JP2002013196A - Self-base isolation method and self-base isolation structure for rc structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a self-base isolation method and a self-base isolation structure for an RC(reinforced concrete) structure capable of controlling the maximum horizontal displacement assumed at an earthquake by introducing a technology for bonding the fixed length portion of an unbonded PC(prestressed concrete) steel product to a precast concrete beam, and increasing the horizontal rigidity after the floating-up of the beam. SOLUTION: The unbonded PC steel product is made to penetrate the precast concrete beam in the longitudinal direction, and both end sections of the unbonded PC steel product are fixed to a precast concrete column. The fixed length portion of the unbonded PC steel product is bonded to the precast concrete beam to control the horizontal displacement caused by the floating-up of the beam.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an unbonded PC.
Prestress is introduced by using steel material, and precast concrete beams (hereinafter sometimes abbreviated as beams) are converted into precast concrete columns (hereinafter sometimes abbreviated as columns).
It belongs to the technical field of self-isolation structure method and self-isolation structure of RC structure bonded by crimping, and more specifically, by controlling the horizontal rigidity of RC structure, the horizontal displacement of the beam after floating is controlled. Self-isolation construction method and self-isolation structure.

[0002]

2. Description of the Related Art A self-isolating structure of an RC structure in which a precast concrete beam is crimped to a precast concrete column by introducing a prestress using an unbonded PC steel material is a so-called horizontal force of an earthquake or the like. This structure changes the horizontal rigidity of the RC structure by lifting the beam according to the size.

That is, the self-isolation structure of the RC structure has a horizontal rigidity equivalent to that of a general RC structure in a normal state, and a horizontal rigidity is reduced by lifting a beam in a large earthquake. As a result, the earthquake input is reduced, so that it is possible to provide a structure that is resistant to microvibration and excellent in habitability.

[0004]

Depending on the use and importance of a building, it may be necessary to control the maximum horizontal displacement expected during an earthquake. In particular, the demand is high in cities where buildings are in forest. The maximum horizontal displacement of the self-isolation structure of the RC structure largely depends on the horizontal rigidity of the beam after lifting.

Therefore, when the self-isolation structure of the RC structure is implemented in a place where the maximum horizontal displacement of the building must be controlled, a technique for controlling (increasing) the horizontal rigidity after the beam is lifted up. Need to be introduced.

However, in the current self-isolation structure of RC-based structures, there has not yet been proposed a technique for increasing the horizontal rigidity after the beams are lifted and controlling the maximum horizontal displacement assumed during an earthquake.

[0007] Accordingly, an object of the present invention is to be assumed during an earthquake by introducing a technique of bonding a fixed length portion of unbonded PC steel to a precast concrete beam to increase the horizontal rigidity after the beam rises. An object of the present invention is to provide a self-isolation structure and a self-isolation structure of an RC structure capable of controlling a maximum horizontal displacement.

[0008]

As means for solving the above-mentioned problems, an RC according to the first aspect of the present invention is provided.
The self-seismic isolation method for RC structures is a self-isolation isolation method for RC structures in which precast concrete beams are prestressed by using unbonded PC steel and crimped to precast concrete columns. The unbonded PC steel is penetrated in the longitudinal direction of the beam, and both ends of the unbonded PC steel are fixed to the precast concrete column, and the unbonded PC steel is fixed.
It is characterized in that a fixed length portion of the C steel material is bonded to the precast concrete beam and horizontal displacement accompanying the lifting of the beam is controlled.

According to a second aspect of the present invention, there is provided the self-isolating system for RC structures according to the first aspect, wherein a grout injection pipe is provided in the precast concrete beam, and at least two packings are mounted on the PC steel material. In addition, grout is injected and filled from the grout injection pipe between the two packings, and a portion between the two packings of the unbonded PC steel is bonded to a precast concrete beam. .

According to a third aspect of the present invention, in the self-isolation method for an RC structure according to the first aspect, the tubular container integrated with the grout injection pipe in a form surrounding the PC steel material is formed into a precast concrete beam. It is characterized in that grout is injected and filled from the grout injection pipe, and the tubular container portion of the unbonded PC steel is bonded to a precast concrete beam.

[0011] The self-isolating structure for an RC structure according to the invention described in claim 4 is characterized in that:
A self-isolating structure of an RC-based structure in which a prestress is introduced using an unbonded PC steel material and pressure-bonded to a precast concrete column, the unbonded PC steel material is penetrated in a longitudinal direction of the precast concrete beam,
Both ends of the unbonded PC steel material are fixed to the precast concrete column, and a fixed length portion of the unbonded PC steel material is bonded to the precast concrete beam to control a horizontal displacement caused by lifting of the beam. It is characterized by the following.

[0012]

1 and 3 show an embodiment of a self-isolation structure method and a self-isolation structure of an RC structure according to the first and fourth aspects of the present invention.

In the self-isolation method for RC structures, a prestressed precast concrete beam 2 is bonded to a precast concrete column 1 by introducing prestress using an unbonded PC steel material 3.

That is, the precast concrete beam 2
The unbonded PC steel material 3 is made to penetrate in the longitudinal direction of the unbonded PC steel material 3, and both ends 3a, 3a of the unbonded PC steel material 3 are fixed to the precast concrete columns 1, 1, and a fixed length portion X of the unbonded PC steel material 3 is fixed. The present invention is characterized in that it is bonded to the precast concrete beam 2 to control the horizontal displacement accompanying the lifting of the beam 2 (the invention according to claim 1).

In the self-isolation structure of the RC structure constructed by the self-isolation structure method, a precast concrete beam 2 is crimped to a precast concrete column 1 by introducing prestress using unbonded PC steel 3. Structure.

That is, the precast concrete beam 2
The unbonded PC steel material 3 is penetrated in the longitudinal direction of the unbonded PC steel material 3, both ends 3a, 3a of the unbonded PC steel material 3 are fixed to the precast concrete columns 1, 1, and a fixed length portion X of the unbonded PC steel material 3 is precast. The present invention is characterized in that it is bonded to the concrete beam 2 so as to control the horizontal displacement accompanying the lifting of the beam 2 (the invention according to claim 4). Incidentally, reference numeral 4 in the drawing indicates a sheath, and reference numeral 7 indicates grout.

Specifically, as shown in FIGS.
A grout injection pipe 8 for injecting a grout 7 into the precast concrete beam 2 is provided, and at least two packings 6, 6 are mounted on the PC steel member 3 with a space X required for obtaining a required horizontal rigidity. , The two packings 6,
6, grout 7 is injected and filled from a grout injection pipe 8 to bond a portion X between the two packings 6, 6 of the unbonded PC steel material 3 to the precast concrete beam 2 (claim 2). Invention). Although not shown, the PC steel member 3 is provided with a positioning stopper for preventing the packing 6 from shearing.

In this embodiment, the PC steel material 3 is 7
A strand 3 of PC steel is used. As the packing 6, a lotus root-shaped rubber packing 6 provided with a through hole 6a through which the seven PC strands 3 pass is used. The grout injection pipe 8 may be previously formed in the precast concrete beam 2 by injection molding, or may be newly provided at the stage of injecting the grout 7.

It should be noted that instead of the above-mentioned PC steel strand 3, PC
It can be carried out in substantially the same manner using a steel rod, a PC steel wire, or a multilayer PC steel stranded wire. Of course, in that case, the through hole 6a of the packing 6 is formed in a shape corresponding to the PC steel bar or the like.

The PC steel material (PC steel stranded wire) 3 is laid in a straight line while being concentrated substantially at the center of the precast concrete beam 2, but the arrangement and the number are not limited to this. The PC steel strand 3 may be bent in an arch shape. In short, the unbonded PC steel 3
Any shape may be used as long as both ends 3a, 3a protrude from both end surfaces of the precast concrete beam 2, and the shape of the portion built into the beam 2 can be implemented in a flexible form.

The method of fixing the end portion 3a of the unbonded PC steel material 3 to the precast concrete column 1 is not particularly novel, and is performed by a method specified in the PC standard of the Architectural Institute of Japan. In this embodiment, since the PC steel strand 3 is used as the unbonded PC steel material 3,
It is fixed by a nut and a support plate using a copper wedge (not shown).

As shown in FIG. 1, both end portions 3a, 3a of the unbonded PC steel material 3 penetrate the opposite side surface of the precast concrete column 1 and are fixed on the back side thereof. Not done. It is also possible to provide a non-through hole in the column 1 and fix the column 1 at an intermediate position.

As described above, the unbonded PC steel material 3 has a substantially central fixed length portion X bonded to the precast concrete beam 2, and both ends 3a, 3a of which are fastened to the columns 1, 1. . Therefore, R according to the present invention
Normally, the self-isolation structure of the C-based structure has a horizontal rigidity equivalent to that of a general RC-based structure because prestress is introduced and the end face of the beam 2 is in close contact with the side surface of the column 1. Have. Further, during a large earthquake, the horizontal rigidity is reduced due to the lifting of the beam 2, and the self-isolation function is exhibited. Can be increased, and as a result, the maximum horizontal displacement of the RC-based structure can be controlled.

The reason why the horizontal rigidity is increased when the fixed length portion X of the unbonded PC steel material 3 is bonded to the precast concrete beam 2 will be described below. The horizontal stiffness after the lifting is based on the following [Equation 1] based on FIGS. 7A and 7B.
_Is uniquely determined from I _eff shown by

(Equation 1) I _eff : Equivalent second moment of area when joint interface is lifted up M _θ : Moment when joint interface rotation angle is θ l: Span length θ: Node rotation angle E _c : Young's modulus of beam concrete D: sei Ryo a _p: sectional area of PC steel E _p: Young's modulus of the PC steel P _o: initial tension of PC steel L _p: PC unbonded length per joint interface one place of steel

[0025] Therefore, if shortening the length of the L _p, i.e., if the predetermined length portion X of the unbonded PC steel material 3 short overall unbonded lengths and bond to the precast concrete beam 2, inevitably Therefore, the horizontal stiffness of the self-isolated structure after lifting will increase.

The bond length (constant length portion X) in the unbonded PC steel material 3 is set to a necessary length in structural design based on the above [Equation 1]. In this case, it is preferable to bond the substantially central portion in consideration of the balance of the entire structure.

Therefore, according to the self-isolation structure and the self-isolation structure of the RC structure according to the present embodiment, grouting of the PC steel material 3 at an arbitrary position and at an arbitrary length can be easily performed. A fixed length portion X of the unbonded PC steel material 3 can be simply and reliably bonded to the precast concrete beam 2. Therefore, precast concrete beam 2
The horizontal rigidity of the RC structure after floating can be increased flexibly, and as a result, the maximum horizontal displacement of the RC structure can be freely controlled.

8 to 10 show different embodiments. This embodiment is different from the above-described embodiment in a method of bonding a fixed length portion X of the unbonded PC steel material 3 to the precast concrete beam 2.

That is, a cylindrical container 9 integrated with a grout injection pipe 9a is provided in the precast concrete beam 2 so as to surround the PC steel material 3, and grout 7 is injected and filled from the grout injection pipe 9a. The tubular container portion of the unbonded PC steel material 3 is bonded to the precast concrete beam 2 (the invention according to claim 3).

As the PC steel material 3, a PC steel rod 3 is preferably used. The cylindrical container 9 is a stretchable container having a hollow loupe (FIG. 9A) in longitudinal section and implemented in the form of a tube (FIG. 9B) in the longitudinal direction of the precast concrete beam 2. The length in the longitudinal direction of the cylindrical container 9 is set to a length capable of exhibiting a required horizontal rigidity in structural design. Further, the cylindrical container 9 is previously formed by being driven into the precast concrete beam 2. The cylindrical container 9
The shape of the surrounding portion of the PC steel material 3 is not limited to an annular shape. As shown in FIG. 11, the present invention can be implemented in substantially the same manner even in a shape in which an annular part is cut out.

Therefore, according to the self-isolation structure method and the self-isolation structure of the RC structure according to the different embodiment, substantially the same operation and effects as those of the above embodiment can be obtained. That is, PC
Since grout having an arbitrary length can be easily injected into the steel material 3 at an arbitrary position, the fixed length portion X of the unbonded PC steel material 3 can be easily and reliably bonded to the precast concrete beam 2. Therefore, the horizontal rigidity of the precast concrete beam 2 after lifting can be flexibly increased, and as a result, the maximum horizontal displacement of the RC structure can be freely controlled.

In each of the above-described embodiments, one span corresponds to one
Although the present embodiment is performed using one PC steel material 3, the present invention can be implemented using one PC steel material 3 in multiple spans.

[0033]

According to the self-isolation structure method and the self-isolation structure of the RC structure described in claims 1 to 4, the PC
Since local grout of an arbitrary length can be easily injected into the steel material at an arbitrary position, a fixed length portion of the unbonded PC steel can be easily and reliably bonded to the precast concrete beam. Therefore, the horizontal rigidity of the precast concrete beam after lifting can be flexibly increased, and as a result, the maximum horizontal displacement of the RC structure can be freely controlled. Therefore, the present invention can be suitably implemented even in a place where the maximum horizontal displacement expected during an earthquake must be controlled, such as in a city where buildings stand in a forest.

[Brief description of the drawings]

FIG. 1 is an elevation view showing a self-isolating structure of an RC-based structure according to the present invention.

FIG. 2 is a longitudinal sectional view of a precast concrete beam.

FIG. 3 is an elevational view showing a floating state of the self-isolation structure of the RC structure according to the present invention.

FIG. 4 is a cross-sectional view showing a state in which a fixed length portion of unbonded PC steel is bonded to a precast concrete beam.

FIG. 5 is a front view showing the shape of the packing.

FIG. 6 is a cross-sectional view showing a state in which a fixed length portion of unbonded PC steel is bonded to a precast concrete beam by grout.

FIG. 7A is an elevation view schematically showing a self-isolation structure of an RC-based structure, and FIG. 7B is an enlarged view showing a column-to-beam joint of A.

FIG. 8 is a longitudinal sectional view of a precast concrete beam showing a different embodiment.

FIG. 9A is a front view showing a cylindrical container used in different embodiments, and FIG. 9B is a side view thereof.

FIG. 10 is a cross-sectional view showing a state in which a fixed length portion of unbonded PC steel is bonded to a precast concrete beam by grout.

FIG. 11 is a front view showing the shape of a different cylindrical container.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Precast concrete column 2 Precast concrete beam 3 Unbonded PC steel 4 Sheath 6 Packing 7 Grout 8 Grout injection pipe 9 Cylindrical container

 ────────────────────────────────────────────────── ─── Continuing from the front page (72) Inventor Yoshihiro Ota 1-5-1, Otsuka, Inzai City, Chiba Prefecture F-term in Takenaka Corporation Technical Research Institute (reference) 2E001 DG01 DG02 EA03 FA01 FA02 GA62 GA63 GA77 HA01 HA06 HB01 KA05 LA09 LA11 2E163 FA02 FA12 FD03 FD25 FD34

Claims (4)

[Claims] The present invention relates to a self-isolation method for an RC structure in which a prestressed precast concrete beam is bonded to a precast concrete column by introducing a prestress using an unbonded PC steel, The unbonded PC steel material is penetrated, and both ends of the unbonded PC steel material are fixed to the precast concrete column, and a fixed length portion of the unbonded PC steel material is bonded to the precast concrete beam. RC characterized by controlling horizontal displacement
Self-isolation method for system structures. 2. A grout injection pipe is provided on a precast concrete beam, at least two packings are mounted on a PC steel material, and grout is injected and filled from the grout injection pipe between the two packings. Unbond PC
2. The method according to claim 1, wherein a portion of the steel material between the two packings is bonded to a precast concrete beam.
Self-isolation structure method for RC-type structures described in (1). 3. A precast concrete beam is provided with a cylindrical container integrated with a grout injection pipe so as to surround the PC steel material, and grout is injected and filled from the grout injection pipe to form the cylinder of the unbonded PC steel material. The self-isolating method for an RC-based structure according to claim 1, wherein the container portion is bonded to a precast concrete beam. 4. A self-isolation structure of an RC structure in which a prestressed precast concrete beam is press-bonded to a precast concrete column by introducing a prestress using an unbonded PC steel material, wherein a longitudinal direction of the precast concrete beam is provided. The unbonded PC steel material is penetrated, both ends of the unbonded PC steel material are fixed to the precast concrete column, a fixed length portion of the unbonded PC steel material is bonded to the precast concrete beam, and the horizontal displacement accompanying the lifting of the beam is performed. A self-isolating structure of RC structure, characterized in that the structure is controlled.