JP2001355351A - Self-balanced type cable tower structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cable tower constituting a structural body with tensile members. SOLUTION: A lower portion of a tower shaft supporting the dead-weight of the tower is supported by angle braces raised diagonally upward from a tension ring at the boundary portion, and the tension ring is supported by a plurality of leg frameworks on the ground surface. A plurality of cables are arranged in vertical direction along the outer periphery of dwelling facilities such as compression rings, observation platforms or the like located at the outer peripheral portioned at intervals in up-down direction of the tower shaft, the bottom ends of the cables are connected to the tension ring at the boundary portion and the top ends are connected to the top of the tower shaft in a manner transmitting the stresses respectively, and the axial force of the angle braces supporting the dead-weight of the tower greatly exceeds tension in the cable in vertical direction thereby looseness in the balanced cables is not created. The dead-weight of the tower exceeds the horizontal load thereby prohibiting the occurrence of a balanced pull-out force to the horizontal load.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention belongs to the technical field of a cable tower structure in which a structure is constituted by a tension member (cable), and more specifically, the axial force of a boundary portion which greatly exceeds the cable tension and is superior. Maintain self-balance with superiority,
Also, the present invention relates to a self-balancing cable tower structure in which the tower's own weight is predominantly maintained for a horizontal load.

[0002]

2. Description of the Related Art The most important point for a cable structure in which a structure is composed of a tension member (cable) is a boundary portion (a boundary condition portion) for processing a force that balances cable tension.
The structure is as follows. When the boundary portion is displaced, the cable tension is released (loose), so that it is required as a condition that the boundary portion is not deformed by the cable tension.

Since the ordinary cable structure is widely applied to a large-span roof as shown in FIG. 3, the inclination of the erected shape of the cable C is almost horizontal, and the upward component force of the cable tension is so small that it does not matter. A self-balancing system can be configured with the compression ring A that balances the horizontal component force.

On the other hand, in the case of a cable tower structure as shown in FIG. 4 (see, for example, the invention described in Japanese Patent No. 2829628), the cables C are arranged radially in a plan view, Generally, one end of C is fixed to the tower shaft B and the other end is fixed to the underground foundation D.
Therefore, the inclination of the erection shape of the cable C is vertically close very large upward component force P ₁ of the cable tension P.

[0005]

For cable tower structure of Fig. 4 A present invention is to provide a, portion for anchoring the cable C into the ground underlying D is the horizontal component force P ₂ of the cable tension, circular basal level The compression ring is installed to restrain the horizontal displacement of the boundary.

However, the upward component force P ₁ of the cable tension
In the past, despite the fact that it was particularly large, the conventional approach was simply to increase the size and weight of the underground foundation.

[0007] However earthquake, when the horizontal force acts such as strong winds, so further lifting force in addition to the upward component force P ₁ of the cable tension P described above is increased, the need to resist this, the ground foundation further It is necessary to increase the size and weight. As a result, the fact that the advantage of being able to construct a lightweight structure with a small number of members, which is an advantage unique to the cable structure, is actually hindered.

Accordingly, it is an object of the present invention to provide a self-balancing cable tower structure that makes the most of the superiority of a cable structure in which the structure is constituted by cables in the construction of a tower structure.

An object of the present invention is to provide a supporting portion of the tower's own weight at a boundary portion for ensuring the balance with the cable tension P to maintain self-balancing, and to support the portion below the boundary portion on the ground with a small number of foot frames. The present invention is to provide a self-balancing cable tower structure of the following type.

According to the present invention, the tower tension is balanced against the cable tension during a long-term load, and the lift reaction force is also balanced against the lifting reaction force during a horizontal load.
It is to provide a self-balancing cable tower structure.

[0011]

As a means for solving the above-mentioned problems of the prior art, a self-balancing cable tower structure according to the first aspect of the present invention is a cable tower having a structure formed of cables. The structure, the lower part of the tower shaft supporting the tower's own weight, is supported by a cheek cane strut rising diagonally upward from the tension ring at the boundary, and the tension ring is supported on the ground by a plurality of foot frames. That is, a plurality of cables are arranged in a vertical direction along the outer periphery of a residential facility such as a compression ring and an observatory, which are arranged on an outer peripheral portion of the tower shaft at intervals in a vertical direction, and a lower end of the cable is The tension ring at the boundary portion and the upper end are respectively connected to the top of the tower shaft so as to transmit stress, and That the axial force of the cheek cane supporting the weight greatly exceeds the tension of the vertical cable and does not cause the loosening of the balancing cable, and that the tower's own weight does not generate the balancing pulling force for the horizontal load. Each feature.

According to a second aspect of the present invention, there is provided a self-balancing cable tower structure, wherein the cable tower structure comprises a cable, and a lower portion of a tower shaft supporting the tower's own weight has a boundary portion. The compression ring is supported by a hanging material arranged obliquely downward from the compression ring, and the compression ring is supported on the ground by a plurality of foot frames, and is disposed on an outer peripheral portion of the tower shaft at a position vertically spaced. A plurality of cables are arranged vertically along the outer circumference of the residential facility such as a compression ring and an observatory, and the lower end of the cable can transmit stress to the compression ring at the boundary and the upper end can transmit stress to the top of the tower shaft. And the tensile force of the hanging material supporting the tower's own weight is Do not exceed the force greater excellence to cause loosening of the balance cable, tower own weight in the horizontal load is respectively characterized in that does not cause a balance pullout force outstandingly.

According to a third aspect of the present invention, in the self-balancing cable tower structure according to the first or second aspect, the lower end of the tower shaft is not supported on the ground.

According to a fourth aspect of the present invention, in the self-balancing cable tower structure according to the first or second aspect, a horizontal restraining cable or a horizontal portion is provided between the tension ring or the compression ring at the boundary and the tower shaft. It is characterized by being fastened by a steel frame member, and furthermore, by a diagonal cable having a phase difference in the circumferential direction between the ring at the boundary portion and the other compression ring and the living facility.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows an embodiment of a self-balancing cable tower structure according to the first, third and fourth aspects of the present invention.

This self-balancing cable tower structure
The tower shaft 1 is a cable tower structure in which a structure is constituted by a vertical cable 5 arranged in a radial shape in a plan view and a hyperbolic shape in an elevation view, and a lower portion of the tower shaft 1 supporting the tower's own weight is: A plurality of cheek staff posts 3 rising diagonally upward from the tension ring 2 at the boundary part ...
Supported by The lower portion of the tower shaft 1 is fastened by a restraining cable 4 (or a restraining member such as a steel frame member) arranged radially in the horizontal direction between the tower shaft 1 and the tension ring 2, and is fixed in a vertical posture.

Normally, the boundary portion (tension ring 2) located at the foundation level is elevated above the ground, and the lower end of the tower shaft 1 is not supported by the foundation (the invention according to claim 3). However, a part may be supported on the basis. In the case of the illustrated example, the tension ring 2 has four legs and is supported on the ground by a small number of foot frames 6 (so-called mega pillars).

A plurality of compression rings 7 are arranged at a plurality of positions spaced apart in the vertical direction of the tower shaft 1 as an outer peripheral portion of the tower shaft 1. Observation deck 9, 10
Is also provided. The plurality of vertical cables 5 are connected to the respective compression rings 7.
And are arranged in a hyperbolic arrangement in the vertical direction along the outer circumferences of the observatories 9 and 10 and in a radial arrangement equally distributed in the circumferential direction, and a cable structure is formed by tightening the respective contacts. I have. Further, the lower end of each of the cables 5 is connected to the tension ring 2 at the boundary portion, and the upper end is connected to the top 8 of the tower shaft 1 so as to transmit stress.

The tension ring 2 at the boundary or the compression ring 7 at each height and the tower shaft 1 are tightly fixed by a horizontal restraining cable 11 (or a restraining member such as a steel member). Also, between the tension ring 2 at the boundary portion and the compression ring 7 at each height position above, and between each of the observatories 9 and 10, the diagonal direction having a phase difference in the circumferential direction between each of them. Tightened by the cable 12 to enhance the rigidity effect of the cable structure.

The self-balancing cable tower structure shown in FIG. 1 is planned to be implemented at a height of about 500 m to 600 m above the ground and as a scale.

In the self-balancing cable tower structure having the above-described structure, the normal load W (vertical load) of the tower shaft 1 supporting the tower's own weight is entirely equal to the plurality of cheek cane posts 3.
Are transmitted to the tension ring 2 and supported. The vertical component force F and the horizontal component force N of the tower's own weight that the cheek staff 3 bears are balanced with the upward tension M (cable tension) of the vertical cable 5 to be a self-balancing type (closed force). Form a triangle FNM.).

Therefore, the force at the boundary (tension ring 2) is balanced because the axial force of the cheek staff column 3 supporting the tower's own weight W greatly exceeds the tension M of the vertical cable 5 and is excellently balanced. 5 does not loosen. In addition, the tower self-weight W does not predominantly generate a balancing pull-out force even during a horizontal load due to an earthquake or the like, so that a stable self-balancing type is realized.

Therefore, there is no problem of deformation of the boundary condition portion and loosening of the cable 5 caused by the deformation. In addition, since it is unnecessary to increase the size of the foundation and the cable structure is established with a small number of components, the superiority of the cable structure can be satisfied.

Next, FIG. 2 shows an embodiment of a self-balancing cable tower structure according to the second and third aspects of the present invention.

This self-balancing cable tower structure also has
This is also a cable tower structure in which the structure is constituted by the cable 5, but the tower shaft 1 supporting the tower's own weight
Is supported by a plurality of hanging members 22 equidistantly and obliquely downward from the compression ring 20 at the boundary portion.

Compression ring 2 at the boundary
0 is supported high on the ground by a small number of foot frames 6.
A plurality of compression rings 7 arranged on an outer peripheral portion of the tower shaft 1 spaced apart in the vertical direction and a plurality of cables 5 are arranged vertically along the outer periphery of the observation decks 9 and 10 as living facilities. The lower end of the cable 5 is connected to the compression ring 20 at the boundary, the upper end is connected to the top 8 of the tower shaft 1 so as to transmit stress, and the suspension member 22 supporting the tower's own weight is connected. The structure in which the tensile force greatly exceeds the upward tension of the vertical cable 5 and is excellently balanced, and the tower's own weight is also excellently balanced in the horizontal load, is the same as the self-balanced cable tower structure of FIG. They are almost common.

[0027]

According to the self-balancing cable tower structure according to the present invention, the superiority of the cable structure comprising the cable 5 is maximized in the construction of the tower structure. Exhibit to the limit.

That is, a support portion for the tower's own weight W is provided at a boundary portion (tension ring 2 or compression ring 20) for ensuring a balance with the cable tension M, and the foot frame structure 6 having a small number of legs is placed on the ground below the boundary portion. Because it is in the form that it is supported in the extended shape, it keeps balance with the cable's excellent weight against cable tension during long-term load. At the time of horizontal load, the tower is balanced by the outstanding weight of the tower against the rising reaction force, so that a stable and economical self-balancing cable structure is established.

[Brief description of the drawings]

FIG. 1 is an elevational view showing an embodiment of a self-balancing cable tower structure according to the present invention.

FIG. 2 is an elevational view showing an embodiment of the self-balancing cable tower structure according to the second aspect of the present invention.

FIG. 3 is a perspective view showing a conventional cable roof structure.

FIG. 4 is an elevation view showing an example of a conventional cable tower structure.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Tower shaft 2 Boundary part tension ring 3 Cheek cane support 7 Compression ring 9, 10 Observation deck 5 Cable 20 Boundary part compression ring 22 Suspension material

Claims (4)

[Claims] 1. A cable tower structure having a structure formed by cables, wherein a lower portion of a tower shaft supporting a tower's own weight is supported by a cheek staff column rising obliquely upward from a tension ring at a boundary portion, The tension ring is supported on the ground by a plurality of foot frames, and the compression ring and the compression ring disposed on the outer peripheral portion of the tower shaft at intervals in the vertical direction and along the outer periphery of a residential facility such as an observation deck. A plurality of cables are arranged in the direction, the lower end of the cable is connected to the tension ring at the boundary portion, and the upper end is connected to the top of the tower shaft so as to transmit stress, respectively. The force does not significantly exceed the tension of the vertical cable and does not cause the counterbalance cable to loosen, A self-balancing cable tower structure, characterized in that the tower's own weight does not generate a balanced pull-out force for horizontal loads. 2. A cable tower structure having a structure formed by cables, wherein a lower portion of a tower shaft supporting a tower's own weight is supported by a hanging member disposed obliquely downward from a compression ring at a boundary portion, wherein the compression is performed. The ring is supported on the ground by a plurality of foot frames, and a vertical direction along the outer periphery of the residential facility such as a compression ring and an observation deck arranged at an outer peripheral portion of the tower shaft at intervals in a vertical direction. The lower end of the cable is connected to the compression ring at the boundary portion and the upper end is connected to the top of the tower shaft so as to transmit stress, and the pulling force of the hanging material supporting the tower's own weight is provided. However, the tension of the vertical cable greatly exceeds the tension of the vertical cable. A self-balancing cable tower structure, characterized in that the tower weight does not generate a balanced pull-out force for horizontal loads. 3. The self-balancing cable tower structure according to claim 1, wherein the lower end of the tower shaft is not supported on the ground. 4. The boundary between the tension ring or the compression ring and the tower shaft is fastened by a horizontal restraining cable or a steel frame member, respectively, and the boundary between the ring and the other compression ring and the accommodation facility. 3. The self-balancing cable tower structure according to claim 1, wherein the cables are connected by oblique cables having a phase difference in a circumferential direction with respect to each other. 4.