JPH06101274A - Method of constructing roof of cable dome - Google Patents

Abstract

PURPOSE:To prevent the application of excess tension to a cable at the time of construction by installing a tension ring at a central section to a temporary mast in a freely vertically movable manner, pushing up a cable roof stretched between the tension ring and a compression ring on an outer circumferential section up to a specified position and applying fixed tension. CONSTITUTION:A tension ring 16 at the central section of a roof 12 composed of ridge cables 22, hoop cables 24, a post 26, a diagonal cable, etc., connecting the upper end and lower end of the post is mounted to a temporary mast 30 in a freely vertically movable manner. The tension ring 16 is lifted up to a specified position along the temporary post 30 while being fixed to a compression ring 14 on an outer circumferential section by using temporary cables 32, 34, etc. Predetermined tension is applied to each cable, and the application of excess tension to the ridge cable 22 on an innermost circumference is prevented at the time of construction. Accordingly, each cable need not be thickened more than required.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of constructing a cable dome roof defining a space for a stadium, for example.

[0002]

2. Description of the Related Art Conventionally, a compression ring and a tension ring inside the compression ring, a plurality of ridge cables arranged between the compression ring and the tension ring and connecting both rings, and an inner end of each ridge cable. A post having a connected upper end,
Construction of a roof of a cable dome comprising the compression ring and the lower ends of the outermost posts, and the upper ends of the outer posts and diagonal cables respectively connected to the lower ends of the posts inwardly adjacent to the posts. At this time, in order to connect the outer end of each of the other ridge cables to the lower end of the post, the tension ring is raised to a position above the post (Japanese Patent Laid-Open No. 63-226427). Issue).

[0003]

By the way, in the completed cable dome, the tension acting on the innermost (innermost) ridge cable is smaller than the tension acting on the outermost ridge cable. Therefore, the innermost ridge cable is designed to be thin, and the outermost ridge cable (outermost) is designed to be thick. However, in the above conventional method,
Since the other ridge cable is connected to the post with the height position of the tension ring higher than the post, excessive tension acts on the innermost ridge cable. For this reason, the innermost ridge cable is set to a thickness dimension exceeding the design value so as to withstand this excessive tension. However, in the completed cable dome, the innermost ridge cable is not required to have the strength to withstand such a large tension. It is an object of the present invention to provide a method of constructing a cable dome roof without providing an innermost ridge cable of sufficient thickness to withstand excessive tension.

[0004]

SUMMARY OF THE INVENTION The present invention is directed to a compression ring and its inner tension ring, a plurality of ridge cables disposed between said compression ring and said tension ring and connecting both rings, and each ridge. A post having an upper end connected to the inner end of the cable, the compression ring and the lower end of each outermost post, and the upper end of each outer post and the lower end of the post adjacent to the inside of the post. A method of constructing a roof of a cable dome, each of which is connected with a diagonal cable, wherein the tension ring is located below the upper end of the post with respect to other ridge cables other than the innermost ridge cable, the post and the diagonal cable. Connection of the diagonal cable while maintaining the height position It includes performing. The innermost ridge cable can be set in advance to have an excessively long dimension and can be moved relative to the tension ring.

[0005]

According to the present invention, the diagonal cable is connected while the tension ring is maintained at a height position below the upper end of the inner post, and as a result, the innermost ridge is formed. The cable is not subjected to excessive tension beyond the magnitude required when the cable dome is completed. Therefore, it is not necessary to prepare the innermost ridge cable having an unnecessarily large thickness and hence a large weight. Further, at this time, a large tension acts on the outermost ridge cable, but this is within the range of the tension acting on the outermost ridge cable at the time of completion.

When the innermost ridge cable is set to have an excessively long length in advance and is movable relative to the tension ring in the length direction of the cable, when the tension ring is raised, The ridge cable at the innermost circumference can be made to hang down instead of being in a horizontal state where an infinite tensile force theoretically acts on it. This allows
It is possible to avoid the accident of cutting the innermost ridge cable when constructing the cable dome.

[0007]

1 is a plan view of a roof 12 of a cable dome 10 constructed in accordance with the present invention. The roof 12 includes a compression ring 14 having a circular shape or an illustrated regular polygonal shape, and the compression ring 1
4 includes a tension ring 16 having a regular polygonal shape or a circular shape inward of the space defined by 4.
Have centers on the same vertical line. The illustrated compression ring 14 is formed of reinforced concrete, steel-framed reinforced concrete, steel frame, or the like. Compression ring 1
4 is supported on the ground by a support structure 18 including a plurality of columns and beams. Also, in the illustrated example, another one of the same shape is provided below the tension ring 16 as shown in FIG. 9 which is a longitudinal sectional view of the roof 12 constructed according to the present invention.
One tension ring 20 is arranged and both tension rings are connected to each other.

Between the compression ring 14 and the tension ring 16, a plurality of ridge cables 22 for connecting the rings 14 and 16 are arranged. In the illustrated example, three hoop cables 24 that surround the vertical line in a triple manner are arranged between the compression ring 14 and the tension ring 16, and the compression ring 14 and the outermost (outermost) hoop cable 24 are Between the two hoop cables 24, and between the innermost hoop cable (innermost) hoop cable 24 and the tension ring 1
6, a plurality of ridge cables 22 are arranged respectively, and are connected to each hoop cable 24 in cooperation with the hoop cables 24 so as to form an isosceles triangle.

Further, as shown in FIG. 9, the inner end of each ridge cable 22 (the end on the tension ring 16 side).
To the post 26 having an upper end connected to the compression ring 14, the lower ends of the outermost posts 26, and the upper ends of the outer posts 26 and the lower ends of the posts 26 adjacent to the inside of the posts, respectively. The diagonal cable 28 is connected. The ridge cable 22, the post 26 and the diagonal cable 28, which are connected to each other, together define a triangle. The tension rings 16, 20, the ridge cable 22, the hoop cable 24, the post 26 and the diagonal cable 28 have a predetermined tension when their interconnection is completed, that is, when the triangle shown in FIG. 9 is completed. be introduced.

The roof 1 of the cable dome 10 is shown in FIGS.
The construction process of No. 2 is shown step by step. The roof 1 is shown in FIGS.
The cross-sectional shape when the skeleton 2 is completed, that is, the cross-sectional shape shown in FIG. 9 is shown by a chain line. Referring to FIG.
A temporary mast 30 extending along the vertical line is installed at the center of the compression ring 14 formed previously. The ridge cables 22 are connected to each other on the ground, and one end of the temporary cable 32 is attached to the compression ring 14. Further, the innermost ridge cable 22 is connected to the tension ring 16 so as to be capable of relative displacement. Only the innermost ridge cable 22 is set to have an excessive length that exceeds a predetermined dimension when the roof 12 is assembled. The other end of the temporary cable 32 is connected to the outer end of the outermost ridge cable 22, and the tension rings 16 and 20 through which the temporary mast 30 penetrates use the temporary mast 30 and are slightly raised along the temporary mast. . Then, the temporary cable 32 is pulled to connect the outer end of the outermost ridge cable 22 to the compression ring 14. Next, the upper end of the post 26 is connected to the inner end of each ridge cable 22, and the innermost and outermost hoop cables 24 are connected.
Is connected to the ridge cable 22, and the connection destination of the temporary cable is changed to the lower end of the outermost post 26.

Next, as shown in FIG. 3, the tension ring 16 is raised along the temporary mast 30. The rise of the tension ring 16 is stopped at a height position lower than the upper end of the outermost post 26, preferably at a height position between the upper and lower ends of the post 26, when the roof 12 is shown by the assembled chain line. While maintaining the tension ring 16 at this height position, the compression ring 14 and the lower ends of the outermost posts 26 are connected by a diagonal cable 28. For these connections, the lower end of the post 26 is pulled from the compression ring 14 via the temporary cable 32, and both ends of the diagonal cable 28 prepared in advance are connected to the lower end of the post 26 and the compression ring 14.
By connecting to and. The connection of the diagonal cable 28 forms the triangle (FIG. 4).

During the connection of the diagonal cable 28, when the height position of the tension ring 16 is maintained at a level lower than the upper end of the post 26, compared to the case where the height position of the tension ring 16 is maintained at the same level as or higher than the upper end of the post 26. Thus, the magnitude of the tension acting on the innermost ridge cable 22 is small. This may eliminate the need for cables that are unnecessarily large in diameter to build the roof 12 and therefore withstand high tensions beyond those required to maintain the roof 12. Prior to connecting the diagonal cable 28, the hoop cable 2 of the second circumference from the outer circumference to the inner circumference is connected.
Place 4

Next, the diagonal cable 28 is connected in the second and third turns. The diagonal cable 28 in each circumference is composed of the posts 2 on the inner circumference of the circumference.
6 and the lower end of the post 26 outside the circumference.

Due to the connection work in the second round, FIG.
As shown in, the temporary cable 3 is attached to each post 26 on the second circumference.
4 is attached, and the tension ring 16 is raised to the height position between the upper and lower ends of the post when the roof 12 is completed. Before the tension ring 16 is raised, the innermost diagonal cable 28 is slackened and connected to the upper ends of the innermost posts 26 and the tension ring 20. While the tension ring 16 is maintained at the height position, the temporary cable 34 is pulled outward, and the upper end of the outer post 26 connected to the outer end of the ridge cable 22 and its adjacent to the post. The lower end of the post 26 located inward (inner circumference) is connected by the diagonal cable 28 prepared for the second circumference (see FIG. 6).

Also during the connection work on the third circumference, the tension ring 16 is maintained at the height position between the upper and lower ends of the post 26 indicated by the chain line, during which the temporary cable 34 is pulled up and the diagonal cable 28 is used to The upper end of the post 26 in the second circumference and the lower end of the post 26 in the third circumference are connected. In the illustrated example, the cables 22 and 28 and the post 2 on the third circumference are connected to each other.
The height position of 6 is the both innermost cables 22 (4th round),
Determined after interconnection of 28 and post 26.

Next, the tension ring 16 is raised, preferably until its height position is at the same height position as the upper end of the post 26 on the third circumference (FIG. 7), and the ridge cable 22 on the innermost circumference is temporarily fixed. Tension ring 16
Then, the length dimension is adjusted so as to be exactly the designed length (Fig. 8). At this time, the ridge cable 22 hangs slightly or becomes slightly tense. When connecting the innermost ridge cable 22, the innermost diagonal cable 28 is slightly tensioned, and the weight of the tension ring 16 is temporarily received by the diagonal cable 28. Then, the innermost diagonal cable is tensioned to the design tension. As a result, the tension as designed is introduced into each cable, the tension ring 20 is separated from the temporary mast 30 and is raised a predetermined distance, and the frame of the roof 12 is completed. After that, the temporary mast 30 is dismantled and removed.

[Brief description of drawings]

1 is a plan view of the roof of a cable dome constructed in accordance with the present invention. FIG.

FIG. 2 is a vertical sectional view of a ridge cable, a post, a diagonal cable, and the like in a state of being pulled up in the air.

FIG. 3 is a vertical cross-sectional view showing a state in which a tension ring is raised to attach the outermost diagonal cable.

FIG. 4 is a vertical cross-sectional view showing a state in which a tension ring is raised to attach a second-round diagonal cable.

FIG. 5 is a vertical cross-sectional view showing a state in which a tension ring is raised to attach a diagonal cable of the third circumference.

FIG. 6 is a vertical cross-sectional view showing a state in which a temporary cable is attached to the lower end of a post on the third circumference.

FIG. 7 is a vertical cross-sectional view showing a state in which a tension ring is raised to attach the innermost diagonal cable.

FIG. 8 is a vertical cross-sectional view showing a state where the innermost ridge cable is adjusted to a predetermined length and connected.

FIG. 9 is a cross-sectional view of the completed roof.

[Explanation of symbols]

 10 Cable Dome 12 Roof 14 Compression Ring 16 Tension Ring 22 Ridge Cable 24 Hoop Cable 26 Post 28 Diagonal Cable

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location E04G 21/16 7228-2E

Claims (2)

[Claims] 1. A compression ring and a tension ring inside the compression ring, a plurality of ridge cables arranged between the compression ring and the tension ring and connecting both of these rings, and connected to an inner end of each ridge cable. A post having an upper end, a lower end of each of the compression ring and the outermost post, and a diagonal cable connected to the upper end of each outer post and the lower end of a post adjacent to the inside of the post. A method of constructing a roof of a cable dome comprising a ridge cable other than the innermost ridge cable, a post and a diagonal cable, while maintaining the tension ring in a height position below the upper end of the post. Connect the diagonal cable to the cable dome How to build a roof. 2. The method according to claim 1, wherein the innermost ridge cable is preliminarily set to have an excessive length and is movable relative to the tension ring.