KR20100089258A - Isolation building structure - Google Patents

Abstract

PURPOSE: A seismic isolation architectural construction, which has a seismic isolation system between an upper body and a lower body, is provided to reduce construction costs by increasing the isolation performance of a seismic isolation system. CONSTITUTION: A seismic isolation architectural construction comprises a top body(B2), a lower body(B1) and a seismic isolator. The seismic isolator is located between the top body and lower body. The seismic isolator is composed of a seismic isolation device body and a connection block. The connection block is integrally installed on the top of the seismic isolation device body. The connection block mounts a pillar(4) and a beam(5) of a building structure.

Description

Isolation building structure {ISOLATION BUILDING STRUCTURE}

The present invention relates to an isolating building structure in which an isolating device is interposed between an upper body and a lower body.

In recent years, the concept of buildings resistant to earthquakes has changed from earthquake to seismic isolation. In response to the seismic structure, the cross section of the pillar or the beam is increased or a member having a higher strength is used to increase the building rigidity and strength. When the construction period also becomes longer, in the case of the above-described base isolation structure, a base isolation device (for example, registered Japanese Utility Model No. 3021447 and Japanese Patent No. 2636950) is used between the upper body and the lower body. ), The seismic energy can be absorbed and relaxed by the seismic isolator, so that the member of the body (upper body) does not have to be made larger than necessary compared with the seismic structure. The advantage which becomes possible is mentioned.

Conventionally, as this kind of building structure which can be constructed in a short construction period, a reinforced structure, a steel pipe concrete structure, etc. are mentioned, for example.

According to the conventional structure described above, it is possible to shorten the construction period. However, when the built-in seismic isolator is incorporated, since the upper body is a soft structure, the upper body also fluctuates due to an earthquake, so There is a problem that it is difficult to sufficiently exhibit the seismic force absorption performance.

In order to solve this problem, for example, the rubber material of the seismic isolation device itself is further softened, the rubber thickness is increased, and the countermeasure (hereinafter referred to as the first countermeasure) which improves the left and right oscillation property more or the upper part, The countermeasure (henceforth a 2nd countermeasure) which adds rigidity by increasing a wall part and a support | pillar to a body, or enlarges the member cross section of a body can be considered.

However, according to the first countermeasure, the seismic isolator itself is expensive, and as the deformability of the isolator improves, the building support tends to become unstable, and consequently, the section of the seismic isolator is increased. Since it must be, there is a problem that also becomes expensive.

On the other hand, according to the said 2nd countermeasure, the freedom of the use compartment in a building falls, and there exists a problem which is easy to deteriorate usability.

Accordingly, an object of the present invention is to easily solve the above problems and maintain the advantage that construction can be carried out in a short construction period, while further exhibiting the seismic isolation performance of the seismic isolation device, so that the seismic isolation structure can be constructed at low cost. To provide.

As for the characteristic structure of Claim 1, as shown in FIG. 1, in the base isolation building structure in which the base isolation apparatus 1 is interposed between the upper body B2 and the lower body B1, the upper body B2 Is connected to the pillar part 4 and the beam part 5 by the tension of the long body 4a for prestress introduction, and the said base isolation device is a base of the base isolation apparatus main body. The connecting block is formed integrally with the upper portion, and at the same time, the mounting block is provided with a mounting portion capable of mounting a beam end disposed on the side thereof, and the lowermost beam portion of the upper body is connected to the connecting block. It is connected with the said connection block by tension of the elongate body for prestress introduction in the state which mounted the beam edge part on the said mounting part of a block.

1 and 2, the pillar structure and the beam part of the said upper body are comprised from the precast concrete, and the beam part can be equipped with the beam edge part, The characteristic structure of Claim 2 is shown. The mounting portion is provided, and the beam end is mounted on the mounting portion of the pillar portion.

The characteristic structure of this invention of Claim 3 is that the said beam part 5 is prestressed concrete, as shown in FIG.

And as mentioned above, although the code | symbol was described in order to make contrast with a drawing easy, this invention is not limited to the structure of an accompanying drawing by the said description.

According to the characteristic structure of Claim 1, since the said upper body connects the pillar part and the beam part by the tension | tensile_strength of the prestress introduction body, the rigidity as an upper body becomes high, and the upper body according to an earthquake It is possible to suppress the deformation of and to exert the seismic isolation action of the seismic isolator more efficiently.

Therefore, it is not necessary to upgrade the base isolation device more than necessary, and it is also possible to prevent cost increase.

Moreover, since both can be connected by the tension operation of the said elongate body over a pillar part and a beam part, it becomes possible to perform a connection work efficiently.

As a result, it is possible to further improve the speed and economics of the construction.

According to the characteristic constitution of the invention of claim 2, the effect of the invention according to the invention of claim 1 can be realized, and in addition, since the beam part is precast concrete, the frame construction and the backing work in the field are formed to form a beam. The beam part can be attached to a pillar part as it is, even if it does not carry out concrete pouring construction etc., and it becomes possible to perform the formation work of an upper body efficiently.

In addition, it is possible to make the beam part with high quality stability by factory production.

According to the characteristic constitution of the invention of claim 3, the effect of the invention according to claim 1 or 2 can be realized. In addition, since the beam part is prestressed concrete, the beam part of a long span is formed, or the beam Since the negative member cross-sectional area can be made small and a wider indoor space can be ensured, it becomes possible to make a building with high usability and functionality.

In addition, mechanically, the rigidity of the upper body can be further increased, and the seismic isolating effect of the seismic isolator can be more efficiently exhibited.

EMBODIMENT OF THE INVENTION Below, the Example of this invention is described with reference to drawings. In the drawings, parts denoted by the same reference numerals as those in the prior art indicate the same or equivalent parts.

Fig. 1 shows a building B formed by applying the base isolated building structure of the present invention. The building B is provided with a plurality of independent foundations (equivalent to the lower body) B1 on the foundation ground G portion where the ground is improved, and the seismic isolation device 1 is installed on these independent foundations B1. A plurality of hierarchical building structures (corresponding to the upper body) B2 are formed through the structure.

As shown in FIG. 2, the said independent base B1 is made of reinforced concrete, and the metal lower plate 2 for mounting the said base isolation device 1 is integrally provided in the upper surface. In this lower plate 2, the bag nut 2b is fixed separately to the lower surface side in accordance with the plurality of bolt insertion holes and holes 2a and the respective bolt insertion holes and holes 2a. Therefore, in the state where the base isolation device 1 is mounted on the lower plate 2, the fixing bolt 3 is screwed to the bag nut 2b through the base isolation device 1 and the bolt insertion hole 2a. By doing so, the base isolation device 1 can be fixed to the independent base B1.

The seismic isolator 1 is integrally provided with the seismic isolator main body 1A and its upper portion, and the connection block 1B to which the pillar part 4 and the beam part 5 of the building structure part B2 can be mounted. ) However, the integration of the base isolation device main body 1A and the connection block 1B may be performed at the time of installation or at the time of installation.

The base isolation device 1A is formed by alternately stacking a metal thin plate 1a and a rubber thin plate 1b so as to be integrally formed, and the respective thin plates 1a and 1b are formed so as to be capable of interlayer displacement in the horizontal direction. As a result, it is configured to follow the resistive movement of the independent foundation B1 and the building structure portion B2 in the horizontal direction, and to exhibit a seismic isolation effect. In the center portions of the thin plates 1a and 1b, a soft rod-like body 1c is provided in a state that penetrates each of the thin plates 1a and 1b. It is comprised so that the damper effect on the interlayer displacement of 1b) can be exhibited more.

Moreover, the metal plate 1d of larger diameter than the main-body part is integrally provided in the upper and lower end surface part of 1 A of isolation | separation isolation | separation apparatus main bodies, and this metal plate 1d also passes through each bolt insertion of the said lower plate 2. Like the hole 2a, the bolt insertion hole and the hole are formed in the corresponding position, respectively.

The connecting block 1B is made of reinforced concrete, and a metal upper plate 6 for connecting with the base isolation device main body 1A is integrally provided on the lower surface thereof. This upper plate 6 is also formed in the same configuration as the lower plate 2, and is arranged in a reverse rotation state of the lower plate 2. Then, the base isolation device main assembly 1A and the upper plate 6 are bolted together to achieve integration.

In addition, as described above, the connection block 1B is provided with a pillar mounting portion 7 for mounting the pillar portion 4 of the building structure portion B2 and a beam mounting portion 8 for mounting the beam portion 5. It is.

The pillar mounting portion 7 includes a plurality of PC steel bars 7a embedded in the connection block 1B. Each of the PC steel bars 7a is embedded in the state where the distal end protrudes upward from the connection block 1B, so that the PC steel bars 7a and the coupler 9 are inserted into the filler portions 4 arranged above. It is formed to be connected by. Further, the proximal end of the PC steel bar 7a is formed in a collar shape for securing reaction force due to PC steel bar tension. A plurality of spiral reinforcing bars 7b for reinforcing concrete are embedded around the base end of the PC steel bar 7a in the connection block 1B.

Therefore, while connecting the PC steel bar 4a of the filler part 4 to the PC steel bar 7a of the connection block 1B, the lower end part of the said filler part 4 is located on the connection block 1B. By installing and tensioning the PC steel bar 7a, it is possible to firmly connect the base isolation device 1 and the filler portion 4.

On the other hand, the beam mounting portion 8 includes a beam end mounting end 8a formed on the side of the connecting block 1B and a plurality of PC steel wire insertion sheaths embedded in the connecting block 1B ( Sheath) 8b is provided.

Moreover, the beam part 5 is comprised from the precast member made from prestressed concrete, and the sheath 5a which the PC steel wire used for connection with the said connection block 1B and the filler part 4 can pass through. ) Is embedded in a position corresponding to the opening of the sheath 8b of the beam mounting portion 8.

Moreover, the filler part 4 is also comprised by the precast member, and it is a structure which makes the PC steel bar 4a penetrate and tensions in the up-down direction as mentioned above, and at the side part of the beam mounting predetermined position, Similarly to the connection block 1B, the beam end mounting end 4b is provided separately (see FIG. 1). Moreover, the sheath 4c which can pass through the PC steel wire used for connection with the beam part 5 is embedded in the position corresponding to the opening of the sheath 5a of the beam part 5 mounted on each edge part 4b. It is.

Therefore, in the state which mounted the edge part of the beam part 5 on the said end part 8a, the base isolation apparatus 1 and the beam part are fixed by inserting a PC steel wire in the state which was tensioned by inserting the PC steel wire into mutual sheath 5a and 8b. It becomes possible to connect (5) firmly.

In addition, also regarding the connection of the pillar part 4 and the beam part 5, the sheath 4c of each other and the state of having mounted the edge part of the beam part 5 on the edge part 4b of the pillar part 4 similarly By inserting a PC steel wire (corresponding to a prestressed elongated body) into the tensioned state in (5a), the pillar portion 4 and the beam portion 5 can be firmly connected.

And the lower end part of the filler part 4 is provided with the plinth block 4d formed separately from the filler main body, and corrects the height of this plinth block 4d, and the precision of the filler part side is corrected. It is configured to secure. Moreover, the sheath 4c for tension-connecting the beam part 5 by PC steel wire is formed also in this pillar block 4d, and is fixed according to the connection method of the pillar part 4 and the beam part 5.

Therefore, according to the base isolation building structure of the above embodiment, it is a building in which the base isolation device 1 is installed, and the base isolation building is formed in a short construction period only by efficiently building the building structure part B2 on the base isolation device 1 in order. At the same time, the rigidity of the building structural unit B2 can be ensured to be high, and the seismic isolation performance of the base isolation device 1 can be more efficiently exhibited.

Another embodiment is described below.

(1) The upper body is not limited to the beam portion of the prestressed concrete structure and the precast pillar portion described in the previous embodiment, and is not limited to the pillar portion of the site casting, the pillar portion of the steel pipe concrete, or the simple precast portion. The structure which combined the beam part etc. may be sufficient, In other words, what is necessary is just to connect the pillar part 4 and the beam part 5 by the tension of the elongate body 4a for prestress introduction.

(2) The long prestress for introducing the prestress is not limited to the PC steel wire described in the above embodiments, and may be, for example, a PC steel bar.

(3) The lower body is not limited to the independent foundation described in the above embodiments, and, for example, in a building in which a seismic isolator is installed in the middle stairway, each of the hierarchical portions below the seismic isolator is provided to the lower body. Corresponding. In short, the body which continues downward from the base isolation apparatus is called a lower body. In addition, the upper body is similarly called an upper body than the isolation device in the isolation device installation hierarchy.

(4) The said base isolation apparatus main body laminate | stacks the metal thin plate 1a and the rubber thin plate 1b which were demonstrated in the previous Example, and built the damper of the soft rod-shaped body 1c in the center shaft part. It is not limited to the one of the type | mold which was made, but the base isolation apparatus main body of the type without the said rod-shaped body 1c may be sufficient. In addition, a seismic isolator main body of the type which combines an oil damper, a metal damper, and a support may be sufficient, and these are collectively called a seismic isolation device main body.

Moreover, in addition to configuring a base isolation apparatus with the base isolation apparatus main body and a connection block, you may comprise an base isolation apparatus by the unit of a base isolation apparatus main body.

1 is a cross-sectional view seen from the side of a building.

2 is an exploded cross-sectional view showing an isolated part of the building.

Claims (3)

As a base isolation building structure in which a base isolation device is interposed between an upper body and a lower body, The upper body connects the pillar portion and the beam portion by tension of a long body for prestress introduction, and the seismic isolation device is integrally connected to the upper portion of the base isolation body. And a mounting portion capable of mounting a beam end disposed on the side of the connecting block, and the lowermost beam portion of the upper body is formed on the mounting portion of the connecting block. The base-building structure which is connected with the said connection block by tension of the elongate body for prestress introduction in the state which mounted the beam edge part. The method of claim 1, The pillar portion and the beam portion of the upper body are made of precast concrete, and the pillar portion is provided with a mount portion for mounting the beam end portion, and the beam end portion is mounted on the pillar portion of the pillar portion. , Seismic building structure. The method according to claim 1 or 2, And the beam portion is prestressed concrete.

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