JP2005299219A - Damping structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a damping structure capable of preventing the occurrence of a crack in slabs around a boundary beam damper when an earthquake occurs and, at the same time, sufficiently displaying a damping performance of the boundary beam damper. <P>SOLUTION: In the damping structure equipped with the boundary beam damper 4 having a vibration control damper 6 built between adjoining vertical skeletons and concrete encased column base sections 7 covering the end sections of the vibration control damper 6 by being respectively formed so as to oppose them to side sections of the adjoining vertical skeletons 3 and 5 each other, a first slit material 17 is made to intervene between the concrete encased column base section 7 and the concrete-made slabs 12 and 15 formed around the concrete encased column base section 7. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a vibration control structure using a boundary beam damper.

  At present, super-high-rise RC apartment houses are becoming more and more common to have a high ceiling for high quality and a structure that does not project a beam from the ceiling. In order to secure the ceiling height while suppressing the floor height, it is necessary to keep the beam formation small. As one of the solutions, a structure using an RC core wall is generally adopted. By adopting this RC core wall, it is possible to secure the ceiling height while suppressing the floor height, and to create a space with a high degree of freedom.

In recent years, in order to reduce the shaking at the time of earthquake while taking advantage of the RC core wall, a boundary beam type damping damper (boundary beam damper) is installed between the column and the RC core wall or between the RC core walls. Seismic structure is provided. According to this seismic control structure, the bending deformation of the RC core wall is absorbed by the boundary beam damper, and the shaking at the time of the earthquake can be reduced. The boundary beam damper is composed of a vibration control damper spanned between the RC core walls and a root-wrapped concrete part that covers both ends of the vibration control damper, and is deformed up and down according to the bending deformation of the RC core wall. This suppresses shaking (see, for example, Patent Document 1).
JP 2003-90142 A

  However, in the conventional vibration control structure described above, the root-wrapped concrete part and the surrounding concrete slab are integrated, so there is a problem that if the boundary beam damper is deformed when an earthquake occurs, the slab will crack. Exists. In addition, if the root-wrapped concrete part and the surrounding concrete slab are integrated, the boundary beam damper is constrained by the surrounding slab, so that the seismic performance of the boundary beam damper is fully demonstrated. There is a problem that you can not.

  The present invention takes the above-mentioned conventional problems into consideration, and prevents the occurrence of cracks in the slab around the boundary beam damper when an earthquake occurs and sufficiently exhibits the seismic performance of the boundary beam damper. The purpose is to provide a seismic control structure.

The vibration control structure according to the present invention is formed such that the vibration control damper spanned between adjacent vertical frames and the side of the adjacent vertical frame are opposed to each other, and the end portion of the vibration control damper is provided. In the vibration-damping structure provided with the boundary beam damper having the root winding concrete portion to be covered, a first slab is formed between the root winding concrete portion and the concrete slab formed around the root winding concrete portion. A slit material is interposed.
Due to such characteristics, the root-wrapped concrete portion and the slab are cut off by the first slit material.

Further, in the vibration control structure according to the present invention, a second portion extending in a direction orthogonal to the extending direction of the boundary beam damper is provided in an intermediate portion of the slab formed between the opposed wound concrete portions. It is preferable that the slit material is formed.
Thereby, the slab joined to one root-wrapped concrete part and the slab joined to the other root-wrapped concrete part are edge-cut by the second slit material.

  According to the vibration-damping structure of claim 1, since the first slit material is interposed between the root-wrapped concrete portion and the slab formed therearound, the root-wrapped concrete portion and the slab are It is possible to prevent the slab from being cracked when an earthquake occurs. Further, the boundary beam damper can be deformed without being constrained by the slab, and the seismic performance of the boundary beam damper can be sufficiently exhibited.

  According to the vibration control structure of claim 2, the second portion extending in the direction perpendicular to the extending direction of the boundary beam damper is formed in the intermediate portion of the slab formed between the opposing root-wrapped concrete portions. Since the slit material is formed, the slab joined to one root-wrapped concrete part and the slab joined to the other root-wrapped concrete part are edged by the second slit material, and face each other when an earthquake occurs It can prevent that a crack generate | occur | produces in the slab between root wound concrete parts.

  Hereinafter, embodiments of the vibration control structure according to the present invention will be described with reference to the drawings.

  FIG. 1 is a plan view showing a structure 1 such as a super high-rise RC apartment house using an RC core wall 3. The structure 1 includes a vibration control structure 2 according to the present invention, and the vibration control structure 2 includes a boundary beam damper 4. The boundary beam damper 4 is incorporated between adjacent vertical members, and is effectively used as a short span beam in a portion where the span is short. Specifically, it is used as a short span beam that connects the section S sandwiched between the end face of the RC core wall 3 and the side face of the column 5.

  Note that the column 5 and the RC core wall 3 over which the boundary beam damper 4 is bridged are made of reinforced concrete or the like, and a position where the boundary beam damper 4 is provided is provided with a large distance between the main bars in advance. The bars are arranged so that the ends of the dampers 4 are accommodated.

  FIG. 2 is a view of the boundary beam damper 4 as viewed from the side, and shows a basic configuration of the boundary beam damper 4. As shown in FIG. 2, the boundary beam damper 4 is bridged between the adjacent RC core wall 3 and the column 5, and covers the damping damper 6 and both ends of the damping damper 6. It is composed of a reinforced concrete root-wrapped concrete portion 7 and a fixing portion 8 fixed in the RC core wall 3 or the pillar 5. The damping damper 6 is provided with a pair of end members 6a made of high-strength H-shaped steel such as high-strength steel at both ends, and an ultra-soft steel panel 6b at the center. The damping damper 6 has a rectangular rib plate 6c welded to both sides of an opening formed by hollowing out a central web of H-shaped steel, and a very mild steel panel 6b is fitted between the rib plates 6c. It is. The rib plate 6c is formed to have substantially the same width as the upper and lower flanges and substantially the same height as the height between the upper and lower flanges, and the ultra mild steel panel 6b is disposed on the same axis as the webs on both sides. They are joined and integrated so as to be rigid by a fastening means such as welding.

  The ultra mild steel panel 6b of the seismic damper 6 having such a configuration fulfills a function of suppressing the shaking of the structure 1 by causing shear deformation and absorbing energy when an earthquake or the like occurs. The extremely mild steel panel 6b is not particularly limited to extremely mild steel as long as it has a lower yield point than the end member 6a, and a panel made of mild steel or general steel may be used.

  Further, the root-wrapped concrete portion 7 is composed of a main reinforcement 7a, a loose reinforcement 7b, and concrete 7c. The root-wrapped concrete portion 7 is formed so as to face the end surface of the adjacent RC core wall 3 and the side surface of the column 5, respectively, and the boundary between the end member 6a and the ultra mild steel panel 6b in the vibration damper 6 From the position to the side surface of the RC core wall 3 or the pillar 5 is formed. The main reinforcement 7a is arranged in parallel with the vibration control damper 6, but the end of the main reinforcement 7a on the RC core wall 3 side or the column 5 side is disposed so as to fit inside the RC core wall 3 or the column 5. Has been.

  It should be noted that a commonly used steel bar is used for the main reinforcing bar 7a, and fixing tools 9 are attached to both ends, and the length of the main reinforcing bar 7a that fits into the RC core wall 3 or the column 5 is shortened. Further, reinforcing bars (T head reinforcing bars) having enlarged diameter portions at both ends may be used, and the fixing length to the RC core wall 3 or the column 5 may be increased using the long main reinforcing bars 7a. .

  Further, the fixing portion 8 is welded to the end portion of the end member 6a and is disposed on the base plate 8a that is flush with the end surface of the RC core wall 3 or the side surface of the column 5, and in the RC core wall 3 or the column. 5 has a structure in which a plurality of anchor members 8b embedded in the projection are provided. Note that the fixing portion 8 may be omitted by embedding and fixing the end portion of the end member 6a of the vibration damping damper 6 in the RC core wall 3 or the column 5.

  3 is a cross-sectional view taken along the line AA shown in FIG. 2, and FIG. 4 is a view showing the upper surface of the vibration control structure according to the present invention. As shown in FIGS. 2, 3, and 4, slabs 12 and 15 are formed on both sides of the boundary beam damper 4, and a perforated PC floor slab 10 is formed on one side of the boundary beam damper 4. A first slab 12 having a reinforced concrete floor slab 11 formed thereon is provided, and a reinforced concrete floor slab 14 is formed on a deck plate 13 on the other side of the boundary beam damper 4. Two slabs 15 are provided. In addition, a third slab 16 made of reinforced concrete is provided between the opposing root-wrapped concrete portions 7. The third slab 16 is in a state of being bridged between the root-wrapped concrete portions 7 facing above the central portion of the vibration damper 6, and the lower surface of the third slab 16 and the central portion of the vibration damper 6. A gap is formed between the upper flange surface. Further, the upper surfaces of the first, second and third slabs 12, 15 and 16 are formed substantially flush with the upper surface of the root-wrapped concrete portion 7, respectively.

  As shown in FIGS. 3 and 4, between the first and second slabs 12, 15 and the root-wrapped concrete portion 7, a strip-shaped first extending from the end surface of the RC core wall 3 to the side surface of the column 5. One slit member 17 is interposed. One first slit member 17 a provided between the first slab 12 and the root-wrapped concrete portion 7 is interposed between the end surface of the first slab 12 and the side surface of the root-wrapped concrete portion 7. The reinforced concrete floor slab 11 and the root-wrapped concrete portion 7 are completely separated. The other first slit member 17 b provided between the second slab 15 and the root-wrapped concrete portion 7 is interposed between the upper part of the reinforced concrete floor slab 14 and the side surface of the root-wrapped concrete portion 7. The lower part of the reinforced concrete floor slab 14 is formed integrally with the root wound concrete part 7, and a cut is made between the upper part of the reinforced concrete floor slab 14 and the root wound concrete part 7.

  As shown in FIGS. 2 and 4, a second slit member 18 extending in a direction orthogonal to the extending direction of the boundary beam damper 4 is formed at the center of the third slab 16. The third slab 16 includes one third slab 16a joined to the RC core wall 3 side rooted concrete portion 7 and the pillar 5 side rooted concrete portion with the second slit member 18 interposed therebetween. 7, and the other third slab 16 b joined to 7. The second slit member 18 is a belt-like member extending from one first slit member 17a to the other first slit member 17b, and completely divides the third slab 16 in the middle. .

  The first and second slit members 17 and 18 absorb the bending deformation of the boundary beam damper 4 transmitted from the root-wrapped concrete portion 7 and prevent the first, second, and third slabs 12, 15, and 16 from being damaged. For example, foamed polyethylene. Further, in order to prevent water leakage from the first and second slit members 17 and 18, a sealing 19 is covered on the first and second slit members 17 and 18.

  The first and second slit members 17 and 18 are respectively set at predetermined positions before placing the concrete of the first, second and third slabs 12, 15 and 16 and the root winding concrete portion 7. The first, second and third slabs 12, 15, 16 are embedded in the concrete of the root-wrapped concrete portion 7 and are sealed on the first and second slit members 17, 18 after placing the concrete. 19 is applied.

  According to the vibration control structure 2 having the above-described configuration, the first slit member 17 is interposed between the root-wrapped concrete portion and the first and second slabs 12 and 15 formed therearound. Therefore, the root-wrapped concrete portion 7 and the first and second slabs 12 and 15 are cut off, and it is possible to prevent the first and second slabs 12 and 15 from cracking when an earthquake occurs. . Further, the boundary beam damper 4 can be deformed without being constrained by the first and second slabs 12 and 15, and the seismic performance of the boundary beam damper 4 can be sufficiently exhibited.

  In addition, a second slit member 18 extending in a direction orthogonal to the extending direction of the boundary beam damper 4 is formed in the center portion of the third slab 16 formed between the opposing root-wrapped concrete portions 7. Therefore, one third slab 16a and the other third slab 16b are bordered by the second slit material 18, and the third slab 16 between the opposing root-wrapped concrete portions 7 when an earthquake occurs. It is possible to prevent cracks from occurring.

  As mentioned above, although embodiment of the damping structure which concerns on this invention was described, this invention is not limited to above-described embodiment, In the range which does not deviate from the meaning, it can change suitably. For example, in the above-described embodiment, the first slit member 17 extends from the end surface of the RC core wall 3 to the side surface of the column 5, and is formed on the third slab 16 between the opposing root-wrapped concrete portions 7. Although the second slit member 18 is formed, the present invention forms the first slit member 17 in a U-shape so as to surround the side surface and the front end surface of the root-wrapped concrete portion 7, and the second slit member 18 is formed. The material may be omitted.

  Further, in the above-described embodiment, the second slit member 18 is formed in the central portion of the third slab 16 formed between the opposing root-wrapped concrete portions 7. The slit material of 2 may be formed in the position shifted | deviated from the center position between the root winding concrete parts which oppose.

1 is an overall plan view for explaining an embodiment of a vibration control structure according to the present invention. It is a sectional side view for demonstrating embodiment of the damping structure which concerns on this invention. It is sectional drawing for demonstrating embodiment of the damping structure which concerns on this invention. It is a top view for demonstrating embodiment of the damping structure which concerns on this invention.

Explanation of symbols

3 Core wall (vertical enclosure)
5 pillars (vertical frame)
6 Damping damper 7 Necked concrete part 4 Boundary beam damper 2 Damping structure 12 First slab (slab)
15 Second slab (slab)
16 Third slab (slab)
17 1st slit material 18 2nd slit material

Claims (2)

A boundary having a vibration control damper spanned between adjacent vertical frames, and a root-wrapped concrete part that is formed so as to face each other on the side part of the adjacent vertical frame and covers the end of the vibration control damper In the vibration control structure equipped with beam dampers,
A damping structure, wherein a first slit member is interposed between the root-wrapped concrete portion and a concrete slab formed around the root-wrapped concrete portion. In the vibration control structure according to claim 1,
A second slit member extending in a direction orthogonal to the extending direction of the boundary beam damper is formed in an intermediate portion of the slab formed between the opposing root-wrapped concrete portions. The vibration control structure.

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