JPH07286451A - Earthquake resisting wall - Google Patents

Abstract

PURPOSE:To save the labor for the assembling work of an earthquake resisting wall to a skeleton and provide a satisfactory earthquake resisting structure. CONSTITUTION:A PC steel bar 3 is arranged in the diagonal direction of a wall body 2 consisting of a precast board. A fastening force is preliminarily imparted to the PC steel bar 3, whereby a compressive prestress is introduced into the wall body 2. The wall body 2 is arranged in a prescribed position of a skeleton, a column 11, a beam 13, and a slab 14 are constructed by arranging reinforcements and placing concrete, and the circumference of the wall body 2 having a cotter 7 and a shear reinforcement 8 provided thereon is buried in the lower ends of the column 11 and the beam and the top end of the stab 14, and integrated thereto.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic wall which is assembled to a frame to reduce the load acting on the frame.

[0002]

2. Description of the Related Art Currently, a precast plate having a steel brace built therein is used as a seismic wall. And when assembling this type of precast plate, the end of the brace built in this precast plate is welded and fixed to the steel frame of the pillar, beam, and slab in situ, and then the pillar, beam, and slab are Build by and fix the precast version.

[0003]

By using the precast plate as an earthquake-resistant wall as described above, it is possible to save work in the field, but the brace built into the precast plate requires accuracy. It took a lot of time and effort to produce the precast version itself. Further, when the precast plate is assembled to the body, the end of the brace must be surely welded to the body, and therefore, there is a problem that the work and welding management on site are still complicated.

The present invention has been made in view of the above circumstances, and is an earthquake-resistant wall that can be extremely easily assembled to a body to save labor in the field and to obtain a reliable earthquake-resistant structure. It is intended to be provided.

[0005]

In order to achieve the above object, the seismic resistant wall according to claim 1 has a wall body whose periphery is fixed to a skeleton, and a steel material arranged in a diagonal direction of the wall body. And pre-stressing the steel material to introduce compressive prestress into the wall body.

Further, the earthquake-resistant wall according to claim 2 is characterized by that according to claim 1.
The earthquake-resistant wall described is characterized in that a cotter having a plurality of irregularities embedded in concrete constituting the skeleton is provided around the wall body. further,
The earthquake-resistant wall according to claim 3 is characterized in that, in the earthquake-resistant wall according to claim 1 or 2, sheer streaks embedded in the concrete constituting the body and the skeleton are protrusively provided. .

[0007]

According to the earthquake-resistant wall of the first aspect, when a horizontal load or a vertical load acts on the body due to an earthquake, a strong wind, etc., these loads are transmitted to the wall. here,
Since compressive prestress is introduced into the wall body by the strained steel material, the load transmitted from the body is suppressed by the wall body, and the deformation of the entire body due to the load is reduced. Further, a stress is applied to the wall body by the load transmitted from the body, but the stress is offset by the steel material in the tension state, and the generation of cracks in the wall body is prevented.

Further, according to the seismic resistant wall of the second aspect, the cotter formed around the wall body bites into the concrete constituting the skeleton, so that the wall body and the skeleton are surely integrated, and This ensures that the load acting on the body is transmitted to the wall body. Further, according to the earthquake-resistant wall of claim 3, the shear bars projecting around the wall body bite into the concrete constituting the skeleton, so that the wall body and the skeleton are reliably integrated, whereby The load acting on the body is reliably transmitted to the wall.

[0009]

EXAMPLE An example of the earthquake-resistant wall of the present invention will be described below with reference to the drawings. 1 and 2, reference numeral 1 is an earthquake resistant wall. The seismic resistant wall 1 is made of a precast plate manufactured in a factory or the like, and a PC steel rod 3 is previously arranged inside the wall body 2. These PC steel rods 3 are
The pair of right and left walls 2 are diagonally intersected in a diagonal direction, and are arranged in a pretensioned state. Further, in each of the PC steel rods 3, the end portion at the center of the wall body 2 is the fixing end 4, and the end portions at both end portions of the wall body 2 are the tension ends 5.

As described above, these PC steel rods 3 have
Since tension is applied in advance, the wall body 2 is
The compressive prestress is introduced by the tension of the C steel rod 3. The PC steel rods 3 are arranged in a so-called unbonded type in which the fixing end 4 and the tensioning end 5 are fixed to the wall body 2.

Further, the wall body 2 is formed as a concave and convex cotter 7 by forming a plurality of concave portions 6 at intervals in the circumferential direction, and each concave portion 6 is formed in the cotter 7. Further, a shear bar 8 made of, for example, a reinforcing bar or a stud bolt is provided so as to project outward. Also,
The wall 2 is provided with a fixing bracket 9 on its side,
These fixing fittings 9 are fixed to a fixing plate 12 provided on the steel frame 11a of the pillar 11 with bolts, nuts or the like.

When assembling the earthquake-resistant wall 1 having the above-mentioned structure and structure to the frame, first, the wall 2 is arranged at a predetermined position of the frame, and the fixing brackets 9 on both sides are provided on the steel frame 11a of the pillar 11. The pillar 11, the beam 13, and the slab 14 are constructed by fastening and fixing to the fixed plate 12 with bolts, nuts, etc., and then arranging reinforcing bars (not shown) and pouring concrete. In this way, when the pillar 11, the beam 13, and the slab 14 are constructed, the periphery of the wall body 2 is embedded in the lower ends of the pillar 11, the beam 13, and the top end of the slab 14, and the wall body 2 is Surrounding cotters 7 and shear lines 8 are pillars 11, beams 13, slabs 14.
It bites into the concrete and is surely integrated.

As described above, when a horizontal load is applied to the frame provided with the earthquake resistant wall 1 by an earthquake, a strong wind or the like, this horizontal load is applied to the wall 2 via the cotter 7 and the shear line 8. Be transmitted to. Here, in the wall body 2,
Since the pre-compression stress has been introduced by the PC steel rod 3 in advance, the wall body 2 suppresses the horizontal load and reduces the deformation of the entire body due to the horizontal load. At this time, a tensile stress acts on the wall body 2 in the direction of arrow A in FIG. 3, but this tensile stress is canceled by the PC steel rod 3 which is strained in the direction opposite to the direction in which this stress acts. Therefore, the wall 2 is not cracked by the tensile stress.

As described above, according to the earthquake-resistant wall 1 of the above-mentioned embodiment, since the pre-compression prestress is introduced by the built-in PC steel rod 3, the horizontal load acting on the body can be surely suppressed. Therefore, it is possible to significantly reduce the deformation of the entire body due to the horizontal load. Further, the tensile stress acting on the wall 2 can be canceled by the PC steel rod 3 in the tensioned state, so that the generation of cracks in the wall 2 due to the tensile stress can be prevented.

Further, the wall body 2 can be very easily embedded in the cotter 7 only by embedding the periphery of the wall body 2 in the concrete of the pillars 11, the beams 13 and the slabs 14 constituting the skeleton.
And the shear line 8, the pillar 11, the beam 13, the slab 14
It can be assembled in a state of being integrated with, and it is possible to eliminate complicated welding work, welding management and the like as in the conventional case.

In the above embodiment, the PC steel rod 3 was used as the steel material for introducing the compressive prestress into the wall 2.
The steel material is not limited to a steel rod and may be, for example, a wire or the like. Further, in the earthquake-resistant wall 1 of the embodiment, the so-called unbonded type in which the both ends of the PC steel rod 3 are fixed to the wall body 2 is adopted, but the PC in the tensioned state is used.
A so-called bond type in which the steel rod 3 and the wall body 2 are integrated may be used. That is, the unbond type gives tension to the PC steel rod 3 after the wall body 2 is molded, whereas the bond type is the PC steel rod 3 before the wall body 2 is molded.
A tension force is applied to the wall of the PC steel rod 3, and then the concrete 2 is cast into the form in which the PC steel rod 3 is arranged to form the wall 2 integrated with the PC steel rod 3.

In the above embodiment, the case where a horizontal load is applied to the body has been described. However, even when a vertical load is applied to the body, the load can be suppressed as in the above embodiment. Is.

[0018]

As described above, according to the earthquake-resistant wall of the present invention, the following effects can be obtained. According to the earthquake-resistant wall of claim 1, since the pre-compression prestress is introduced into the wall body by the built-in steel material, the horizontal load or the vertical load acting on the frame due to an earthquake, a strong wind, or the like can be surely suppressed. Therefore, the deformation of the skeleton due to the load can be significantly reduced. Further, the stress acting on the seismic wall itself can be canceled by the steel material in the tensioned state, and therefore the generation of cracks in the wall body constituting the seismic wall can be prevented. In addition, simply arranging a steel material inside the wall body and tensioning this steel material, compared to the conventional earthquake-resistant wall in which a brace for welding and fixing to the steel frame of the body is built in,
High molding precision is not required, and therefore the labor and time required for molding can be reduced, and the manufacturing cost of the wall body can be reduced.

According to the seismic resistant wall of the second aspect, it is extremely easily formed around the wall body only by burying the periphery of the wall body in concrete such as pillars, beams and slabs constituting the frame body. The cotter can be made to bite into the concrete forming the skeleton, the wall body and the skeleton can be reliably integrated, and the load acting on the skeleton can be reliably transmitted to the wall body. That is, unlike the conventional case, it is not necessary to perform extremely complicated welding work, welding management, and the like, which can greatly improve workability in the field and shorten the construction period.

According to the earthquake-resistant wall of the third aspect of the invention, the wall is surrounded by concrete such as pillars, beams, slabs, etc., which form the skeleton, so that it is extremely easily projected around the wall. It is possible to cause the shear streaks to bite into the concrete constituting the skeleton, to surely integrate the wall and the skeleton, and to reliably transmit the load acting on the skeleton to the wall. That is, unlike the conventional case, it is not necessary to perform extremely complicated welding work, welding management, and the like, which can greatly improve workability in the field and shorten the work period.

[Brief description of drawings]

FIG. 1 is a front view of an earthquake-resistant wall assembled to a frame for explaining the structure and structure of the earthquake-resistant wall according to an embodiment of the present invention.

FIG. 2 is a plan view of the earthquake-resistant wall assembled to the frame for explaining the structure and structure of the earthquake-resistant wall according to the embodiment of the present invention.

FIG. 3 is a schematic front view of the earthquake-resistant wall for explaining the earthquake-resistant structure of the earthquake-resistant wall according to the embodiment of the present invention.

[Explanation of symbols]

 1 Seismic wall 2 Wall body 3 PC steel rod (steel material) 6 Recess 7 Cotter 8 Shear streak

Claims (3)

[Claims] 1. A wall body, the periphery of which is fixed to a frame, and a steel material arranged in a diagonal direction of the wall body. The steel material is pretensioned to compress the wall body. A seismic wall characterized by being prestressed. 2. The earthquake-resistant wall according to claim 1, wherein a cotter having a plurality of irregularities embedded in concrete forming the skeleton is provided around the wall. 3. The earthquake-resistant wall according to claim 1, wherein shear walls embedded in the concrete forming the skeleton are projectingly provided around the wall body.