JP2019011590A - Building structure - Google Patents

Abstract

To provide a building structure advantageous for easy repairing after earthquake.SOLUTION: A core tube frame 14 includes a first precast prestressed post 22 arranged at a rectangular shape corner portion in a plan view of the core tube frame 14, a second pre-cast prestressed post 24 arranged on each of four sides of the rectangular portion two by two facing each of the first precast prestressed posts 22, a second beam 26 connecting the second pre-cast prestressed posts 24 adjacent to each other on each of the four sides of the rectangular portion, and energy absorbing beams 28 having energy absorptivity and connecting adjacent first precast prestressed posts 22 and second precast prestressed posts 24 on each of the four sides of the rectangular portion. On the extension of each of the four sides of the rectangular portion, the first precast prestressed post 22 and an outer peripheral rigid-frame 12 are connected by a third beam 30.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a building structure suitable for a high-rise building or a super high-rise building.

  In high-rise buildings and ultra-high-rise buildings, conventionally, an inner tube structure comprising a core wall at the center of the building and an outer tube structure having a ramen structure at the outer periphery of the building have been proposed.

JP2011-69148 JP2011-157750A

However, in such a conventional frame structure, the core wall, pillars, and beams are damaged during the earthquake and the energy of the earthquake is absorbed. Therefore, after the earthquake, many parts and locations require major repairs. was there.
The present invention has been devised in view of the above circumstances, and an object of the present invention is to provide a building structure that is advantageous in easily performing repairs after an earthquake.

In order to achieve the above-described object, the invention according to claim 1 includes an outer peripheral frame structure provided on an outer peripheral portion of a building, and a core tube frame having a rectangular shape in plan view provided on an inner peripheral portion of the building. The core tube frame includes a first precast prestressed column disposed at each corner of a rectangle forming a plan view shape of the core tube frame, and each of the rectangles facing the first precast prestressed column. 2nd precast prestressed pillar arranged two on each of the 4 sides, a second beam connecting the second precast prestressed pillars adjacent on each of the 4 sides of the rectangle, and energy absorption Energy absorbing beams connecting the first precast prestressed column and the second precast prestressed column adjacent to each other on each of the four sides of the rectangle. Is, by the third beam extending on an extension of the four sides of the rectangular, and wherein the first precast prestressed column and said outer peripheral noodles Frame is connected.
Further, the invention according to claim 2 is characterized in that the plan view shape of the first precast prestressed column is a square having a side perpendicular to the rectangular side forming the plan view shape of the core tube frame. .
According to a third aspect of the present invention, the planar view shape of the second precast prestressed column is parallel to the rectangular side forming the planar side shape of the core tube frame, and parallel to the rectangular side. It is a rectangle having sides with dimensions larger than the sides that are orthogonal to each other.
According to a fourth aspect of the present invention, the outer frame frame includes a plurality of first reinforced concrete columns arranged along the outer periphery of the building, and a plurality of first beams that connect the first reinforced concrete columns. The location where the third beam is connected to the outer frame frame is the location of the first reinforced concrete column.
In the invention according to claim 5, the outer frame frame has a rectangular shape in plan view, and four rectangular sides forming a plan view shape of the core tube frame, and a rectangle forming a plan view shape of the outer frame frame structure. The plurality of first reinforced concrete columns are arranged on each of the four sides of the rectangular shape forming a plan view of the outer frame frame, and the adjacent first reinforced concrete columns are Each of the four sides is connected by a first beam.
The invention according to claim 6 is characterized in that the first reinforced concrete column is not arranged at each corner of a rectangle forming a plan view shape of the outer frame frame.
The invention according to claim 7 is characterized in that the core tube frame is provided in a central portion of a building.
The invention according to claim 8 is characterized in that the energy absorbing beam is configured to include a low yield point steel material or fiber reinforced concrete.

According to the first aspect of the present invention, when the first precast prestressed column receives a large amount of energy from the outer frame frame via the third beam during an earthquake, the first precast prestressed column is deformed and the energy is reduced. The absorbing beam deforms and absorbs energy.
Also, the second precast prestressed column connecting the adjacent second precast prestressed columns is difficult to deform, and the second precast prestressed column is an energy absorbing beam and the first precast prestressed column. Since it is connected to, there is no significant deformation.
In addition, a first precast prestressed column, an energy absorbing beam, and a second precast prestressed column are arranged on the four sides of the square forming the plan view shape of the core tube frame, and the first precast prestressed column is arranged on the four sides of the square. Since the three beams are positioned, it is advantageous to efficiently absorb a large energy at the time of the earthquake by the energy absorbing beam through the first precast prestressed column and the second precast prestressed column.
Therefore, it is advantageous to replace the energy absorbing beam after the earthquake, or to easily perform repair after the earthquake.
According to the invention described in claim 2, during the earthquake, the large energy received by the outer frame structure is reliably transmitted to the first precast prestressed column, which is advantageous in efficiently absorbing energy by the energy absorbing beam. This is advantageous for easy subsequent repair.
According to the third aspect of the present invention, the second precast prestressed column is more difficult to be deformed, which is advantageous in efficiently absorbing energy by the energy absorbing beam, and advantageous in easily performing repair after the earthquake. .
According to the fourth, fifth, and sixth aspects of the invention, in the event of an earthquake, large energy received by the outer frame frame is reliably transmitted to the first precast prestressed column, and energy is absorbed efficiently by the energy absorbing beam. It is advantageous for easy repair after an earthquake.
According to the seventh aspect of the invention, it is advantageous for absorbing energy with a well-balanced energy absorbing beam regardless of the direction of large energy at the time of earthquake, and advantageous for easily performing repair after the earthquake. It becomes.
According to the eighth aspect of the invention, it is advantageous to easily manufacture the energy absorbing beam.

This is an explanatory diagram of a high-rise building with an outer frame frame and a core tube frame. To make it easier to understand the structure of the outer frame frame and the core tube frame, the outer frame frame up to the third floor slab and the core tube frame into the fifth floor slab FIG. It is a top view of an outer periphery frame frame and a core tube frame.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
The high-rise building 10 has an outer peripheral frame 12 provided on the outer periphery of the building 10 and a core tube frame 14 provided on the inner periphery of the building 10.
The outer frame frame 12 includes a plurality of first reinforced concrete columns 16 and a plurality of first beams 18.
The first reinforced concrete columns 16 are arranged along the outer periphery of the building 10.
In this Embodiment, the planar view shape of the outer periphery rigid frame 12 exhibits the rectangle, and has shown the square in detail.
Therefore, a plurality of first reinforced concrete columns 16 are arranged along the four sides of the square.
The plan view shape of the first reinforced concrete column 16 is a rectangle having a side orthogonal to the side of the rectangle (square) forming the plan view shape of the outer frame frame 12 and is a square in the present embodiment.
In addition, the 1st reinforced concrete pillar 16 is not provided in each corner | angular part of the rectangle (square) which makes the planar view shape of the outer periphery rigid frame 12.

The first beams 18 connect the first reinforced concrete columns 16 adjacent on the four sides of the square.
Since the first reinforced concrete columns 16 are not provided at the corners of the rectangle (square) forming the plan view shape of the outer frame frame 12, the first beam 18 is bent and provided in an L shape in plan view. ing.
The first beam 18 is a reinforced concrete beam.
The first reinforced concrete pillar 16 and the first beam 18 are provided for each floor.

The core tube frame 14 is provided in the inner periphery of the building 10, and is provided in the center of the building 10 in the present embodiment.
The planar view shape of the core tube frame 14 presents a rectangle with a smaller outline than the rectangle (square) forming the planar view shape of the outer peripheral frame frame 12, and is a square in the present embodiment.
The four sides of the square that form the plan view shape of the core tube frame 14 are parallel to the four sides of the square that form the plan view shape of the outer frame frame 12.
The core tube frame 14 includes a first precast prestressed column 22, a second precast prestressed column 24, a second beam 26, and an energy absorbing beam 28.

The first precast prestressed column 22 is disposed at each corner of a rectangle (square) forming a plan view shape of the core tube frame 14, and the cross section of the first precast prestressed column 22 is rectangular. It is a square.
Since the first precast prestressed column 22 is pre-stressed, it is less likely to deform than reinforced concrete columns, and the construction period can be shortened compared to prestressed columns constructed by placing concrete on site. Is uniform and of high quality.

As with the first precast prestressed column 22, the second precast prestressed column 24 is pre-stressed, so it is less likely to deform than a reinforced concrete column, and the quality is uniform and high quality. Yes.
Two second precast prestressed columns 24 are arranged on each of four sides of a rectangle (square) so as to face each first precast prestressed column 22.
Specifically, the second precast prestressed column 24 is disposed in proximity to two surfaces facing each of the first precast prestressed columns 22 adjacent to each other.
The plan view shape of the second precast prestressed column 24 is more than the side perpendicular to the rectangle (square) side forming the plan view shape of the core tube frame 14 and the side parallel to the rectangle (square) side and perpendicular to the side. It is a rectangle with sides of large dimensions.
Therefore, the second precast prestressed column 24 is less likely to be deformed in the extending direction of the side of the rectangle (square) forming the shape of the core tube frame 14 in plan view than the first precast prestressed column 22.

  In the present embodiment, the second beam 26 is a reinforced concrete beam, and connects the second precast prestressed columns 24 adjacent on one side of a rectangle (square).

The energy absorbing beam 28 extends on one side of a rectangle (square) and connects the first precast prestressed column 22 and the second precast prestressed column 24 adjacent to each other.
The energy absorbing beam 28 has energy absorbing properties, and for example, a beam formed of a member or material having energy absorbing properties such as a low yield point steel material or fiber reinforced concrete can be used.
The first precast prestressed column 22, the second precast prestressed column 24, the first beam 18, and the energy absorbing beam 28 are provided for each floor.

Furthermore, the first precast prestressed column 22 and the outer frame frame 12 are connected by a third beam 30 extending on the extension of each of the four sides of a rectangle (square) forming a planar view shape of the core tube frame 14. ing.
In the present embodiment, the first precast prestressed column 22 and the first reinforced concrete column 16 are connected by the third beam 30.
In other words, two sides facing the outside of the first precast prestressed column 22 and the first reinforced concrete facing the two sides of each of the four sides of the rectangle (square) forming the planar view shape of the core tube frame 14 They are connected by a third beam 30 that passes over the extension.
The third beam 30 is provided for each floor, and is a reinforced concrete beam in the present embodiment.

According to the present embodiment, the axial force acting on the high-rise building 10 is mainly used for the first reinforced concrete column 16 of the outer frame frame 12, the first precast prestressed column 22 and the second precast prestressed column 14 of the core tube frame 14. It bears with the pillar 24.
The horizontal force acting on the high-rise building 10 is mainly borne by the first beam 18 and the third beam 30 of the outer frame frame 12, the second beam 26 of the core tube frame 14, and the energy absorbing beam 28.
When bearing this horizontal force, the first precast prestressed column 22 is more difficult to deform than the first reinforced concrete column 16, so the horizontal force from the first beam 18 and the third beam 30 of the outer frame frame 12 is reduced. It becomes possible to catch it sufficiently.
In addition, since the first reinforced concrete columns 16 are not provided at the respective corners of the rectangle (square) forming the plan view shape of the outer frame frame 12, the first precast prestressed horizontal force received by the outer frame frame 12 is efficiently obtained. This is advantageous when paying for the pillars 22.
Furthermore, since the plan view shape of the first reinforced concrete column 16 is rectangular and the plan view shape of the first precast prestressed column 22 is square, the first reinforced concrete column 16 and the first precast prestressed column 22 are Are securely connected by the third beam 30, which is advantageous in that the horizontal force received by the outer frame frame 12 is efficiently borne by the first precast prestressed column 22.

When the first precast prestressed column 22 receives large energy from the first beam 18 and the third beam 30 of the outer frame frame 12 during the earthquake, the first precast prestressed column 22 is deformed and the second Since the precast prestressed column 24 is less deformable than the first second precast prestressed column 24, the energy absorbing beam 28 is deformed and efficiently absorbs energy.
In addition, the second beam 26 extending between the adjacent second precast prestressed columns 24 is less likely to deform the second precast prestressed column 24, and the second precast prestressed column 24 is energy absorbing beam 28. Since it is connected to the first precast prestressed column 22 via the large energy, the energy absorption beam 28 absorbs a large amount of energy at the time of the earthquake and does not deform greatly.
In this case, the first precast prestressed column 22, the energy absorbing beam 28, and the second precast prestressed column 24 are arranged on the four sides of the square forming the planar shape of the core tube frame 14, and further, the four sides of the square Since the third beam 30 is located on the extension of this, it is advantageous to efficiently absorb the large energy at the time of the earthquake by the energy absorbing beam 28.

Furthermore, in the present embodiment, the planar view shape of the second precast prestressed column 24 is a side perpendicular to the rectangular side forming the planar view shape of the core tube frame 14 and a side parallel to the rectangular side and perpendicular to the rectangular side. Therefore, the second precast prestressed column 24 has a rectangular (square) side which forms a plan view shape of the core tube frame 14 as compared with the first precast prestressed column 22. It is difficult to deform in the extending direction, which is advantageous in suppressing the deformation of the second beam 26.
Therefore, at the time of an earthquake, only the energy absorbing beam 28 is damaged, and the first precast prestressed column 22 and the second precast prestressed column 22 of the first beam 18 and the third beam 30 of the outer frame frame 12 and the core tube frame 14. 24, the second beam 26 is not significantly damaged.
Therefore, it is advantageous to replace the energy absorbing beam 28 after the earthquake, or to easily perform repair after the earthquake.
In the present embodiment, since the core tube frame 14 is provided at the center of the building 10, the energy absorbing beam 28 absorbs the energy in a well-balanced manner regardless of the direction in which the large energy during the earthquake acts. It is advantageous for the above, and it is advantageous for easy repair after the earthquake.

DESCRIPTION OF SYMBOLS 10 High-rise building 12 Outer frame frame 14 Core tube frame 16 1st reinforced concrete column 18 1st beam 22 1st precast prestressed column 24 2nd precast prestressed column 26 2nd beam 28 Energy absorption beam 30 3rd beam

Claims (8)

It has an outer peripheral frame structure provided on the outer periphery of the building, and a core tube frame having a rectangular shape in plan view provided on the inner periphery of the building,
The core tube frame is
First precast prestressed columns respectively disposed at rectangular corners forming a planar view shape of the core tube frame;
A second precast prestressed column disposed two on each of the four sides of the rectangle opposite to each first precast prestressed column;
A second beam connecting the second precast prestressed columns adjacent on each of the four sides of the rectangle;
An energy absorbing beam connecting the first precast prestressed column and the second precast prestressed column adjacent to each other on the four sides of the rectangle.
The first precast prestressed column and the outer frame frame are connected by a third beam extending on an extension of each of the four sides of the rectangle.
Building structure characterized by that. The plan view shape of the first precast prestressed column is a square having a side orthogonal to a rectangular side forming the plan view shape of the core tube frame.
The building structure according to claim 1. The planar shape of the second precast prestressed column includes a side perpendicular to the rectangular side forming the planar shape of the core tube frame, and a side parallel to the rectangular side and having a dimension larger than the perpendicular side. A rectangle having
The building structure according to claim 1 or 2, characterized by the above. The outer peripheral frame structure includes a plurality of first reinforced concrete columns arranged along the outer periphery of the building, and a plurality of first beams connecting the first reinforced concrete columns,
The location where the third beam is connected to the outer frame frame is the location of the first reinforced concrete column,
The building structure according to any one of claims 1 to 3, wherein: The outer frame frame has a rectangular shape in plan view,
The four sides of the rectangle forming the plan view shape of the core tube frame and the four sides of the rectangle forming the plan view shape of the outer peripheral frame frame are parallel to each other,
A plurality of the first reinforced concrete columns are arranged on each of the four sides of the rectangle forming the plan view shape of the outer frame frame, and the adjacent first reinforced concrete columns are the first beams on the four sides. Connected by
The building structure according to claim 4, wherein: The first reinforced concrete column is not disposed at each corner of a rectangle forming a plan view shape of the outer peripheral frame frame,
The building structure according to claim 5. The core tube frame is provided in the center of the building,
The building structure according to any one of claims 1 to 6, characterized in that: The energy absorbing beam is configured to include low yield point steel or fiber reinforced concrete,
The building structure according to any one of claims 1 to 7, characterized in that

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