JP4706302B2 - Triple tube structure and damping system for triple tube structure - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a triple tube structure and a vibration control system for a triple tube structure, and in particular, a high-rise building (void type, center core type, plate type, etc.) such as an apartment building of about 20 to 70 floors, an office building, etc. The present invention relates to a triple tube structure and a vibration control system for the triple tube structure.

  In recent years, as a structure for high-rise buildings such as apartment buildings and office buildings, a void-type structure in which an atrium is provided in the center and a living space is provided around the atrium, and an elevator is provided in the center. S, such as a center core type structure with a living space surrounding the elevator, a plate type structure with a living space along the long side of a rectangular building, RC, etc. Structures, SRC structures, or CFT structures have been proposed (see, for example, Patent Documents 1 to 3).

In the structure having such a structure, a tube structure in which a frame structure of a ramen structure constituted by combining columns and beams is provided in two or three layers is adopted, and this structure allows a super high-rise building (20 The strength and earthquake resistance of about ~ 70 floors) are secured.
JP 2004-2111288 A JP 2004-122495 A JP-A-11-264183

  However, in the structure having the above-described structure, the space between adjacent columns of the outer tube frame is set as narrow as about 4 to 5 m in order to ensure the strength of the building, so the view is narrow. turn into. Moreover, since the beam and pillar of an inner tube frame will be arrange | positioned in the room part of each dwelling unit of a living space, the area of each dwelling unit will become narrow. Furthermore, no lighting can be obtained from the center of the building.

  The present invention has been made in view of the conventional problems as described above, and can broaden the view and can increase the area of each dwelling unit provided in the living space. It is an object of the present invention to provide a triple tube structure and a vibration control system for the triple tube structure that can obtain daylight from the center.

The present invention employs the following means in order to solve the above problems.
That is, the present invention is a triple tube structure in which a frame structure of a ramen structure formed by combining a column and a beam is provided in three layers, and the entire circumference is provided between the intermediate tube structure and the innermost tube structure. In addition, it is completely divided in the vertical direction over the entire height, and a damper is interposed in the divided part over the entire circumference and over the entire height, and the hallway space between the intermediate tube frame and the innermost tube frame. Furthermore, a living space is provided between the intermediate tube frame and the outermost tube frame, and no beam is provided between the intermediate tube frame and the innermost tube frame. It is characterized by.

According to the triple tube structure of the present invention, when applied to a high-rise building such as an apartment house or an office building, the columns and beams of the intermediate tube frame are not arranged in the living space. The area of each dwelling unit provided in the space can be increased. In addition, since the corridor space is provided between the intermediate tube frame and the inner tube frame, the interval between the columns of the outer tube frame can be increased, and a wide view can be obtained. Furthermore, since the inner tube frame has a ramen structure composed of columns and beams, it is possible to obtain daylight from the center of the building. Furthermore, between the intermediate tube frame and the inner tube frame is completely divided in the vertical direction over the entire circumference and the entire height, and a damper is interposed in the divided part over the entire circumference and the entire height. In addition, vibration between the intermediate tube frame and the inner tube frame can be efficiently controlled over the entire height.

In the present invention, the pile supporting the column of the intermediate tube frame and the pile supporting the column of the inner tube frame are decentered from directly below each column via the foundation beam and the foundation slab of the thick plate. It may be good .

According to the triple tube structure of the present invention, even if the space between the tube frames is narrowed by providing a corridor space between the intermediate tube frame and the inner tube frame, the pile supporting the columns of both tube frames. Is eccentric from the bottom of the column via the foundation beam, so that the load from the columns of both tube frames can be sufficiently supported. It can also be applied to direct foundations without piles.

Further, in the present invention, a double-structure floor slab is provided in a corridor space between the intermediate tube frame and the inner tube frame, and a recess is formed in the double-structure floor slab, may be equipment duct is provided in the recess.

According to the triple tube structure of the present invention, the floor slab provided in the corridor space between the intermediate tube frame and the inner tube frame has a double structure that increases the bending rigidity. Moreover, piping, wiring, etc. to each dwelling unit can be laid in the equipment duct provided in the recessed part of a floor slab of a double structure.

Further, in the present invention, the floor slab includes a cantilever slab extending from the intermediate tube frame toward the inner tube frame, and an increased striking portion that is placed on top of the cantilever slab. , may be the recessed portion is provided between the intermediate tube frame and bulking hitting portion.

According to the triple tube structure of the present invention, the floor slab formed between the inner tube frame and the intermediate tube frame is composed of a cantilever slab extending from the intermediate tube frame and an increased number of hits placed thereon. Bending rigidity is enhanced by a double structure composed of a portion. Moreover, piping, wiring, etc. to each dwelling unit can be laid in the equipment duct provided in the recessed part between an increased hitting part and an intermediate tube frame.

Further, in the present invention, the floor slab extends from the intermediate tube frame in the direction of the inner tube frame, and extends from the inner tube frame in the direction of the intermediate tube frame. The cantilever slab is placed on top of the cantilever slab, and the recess may be formed between the cantilever slab on the inner tube frame side and the intermediate tube frame. .

According to the triple tube structure of the present invention, the floor slab formed between the inner tube frame and the intermediate tube frame is placed on the cantilever slab extending from the intermediate tube frame and the upper part thereof. Flexural rigidity is enhanced by a double structure comprising a cantilever slab extending from the inner tube frame. Moreover, piping, wiring, etc. to each dwelling unit can be laid in the equipment duct provided in the recessed part between the cantilever slab by the side of an inner tube frame, and an intermediate tube frame.

Furthermore, the present invention provides a damping system of the triple tube structure for damping a triple tube structure according to any one of claims 1 to 5, wherein the innermost and the middle of the tube frame The damper interposed in the divided portion between the tube frame and the tube frame includes a horizontal end surface of the intermediate tube frame located in the divided portion and a horizontal end surface of the innermost tube frame. it is interposed between, characterized in that it is a vertical damper for performing vibration in the vertical direction.

According to the vibration suppression system for a triple tube structure of the present invention , external forces such as earthquakes and winds are input to the triple tube structure, and the inner tube frame and the intermediate tube frame are relatively moved in the vertical direction. When displaced, the vibration energy in the vertical direction is attenuated by the vertical damper interposed between the two tube frames. In this case, the space between the inner tube frame and the intermediate tube frame is completely divided in the vertical direction over the entire circumference and the entire height, and the vertical damper is installed in the divided part over the entire circumference and the entire height. Therefore, it is possible to efficiently suppress vibration between the inner tube frame and the intermediate tube frame.

Furthermore, the present invention provides a damping system of the triple tube structure for damping a triple tube structure according to any one of claims 1 to 5, wherein the innermost and the middle of the tube frame The damper interposed in the divided portion between the tube frame and the vertical tube end surface of the intermediate tube frame located in the divided portion and the vertical end surface of the innermost tube frame it is interposed between, characterized in that it is a horizontal damper for performing vibration in the horizontal direction.

According to the vibration suppression system for a triple tube structure of the present invention , external forces such as earthquakes and winds are input to the triple tube structure, and the inner tube frame and the intermediate tube frame are relatively moved in the horizontal direction. When displaced, the vibration energy in the horizontal direction is attenuated by the horizontal damper interposed between the two tube frames. In this case, the inner tube frame and the intermediate tube frame are completely divided in the vertical direction over the entire circumference and the entire height, and a horizontal damper is installed in the divided part over the entire circumference and the entire height. Therefore, it is possible to efficiently suppress vibration between the inner tube frame and the intermediate tube frame.

Furthermore, the present invention provides a damping system of the triple tube structure for damping a triple tube structure according to any one of claims 1 to 5, wherein the innermost and the middle of the tube frame The damper interposed in the divided portion between the tube frame and the tube frame includes a horizontal end surface of the intermediate tube frame located in the divided portion and a horizontal end surface of the innermost tube frame. A vertical damper for vibration suppression in the vertical direction interposed between the vertical end surface of the intermediate tube frame and the vertical end surface of the innermost tube frame located in the divided part. it is interposed between, characterized in that it is a horizontal damper for performing vibration in the horizontal direction.

According to the vibration suppression system for a triple tube structure of the present invention , an external force such as an earthquake or wind is input to the triple tube structure so that the space between the inner tube frame and the intermediate tube frame is vertical or horizontal. In the case of relative displacement, the vibration energy in the vertical direction or the horizontal direction is attenuated by the vertical damper or the horizontal damper interposed between the two tube frames. In this case, the space between the inner tube frame and the intermediate tube frame is completely divided in the vertical direction over the entire circumference and the entire height, and the vertical damper is installed in the divided part over the entire circumference and the entire height. Therefore, it is possible to efficiently suppress vibration between the inner tube frame and the intermediate tube frame.

Further, in the present invention, the inner tube frame may be divided into at least two in the vertical direction, and a vertical damper for damping vibration in the vertical direction may be interposed in the divided part.

According to the vibration damping system for a triple tube structure of the present invention , vibration energy in the vertical direction is also attenuated by the vertical damper interposed in the dividing portion of the inner tube frame.

As described above, according to the triple tube structure of the present invention , when applied to a high-rise building such as an apartment house or an office building, columns and beams of an intermediate tube frame are arranged in the living space. Therefore, the area of each dwelling unit provided in the living space can be increased. Moreover, since the corridor space is provided between the intermediate tube frame and the inner tube frame, the interval between the columns of the outer tube frame can be increased, and a wide view can be obtained. Furthermore, since the inner tube frame has a ramen structure composed of columns and beams, it is possible to obtain daylight from the center of the building.
Furthermore, the intermediate tube frame and the innermost tube frame are completely divided in the vertical direction over the entire circumference and the entire height, and a damper is interposed in the divided part over the entire circumference and the entire height. Therefore, it is possible to efficiently control the vibration between the intermediate tube frame and the innermost tube frame over the entire height.

In addition, the space between the tube frames is reduced by providing a corridor space between the intermediate tube frame and the inner tube frame, but the piles that support the columns of both tube frames are connected to the columns via the foundation beam. Therefore, the piles supporting the columns of both tube frames do not overlap, and the loads from the columns of both tube frames can be sufficiently supported. It can also be applied to direct foundations without piles.

Furthermore , since the floor slab provided in the corridor space between the intermediate tube frame and the inner tube frame has a double structure, the bending rigidity of the floor slab can be increased. Also, in the equipment duct provided in the recess formed in a part of the floor slab (between the striking portion and the intermediate tube frame, between the cantilever slab on the inner tube frame side and the intermediate tube frame) Since piping, wiring, etc. to each dwelling unit can be laid, piping, wiring, etc. are not exposed and appearance can be improved.

Furthermore, according to the vibration suppression system for a triple tube structure of the present invention, an external force such as an earthquake or wind is input to the triple tube structure, and a vertical or horizontal gap is formed between the inner tube frame and the intermediate tube frame. In the case of relative displacement in the direction, the vibration energy in the vertical direction or the horizontal direction can be attenuated by the vertical damper or the horizontal damper interposed between the two tube frames. In this case, the space between the inner tube frame and the intermediate tube frame is completely divided in the vertical direction over the entire circumference and the entire height, and the vertical damper or the horizontal damper is applied to the divided part over the entire circumference and the entire height. Therefore, it is possible to efficiently control vibration between the inner tube frame and the intermediate tube frame. In addition, since the floor slab between the inner tube frame and the intermediate tube frame has a double structure to increase bending rigidity, the relative displacement in the vertical direction or horizontal direction generated between the two tube frames can be reduced by the vertical damper or It can be reliably transmitted to the horizontal damper.

Furthermore, the vibration energy in the vertical direction can be attenuated also by the vertical damper between the divided frames divided in the vertical direction of the inner tube frame.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 6 show an embodiment of a triple tube structure according to the present invention. FIG. 1 is a schematic perspective view showing the entire triple tube structure, and FIG. 2 is a triple tube structure of FIG. 3 is a partially enlarged plan view of a middle layer portion and a high layer portion of the triple tube structure of FIG. 1, FIG. 4 is a sectional view taken along line AA of FIG. 3, and FIG. 5 is a triple tube structure of FIG. FIG. 6 is a sectional view taken along line BB in FIG. 5.

  In other words, this triple tube structure 1 can be applied to high-rise buildings (void type, center core type, plate type, etc.) such as apartment buildings of about 20 to 70 floors, office buildings, etc. Or CFT structure, as shown in FIGS. 1 and 2, an inner tube frame 2, an intermediate tube frame 5 arranged outside the inner tube frame 2, and an intermediate tube frame 5 is formed in a three-layer tube structure of an outer tube frame 8 disposed on the outer side.

  The inner tube frame 2, the intermediate tube frame 5, and the outer tube frame 8 each have a ramen structure in which a plurality of columns 3, 6, 9 and beams 4, 7, 10 are combined in a lattice pattern. A blow-off space 20 is provided in an inner portion of the inner tube frame 2, a corridor space 21 is provided between the inner tube frame 2 and the intermediate tube frame 5, and the intermediate tube frame 5 and the outer tube frame are provided. 8, a living space 22 is provided, and an elevator core 23 is provided in a part (upper part in FIG. 2) between the intermediate tube frame 5 and the outer tube frame 8.

  As shown in FIGS. 1 and 2, the outer tube frame 8 is formed in a so-called wide span in which the interval between adjacent pillars 9, 9 is about 8 to 10 m, and is provided in the living space 22 by this wide span. The view of each dwelling unit can be expanded.

  By providing the hallway space 21 between the intermediate tube frame 5 and the inner tube frame 2, it is possible to avoid the columns and beams of the intermediate tube frame 5 being disposed in the living space 22. The area of each dwelling unit provided inside can be increased.

  By providing the corridor space 21 between the intermediate tube frame 5 and the inner tube frame 2, 60% or more of the external force due to an earthquake or the like can be borne by the inner tube frame 2 and the intermediate tube frame 5. Therefore, even if the outer tube frame 8 is wide span, predetermined strength and earthquake resistance as a super high-rise building can be obtained.

  By providing the corridor space 21 between the intermediate tube frame 5 and the inner tube frame 2, the column 6 of the intermediate tube frame 5 and the column 3 of the inner tube frame 2 come close to each other. In this embodiment, the pile supporting the axial force of both columns 6 and 3 is decentered from directly below both columns 6 and 3 via the foundation beam. Therefore, the axial force of both pillars 6 and 3 can fully be supported. It can also be applied to direct foundations without piles.

 In the corridor space 21 between the intermediate tube frame 5 and the inner tube frame 2, as shown in FIGS. 3 and 4, a double-structure floor slab 11 is provided. That is, the floor slab 11 includes a cantilever slab 12 that is integral with the intermediate tube frame 5 that extends from the intermediate tube frame 5, and an increased striking portion 15 that is placed on top of the cantilever slab 12. Therefore, the bending rigidity of the floor slab 11 is enhanced by this double structure.

  The cantilever slab 12 is a cross section formed of a slab body 13 formed integrally with the column 6 and the beam 7 of the intermediate tube frame 5 and an upwardly projecting reverse beam 14 provided integrally with the tip of the slab body 13. It has a substantially L shape and extends in the direction from the intermediate tube frame 5 toward the inner tube frame 2 so that the front surface of the reverse beam 14 faces the front surface of the beam 4 of the inner tube frame 2. I'm out.

The front end surface of the reverse beam 14 of the cantilever slab 12 and the front end surface of the beam 4 of the inner tube frame 2 are completely divided in the vertical direction over the entire circumference of the inner tube frame 2. A vertical damper 25, which will be described later, is interposed over the entire periphery.

  The additional striking portion 15 is formed on the cantilever slab 12 so that a recess 16 having a predetermined depth and width is formed between the post 6 of the intermediate tube frame 5 and the entire circumference of the intermediate tube frame 5. The upper part is driven with a predetermined thickness and width, and an equipment duct 16 is provided in the recessed part 16. Gas, water pipes, electricity, telephone, etc. drawn into each unit formed in the living space 22 in the equipment duct 16. Etc. are laid.

 The double-structure floor slab 11 composed of the cantilevered slab 12 and the additional striking portion 15 as described above may be installed in a portion corresponding to each floor of the high-rise building, or bending deformation of the high-rise building is performed. You may install only in the range (for example, middle layer part, high-rise part) which is excellent.

  As shown in FIGS. 5 and 6, the double-structure floor slab 11 includes a cantilever slab 12 extending from the intermediate tube frame 5 and an inner tube frame 2 extending from the inner tube frame 5. You may comprise by the cantilever slab 17 mounted in the upper part of the cantilever slab 12. FIG.

  In this case, a predetermined gap 18 is provided between the horizontal tip surface of the cantilever slab 12 on the intermediate tube frame 5 side and the horizontal tip surface of the beam 4 of the inner tube frame 2 facing the tip surface. The gap 18 allows a relative displacement in the horizontal direction between the intermediate tube frame 5 and the inner tube frame 2. Further, a predetermined gap 19 is provided between the horizontal front end surface of the cantilever slab 17 of the inner tube frame 2 and the column 6 of the intermediate tube frame 5, and this gap 19 is formed in the living space 22. It functions as a recess (equipment duct) 16 for laying wiring such as gas, water pipes, electricity, telephones, etc. drawn into each dwelling unit provided. Further, between the upper surface of the cantilever slab 12 on the intermediate tube frame 5 side and the lower surface of the cantilever slab 17 on the inner tube frame 2 side facing the upper surface, the entire circumference of the inner tube frame 2 is provided. A horizontal damper 30 to be described later is interposed.

 The double-story floor slab 11 composed of the two cantilevered slabs 12 and 17 as described above may be installed in a portion corresponding to each floor of the high-rise building, and the shear deformation of the high-rise building is outstanding. You may install only in the range (for example, low-rise part).

 An inner portion of the inner tube frame 2 is formed in an atrium space 20 penetrating the skyscraper in the vertical direction, and the aerial space 20 is an opening formed between adjacent columns 3 and 3 of the inner tube frame 2. It communicates with the corridor space 21 via 29, and communicates with the living space 22 between the intermediate tube frame 5 and the outer tube frame 8 via the corridor space 21. Therefore, the daylight can be guided into the living space 22 through the atrium space 20, the opening 29 of the inner tube frame 2, and the hallway space 21.

Next, a vibration suppression system for a triple tube structure according to the present invention will be described.
7 and 8 show a first embodiment of a damping system for a triple tube structure according to the present invention. This damping system 31 includes an inner tube frame 2 and an intermediate tube frame 5. Vertical dampers 25 are interposed in the portions corresponding to the respective floors between the two. In this case, the inner tube frame 2 and the intermediate tube frame 5 are completely divided in the vertical direction, and the intermediate tube frame 5 and the outer tube frame 8 are integrally joined. .

  As shown in FIG. 4, the vertical damper 25 is provided between the tip surface of the reverse beam 14 of the cantilever slab 12 extending from the intermediate tube frame 5 side and the tip surface of the beam 4 of the inner tube frame 2. When the external force due to an earthquake or the like is input to the high-rise building, the vertical vibration generated in the building is attenuated by the vertical damper 25 when it is interposed over the entire circumference of the inner tube frame 2.

  That is, when an external force due to an earthquake or the like is input to the super high-rise building, a relative displacement in the vertical direction occurs between the intermediate tube frame 5 and the inner tube frame 2, and the vertical damper 25 shears according to this relative displacement. By deforming, the vibration energy in the vertical direction generated between the tube frames 2 and 5 is attenuated.

  In this case, the floor slab 11 provided between the intermediate tube frame 5 and the inner tube frame 2 has a double structure to increase the bending rigidity. The displacement can be efficiently transmitted to the vertical damper 25, and the vibration energy in the vertical direction generated between the tube frames 5 and 2 can be efficiently attenuated.

  As shown in FIG. 9, the vertical damper 25 is provided integrally with each steel plate 26 and a pair of steel plates 26, 26, a viscoelastic body 27 made of acrylic or the like interposed between the steel plates 26, 26, and the like. It consists of anchor bolts 28, and each steel plate 26 and viscoelastic body 27 are integrally joined via an adhesive. A viscous body may be used instead of the viscoelastic body 27.

  In the vertical damper 25, one steel plate 26 is integrally fixed to the end surface of the reverse beam 14 of the cantilever slab 12 on the intermediate tube frame 5 side via an anchor bolt 28, and the other steel plate 26 is connected to the inner tube frame. The vertical damper 25 is interposed between the intermediate tube frame 5 and the inner tube frame 2 so as to be integrally fixed to the distal end surface of the beam 4 on the second side via the anchor bolt 28.

  The vertical damper 25 may be incorporated in advance between the beam portion of the inner tube frame 2 and the slab portion of the intermediate tube frame 5 at the factory. By adopting such a method, the work of attaching the vertical damper 25 at the site becomes unnecessary, so that the entire construction period can be shortened.

  Then, by arranging the vertical damper 25 configured as described above using the corridor portion of each floor, an external force such as an earthquake or a wind is input to the triple tube structure 1, and the triple tube structure 1 is generated by the external force. When the inner tube frame 2 and the intermediate tube frame 5 are relatively displaced in the vertical direction, the displacement is input to the viscoelastic body 27 of the vertical damper 25, and the viscoelastic body 27 is subjected to shear deformation. By doing so, vibration energy in the vertical direction is attenuated.

  The vertical damper 25 is not limited to the one having the above-described configuration, and a known hydraulic damper, friction damper, or the like may be used, or a combination thereof may be used.

  FIG. 10 shows a second embodiment of the damping system for the triple tube structure, and this damping system 31 is provided on each floor between the inner tube frame 2 and the intermediate tube frame 5. A horizontal damper 30 is interposed in each corresponding part. In this case, it is assumed that the inner tube frame 2 and the intermediate tube frame 5 are completely separated, and the intermediate tube frame 5 and the outer tube frame 8 are integrally joined.

  The horizontal damper 30 has a configuration similar to that of the vertical damper 25 described above, and as shown in FIG. 6, the upper surface of the cantilever slab 12 extending from the intermediate tube frame 5 side, and the upper surface thereof. When an external force such as an earthquake is input to the high-rise building, it is interposed between the lower surface of the cantilever slab 17 that extends from the inner tube frame 2 side facing to the inner tube frame 2 and the entire circumference of the inner tube frame 2 In addition, horizontal vibration generated in the building is damped by the horizontal damper 30.

  That is, when an external force due to an earthquake or the like is input to a super high-rise building, a relative displacement in the horizontal direction occurs between the intermediate tube frame 5 and the inner tube frame 2, and the horizontal damper 30 shears according to this relative displacement. By deforming, horizontal vibration energy generated between the tube frames 5 and 2 is attenuated.

  In the horizontal damper 30, one steel plate 26 is fixed to the upper surface of the cantilever slab 12 on the intermediate tube frame 5 side via an anchor bolt 28, and the other steel plate 26 is fixed on the cantilever slab 17 on the inner tube frame 2 side. The horizontal damper 30 is interposed between the intermediate tube frame 5 and the inner tube frame 2.

  Then, by arranging the horizontal damper 30 configured as described above using the corridor portion of each floor, an external force such as an earthquake or a wind is input to the triple tube structure 1, and the triple tube structure 1 is generated by the external force. When the space between the inner tube frame 2 and the intermediate tube frame 5 is relatively displaced in the horizontal direction, the displacement is input to the viscoelastic body 37 of the horizontal damper 30, and the viscoelastic body 37 is subjected to shear deformation. By doing so, the vibration energy in the horizontal direction is attenuated.

  In this case, since the floor slab 11 provided between the intermediate tube frame 5 and the inner tube frame 2 has a double structure to increase the bending rigidity, the horizontal relative between the tube frames 5 and 2 is increased. The displacement can be efficiently transmitted to the horizontal damper 30, and the horizontal vibration energy generated between the tube frames 5 and 2 can be efficiently attenuated. Moreover, since the action area of the viscoelastic body 27 can be set to an area corresponding to the upper surface of the cantilever slab 12 on the intermediate tube frame 5 side and the lower surface of the cantilever slab 17 on the inner tube frame 2 side, The effect can be enhanced.

  When manufacturing the cantilever slab 17 of the inner tube frame 2 and the cantilever slab 12 of the intermediate tube frame 5 at the factory, the horizontal damper 30 may be incorporated in advance between them. By adopting such a method, the work of attaching the horizontal damper 30 at the site becomes unnecessary, so that the entire construction period can be shortened.

  The horizontal damper 30 is not limited to the one having the above-described configuration, and a known hydraulic damper, friction damper, or the like may be used, or a combination thereof may be used.

  FIG. 11 shows a third embodiment of the vibration suppression system for a triple tube structure according to the present invention. This vibration suppression system 31 is configured such that the lower layer portion of the inner tube frame 2 is connected to the intermediate tube frame 5. The middle tube portion 2 and the upper layer portion of the inner tube frame 2 are integrally formed with the intermediate tube frame 5, and the intermediate tube is formed in the corridor corresponding to each floor of the divided lower layer portion of the inner tube frame 2. A horizontal damper 30 is interposed between the upper surface of the cantilever slab 12 on the frame 5 side and the lower surface of the cantilever slab 17 on the inner tube frame 2 side.

  In the vibration damping system 31 according to this embodiment, the lower layer portion of the inner tube frame 2 is separated from the middle layer portion and the higher layer portion of the inner tube frame 2, and the intermediate tube frame 5 and the outer tube frame are separated. Since it is also separated from the frame 8, the horizontal rigidity of the lower layer portion of the inner tube frame 2 can be increased, and the lower layer and other parts of the inner tube frame 2 (the middle layer of the inner tube frame 2) It is possible to increase the weight difference between the upper part, the upper part, the intermediate tube frame 5 and the outer tube frame 8). Therefore, since the horizontal displacement difference between the lower layer portion of the inner tube frame 2 and other portions can be increased, the horizontal damping effect when an external force such as an earthquake is input can be enhanced.

  FIG. 12 shows a fourth embodiment of the vibration suppression system for a triple tube structure according to the present invention. The vibration suppression system 31 has a lower layer portion and a middle layer portion in the inner tube frame 2 in the vertical direction. And a vertical damper 35 made of seismic isolation rubber or the like is interposed between them, and between the lower layer portion of the inner tube frame 2 and the intermediate tube frame 5. Corresponding to each floor between the middle and high-rise portions of the inner tube frame 2 and the middle tube frame 5, the horizontal direction dampers 30 are interposed in the portions corresponding to the respective floors using the corridor portions. Each part is provided with a vertical damper 25 using a corridor.

  In the vibration damping system 31 according to this embodiment, only the axial force is transmitted from the middle layer portion and the higher layer portion to the lower layer portion of the inner tube frame 2 via the vertical damper 35. The rigidity in the horizontal direction can be set to the same level as that shown in the third embodiment. Accordingly, since the difference in natural period between the inner tube frame 2 and other portions can be increased, the horizontal damping effect when an external force such as an earthquake is input can be enhanced.

  Even if a pulling force is generated in the vertical damper 35 between the lower layer portion, the middle layer portion, and the higher layer portion of the inner tube frame 2, the middle layer portion and the higher layer portion of the inner tube frame 2 are interposed via the vertical damper 25. Therefore, there is no fear that the middle layer portion and the high layer portion of the inner tube frame 2 will fall down, and safety can be improved.

  Further, the vertical damper 25 between the middle and high layer portions of the inner tube frame 2 and the intermediate tube frame 5 can control the vibration between the tube frames 2 and 5 in the vertical direction. Therefore, an excellent vibration damping effect can be obtained over the entire height of the super high-rise building.

  When configuring the vibration damping system, the vertical damper 25 according to the first embodiment and the horizontal damper 30 according to the second embodiment may be provided on each floor, or according to the level. The vertical damper 25 of the first embodiment or the horizontal damper 30 of the second embodiment may be properly used.

It is a schematic perspective view which shows one Embodiment of the triple tube structure by this invention. It is a top view of the triple tube structure shown in FIG. It is the elements on larger scale of the middle layer part of the triple tube structure shown in FIG. 1, and a high layer part. FIG. 4 is a sectional view taken along line AA in FIG. 3. It is the elements on larger scale of the low layer part of the triple tube structure shown in FIG. FIG. 6 is a sectional view taken along line B-B in FIG. 5. 1 is a schematic plan view showing a first embodiment of a vibration damping system for a triple tube structure according to the present invention. It is the schematic seen along CC line of FIG. It is the schematic of a vertical direction damper. It is the schematic which shows 2nd Embodiment of the damping system of the triple tube structure by this invention, Comprising: It is the schematic seen along CC line of FIG. It is the schematic which shows 3rd Embodiment of the damping system of the triple tube structure by this invention, Comprising: It is the schematic seen along CC line of FIG. It is the schematic which shows 4th Embodiment of the damping system of the triple tube structure by this invention, Comprising: It is the schematic seen along CC line of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Triple tube structure 2 Inner tube frame 3, 6, 9 Column 4, 7, 10 Beam 5 Intermediate tube frame 8 Outer tube frame 11 Floor slab 12, 17 Cantilever slab 13 Slab body 14 Reverse beam 15 Additional shot Part 16 Concave part (equipment duct)
18, 19 Gap 20 Blow-through space 21 Corridor space 22 Living space 23 Elevator core 25, 35 Vertical damper 26 Steel plate 27 Viscoelastic body 28 Anchor bolt 29 Opening 30 Horizontal damper 31 Damping system

Claims (9)

It is a triple tube structure with three layers of tube frames with a ramen structure that is a combination of columns and beams,
The middle tube frame and the innermost tube frame are completely divided in the vertical direction over the entire circumference and the entire height, and a damper is interposed in the divided part over the entire circumference and the entire height. A hallway space is provided between the intermediate tube frame and the innermost tube frame, and a living space is provided between the intermediate tube frame and the outermost tube frame, and the intermediate tube frame and the A triple tube structure characterized in that no beam is provided between the innermost tube frame .   The pile supporting the column of the intermediate tube frame and the pile supporting the column of the inner tube frame are decentered from directly below each column via the foundation beam and the foundation slab of the thick plate. The triple tube structure according to claim 1.   A double-structure floor slab is provided in the corridor space between the intermediate tube frame and the inner tube frame, a recess is formed in the double-structure floor slab, and an equipment duct is provided in the recess. The triple tube structure according to claim 1 or 2, wherein the triple tube structure is provided.   The floor slab comprises a cantilever slab extending from the intermediate tube frame in the direction of the inner tube frame, and an increased hitting part placed on the upper part of the cantilevered slab, The triple tube structure according to claim 3, wherein the recess is provided between the intermediate tube frame.   The floor slab extends from the intermediate tube frame toward the inner tube frame, and extends from the inner tube frame toward the intermediate tube frame. It consists of the cantilever slab mounted in the upper part, The said recessed part is formed between the cantilever slab by the side of the said inner tube frame, and the said intermediate | middle tube frame. Triple tube structure. A damping system for a triple tube structure for damping a triple tube structure according to any one of claims 1 to 5,
The damper interposed in the divided portion between the intermediate tube frame and the innermost tube frame includes a horizontal end surface of the intermediate tube frame located in the divided portion and the innermost tube frame. A damping system for a triple tube structure, characterized in that the damping system is a vertical damper that is interposed between a horizontal end face of a tube frame and performs damping in the vertical direction. A damping system for a triple tube structure for damping a triple tube structure according to any one of claims 1 to 5,
The damper interposed in the divided portion between the intermediate tube frame and the innermost tube frame is configured so that a vertical end surface of the intermediate tube frame located in the divided portion and the innermost tube frame are disposed . A damping system for a triple tube structure, characterized in that it is a horizontal damper that is interposed between a vertical end face of a tube frame and performs horizontal damping. A damping system for a triple tube structure for damping a triple tube structure according to any one of claims 1 to 5,
The damper interposed in the divided portion between the intermediate tube frame and the innermost tube frame includes a horizontal end surface of the intermediate tube frame located in the divided portion and the innermost tube frame. A vertical damper for vibration suppression in the vertical direction, interposed between the horizontal end surface of the tube frame, and the vertical end surface of the intermediate tube frame located in the divided portion and the most A damping system for a triple tube structure, characterized in that it is a horizontal damper for damping in the horizontal direction interposed between the vertical end faces of the inner tube frame.   9. The inner tube frame is divided into at least two in the vertical direction, and a vertical damper for controlling vibration in the vertical direction is interposed in the divided part. The damping system of the triple tube structure of any one of Claims.