JP2800514B2 - How to install the roof membrane - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for mounting a roof membrane in which a roof membrane is supported by a cable installed between outer walls.

[0002]

2. Description of the Related Art In recent years, there has appeared a structure in which a roof of a large space facility having a pillarless structure such as a dome is constructed as a membrane roof. In this membrane roof structure, an upper end portion of an outer wall surrounding a large space facility is covered with a roof membrane formed of a waterproof flexible membrane. The roof membrane is inflated (expanded) by injecting air into the inside of the facility, and a dome-shaped roof having a central portion swelled in the inflated state is formed.
In order to prevent the roof membrane from being fluttered by the influence of wind or the like, the roof membrane is usually supported by a cable installed between opposed outer walls.

[0003]

However, in such a conventional membrane roof structure, since the entire large space facility must be continuously covered with the roof membrane, the roof membrane has an extremely large area. It will be. For this reason, when the roof membrane is manufactured in a factory at the time of construction of the large space facility, and the roof membrane is to be carried to the site, even when the roof membrane is folded, it becomes extremely bulky, and the transportation becomes difficult. In particular, when the insulation film is attached to the roof film to form an insulation film roof, or when a cable is previously attached to the roof film in a factory, the roof film will be further bulky,
There is a problem that the transportation becomes extremely difficult.

[0004] In view of the above-mentioned problems, the present invention provides a method of mounting a roof membrane, which facilitates the transportation of the roof membrane by assembling and mounting components constituting the roof membrane on site. The purpose is to do.

[0005]

In order to achieve the above object, a mounting method according to the present invention is applied to a space between opposed outer walls of a large space facility.
In addition, it is stretched to allow inflation and deflation,
And a roof membrane composed of a double membrane structure
The primary cable in which this roof membrane is installed between these outer walls
Installation of roof membranes supported via cable and secondary cable
In the method, a plurality of membrane pieces constituting the inner membrane are individually enlarged.
In addition to laying on the floor of the space facility,
Route the secondary cable and correspond to this secondary cable respectively
And lay the primary cable on the outside,
A plurality of membrane pieces that constitute the outer membrane are laid outside the
Connect the corresponding ends of the membrane piece to the outer membrane piece
Together with the ends of the intima membrane pieces and the ends of the adventitia membrane pieces
Connect comrades to each other and connect primary
And attach the primary cable to the secondary cable
Was attached.

[0006]

Further, in such an attaching method, it is desirable to attach a heat insulating material in the step of laying the membrane pieces.

[0008]

With the above arrangement, the roof membrane mounting method of the present invention can be used.
The roof membrane has a double membrane structure with an outer membrane and an inner membrane.
As well as the primary and secondary cables.
And the present invention is applied to
When laying multiple membrane pieces that make up the membrane on the floor,
Next, a secondary cable was routed between each of these membrane pieces, and this secondary
Primary cable on the outside of this corresponding to each cable
And construct the adventitia outside the intimal membrane piece
Laying multiple pieces of membrane, correspondence between inner piece and outer piece
To connect the end parts of the membrane,
And the ends of the outer membrane piece are connected to each other.
Attach the primary cable to the connection and
By attaching the secondary cable to the cable, each part constituting the roof membrane can be easily assembled on site. Accordingly, since the roof membrane can be individually carried into the site without completing the assembly at the factory, the transportation can be facilitated. Also,
Because this roof membrane has a double membrane structure, the heat insulation effect is enhanced,
The cable consists of a primary cable and a secondary cable.
One cable was used to support the roof membrane during inflation.
And the other cable is used to hang the roof membrane during deflation.
By using it as a regulation for falling,
Safety can be improved.

[0009]

Further, in this mounting method, by attaching a heat insulating material in the step of laying the film pieces, the roof film can be configured as a heat insulating film roof, and the heat insulating effect thereof can be significantly improved. In addition, since the heat insulating material can be individually carried into the site, the transportation of the heat insulating material is similarly facilitated.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below in detail with reference to the drawings. 1 to 3 show one embodiment of a method of mounting a roof membrane according to the present invention. FIG. 1 is a schematic configuration diagram showing a cross section of a large space facility to which the present invention is applied, and FIGS. ),
(C), (D), (E) are process drawings showing the construction of the roof film in order, and FIGS. 3 (A), (B), (C), (D),
(E) is a process drawing showing step by step connection of the membrane pieces constituting the roof membrane and attachment of the roof membrane to the cable.

That is, the large space facility shown in FIG. 1 is used as an artificial skiing area 10, and outer walls 12, 12 which are continuous on both sides in the front and back directions of the drawing in the figure are constructed.
A roof membrane 14 is stretched between the upper end portions 2 and 12. The floor surface 18 of the large space portion 16 composed of the outer walls 12 and 12 and the roof membrane 14 is continuously inclined in the direction in which the outer walls 12 and 12 extend (perpendicularly to the plane of the drawing). The artificial snow is piled on the floor 18 and the snow can be slid on the snow. The roof membrane 14 includes an outer membrane 14a.
And the inner membrane 14b to form a double membrane structure.

A cable 20 is provided between the facing outer walls 12, 12, and the roof membrane 14 is supported by the cable 20. The cables 20 are paired with each other in the inward and outward directions (the inward and outward directions correspond to the large space 1).
6 shows a direction around the center. The same applies to the following) and includes a primary cable 20a and a secondary cable 20b. In FIG. 1, the solid line indicates that air is injected into the large space portion 16 and the roof membrane 14 is inflated, and the dashed line indicates that the internal air pressure is eliminated and deflated. Indicates the status.

A machine room 22 is provided outside the outer walls 12 and 12.
A lift room 24 is provided, and an air conditioner, an artificial snowmaker, a snow gun, and the like are installed in the machine room 22.

The outer membrane 14a and the inner membrane 14b, which constitute the roof membrane 14 as a double membrane structure, are each formed of a flexible membrane. In particular, the outer membrane 14a is formed of a water-resistant flexible membrane. The outer film 14a and the inner film 14b are connected at appropriate intervals via a number of connecting films 26, and a heat insulating material 30 described later is interposed between the outer film 14a and the inner film 14b. The roof film 14 is configured as a heat insulating film roof.

The primary cable 20a and the secondary cable 20b are arranged between the outer membrane 14a and the inner membrane 14b, and the primary cable 20a is arranged along the inner side of the outer membrane 14a (on the inner membrane 14b side). At the same time, the secondary cable 20b is routed along the outside of the inner membrane 14b (on the outer membrane 14a side). Then, the length of the primary cable 20a is set to a length substantially along the bulging shape of the outer membrane 14a in the inflated state, and the primary cable 20a and the outer membrane 14a are connected to a connecting metal fitting 44 (see FIG. 3). On the other hand, the secondary cable 20b is formed shorter than the primary cable 20a, and when the roof membrane 14 is deflated, the roof membrane 14 is set at a predetermined height h above the floor surface 18.
Set to the length to be hung. In this embodiment, the predetermined height h is approximately 3 m. In addition, the secondary cable 20b
Is attached to the lower side of the connection fitting 44.

The roof membrane 14 is shown in FIGS.
Is stretched between the outer walls 12, 12 in the process shown in FIG. 2 (A) to 2 (E) are each shown as a schematic cross section corresponding to FIG. 1. First, as shown in FIG. 2 (A), the inner film 14b having the heat insulating material 30 attached to the outer surface is placed on the floor surface. 18
The entire inner membrane 14b is laid on the outer wall 12,
Temporarily fix to the mid-height section of No. 12. And FIG. 2 (B)
As shown in FIG.
b, and both ends of the secondary cable 20b are locked to the inner surfaces of the upper ends of the outer walls 12, 12.

Next, as shown in FIG. 2C, a primary cable 20a is routed outside the secondary cable 20b, and an outer membrane 14a is laid outside the primary cable 20a. Then, both ends of the primary cable 20a and both ends of the outer membrane 14a are fixed to upper ends of the outer walls 12, 12, which are above the locking portions of the secondary cable 20b. At this time, the length of the primary cable 20a is set to a length substantially along the bulging shape of the outer membrane 14a in the inflated state as described above.

Next, as shown in FIG. 2D, the secondary cable 20b is pulled up so as to be substantially parallel to the primary cable 20a, and both ends of the inner membrane 14b are engaged with the secondary cable 20b. Fixed near the part. Then, in this state, air is injected into the large space portion 16 to inflate the roof film 14. FIG. 2E shows a state in which the roof membrane 14 has been inflated. When the roof membrane 14 is inflated in this manner, the secondary cable 20b is further pulled and fixed in a tensioned state. At this time, the secondary cable 2
0b is shorter than the primary cable 20a, and when the roof membrane 14 is deflated as shown in FIG. 1, the roof membrane 14 can be suspended at a predetermined height h above the floor surface 18.

Incidentally, since the roof membrane 14 is significantly increased in size, a plurality of membrane pieces are connected to each other to form the roof membrane 1.
4 is constituted. Therefore, when the roof membrane 14 is attached through the process shown in FIG. 2, the connection between the membrane pieces and the roof membrane 14 and the cable 2 are performed through the process shown in FIG. 3.
Mounting with 0 is performed.

That is, in the step of FIG.
4b constituting the film pieces 4b are laid. The heat insulating material 30 is attached to each of the film pieces 32, 32,. Also, a hook 34 is provided at the end of each of the membrane pieces 32, 32.
Are fixed, and the joint films 36 are respectively attached at appropriate distances L from the ends. Then, in the step of FIG. 3B, the secondary cable 20b is routed between the membrane pieces 32,32. In this secondary cable 20b,
A metal fitting 40 having a hook 38 at the upper end is attached.

Next, in the step of FIG. 3C, a primary cable 20a is routed outside the secondary cable 20b corresponding to each of the secondary cables 20b, and a film piece 3 of the inner membrane 14b is formed.
Each membrane piece 42 constituting the outer membrane 14a is laid outside the outer membrane 2. When the primary cable 20a is laid in this way, the connection fitting 44 is attached to the primary cable 20a. Then, as shown in FIG. 3 (D), hooks 34, 34 at both ends of the film pieces 32, 32 are hooked on locking pieces 46, 46 provided at both ends below the connecting fitting 44, respectively. Engagement piece 48 provided below central part of connecting fitting 44
Hooks 38 of the secondary cable 20b. Also,
The opposite ends of the membrane piece 42 of the outer membrane 14 a are connected to bolts 50, 50 implanted on both upper ends of the connection fitting 44.

Next, as shown in FIG.
The distal ends of the joint films 36, 36 extending from the second and second 32 are connected to bolts 52 which are vertically provided below the secondary cable 20b. By connecting the joint films 36, 36 to each other in this manner, the film piece 32 and the joint film 36 continuously cover the inside of the roof film 14, and the film pieces 32 and the joint film 36 An inner membrane 14b is formed. Further, the distal end side of the membrane piece 32 from the attachment portion of the joint membrane 36 is connected to the outer membrane 14a, and that portion becomes the connection membrane 26 described above.

When the end of the membrane piece 32 of the inner membrane 14b is hooked on the connecting fitting 44 to which the outer membrane 14a is fixed, the outer membrane 14a and the inner membrane 14b are supported by the cable 20 at the supporting portion. Linked to each other. Further, the secondary cable 20b is connected to the primary cable 20 via a metal fitting 40.
This secondary cable 20b is connected to the roof membrane 14 by being attached to the lower side of a.

With the above structure, in the method of mounting the roof membrane according to the present embodiment, the roof membrane 14 is connected to the outer membrane 14a and the inner membrane 14b.
Thus, the inner membrane 14b and the outer membrane 14a are configured by connecting the membrane pieces 32 and 42. Then, each of the membrane pieces 32 and 42 can be laid on the floor 18 of the artificial ski resort 10 and connected to each other via the connection fitting 44. When the corneal pieces 32 and 42 are connected in this way, the heat insulating material 30 is attached at the same time, and the primary cable 20a and the secondary cable 20b are attached.

Therefore, in this embodiment, the roof membrane 14 can be assembled at the artificial ski resort 10 which is the site,
Each component constituting the roof membrane 14, that is, the membrane pieces 32,
42, the primary cable 20a, the secondary cable 20b, the heat insulating material 30, and the like can be individually carried into the site. For this reason, even if the area of the roof membrane 14 itself becomes significantly large, it can be easily transported.

In the method of mounting the roof membrane 14,
The membrane piece 32 of the inner membrane 14b and the heat insulating material 30 are laid on the floor surface 18, the secondary cable 20b and the primary cable 20a are routed outside the membrane piece 32, and the membrane piece 42 of the outer membrane 14a is laid. Connect the respective membrane pieces 32, 42 via the connection fitting 44, and connect the primary and secondary cables 20a, 20a.
Since the roof membrane 14 can be attached by attaching b, the attaching work can be significantly simplified.

Further, in this embodiment, as described above, the roof membrane 14 is formed as a double membrane structure by the outer membrane 14a and the inner membrane 14b. Can be significantly improved.

Further, the cable 20 is connected to the primary cable 2.
0a and the secondary cable 20b, and the primary cable 2
0a exclusively supports the inflated roof membrane 14, the secondary cable 20b is shorter than the primary cable 20b, and the deflated roof membrane 14 is suspended from the floor 18 so that a predetermined height h is secured. I have to have. Therefore, even when the roof membrane 14 is deflated when a disaster occurs, the evacuation of personnel can be performed smoothly and safety can be ensured.

In this embodiment, the roof membrane 14 is replaced with the outer membrane 14.
a and the inner membrane 14b have a double membrane structure.
Since the primary cable 20a and the secondary cable 20b are arranged between the inner cable 14b and the inner membrane 14b, it is possible to prevent the cables 20a and 20b from being exposed to the outside and to protect them from rainwater or the like. it can. Therefore, the rusting of the cables 20a and 20b can be prevented and the durability thereof can be improved, and the appearance of the roof membrane 14 can be improved since the cables 20a and 20b are not exposed.

Further, the primary cable 20a and the secondary cable 20b are provided as a pair, and the secondary cable 2 is connected to a locking portion 48 provided on the primary cable 20a via a hook 38.
By hooking Ob, the secondary cable 20b is attached to the roof membrane 14 via the primary cable 20a.
That is, since the secondary cable 20b can support the roof membrane 14 via the roof membrane support portion of the primary cable 20a, there is no need to provide an extra support portion between the secondary cable 20b and the roof membrane 14, and the The configuration can be simplified.

In this embodiment, the roof membrane 14 is replaced with the outer membrane 14a.
And the inner membrane 14b have a double membrane structure, and the cable 20
Is disclosed with a primary cable 20a and a secondary cable 20b, but the present invention is not limited to this, and the present invention is applicable to a roof membrane having a single membrane structure or a single cable. Of course, you can.

Also, the case where the roof membrane mounting method of the present invention is applied to the artificial ski resort 10 has been disclosed. However, the present invention is not limited to this, and is applicable to other large space facilities using a roof membrane, such as a general dome. Of course, the invention can be applied.

[0034]

As described above, in the method of mounting a roof membrane according to the first aspect of the present invention, the roof membrane is formed of an outer membrane and an outer membrane.
A double membrane structure with an inner membrane and a cable
Is composed of a primary cable and a secondary cable.
Te, and transported to the site each components of the roof membrane, this ya
Each component of the periosteum can be assembled on site and attached to a large space facility. Thus, the roofing membrane it is possible to carry on site in the individual the parts from the factory, as well as it can be greatly facilitates its transportation, ya
Because the root membrane has a double membrane structure, the heat insulation effect can be enhanced.
Together with the primary and secondary cables.
One cable was connected to the roof membrane inflation
The other cable for deflation.
Disaster caused by use for regulating dripping
Safety at the time of occurrence can be improved.

[0035]

Further, according to the second aspect of the present invention, by attaching a heat insulating material in the step of laying the membrane pieces constituting the roof membrane, the heat insulating effect of the roof membrane can be remarkably improved.
Because the insulation can also be individually brought into the site,
Similarly, various excellent effects such as easy transportation can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a cross section of an embodiment of a large space facility to which the present invention is applied.

FIG. 2 is a process chart sequentially showing the construction of a roof membrane in one embodiment of the present invention.

FIG. 3 is a process chart showing the connection of the membrane pieces constituting the roof membrane and the attachment of the roof membrane and the cable in order in one embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Artificial skiing area (large space facility) 12 Outer wall 14 Roof membrane 14a Outer membrane 14b Inner membrane 20 Cable 20a Primary cable 20b Secondary cable 30 Insulation material 32, 42 Membrane piece

Continuation of front page (58) Field surveyed (Int.Cl. ⁶ , DB name) E04H 15/00-15/64

Claims (2)

(57) [Claims] 1. An inflatable space between opposing outer walls of a large space facility.
Stretchable for rate and deflate, for outer and inner membranes
With a roof membrane constructed as a more double membrane structure,
The primary cable and secondary
Next, how to attach the roof membrane supported via the cable
Te, floor of the large space facility a plurality of film pieces constituting the inner membrane, respectively
Along with a secondary cable between each of these membrane pieces.
Cable, corresponding to this secondary cable respectively
Route the secondary cable to the outer
Lay multiple membrane pieces constituting the outer membrane on the side, and
Connect the corresponding ends of the outer membrane with the corresponding
The end of the membrane piece and the end of the outer membrane piece
And connect the primary cables to these connections.
And attach a secondary cable to this primary cable.
A method for mounting a roof membrane. 2. The method according to claim 1, wherein a heat insulating material is attached in the roof membrane laying step.