side 30 of the side frame 3 at a distance.

The upper end portion of the panel body 4' comprises an upper surface 42, a rising piece 43 rising from the upper surface 42, and an upper connecting portion 44 formed integrally with the upper end of the rising piece 43 and located above the upper surface 42. In the panel body 4' according to this embodiment, the surface of the rising piece 43 at the upper end portion is flush with the first surface 40, and the upper end portion of the first surface 40 of the panel 4 forms the surface of the rising piece 43. The upper connecting portion 44 of the panel 4 is an element that is partially circular in side or cross-sectional view, and comprises a partially circular outer peripheral surface 440 with the upper and second surface 41 side quadrant cut out.

A lower connecting portion 45 is formed at the lower end of the main body 4' of the panel 4, and in this embodiment, the lower surface 45' of the panel main body 4' is formed from the inner peripheral surface 450 of the lower connecting portion 45. The diameter of the inner peripheral surface 450 of the lower connecting portion 45 is slightly larger than the diameter of the outer peripheral surface 440 of the upper connecting portion 44, and the lower connecting portion 45 of one panel 4 and the upper connecting portion 44 of the other panel 4 are connected to each other circumferentially rotatably with the inner peripheral surface 450 and the outer peripheral surface 440 in close proximity. Two panels 4 adjacent vertically are connected to each other rotatably via the lower connecting portion 45 of the panel 4 located above and the upper connecting portion 44 of the panel 4 located below.

The upper connecting part 44 and the lower connecting part 45 can be locked by inserting the inner peripheral surface 450 of the lower connecting part 45 of the horizontally oriented upper panel 4 horizontally slightly below the outer peripheral surface 440 of the upper connecting part 44 of the vertically oriented lower panel 4, and then moving the lower connecting part 45 diagonally upward to receive the upper connecting part 44 (see the right diagram in Figure 14). An end lock 12 is attached to the widthwise end face of the shutter curtain 1 so as to cover the end face of the connecting part between the lower connecting part 45 of the upper panel 4 and the upper connecting part 44 of the lower panel 4 (see Figures 5 and 6).

The upper end portion of the panel body 4' includes an upper fitting piece 46 formed on the back surface of the rising piece 43, and a lower fitting piece 47 formed on the upper end of the second surface 41 or the second end of the upper surface 42. The upper fitting piece 46 and the lower fitting piece 47 extend across the entire width of the panel 4, and a roller holder or roller support member 13 that holds the guide roller 7 is fitted into both ends of the upper fitting piece 46 and the lower fitting piece 47 in the width direction. The shaft portion 70 of the guide roller 7 is inserted into the hollow portion of the roller holder 13 (see FIG. 5).

Steel end covers 8 are provided at both widthwise ends of the panel body 4' to close the open projections (openings at the widthwise ends of the hollows 4A, 4B, and 4C). The end covers 8 have a vertically elongated shape that corresponds to the outer shape formed by the end faces of the first surface 40, second surface 41, upper surface 42, and lower surface 45' of the panel body 4', and a thermally expandable fire-resistant member 9 is provided on the inner surface of the end covers 8.

As shown in Figures 12 and 13, the end cover 8 comprises a first part 80 having a height dimension that covers the upper hollow part 4A, the central hollow part 4B, and the upper half of the lower hollow part 4C, a second part 81 having a height dimension that covers the lower half of the lower hollow part 4C, and a third part 82 that connects the lower end of the first part 80 to the upper end of the second part 81. The first part 80 and the second part 81 extend vertically, but the second part 81 is biased inward relative to the first part 80, and as described below, when the first part 80 is positioned on the widthwise end face of the panel main body 4', the second part 81 is positioned within the hollow part 4C of the panel main body 4'.

The width dimension of the first portion 80 of the end cover 8 is approximately the same as the width dimension of the panel body 4' (the dimension between the outer surface of the first surface 40 and the outer surface of the second surface 41), and the upper edge of the first portion 80 is shaped to follow the cross-sectional shape of the upper surface 42 of the panel body 4'. The width dimension of the second portion 81 of the end cover 8 is slightly smaller than the dimension between the inner surface of the first surface 40 and the inner surface of the second surface 41 of the panel body 4'.

As shown in FIG. 13, a first thermal expansion fire-resistant member 90 is fixed to the entire inner surface of the first portion 80 of the end cover 8. The first thermal expansion fire-resistant member 90 in this embodiment is a plate-like body having substantially the same shape and area as the first portion 80. In this embodiment, the first thermal expansion fire-resistant member 90 is bonded to the inner surface of the first portion 80 and fixed to the first portion 80 with rivets 16, but the fixing means is not limited.

As shown in FIG. 13, a second thermal expansion fire-resistant member 91 is fixed to the entire inner surface of the second portion 81 of the end cover 8. The second thermal expansion fire-resistant member 91 in this embodiment is a plate-like body having substantially the same shape and area as the second portion 81. In this embodiment, the second thermal expansion fire-resistant member 91 is bonded to the inner surface of the second portion 81 and fixed to the second portion 81 with rivets 16, but the fixing means is not limited.

As shown in FIG. 13, the first part 80 of the end cover 8 has a first side edge 800 on the first side and a second side edge 801 on the second side, and the upper and lower ends of the second side edge 801 are bent to form attachment pieces 83. The end cover 8 is configured such that the first thermal expansion fire-resistant member 90 fixed to the inner surface of the first part 80 abuts against the widthwise end faces of the panel body 4' that form the upper hollow portion 4A, the central hollow portion 4B, and the upper half of the lower hollow portion 4C, and the second part 81 and the second thermal expansion fire-resistant member 91 fixed to the inner surface of the second part 81 are inserted into the lower half of the lower hollow portion 4C, and the upper and lower attachment pieces 83 abut against the second surface 41 of the panel body 4' and are fixed with rivets 17.

In this embodiment, the first thermally expandable fire-resistant member 90 is located between the inner peripheral portion of the first portion 80 of the end cover 8 and the widthwise end face of the panel body 4', and the first portion 80 of the end cover 8 is not in contact with the widthwise end face of the panel body 4'. In the end cover 8 provided at the widthwise end of the panel body 4', the second portion 81 of the end cover 8 corresponds to the portion where the end lock 12 is attached. In one embodiment, the end lock 12 is attached before attaching the end cover 8 to the widthwise end of the panel body 4', but the order of attachment of the end lock 12 and the end cover 8 may be reversed.

[B-2] Bottom section or bottom panel The bottom section 5 according to this embodiment will be described with reference to Figs. 15 to 22. The bottom section 5 is made of a hollow aluminum body 5' with open end faces or projections at both widthwise ends, a steel end cover 8' provided at both widthwise ends of the body 5' so as to close the projections, and a heat-expandable fireproof member 90' (see Fig. 19) provided on the inner surface of the end cover 8'. As shown in Figs. 16 and 18, in addition to the upper guide roller 7, a lower guide roller 7 is provided at the lower end of the widthwise end of the bottom section 5. As shown in Figs. 15 and 17, the body 5' of the bottom section 5 is a hollow aluminum shaped material formed to have a first surface 50, a second surface 51, an upper surface 52, a rising piece 53, an upper connecting portion 54, a lower end portion (a first lower end horizontal piece 501, a second lower end horizontal piece 510), and inner intermediate sides 58 and 59. The body 5' of the bottom section 5 has a configuration similar to the shape of the body 4' of the middle section 4, except for the shape of the lower end portion, and the description of the body 4' of the middle section 4 can be used as appropriate.

When the shutter curtain 1 is in the fully closed position, the first surface 50 of the bottom section 5 becomes the exterior facing surface, and the second surface 51 of the bottom section 5 becomes the interior facing surface, facing the interior side (inside the garage). As shown in the lower diagram of FIG. 15 and the lower diagram of FIG. 16, a thin, plate-shaped thermal expansion fire-resistant member 500 is fixed to both ends of the width direction of the first surface 50 (the surface located on the exterior side when the opening is fully closed) of the main body 5' of the bottom section 5 over almost the entire height (not provided at the lower end in the illustrated embodiment). When the opening is fully closed, the thermal expansion fire-resistant member 500 provided at both ends of the width direction of the first surface 50 of the main body 5' faces the inner surface of the first edge 30 of the side frame 3 at a distance.

The upper end portion of the main body 5' of the bottom section 5 has a configuration similar to that of the upper end portion of the intermediate panel 4, and the upper connecting portion 54 of the bottom section 5 is rotatably connected to the lower connecting portion 45 of the intermediate panel 4 directly above the bottom section 5. The upper end portion of the main body 5' of the bottom section 5 has an upper fitting receiving piece 56 formed on the back surface of the rising piece 53, and a lower fitting receiving piece 57 formed on the upper end of the second surface 51 or the end of the second side of the upper surface 52. The upper fitting receiving piece 56 and the lower fitting receiving piece 57 extend across the entire width of the bottom section 5, and a roller holder or roller support member 13 that holds the guide roller 7 is fitted into both ends of the upper fitting receiving piece 56 and the lower fitting receiving piece 57 in the width direction. The shaft portion 70 of the upper guide roller 7 is inserted into the hollow portion of the roller holder 13.

The lower end portion of the main body 5' of the bottom section 5 comprises a first lower end horizontal piece 501 formed at the lower end of the first surface 50 and a second lower end horizontal piece 510 formed at the lower end of the second surface 51, and the tip of the first lower end horizontal piece 501 and the tip of the second lower end horizontal piece 510 are spaced apart. The lower end portion of the main body 5' of the bottom section 5 further comprises an element 13' located above the first lower end horizontal piece 501 and the second lower end horizontal piece 510, integrally formed to bridge between the inner surfaces of the lower end portions of the first surface 50 and the second surface 51, and extending across the entire width of the main body 5', and both ends of the element 13' in the width direction (length direction) serve as insertion portions for the shaft portion 70 of the lower guide roller 7 (see FIG. 21).

The lower end portion of the bottom section 5, unlike the lower end portion of the intermediate panel 4, is provided with a bottom blocking member 55, which is further provided with a bottom airtight material 55'. As described above, in this embodiment, the element 13' extends across the entire width of the bottom section 5, and the bottom blocking member 55 is fixed to the element 13' with screws 19 at multiple locations in the longitudinal direction (see FIG. 17). Note that in this embodiment, the element 13' is a common element that forms the insertion portion of the shaft portion 70 of the guide roller 7 and the fixed portion of the bottom blocking member 55, respectively, but the insertion portion of the shaft portion 70 of the guide roller 7 and the fixed portion of the bottom blocking member 55 may be formed from separate elements.

The bottom blocking member 55 provided at the lower end of the main body 5' of the bottom section 5 is a long member extending in the width direction of the main body 5' of the bottom section 5, and as shown in FIG. 20, has an upper end 550 consisting of a horizontal piece, a first hanging piece 551 and a second hanging piece 552 hanging down in opposing directions from the underside of the upper end 550, a first horizontal piece 553 and a second horizontal piece 554 extending horizontally so as to be spaced apart from each other from the first hanging piece 551 and the second hanging piece 552, and a second horizontal piece 555 hanging down from the first horizontal piece 553. The bottom closing member 55 includes a first end piece 555, a second end piece 556 that is dangling from the second horizontal piece 554 and has an upper portion that faces the first end piece 555 and a lower portion that extends downward from the lower end of the upper portion, a first engaging piece 557 that protrudes from the lower end of the first end piece 555 toward the second end piece 556, and a second engaging piece 558 that protrudes from the middle portion of the second end piece 556 so as to face the first engaging piece 557. A thermal expansion fire-resistant member 559 is provided on the upper surface of the upper end 550 of the bottom closing member 55. In this embodiment, the thermal expansion fire-resistant member 559 is provided over the entire width (total length) of the bottom closing member 55 (upper end 550).

The bottom airtight material 55' supported by the bottom blocking member 55 is a long member extending in the length direction of the bottom blocking member 55, and is composed of a hollow main body 550' and a first locking piece 551' and a second locking piece 552' integrally formed at the upper end of the main body 550'. The first locking piece 551' is locked to the first locked piece 557, and the second locking piece 552' is locked to the second locked piece 558, and is supported by the bottom blocking member 55. When the shutter curtain 1 is in a fully closed position, the bottom airtight material 55' at the lower end of the bottom section 5 lands on the floor and elastically deforms to come into close contact with the ground. At this time, the lower end of the first attachment piece 556 of the bottom blocking member 55 abuts or comes close to the ground, improving fire prevention performance, especially when the first side is the fire side.

The lower end portion of the main body 5' of the bottom section 5 comprises a first lower end horizontal piece 501 formed at the lower end of the first surface 50 and a second lower end horizontal piece 510 formed at the lower end of the second surface 51, and the tip of the first lower end horizontal piece 501 and the tip of the second lower end horizontal piece 510 are spaced apart. When the bottom blocking member 55 is fixed to the main body 5', the upper end 550 of the bottom blocking member 55 is spaced apart above the first lower end horizontal piece 501 and the second lower end horizontal piece 510 of the main body 5', and the first hanging piece 551 and the second hanging piece 552 of the bottom blocking member 55 hang down from the opening between the tip of the first lower end horizontal piece 501 and the tip of the second lower end horizontal piece 510. The first horizontal piece 553 of the bottom blocking member 55 abuts or is close to the underside of the first lower end horizontal piece 501 of the main body 5', and the second horizontal piece 554 of the bottom blocking member 55 abuts or is close to the underside of the second lower end horizontal piece 510 of the main body 5'. The bottom blocking member 55 blocks the lower end portion of the main body 5' (the opening between the tip of the first lower end horizontal piece 501 and the tip of the second lower end horizontal piece 510).

As described above, the lower end portion of the main body 5' of the bottom section 5 is located above the first lower end horizontal piece 501 and the second lower end horizontal piece 510, and is provided with an element 13' that is integrally formed so as to bridge the inner surfaces of the lower end portions of the first surface 50 and the second surface 51. As shown in the left diagram of FIG. 22, the element 13' is generally cylindrical in cross section and has an inner diameter that is approximately the same as the outer diameter of the shaft portion 70 of the guide roller 7 (slightly larger than the outer diameter of the shaft portion 70 so that it can be inserted). The first side portion of the outer periphery of the element 13' is connected to the inner surface of the lower end portion of the first surface 50 by a connecting piece 502, and the second side portion of the outer periphery of the element 13' is integrated with the inner surface of the lower end portion of the second surface 51, and a gap is formed between the lower end portion 130' on the first side and the lower end portion 131' on the second side, and the lower portion of the peripheral surface of the shaft portion 70 of the guide roller 7 is exposed from the gap.

At the lower end of both widthwise ends of the main body 5' of the bottom section 5, a bracket 18 having a U-shape in cross section is provided, which is made up of a first attachment piece 180, a second attachment piece 181, and a bottom piece 182, and the first attachment piece 180 is provided with a wire fastening portion 183 to which the lower end of the winding wire (not shown) is fixed. The bracket 18 is fixed with a bolt 184 so that the first attachment piece 180 abuts against the first attachment surface 50 of the main body 5', the second attachment piece 181 abuts against the second attachment surface 51 of the main body 5', and the bottom piece 182 abuts against the lower surface of the main body 5' (first lower end horizontal piece 501, second lower end horizontal piece 510). In this embodiment, the first attachment piece 180 is fixed so as to cover the lower end portion of the thermal expansion fire-resistant member 500, and as shown in FIG. 21, half of the bottom piece 182 (the portions located at both ends in the width direction of the bottom blocking member 55) is cut out.

The body 5' of the bottom section 5 according to this embodiment has a hollow portion extending in the width direction, and both ends of the hollow portion in the width direction are open in the projection portion of the body 5'. Steel end covers 8' are provided at both ends of the body 5' in the width direction of the bottom section 5 to close the open projection portion. As shown in FIG. 19, the surface portion 80' of the end cover 8' has a height dimension that covers the projection portion of the body of the bottom section 5 over its entire height, and the width dimension is approximately the same as the width dimension of the body (the dimension between the outer surface of the first surface 50 and the outer surface of the second surface 51), and the upper edge is shaped along the upper surface 52 of the body 5', and the lower edge is shaped (horizontal edge) along the lower surface of the body 5' (first lower end horizontal piece 501, second lower end horizontal piece 510).

A thermal expansion fireproof member 90' is fixed over the entire inner surface of the face portion 80' of the end cover 8'. In this embodiment, the thermal expansion fireproof member 90' is bonded to the inner surface of the end cover 8' and fixed by rivets 16, but the fixing means is not limited. The face portion 80' of the end cover 8' has a first side edge 800' on the first side and a second side edge 801' on the second side, and mounting pieces 83' are bent and formed at the upper and lower ends of the second side edge 801'. The end cover 8' abuts the thermal expansion fireproof member 90' against the end surface of the main body, and the upper and lower mounting pieces 83' abut against the second surface 51 of the main body and are fixed with rivets 17. In this embodiment, the thermal expansion fireproof member 90' is located between the peripheral portion of the inner surface of the face portion 80' of the end cover 8' and the end surface in the width direction of the main body, and the end cover 8' does not contact the end surface in the width direction of the main body. A circular opening 84' is formed in the lower portion of the surface 80' of the end cover 8' to correspond to the shaft 70 of the lower guide roller 7 and the element 13'. After the end cover 8' is attached to the main body 5', the shaft 70 of the lower guide roller 7 is inserted into the element (insertion portion) 13' through the opening 84'.

As shown in the left figure of FIG. 22, a space S is formed at the lower end of the main body 5' of the bottom section 5 by the lower end of the first surface 50, the lower end of the second surface 51, the first lower end horizontal piece 501, the second lower end horizontal piece 510, the element 13', and the connecting piece 502. The lower part of the space S is blocked by the bottom blocking member 55, and the side is blocked by the surface part 80' of the end cover 8'. The peripheral part of the shaft part 70 of the lower guide roller 7 faces the space S as an exposed part, and the thermal expansion fire-resistant member 559 provided on the upper surface of the upper end part 550 of the bottom blocking member 55 is located in the space S and faces the exposed part of the shaft part 70 of the lower guide roller 7. When a fire occurs with the opening fully closed, the thermal expansion fire-resistant member 559 foams and expands due to the heat of the fire, and the foamed and expanded thermal expansion fire-resistant member 559' blocks the space S (right figure of FIG. 22).

[B-3] Top section or top panel The top section 6 is shown in FIG. 23. The main body of the top section 6 is a hollow aluminum profile formed to have a first surface 60, a second surface 61, an upper surface 62, a lower surface (hidden by the end lock 12), and an internal intermediate side (a part of the intermediate side is hidden by the end cover 8''). As shown in FIG. 2, the top section 6 according to this embodiment has a height dimension larger than that of the intermediate panel 4. The lower end portion of the top section 6 has a configuration similar to that of the lower end portion of the intermediate panel 4, and the description of the lower end portion of the intermediate panel 4 can be used. The lower end portion of the top section 6 has a lower connecting portion, and the lower connecting portion has the same shape as the lower connecting portion 45 of the intermediate panel 4, and is an element having a segmented circle shape in a side view or cross-sectional view, and has a segmented circle inner peripheral surface. The lower connecting portion of the lower end portion of the top section 6 is connected to the upper connecting portion 44 of the upper end portion of the intermediate panel 4 directly below.

The upper end of the top section 6 is different from the upper end of the intermediate panel 4. As shown in Figs. 7 and 23, a member 63 extending in the width direction is attached to the upper surface 62 of the top section 6. As shown in Fig. 7, the member 63 includes a horizontal fixing piece 630 fixed to the upper surface 62, a vertical fixing piece 631 hanging down from the horizontal fixing piece 630 along the first surface 60 and fixed to the upper end of the first surface 60, a horizontal piece 632 extending horizontally in a protruding shape away from the first surface 60 at the lower end of the vertical fixing piece 631, and a hanging piece 633 hanging down from the tip of the horizontal piece 632. A thermally expandable fire-resistant member 634 is fixed to the lower surface of the horizontal piece 632 across the width.

As shown in FIG. 23, a member 14 having an L shape in plan view or cross section is fixed to both widthwise ends of the first surface 60 of the top section 6, with a first piece 140 fixed to the first surface 60 and a second piece 141 extending vertically from the first surface 60. The member 14 extends over the entire height of the first surface 60, and a narrow thermally expandable fireproof member 600 is fixed to the first piece 140 of the member 14 over the entire height. The second piece 141 extends flush with the widthwise end faces of the main body of the top section 6.

The main body of the top section 6 in this embodiment has a hollow portion extending in the width direction, and both ends of the hollow portion in the width direction are open in the projection portion of the main body. Steel end covers 8'' are provided at both ends of the main body of the top section 6 in the width direction to close the open projection portions.

As shown in FIG. 24, the end cover 8'' comprises a first portion 80'' having a predetermined height dimension, a lower low second portion 81'', and a third portion 82'' connecting the lower end of the first portion 80'' and the upper end of the second portion 81''. The width dimension of the first portion 80'' of the end cover 8'' is approximately the same as the width dimension of the main body of the top section 6 (the dimension between the outer surface of the first surface 60 and the outer surface of the second surface 61), and the width dimension of the second portion 81'' of the end cover 8'' is slightly smaller than the dimension between the inner surface of the first surface 60 and the inner surface of the second surface 61 of the main body of the top section 6.

When the end cover 8'' is attached to the widthwise end of the main body of the top section 6, the second part 81'' of the end cover 8'' corresponds to the part where the end lock 12 is attached, and the upper end of the first part 80'' located above the second part 81'' does not reach the upper end of the main body of the top section 6. Therefore, in this embodiment, the upper part of the widthwise end face of the top section 6 is open, but when the opening is fully closed, the upper end part of the first surface part 60 of the top section 6 is located inside the upper wall W3.

A first thermal expansion fire-resistant member 90'' is fixed to the entire inner surface of the first portion 80'' of the end cover 8''. The first thermal expansion fire-resistant member 90'' in this embodiment is a plate-like body having substantially the same shape and area as the first portion 80''. In this embodiment, the first thermal expansion fire-resistant member 90'' is bonded to the inner surface of the first portion 80'' and fixed to the first portion 80'' with rivets 16, but the fixing means is not limited.

A second thermal expansion fire-resistant member 91'' is fixed to the entire inner surface of the second portion 81'' of the end cover 8''. The second thermal expansion fire-resistant member 91'' in this embodiment is a plate-like body having substantially the same shape and area as the second portion 81''. In this embodiment, the second thermal expansion fire-resistant member 91'' is bonded to the inner surface of the second portion 81'' and fixed to the first portion 80'' with rivets 16, but the fixing means is not limited.

The first part 80'' of the end cover 8'' has a first side edge 800'' on the first side and a second side edge 801'' on the second side, and the upper and lower ends of the second side edge 801'' are bent to form attachment pieces 83''. The end cover 8'' is configured such that the first thermal expansion fire-resistant member 90'' fixed to the inner surface of the first part 80'' is abutted against the end surface in the width direction of the main body of the top section 6, and the second part 81'' and the second thermal expansion fire-resistant member 91'' fixed to the inner surface of the second part 81'' are inserted into the lower half of the lower hollow part, and the upper and lower attachment pieces 83'' are abutted against the second surface 61 and fixed with rivets 17.

In this embodiment, the first thermally expandable fire-resistant member 90'' is located between the peripheral portion of the inner surface of the first portion 80'' of the end cover 8'' and the widthwise end face of the body of the top section 6, and the first portion 80'' of the end cover 8'' is not in contact with the widthwise end face of the body of the top section 6. In one aspect, the end lock 12 is attached before attaching the end cover 8'' to the widthwise end of the body of the top section 6, but the order of attachment of the end lock 12 and the end cover 8'' may be reversed.

[C] Fireproof Structure When the opening is fully closed, the guide rollers 7 at both ends of the width direction of the shutter curtain 1 (sections 4, 5, 6) are located within the first portion 20 of the guide rail 2, and are in a vertical position to block the opening. The overhead door according to this embodiment is a fireproof type, and a fireproof structure is formed when the opening is fully closed.

[C-1] Fireproof structure of the upper part of the opening when the opening is fully closed As shown in Fig. 7, in the overhead door according to this embodiment, when the opening is fully closed, a so-called hook-and-loop structure is formed in the upper part of the opening by the member 63 on the shutter curtain side and the member 15 on the frame side, and further, a fireproof structure is formed by providing thermal expansion fireproof members 634, 153. This will be explained in more detail below.

The structure located on the outside of the room above the opening is provided with a member 15 consisting of an attachment piece 150, a horizontal piece 151 that extends horizontally from the bottom end of the attachment piece 150 toward the inside of the room, and a rising piece 152 that rises vertically from the tip of the horizontal piece 151. A thermally expandable fire-resistant member 153 is provided on the outer surface of the rising piece 152 along its length.

When the opening is fully closed, the horizontal piece 632 of the member 63 provided on the top section 6 extends horizontally at a position spaced above the upper end of the rising piece 152 of the member 15 on the body side, and the lower half of the hanging piece 633 of the member 63 and the upper half of the inner surface of the rising piece 152 of the member 15 face each other at a distance. The thermally expandable fire-resistant member 153 fixed to the outer surface of the rising piece 152 of the member 15 faces the upper part of the first surface 60 of the top section 6 at a distance. In the event of a fire, the thermally expandable fire-resistant members 634, 153 foam and expand due to the heat of the fire, blocking the gap between the upper end of the shutter curtain 1 and the body, preventing flames and hot smoke from getting in through the gap between the upper end of the shutter curtain 1 and the body.

[C-2] Fireproof structure at both ends of the opening width direction when the opening is fully closed When the opening is fully closed, both ends of the shutter curtain 1 width direction are received in the side frames 3 on the left and right sides of the opening, and the first faces 40, 50, 60 of each section 4, 5, 6 face the inner surface of the first edge 30 of the side frame 3 at a distance. A thermally expandable fireproof member 400 is provided over the entire height at both ends of the width direction of the first face 40 of each intermediate section or intermediate panel 4. A thermally expandable fireproof member 500 is provided over the entire height at both ends of the width direction of the first face 50 of the bottom section 5. A narrow thermally expandable fireproof member 600 is fixed over the entire height to both ends of the width direction of the first face 60 of the top section 6 via the first piece 140 of the member 14.

That is, at both widthwise ends of the first surface of the shutter curtain 1 in the fully closed position, thermally expandable fire-resistant members are continuously provided in the height direction, and these thermally expandable fire-resistant members face the inner surface of the first edge 30 of the side frame 3 at a distance. In addition, in the internal space of the side frame 3, a member 23 is provided in the height direction, which is located on the first side of the first part 20 of the guide rail 2 and extends in the expected direction, and a thermally expandable fire-resistant member 24 is provided in the height direction on the member 23. In the event of a fire, the thermally expandable fire-resistant members 400, 500, 600, 24 foam and expand due to the heat of the fire, thereby blocking the gaps between both widthwise ends of the shutter curtain 1 and the side frame 3 in the height direction, preventing flames and high-temperature smoke from getting in through the gaps between both widthwise ends of the shutter curtain 1 and the side frame 3.

[C-3] Fireproof structure of shutter curtain surface when opening is fully closedWhen a fire breaks out when the opening is fully closed, the surface of the shutter curtain 1 is exposed to high temperatures. For example, when a fire breaks out on the outside of the room when the opening is fully closed, the first surface of the shutter curtain 1 is exposed to high temperatures. At this time, each section 4, 5, 6 has a predetermined thickness and capacity from the first surface 40, 50, 60, the second surface 41, 51, 61, and the hollow space between them, but when the visible surface of the panel melts over time during a fire, high-temperature and high-pressure air caused by the flames enters the inside of the panel.

In this embodiment, both widthwise ends of each section 4, 5, 6 are blocked by end covers 8, 8', 8'', and thermally expandable fire-resistant members 9 (90, 91, 90', 90'', 91'') are provided on the inner surfaces of the end covers 8, 8', 8'', and in the event of a fire, the thermally expandable fire-resistant members 9 expand due to the heat of the fire and block the widthwise ends of the hollow portions of each section 4, 5, 6, improving airtightness. Even if the end regions of each section 4, 5, 6 are thermally deformed, the blocked state of both widthwise ends of each section 4, 5, 6 is maintained by the thermally expanded thermally expandable fire-resistant members 9.

Even if the surface of any of sections 4, 5, and 6 melts and high-temperature, high-pressure air flows inside, it will not flow out from the widthwise ends, preventing the generation of a hot air current in which flames pass through the hollow parts of each section 4, 5, and 6 and flow from the ends into the internal space of the side frames, and preventing the guide rollers 7 from being exposed to hot air, igniting the lubricant and causing a flame inside the room. In addition, the thermally expandable fire-resistant members 9 expand at the widthwise ends of the hollow parts of each section 4, 5, and 6, and the expanded thermally expandable fire-resistant members 9 can reduce the heat transfer from the high-temperature, high-pressure air that flows into the inside of sections 4, 5, and 6 to the roller shaft.

[C-4] Fireproof structure at the lower end of both ends of the opening width direction when the opening is fully closed. A lower guide roller 7 is provided at the lower end of the main body 5' of the bottom section 5, and the shaft 70 of the guide roller 7 is inserted into an insertion part formed from both ends of the element 13' in the width direction. In this embodiment, the peripheral surface of the shaft 70 of the guide roller 7 faces the space S at the lower end of the main body 5' of the bottom section 5. A lubricant, which is a flammable element, is present in the bearing part of the guide roller 7, and if the lubricant is exposed to high temperatures during a fire, the lubricant may flow along the shaft 70 of the guide roller 7 and ignite. The space S at the lower end of the main body 5' of the bottom section 5 is a closed space, with the lower part blocked by the bottom blocking member 55 and the sides blocked by the surface part 80' of the end cover 8', but there is a risk of a fire breaking out from the gap caused by thermal deformation of the lower end of the main body 5' and/or the bottom blocking member 55. Alternatively, the lubricant on the peripheral surface of the shaft portion 70 of the guide roller 7 may flow along the bottom closing member 55 to the outside of the bottom section 5 and cause a fire.

In this embodiment, the thermally expandable fire-resistant member 559 provided on the upper surface of the upper end portion 550 of the bottom blocking member 55 is located in the space S and faces the exposed portion of the shaft portion 70 of the lower guide roller 7. When a fire occurs with the opening fully closed, the thermally expandable fire-resistant member 559 foams and expands in the space S due to the heat of the fire, blocking the space S (right diagram in Figure 22). The foamed thermally expandable fire-resistant member 559 blocks the space S, suppressing the ejection and ignition of the lubricant transferred to the shaft portion 70 of the guide roller 7, and preventing the outbreak of fire from the bottom section 5 (to the fire-affected side). In addition, the foamed thermally expandable fire-resistant member 559' blocks the space S, blocking the air layer around the shaft portion 70 of the guide roller 7, thereby suppressing heat transfer to the shaft portion 70 in the event of a fire. In this embodiment, the bottom blocking member 55 provided with the thermal expansion fire-resistant member 559 is attached to the lower end of the main body 5' of the bottom section 5 by sliding it from the length direction, so that the thermal expansion fire-resistant member 559 can be placed inside the space S, which is a closed space, and workability is good. In this embodiment, the thermal expansion fire-resistant member 559 is provided over the entire width (total length) of the bottom blocking member 55, but it is sufficient that it is provided at least in the space around the insertion part at both ends in the length direction of the element 13'.

[Note]
The technical means for solving the former problem in the background art are as follows.
In an overhead door, a shutter curtain is formed by connecting a number of panels in the height direction, and guide rollers provided at both ends of the panels in the width direction are guided by guide rails extending along the ceiling from both ends of the opening width direction, thereby opening and closing the opening.
When the opening is in a fully closed state, the widthwise ends of the panel are received in the side frames erected on both sides of the opening in the width direction, and the guide rollers are located in the vertical portions of the guide rails provided in the side frames,
A thermal expansion fireproof member is provided on the inner surface of the side frame and/or on the width direction end of the front surface of the panel, facing the internal space of the side frame;
The panel is composed of a hollow aluminum panel body with open projections at both widthwise ends, metal end covers provided at both widthwise ends of the panel body so as to close the projections, and a thermally expandable fire-resistant member provided on the inner surface of the end covers.
Fire-resistant construction of overhead doors.
By adopting the above technical means, end covers equipped with heat-expanding fire-resistant materials are provided at the widthwise ends of the panel, and in the event of a fire, both widthwise ends of the hollow portion of the panel are blocked by the heat-expanding fire-resistant material that has been foamed by heating. Therefore, even if the surface of the panel facing the fire melts and high-temperature air flows into the interior of the panel when the opening is fully closed, the high-temperature air will not flow out from the widthwise ends, preventing the generation of a hot air current in which flames pass through the hollow portion of the panel and flow from the ends into the internal space of the side frame, and preventing the guide rollers from being exposed to hot air and igniting the lubricant, causing flames on the inside of the room.
In one embodiment, a part or all of the thermal expansion fire-resistant member provided on the inner surface of the end cover is located between the end face of the panel body forming the projection and the inner surface of the end cover.
In one embodiment, a part or all of the thermal expansion fire-resistant member provided on the inner surface of the end cover is located inside the end face of the panel main body that forms the projection portion.
In one embodiment, a part or the whole of the end cover is located inside the end surface of the panel body that forms the projection portion.
In one embodiment described below, the end cover has a first part and a second part, a first thermally expandable fire-resistant member is provided on the inner surface of the first part, and a second thermally expandable fire-resistant member is provided on the inner surface of the second part, the first thermally expandable fire-resistant member is located between the end face of the panel body and the first part, the second part and the second thermally expandable fire-resistant member are located inside the end face of the panel body, and an end lock is provided on the end face of the panel body, located outside the second part.
Other technical means adopted in the present invention are:
A hollow aluminum panel body with open projections at both ends in the width direction;
a metal end cover provided at each end of the panel body in the width direction so as to close the projection portion;
A thermal expansion fireproof member provided on the inner surface of the end cover.
It has a panel structure.
In one embodiment, a part or all of the thermal expansion fire-resistant member provided on the inner surface of the end cover is located between the end face of the panel body forming the projection and the inner surface of the end cover.
In one embodiment, a part or all of the thermal expansion fire-resistant member provided on the inner surface of the end cover is located inside the end face of the panel main body that forms the projection portion.
In one embodiment, a part or the whole of the end cover is located inside the end surface of the panel body that forms the projection portion.

5 Bottom section or bottom panel 5' Body 55 Bottom closing member 550 Upper end 559 Thermal expansion refractory member 7 Guide roller 70 Shaft portion 13' Element (insertion portion of the shaft portion of the guide roller on the lower side of the bottom section)
S Space

Claims (4)

The panel body,
Guide rollers protruding from both ends of the panel body in the width direction;
It consists of:
The shaft portion of the guide roller is inserted into the shaft insertion portion inside the panel body,
A space is formed around the shaft portion, and a thermally expandable fire-resistant member is provided inside the panel body facing the space.
Panel structure with improved fire resistance. The panel body is a body of a bottom section of an overhead door;
The guide roller is provided protruding from the lower end portion of the bottom section.
The panel structure of claim 1. A bottom closing member is provided at the lower end of the panel body,
The upper end of the bottom closing member is located inside the panel main body,
The thermal expansion refractory member is provided at an upper end of the bottom closing member.
The panel structure according to claim 2. The panel body is a hollow aluminum panel body having open projections at both ends in the width direction,
Metal end covers are provided at both widthwise ends of the panel body so as to close the projection portions,
The end cover has an inner surface provided with a thermally expandable refractory member,
The end cover closes the side of the space around the shaft portion.
A panel structure according to claim 2 or 3.

Images