JP6981826B2 - Airflow structure - Google Patents

Description

The present invention relates to an airflow structure.

Glass curtain walls may be used for the purpose of reducing the weight of high-rise buildings, improving the exterior design, and ensuring the view from the indoor side. On the other hand, the glass curtain wall is inferior in heat insulating property to the concrete wall, so that the heating and cooling efficiency of the building is lowered. Therefore, the air conditioning load may be reduced by adopting a double-skin structure or an airflow structure in which the inner glass surface is provided on the indoor side of the outer glass surface facing the outer surface of the building (for example, Patent Documents 1 to 1 to Patent). See Document 3). The double-skin structure and the airflow structure are intended to improve the heat shielding performance by the cavity space (air layer) formed between the outer glass surface body and the inner glass surface body. Further, in the double skin structure, the outside air taken in from the lower part of the cavity space is exhausted from the upper part to suppress the temperature rise in the cavity space in the summer. On the other hand, in the air flow structure, the temperature in the cavity space is kept constant by taking in the indoor air from the lower part of the cavity space and exhausting it from the upper part.

Japanese Unexamined Patent Publication No. 2003-106598 Japanese Unexamined Patent Publication No. 2007-100437 Japanese Unexamined Patent Publication No. 2005-048425

In the double-skin structure and the airflow structure, an opening / closing door or the like may be provided on the inner glass surface for the purpose of regular maintenance and cleaning of the cavity space. In order to provide an opening / closing door, it is common to use a sash, but if a sash is used, the view from the indoor side will be reduced due to the presence of the window frame. In addition, the support structure of the rotary opening / closing door (swing door) becomes complicated. On the other hand, the sliding door (sliding door) is installed so that it is displaced in the out-of-plane direction with respect to the other glass plates adjacent to the left and right (sliding door), so if the inner glass surface is flush with each other. However, the indoor landscape deteriorates.
From such a viewpoint, it is an object of the present invention to propose an airflow structure excellent in indoor landscape while minimizing the number of members obstructing the view.

In order to solve the above problems, the airflow structure of the present invention includes an outer glass surface facing the outside of the building, an inner glass surface arranged on the indoor side of the outer glass surface, the outer glass surface and the inner glass. It is provided with a cavity space, which is a gap between the face piece and the face piece. The inner glass surface body is formed by arranging a plurality of glass plates side by side so that the plate surfaces are flush with each other, and the plurality of glass plates are arranged with a gap from the floor surface. A sealing material or a gap having a size capable of absorbing deformation at the time of an earthquake is provided between the adjacent glass plates . Further, at least one of the plurality of glass plates is a mobile glass plate suspended at the upper end portion so as to be able to be moved laterally after being moved out of the plane. ..

According to such an airflow structure, since the mobile glass plate is provided, maintenance of the cavity space is possible. Since the movable glass plate is moved laterally after being moved out of the plane, it can be arranged so that the plate surfaces are flush with other adjacent glass plates in a normal state. Moreover, since the mobile glass plate is suspended, the number of members (window frames, hinges, etc.) that obstruct the view can be reduced as much as possible, and therefore the indoor landscape is not deteriorated.

If the stopper for fixing the mobile glass plate by protruding upward from the floor surface is formed directly under the mobile glass plate, the mobile glass plate suspended at the upper end is prevented from shaking. be able to. Therefore, the burden on the mobile glass plate and the support member can be reduced.
Further, as the supporting means for the mobile glass plate, a hanger having a traveling means capable of traveling on a rail formed above the inner glass surface can be adopted. It is desirable that the rail includes a rail body on which the traveling means travels, and a locking means formed on the indoor side of the rail body to lock the traveling means. In this configuration, when the mobile glass plate is moved out of the plane, the traveling means moves from the locking means onto the rail body, so that the mobile glass plate can be moved laterally.

According to the airflow structure of the present invention, it is possible to construct a building having an excellent indoor landscape while minimizing the number of members obstructing the view.

It is a perspective view which shows a part of the airflow structure which concerns on embodiment of this invention. (A) is a plan sectional view showing a part of an airflow structure, and (b) is a front view thereof. (A) is a side view of the rail, and (b) is a plan view of the rail. It is sectional drawing which shows the hanger and rail of a mobile glass plate. It is a figure which shows the detail of a stopper, (a) is a side view, (b) is the BB arrow view of (a), (c) is the AA sectional view of (a). (A) to (c) are plan sectional views showing each step in moving a mobile glass plate.

As shown in FIG. 1, the airflow structure 1 of the present embodiment includes an outer glass surface body 2, an inner glass surface body 3, and a cavity space 4.
The outer glass surface body 2 is formed by arranging a plurality of glass plates (outer glass plates 21, 21, ...) In parallel facing the outside of the building. The outer glass surface 2 constitutes a so-called glass curtain wall, not a building structure. The outer glass surface body 2 is formed by fitting the outer glass plate 21 into the frame member 22 formed along the outer surface of the building. Further, the outer glass plates 21 are arranged side by side so that the plate surfaces are flush with each other. The size of the outer glass plate 21 (frame material 22) constituting the outer glass surface body 2 is not limited. Further, the method of fixing the outer glass plate 21 is not limited. Further, in the present embodiment, the outer glass surface body 2 (frame material 22) is formed for each floor (layer), but the outer glass surface body 2 may be formed over a plurality of floors.

The inner glass surface body 3 is formed by juxtaposing a plurality of glass plates (inner glass plates 31, 31, ...) Inside the outer glass surface body 2 (indoor R side). The inner glass surface 3 of the present embodiment is formed for each floor (each floor). The inner glass plates 31 are arranged side by side so that the plate surfaces are flush with each other. The plurality of inner glass plates 31 are arranged with a gap (vent 33) from the floor surface F. A sealing material (gasket) 32 is interposed between the adjacent inner glass plates 31. It is desirable that the width (thickness) of the sealing material 32 be as thin as possible so as not to obstruct the landscape, but the width (thickness) should be large enough to absorb deformation during an earthquake or the like. The sealing material 32 may be installed as needed and may be omitted. However, when the sealing material 32 is omitted, a gap sufficient to absorb deformation during an earthquake or the like is provided in the inner glass. It is preferable to form it between the plates 31.

As shown in FIGS. 2A and 2B, the inner glass surface 3 is formed with an opening 34 that communicates the cavity space 4 and the chamber R. A mobile glass plate 35 is installed in the opening 34. The number of mobile glass plates 35 (the number of openings 34) provided on the inner glass surface 3 is not limited, and may be appropriately determined.
The mobile glass plate 35 is suspended at the upper end thereof (see FIG. 3A). The mobile glass plate 35 is configured to be movable, and the opening / closing 34 is opened / closed by moving the mobile glass plate 35. On the other hand, the inner glass plate 31 other than the mobile glass plate 35 is placed on a base 36 formed on the floor surface F at a predetermined interval, and the upper end thereof is fixed so as to be immovable. Has been done. Sealing materials (packing) are provided on the side edges of the inner glass plate 31 (inner glass plates 31 arranged on the left and right sides of the opening 34) adjacent to the opening 34 on the opening 34 side and on both side edges of the mobile glass plate 35. 32 is installed. The sealing material 32 may be provided on only one of the inner glass plate 31 and the mobile glass plate 35.

As shown in FIG. 3A, the mobile glass plate 35 of the present embodiment is suspended by the hanger 6 at two places on the left and right of the upper end portion. The hanger 6 travels on a rail 5 fixed to the ceiling. The number of hanging tools 6 for suspending the mobile glass plate 35 is not limited as long as it is plural.
As shown in FIG. 4, the hanger 6 includes a hanger main body 61 and a traveling means 62 that travels on the rail 5. The upper portion of the hanger main body 61 supports the traveling means 62, and the lower end portion of the hanger main body 61 is fixed to the upper end portion of the mobile glass plate 35.

The hanger body 61 of the present embodiment has a U-shape and is arranged so as to cover the upper and lower sides of the rail 5 and one side surface. That is, the hanger body 61 is arranged so as to surround the rail 5. The first piece 63 on the upper side of the hanger body 61 is formed with a recess 64 for holding the traveling means 62. The traveling means 62 of the present embodiment is a so-called ball caster provided with a sphere. The configuration of the traveling means 62 is not limited, and may be, for example, wheels. A mounting portion 66 extending downward is formed on the second piece 65 on the lower side of the hanger body 61. The mounting portion 66 is a plate-shaped member attached to the plate surface of the mobile glass plate 35. The mounting portion 66 is formed with a through hole for inserting the fixing pin 67. The hanger 6 is fixed to the mobile glass plate 35 by a fixing pin 67 inserted through the through hole of the mounting portion 66 and the through hole formed in the upper part of the mobile glass plate 35. The first piece 63 and the second piece 65 are connected by the third piece 68. The third piece 68 is a plate-shaped portion having a height larger than the height dimension of the rail 5.

As shown in FIG. 3B, the rail 5 of the present embodiment is formed on the rail body 51 on which the traveling means 62 travels and on the indoor R side of the rail body 51, and is locked to lock the traveling means 62. It comprises a metal member comprising means 52. The material constituting the rail 5 is not limited as long as it has the strength to support the mobile glass plate 35.
As shown in FIG. 4, the rail 5 is fixed to the ceiling C via the mounting member 53. The mounting member 53 is an inverted L-shaped member having an inverted cross section including a horizontal plate 54 and a vertical plate 55, and uses a bolt 58 penetrating the horizontal plate 54 with the horizontal plate 54 attached to the ceiling C. It is fixed to the ceiling C. The rail 5 includes a rail face plate 56 and a mounting plate 57 formed on the lower surface of the rail face plate 56, and has an inverted L-shaped cross section. The rail 5 is fixed to the mounting member 53 by fixing the mounting plate 57 to the vertical plate 55 with bolts 58. The lower end of the mounting member 53, the decorative top board C ₁ is attached.

The rail body 51 and the locking means 52 are formed on the upper surface of the rail face plate 56. The rail body 51 is a traveling path of the traveling means 62, and is a semi-cylindrical groove having the same diameter as the outer diameter of the sphere of the traveling means 62. As shown in FIG. 3B, the rail body 51 has a straight portion 51a formed in parallel with the outdoor edge of the rail face plate 56 (the upper edge in FIG. 3B) and the straight portion 51a. It is provided with an inclined portion 51b inclined in parallel with an inclined portion 51b and an end portion 51c formed in parallel with the indoor side edge (lower edge in FIG. 3B) of the rail face plate 56. That is, the rail body 51 is a groove formed along the outdoor edge of the rail face plate 56, except for one end 51c (the left end in FIG. 3B). The rail body 51 of the present embodiment has a length of about twice the width of the mobile glass plate 35. The length of the rail body 51 is determined in consideration of the width of the opening 34 when the mobile glass plate 35 is moved, but the width of the opening 34 is secured to a size that allows a person to pass through. If possible, the width is not limited, and for example, the width of the mobile glass plate 35 may be +50 cm.

The locking means 52 is a recess (recess) for holding the sphere of the traveling means 62. The locking means 52 has a spherical surface having the same diameter as the outer diameter of the sphere (see FIG. 4). In the present embodiment, in the central portion of the rail face plate 56, one locking means 52 is formed on the indoor side of the rail main body 51. The locking means 52 is located on an extension of one end portion 51c. The locking means 52 may be formed on the outdoor side of the rail body 51. Further, the number of locking means 52 is not limited, and may be appropriately formed according to the number of hanging tools 6.

As shown in FIGS. 5A to 5C, a stopper 7 is formed below (directly below) the mobile glass plate 35. The stopper 7 projects upward from the floor surface F to fix the mobile glass plate 35.
The stopper 7 of the present embodiment is a rectangular plate-shaped member erected on the floor surface F. The stopper 7 is rotatably supported by a horizontal shaft 71 provided on the lower side of the floor surface F. The stopper 7 has a height larger than the height of the vent 33 when it is erected. When the stopper 7 is rotated about the horizontal axis 71, the height of the stopper 7 becomes smaller than the height of the vent 33. In the present embodiment, when the stopper 7 is tilted down, a rectangular hole F _H in which at least a part of the stopper 7 is housed is formed on the floor surface F.

A protective material 37 is fixed to the lower end of the mobile glass plate 35. The protective material 37 is formed with a recess 38 that opens downward. When the stopper 7 is erected, as shown in FIG. 5C, the upper portion of the stopper 7 is inserted into the recess 38 of the protective material 37, so that the stopper 7 is locked to the lower end of the mobile glass plate 35. On the other hand, when the stopper 7 is rotated by 90 °, the stopper 7 comes out of the recess 38 of the protective material 37, and the locked state between the mobile glass plate 35 and the stopper 7 is released. The configuration of the stopper 7 is not limited.

As shown in FIG. 1, the cavity space 4 is a space formed between the outer glass surface body 2 and the inner glass surface body 3, and forms an air layer. The size (width) of the cavity space 4 is not limited, but in the present embodiment, the size is secured so that the worker can perform work such as maintenance inside. The air taken into the cavity space 4 from the ventilation port 33 formed between the inner glass surface body 3 and the floor surface F is discharged from the exhaust port (not shown) formed above the cavity space 4. The air discharged from the exhaust port is guided to a duct (not shown) connected to the air conditioner or the like in the room R. As described above, in the building of the present embodiment, the air in the room R is circulated through the cavity space 4. If necessary, light-shielding equipment such as blinds and curtains, lighting, and the like may be installed in the cavity space 4. Further, the air taken into the cavity space 4 does not necessarily have to be returned to the indoor R, and may be exhausted to the outside of the building.

At the time of maintenance or the like in the cavity space 4, the movable glass plate 35 is moved to enter and exit through the opening 34.
When moving the movable glass plate 35, first, the fixing by the stopper 7 is released (see FIG. 5). Next, as shown in FIG. 6B, the mobile glass plate 35 is pushed out of the room (moved out of the plane). When the mobile glass plate 35 is pushed out, the traveling means 62 of the hanger 6 fixed to the other end side (right side in the drawing) of the mobile glass plate 35 moves from the locking means 52 to the rail body 51 (FIG. 3). (A) and (b)). At this time, the mobile glass plate 35 is in an inclined state so that one end side is the indoor R side and the other end side is the outdoor side. Next, as shown in FIG. 6 (c), the mobile glass plate 35 is moved laterally (moved to the right in the drawing). When a lateral force is applied to the mobile glass plate 35, the traveling means 62, 62 move along the rail body 51, and the mobile glass plate 35 overlaps the outdoor side of another adjacent inner glass plate 31. It becomes.
After the work, the mobile glass plate 35 is laterally moved in the reverse direction (leftward in the drawing) and then pulled into the indoor side (moved out of the plane). By doing so, the traveling means 62 on the other end side moves from the rail main body 51 to the locking means 52, and as shown in FIG. 6A, the plate surface of the mobile glass plate 35 is in the other adjacent portion. It is flush with the plate surface of the glass plate 31.

According to the airflow structure 1 of the present embodiment, since the mobile glass plate 35 is provided, the cavity space 4 can be maintained. Since the movable glass plate 35 is moved laterally after being moved out of the plane, it can be arranged so that the plate surfaces are flush with other adjacent inner glass plates 31 in a normal state. , Excellent landscape.
Further, since the mobile glass plate 35 is suspended, members (window frames, hinges, etc.) that obstruct the view can be made as small as possible, and therefore the indoor landscape is not deteriorated.
Further, by fixing the mobile glass plate 35 with the stopper 7 protruding upward from the floor surface F, it is possible to prevent the mobile glass plate 35 suspended at the upper end from shaking. Therefore, the burden on the mobile glass plate 35 and the support member can be reduced.

The embodiment of the present invention has been described above. However, the present invention is not limited to the above-described embodiment, and each of the above-mentioned components can be appropriately modified without departing from the spirit of the present invention.
The rail body 51 may be straight over the entire length. In this case, a plurality of locking means 52 are formed on the indoor side of the rail main body 51 according to the position (number) of the hanging tools 6.
Further, in the above embodiment, when the mobile glass plate 35 is moved out of the plane, only the other end side is moved to the outdoor side, but the out-of-plane movement of the mobile glass plate 35 is not limited to this. Instead, the mobile glass plate 35 may be translated in the out-of-plane direction.
Further, when the mobile glass plate 35 is moved out of the plane, it may be moved to the indoor side.

1 Airflow structure 2 Outer glass surface 21 Outer glass plate 22 Frame material 3 Inner glass surface 31 Inner glass plate (glass plate)
32 Sealing material 33 Vent 34 Opening 35 Mobile glass plate (glass plate)
4 Cavity space 5 Rail 51 Rail body 52 Locking means 6 Hanging tool 61 Hanging tool body 62 Traveling means 7 Stopper C Ceiling F Floor surface R Indoor

Claims (3)

The outer glass facet facing the outside of the building,
The inner glass surface formed on the indoor side of the outer glass surface and the inner glass surface
An airflow structure including a cavity space which is a gap between the outer glass surface and the inner glass surface.
The inner glass surface body is formed by arranging a plurality of glass plates side by side so that the plate surfaces are flush with each other.
The plurality of glass plates are arranged with a gap from the floor surface.
A sealing material or a gap having a size capable of absorbing deformation at the time of an earthquake is provided between the adjacent glass plates.
An airflow structure characterized in that at least one of the plurality of glass plates is a mobile glass plate suspended at an upper end portion so as to be able to be moved laterally after being moved out of the plane. .. The airflow structure according to claim 1, wherein a stopper for fixing the mobile glass plate by projecting upward from the floor surface is formed directly under the mobile glass plate. The mobile glass plate is suspended by a hanger that can be moved along a rail formed above the inner glass surface.
The hanger comprises a traveling means for traveling on the rail.
The rail is characterized by comprising a rail body on which the traveling means travels, and a locking means formed on the indoor side of the rail body to lock the traveling means. Alternatively, the airflow structure according to claim 2.

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