JP4565309B2 - Boundary beam damper - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a boundary beam damper capable of rationally suppressing vibration in an RC structure without obstructing a space in a building.
[0002]
[Prior art]
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.
[0003]
As one of the solutions, a structure using an RC core wall is generally adopted. The adoption of the RC core wall improves the seismic performance of the building and brings about an effect of improving the energy absorption capacity of the building by incorporating a boundary beam type damping damper in the RC core wall.
[0004]
[Problems to be solved by the invention]
However, such a technique of incorporating a boundary beam type damping damper into such an RC core wall is difficult to construct and often costs high.
[0005]
In view of the above circumstances, the present invention provides a boundary beam damper that is low cost, has good workability, and can reasonably suppress vibration in an RC structure without obstructing the space in the building. It is an object.
[0006]
[Means for Solving the Problems]
The boundary beam damper according to claim 1 is a short-span boundary beam damper incorporating a vibration control damper spanned between adjacent vertical members so that the side portions of the adjacent vertical members face each other. Brackets made of reinforced concrete are arranged, arranged in the direction perpendicular to the vertical members at the upper and lower parts of the brackets, and a plurality of beam reinforcing bars forming the main bars of the brackets are members from spans between adjacent vertical members It is long and is disposed so as to connect the paired brackets, and both ends thereof are embedded in the vertical member.
[0007]
The boundary beam damper according to claim 2 is characterized in that a rebar with a head is used as the beam rebar.
[0008]
The boundary beam damper according to claim 3 is a short-span boundary beam damper incorporating a vibration control damper spanned between adjacent vertical members, and the side portions of the adjacent vertical members are opposed to each other. A bracket made of reinforced concrete is arranged on the top, and the main bars of the bracket are arranged at the upper and lower parts of the bracket, and the end of the main bar on the vertical member side is embedded in the vertical member, on the opposite end face of the bracket Is provided with a damping damper to connect the brackets, and the damping damper is provided with an H-shaped steel using a steel material having a lower yield point than the upper and lower flanges for the web, and at both ends of the H-shaped steel. A pair of steel plates joined on one surface and a plurality of stud gibels fixed to the center of the other surface of the steel plates forming the pair, are arranged in front of the end surface of the bracket. While the other surfaces of the steel plates are joined to each other, one end of the main bar of the bracket is fixed to the other surface of the steel plate, and the other end of the main bar reaches the vertical member. It is characterized by being.
[0009]
The boundary beam damper according to claim 4, wherein a plurality of short reinforcing bars are used instead of the H-shaped steel and the stud gibber for the damping damper, and the short reinforcing bars connect the brackets facing each other. As described above, a plurality of the wires are arranged in parallel, and end portions thereof are embedded in the bracket.
[0010]
6. The boundary beam damper according to claim 5, wherein a steel plate panel made of mild steel is joined to the damping damper in place of the H-shaped steel and the stud gibber, and one surface is joined to both end portions of the steel plate panel. A panel damper comprising: a pair of steel plates; a pair of connecting plates provided so as to form a plane parallel to the steel plate panel at an end of the other surface of the steel plate; and A connecting plate forming a pair of panel dampers is arranged so as to sandwich both side surfaces of the bracket, and is fastened by bolts penetrating the connecting plate and both side surfaces of the bracket.
[0011]
The boundary beam damper according to claim 6, in place of the H-shaped steel, the steel plate, and the stud gibber, the steel pipe having a central axis directed in a direction of connecting adjacent vertical members, A steel pipe concrete damper comprising a plurality of steel pipe rebars arranged along the inner peripheral surface of the steel pipe and projecting from both ends of the steel pipe, and concrete embedding the hollow portion of the steel pipe, is used. The ends of the steel pipe internal reinforcing bars are embedded in the bracket, and the both ends of the steel pipe are joined to the end faces of the brackets face to face.
[0012]
The boundary beam damper according to claim 7, wherein the seismic damper includes, instead of the H-shaped steel, the stud gibber, one steel plate arranged in parallel so as to face each other, and the other steel plate, A fixed plate fixed so that the surface is orthogonal to one surface of the steel plate, a cylindrical tube fixed to one steel plate with a substantially central portion through the fixed plate, and an end of the cylindrical tube, respectively A pair of twist plates in which the surfaces in the vicinity of one end are fixed so as to cover; a steel rod connecting the vicinity of the other end of the pair of twist plates; and the steel rod of the other steel plate A torsional damper configured to engage with one surface and a torsional damper are used, and the other surface of each of the one steel plate and the other steel plate constituting the torsional damper is face-to-face with the end surface of the bracket. Joined with one steel plate and the other To each of the other surface of the steel rebar said plurality of fixed its end, the iron muscles, is characterized in that is embedded in said bracket.
[0013]
The boundary beam damper according to claim 8, wherein, in place of the H-shaped steel and the stud gibber, the seismic damper has a pair of steel plates in which the other surface is fixed to the end surface of the bracket, and the steel plate One end is fixed to be parallel to each other with a certain interval, and a pair of side plates that face each other in a direction perpendicular to the vertical axis, and both ends between the paired side plates Steel plates forming a pair constituting a coil spring damper using a connection plate arranged so that each portion is sandwiched, a plurality of coil springs connecting the connection plate and the side plate, and a coil spring damper A plurality of reinforcing bars have their ends fixed to the other surface, and the reinforcing bars are embedded in the bracket.
[0014]
The boundary beam damper according to claim 9 is characterized in that a rebar with a head is used as a main reinforcement of the bracket.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of a boundary beam damper according to the present invention will be described with reference to FIGS.
[0016]
The boundary beam damper 1 of the present invention is effectively used as a short span beam in a portion where the span between adjacent vertical members is short. As an example of installation, in a super high-rise RC apartment house using RC core wall 2, it is used as a short span beam connecting RC core walls 2, RC core wall 2 and columns, or columns and columns. In the present embodiment, a case where it is applied to the RC core walls 2 will be described in detail as an example.
[0017]
Here, the RC core wall 2 over which the boundary beam damper 1 is bridged is made of reinforced concrete or the like. Similarly, the main beam 3 a, the stirrup 3 b, and the concrete 3 are provided at the position where the boundary beam damper 1 is provided. A bracket 3 made of reinforced concrete composed of c is provided. The main bars 3 a are arranged in the vicinity of the upper end portion and the lower end portion of the bracket 3 in a direction orthogonal to the RC core wall 2, and are arranged in parallel in the width direction of the bracket 3. Both end portions on the 2 side reach the inside of the RC core wall 2.
[0018]
The main bars 3a may be individually disposed in the vicinity of the upper end and the lower end of the bracket 3 as shown in FIG. 2 (a). However, as shown in FIG. A plurality of reinforcing bars processed into a U-shape having a width approximately equal to the member height may be arranged in parallel to the width direction of the bracket 3.
Further, as the reinforcing bar used for the main reinforcing bar 3a, a reinforcing bar with a head provided with a bump-like head at both ends thereof may be used. In addition, the shape of the both ends in the rebar with the head is not particular about this, as long as the rebar has an end portion that is difficult to come out from solidified concrete, such as a portion having a cross section larger than the diameter of the rebar is provided at both ends. Good.
[0019]
(First embodiment of the present invention)
FIG. 1 shows a first embodiment of a boundary beam damper 1. The boundary beam damper 1 in FIG. 1 connects a bracket 3 provided on an adjacent RC core wall 2 with a plurality of beam rebars 4, and connects the end 4 a of the beam rebar 4 to the inside of the RC core wall 2. It is an embedded structure. The beam reinforcing bars 4 are thick reinforcing bars having a large diameter, and a plurality of the reinforcing bars are arranged in parallel in the width direction of the bracket 3 near the upper end portion and the lower end portion of the bracket 3.
[0020]
In the boundary beam damper 1 according to the first embodiment, since the beam reinforcing bar 4 has the function of the main reinforcing bar 3 a, the main reinforcing bar 3 a is not provided, and the ribs are arranged on the outer periphery of the beam reinforcing bar 4. A streak 3b is provided. In addition, as described above, all main bars 3a are replaced with beam reinforcing bars 4, and the structure in which the opposite brackets 3 are connected to each other is not particular, and the main bars 3a are arranged on the brackets 3 at a certain interval. Thus, the beam reinforcing bars 4 may be arranged between the main reinforcing bars 3a in parallel to the main reinforcing bars 3a, and the brackets 3 facing each other may be connected by the beam reinforcing bars 4.
[0021]
With such a configuration, the boundary beam damper 1 according to the first embodiment is designed to absorb energy by bending and yielding the beam reinforcing bar 4 exposed from the bracket 3 when an earthquake or the like occurs. .
[0022]
According to the configuration described above, in the first embodiment, the structure of the boundary beam damper 1 is that the opposing brackets 3 provided on the adjacent RC core walls 2 are simply connected by a plurality of beam reinforcing bars 4. In addition, the structure is rational and simple, the workability is good, and it is possible to effectively absorb energy during an earthquake.
[0023]
Further, with respect to the beam rebar 4, it is possible to secure fixing strength while shortening the embedding length in the RC core wall 2 by using a rebar with a head having a head on a bump on both ends. This can reduce the material cost.
[0024]
(Second embodiment of the present invention)
FIG. 2 shows a second embodiment of the boundary beam damper 1. The boundary beam damper 1 in FIG. 2 has a structure in which brackets 3 provided on adjacent RC core walls 2 are connected by an H-shaped steel damper 5 using an H-shaped steel 6.
The H-shaped steel damper 5 includes the H-shaped steel 6, a pair of steel plates 7 for fastening the H-shaped steel 6 to the bracket 3, and stud gibbles 8 fixed to the steel plate 7. The
[0025]
In the H-shaped steel 6, the upper and lower flanges 6a are made of high-tensile steel, and the web 6b is made of extremely soft steel having a lower yield point than the upper and lower flanges 6a. When an earthquake or the like occurs, The web 6b functions as a damper by causing shear deformation and absorbing energy. In the boundary beam damper 1 of the second embodiment, an H-section steel 6 using ultra-soft steel is used for the web 6b, but considering that high tension is used for the upper and lower flanges 6a. Without being limited thereto, general steel may be applied to the web 6b.
[0026]
One surface 7a of the steel plate 7 is fixed to both ends of the H-shaped steel 6 by means of fastening such as welding. In the vicinity of the central portion of the other surface 7 b of the steel plate 7, a plurality of stud dowels 8 are fastened by means of welding or the like, and further, in the vicinity of the upper end portion and the lower end portion of the other surface 7 b, Inside the bracket 3, end portions of the main bars 3 a arranged in the width direction of the upper and lower flanges 6 a of the H-shaped steel 6 are fixed by welding or the like.
[0027]
These H-shaped steel dampers 5 are fixed so that the other surface 7b of the steel plate 7 and the end surface 3a of the bracket 3 are abutted with each other, and the stud attached to the other surface 7b. The gibber 8 is embedded in the bracket 3.
[0028]
With such a configuration, in the boundary beam damper 1 in the second embodiment, when an earthquake or the like occurs, the shear force of the web 6 b of the H-section steel 6 is transmitted to the bracket 3 by the stud gibber 8, The tensile force generated in the upper and lower flanges 6a is transmitted to the main bar 3a fixed to the steel plate 7.
[0029]
According to the configuration described above, in the second embodiment, the opposing bracket 3 provided on the adjacent RC core wall 2 is simply connected to the web 6b with the H-section steel 6 using a steel material having a low yield point. Therefore, the structure is rational and simple, and the workability is good, and it is possible to effectively absorb energy during an earthquake.
[0030]
(Third embodiment of the present invention)
FIG. 3 shows a third embodiment of the boundary beam damper 1. The boundary beam damper 1 in FIG. 3 has a structure in which a bracket 3 provided on an adjacent RC core wall 2 is connected by a panel damper 9 provided so as to cover the end surface 3 d and the side surface 3 e of the bracket 3.
The panel damper 9 includes a panel damper main body 10, a pair of steel plates 7 for fastening the panel damper main body 10 to the bracket 3, and a pair of connecting plates 11 provided at both end portions of the steel plate 7. And more composed.
On the other hand, the bracket 3 is provided with a female screw 12 and a bolt 13 for connecting the connecting plates 11 together.
[0031]
The panel damper body 10 is a vibration control device made of extreme yield point steel. One surface 7a of the steel plate 7 is fixed to both side ends of the panel damper main body 10 by welding or the like. Further, on both sides of the other surface 7 of the steel plate 7, the connecting plate 11 is fixed by welding or the like with the surface facing in a direction parallel to the panel damper main body 10. The connecting plate 11 is provided with a plurality of holes 11 a in a lattice shape, and the connecting plates 11 facing each other are provided on the side surface 3 e of the bracket 3 via bolts 13 passing through the holes 11 a. The bracket 3 is fixed by being fastened to the female screw 12.
[0032]
The female screw 12 provided on the side surface 3e of the bracket 3 is positioned so as to fit in the plurality of lattice-shaped holes 11a provided in the connecting plate 11 in the width direction of the bracket. Multiple books are pre-embedded. The member length of the female screw 12 is substantially the same as the width of the bracket 3, and both end portions of the female screw 12 are located on the same plane as the both end surfaces 3 e.
[0033]
When the panel damper 9 is attached to the bracket 3, the other surface 7 of the steel plate 7 is in contact with the end surface 3 d of the bracket 3, and the facing surfaces of the connecting plates 11 facing each other are the side surfaces 3 of the bracket 3. The panel damper 9 is disposed in the bracket 3 so that the female screw 12 and the hole 11a of the connecting plate 11 are aligned with each other in a state where the surfaces are in contact with each other, and the bolt 13 is fitted to the female screw 12 Fix it.
[0034]
In the present invention, the female screw 12 having a member length substantially the same as the width of the bracket 3 is used. However, the present invention is not limited to this, and a female screw having a short member length is used for both side surfaces 3 e of the bracket 3. May be embedded in each. Further, instead of the female screw 12, male screws (not shown) may be embedded in both side surfaces 3 e of the bracket 3 and fixed using nuts.
[0035]
With such a configuration, the boundary beam damper 1 according to the third embodiment causes the bending moment and shearing force generated in the panel damper 9 to be applied to the bracket 3 via the bolt 12 when an earthquake or the like occurs. Communicated.
[0036]
Further, when the panel damper 9 is damaged, the bolt 13 is removed, the panel damper 9 is removed from the bracket 3, and a new panel damper 9 is installed by the same means.
[0037]
According to the configuration described above, in the third embodiment, the opposing bracket 3 provided on the adjacent RC core wall 2 is connected by the panel damper 9, and the mounting is performed in the width direction of the bracket 3. Since it is performed by tightening the bolt 13 to the provided female screw 12, it can be easily removed, and even when the panel damper 9 is damaged, it can be easily replaced.
[0038]
(Fourth embodiment of the present invention)
FIG. 4 shows a fourth embodiment of the boundary beam damper 1. The boundary beam damper 1 in FIG. 4 has a structure in which brackets 3 provided on adjacent RC core walls 2 are connected by a plurality of short reinforcing bars 14.
The short reinforcing bar 14 is a thick reinforcing bar having a large cross-sectional diameter, and a plurality of the short reinforcing bars 14 are connected so as to connect the end faces 3 d of the bracket 3 so as to form a grid in the width direction and the height direction of the bracket 3. (See FIG. 4B). At this time, the bracket 3 is set to have a longer member length than the first to third embodiments, and the length T at which the short reinforcing bar 14 is exposed is made as short as possible.
[0039]
With such a configuration, the boundary beam damper 1 according to the fourth embodiment is designed to absorb energy when the short rebar 14 connecting the brackets 3 shears and yields when an earthquake or the like occurs. .
[0040]
According to the above-described configuration, in the fourth embodiment, the opposing brackets 3 provided on the adjacent RC core walls 2 are merely connected by the short reinforcing bars, so that the structure is rational and simple and the workability is excellent. In addition to being good, the cost for the member can be reduced, and thus the cost can be reduced.
[0041]
(Fifth embodiment of the present invention)
FIG. 5 shows a fourth embodiment of the boundary beam damper 1. The boundary beam damper 1 in FIG. 5 has a structure in which brackets 3 provided on adjacent RC core walls 2 are connected by a steel pipe concrete damper 15.
The steel pipe concrete damper 15 includes a steel pipe 16 having a central axis A in a direction in which the adjacent brackets 3 are connected to each other, a steel pipe internal rebar 17 disposed inside the steel pipe 16, and a hollow in the steel pipe 16. It is composed of concrete 18 that embeds the part
[0042]
The steel pipe 16 is made of a commonly used ordinary steel material, and has an outer diameter that fits within the area of the end face 3d of the bracket 3. Inside the steel pipe 16, a plurality of the steel pipe internal reinforcing bars 17 are arranged at equal intervals along the inner peripheral surface. The steel pipe rebar 17 is a steel bar made of ordinary steel, and the length thereof is longer than that of the steel pipe 16, and the steel pipe 16 is disposed so that the same length projects from both ends. The steel pipe internal reinforcement 17 is fixed by the concrete 18 filling the inner space of the steel pipe 16.
[0043]
Such a steel pipe concrete damper 15 is fixed so that the upper end and lower end of the steel pipe 16 are joined to the end face 3d of the bracket 3 paired with each other, and from both ends of the steel pipe 16. Both ends of the projecting steel pipe reinforcing bar 17 are accommodated in the bracket 3.
[0044]
With such a configuration, the boundary beam damper 1 according to the fifth embodiment prevents the shear failure due to the effect of the steel pipe 16 in the steel pipe concrete damper 15 when an earthquake or the like occurs, and the steel pipe internal rebar 17 Energy absorption is achieved by bending yielding.
[0045]
According to the above-described configuration, in the fifth embodiment, since the opposing bracket 3 provided on the adjacent RC core wall 2 is merely connected by the steel pipe concrete damper 15, the structure is rational and simple. This makes it possible to absorb energy during an earthquake effectively.
[0046]
(Sixth embodiment of the present invention)
FIG. 6 shows a sixth embodiment of the boundary beam damper 1. The boundary beam damper 1 in FIG. 6 has a structure in which the bracket 3 provided on the adjacent RC core wall 2 is connected by a twist damper 19.
The torsional damper 19 includes one steel plate 20 arranged in parallel so as to face each other, the other steel plate 21, a fixing plate 22 fixed to the one steel plate 20, and one steel plate via the fixing plate 22. A cylindrical tube 23 fixed to 20, a torsion plate 24 having one end fixed to the end of the cylindrical tube 23, a steel rod 25 connecting the torsion plate 24 forming the pair, and the steel And a locking member 26 for locking the rod 25 to the other steel plate 7.
[0047]
In the one steel plate 20, the other surface 20b is fixed to the end surface 3d of the bracket 3, and one end portion of the fixing plate 22 is fixed to the one surface 20a so that the surfaces of each other are fixed to each other. Forming a vertical. At this time, the fixed plate 22 faces the direction perpendicular to the vertical axis. In the vicinity of the other end of the fixed plate 22, a hole 22a having the same size as the outer diameter of the cylindrical tube 23 is provided, and the cylindrical tube 23 is fitted to the hole 22a up to the center of the outer peripheral surface thereof. It is fixed by welding.
[0048]
The cylindrical tube 23 is a hollow steel tube made of extremely mild steel having good elongation performance. The steel material to be used is not limited to this, and other steel materials may be used. Surfaces in the vicinity of one end 24 a of the twist plate 24 are fixed to both ends of the cylindrical tube 23, and the other end 24 b of the twist plate 24 is attached to the other steel plate 21. It extends toward.
[0049]
On the other hand, the other surface 21 b of the other steel plate 21 is fixed to the end surface 3 d of the bracket 3, and the twisted plate forming a pair extending toward the other steel plate 21 on one surface 21 a. A locking member 26 for locking the steel rod 25 is fixed at a position sandwiched between the other ends 24 b of 24. The locking member 26 is provided with a groove 26a having the same width as the outer diameter of the steel rod 25 in a direction perpendicular to the surface of the twist plate 24, and the steel rod 25 is fitted into the groove 26a. Therefore, the rotation and the movement in the depth direction of the groove are arranged in a free state.
[0050]
Both ends of the steel rod 25 are fixed to the surface in the vicinity of the other end 24 b of the twist plate 24. In other words, the twist plate 24 has one end 24 a fixed by the cylindrical tube 23 fixed to the one steel plate 20 by the fixing plate 22, while the other end 24 b is fixed by the steel rod 25. It is also movable in the direction that can be moved.
[0051]
In such a torsion damper 19, a plurality of holes (not shown) are provided in the one steel plate 20 and the other steel plate 21, and the holes are fitted to the female screw 12 provided on the end surface 3d of the bracket 3. Then, it is fixed by tightening with bolts 13. Further, the bracket 3 on the side on which the other steel plate 21 is provided has a larger number of female screws 12 than the bracket 3 on the side on which the one steel plate 20 is provided, thereby further strengthening the fixing strength to the bracket 3. It has become.
[0052]
With such a configuration, the boundary beam damper 1 according to the sixth embodiment has a displacement amount of the one steel plate 20 relative to the other steel plate 21 when an earthquake occurs. Is transmitted to the other end 24 b of the torsion plate 24 integrated with the steel rod 25 as a rotational motion. Next, this movement applies a torsional moment to the cylindrical tube 23 fixed to one end 24a of the torsion plate 24, so that the cylindrical tube 23 is plasticized by a torsional deformation having a shear yield and is deformed. It is intended to absorb energy.
[0053]
According to the configuration described above, in the sixth embodiment, only the opposing bracket 3 provided on the adjacent RC core wall 2 is connected by the torsional damper 19, so compared with the case where a conventional steel damper is applied. Thus, the cross section of the bracket 3 can be made small and can be produced at low cost. The torsion damper 19 can be attached to the bracket 3 by fastening the bolt 13 to the female screw 12 embedded in the bracket 3 in advance, so that the torsion damper 19 can be easily removed. Exchange work can be performed.
[0054]
(Seventh embodiment of the present invention)
FIG. 7 shows a seventh embodiment of the boundary beam damper 1. The boundary beam damper 1 shown in FIG. 7 has a structure in which a bracket 3 provided on an adjacent RC core wall 2 is connected by a coil spring damper 27.
The coil spring damper 27 has one end 30a fixed to one surface 7a of a pair of steel plates 7, and is perpendicular to the steel plate 7 and arranged in parallel at a certain interval. And a connecting plate 29 disposed so as to be sandwiched between the other end 30 b of the side plate 30 via a coil spring 28.
[0055]
The coil spring 28 has been conventionally applied as a seismic isolation device. In the present invention, one end of each of the coupling plates 29 is fixed at the same position on both sides of the connection plate 29. The other end of the coil spring 28 is fixed to the opposing surface of a pair of side plates 30 fixed to the steel plate. That is, the end of the connecting plate 29 is connected to the side plate 30 through the coil spring 28. The paired steel plates 7 are provided with a plurality of holes (not shown).
[0056]
In such a coil spring damper 27, the end surface 3d of the bracket 3 is abutted with the other surface 7b of the steel plate 7 forming the pair, and a plurality of holes (not shown) of the steel plate 7 forming the pair include The position is adjusted to a female screw 12 provided on the end surface 3 d of the bracket 3 and is fixed by being fastened by a bolt 13.
[0057]
With such a configuration, the boundary beam damper 1 according to the seventh embodiment is configured such that when the earthquake occurs, the paired steel plates 7 are relatively displaced, whereby the coil spring 28 is deformed to absorb energy. Is intended.
[0058]
According to the above-described configuration, in the seventh embodiment, since the opposing bracket 3 provided on the adjacent RC core wall 2 is simply connected by the coil spring damper 27, the structure is rational and simple, and the construction is easy. In addition to being good, it is possible to effectively absorb energy during an earthquake. Moreover, since the expense concerning a member is held down, it becomes possible to reduce cost. Further, the coil spring damper 27 can be attached to the bracket 3 by fastening the bolt 13 to the female screw 12 embedded in the bracket 3 in advance, so that it can be easily removed and even when the coil spring damper 27 is damaged. Exchange work can be performed.
[0059]
【The invention's effect】
The boundary beam damper according to claim 1 is a short-span boundary beam damper incorporating a vibration control damper spanned between adjacent vertical members, and is opposed to the side portions of the adjacent vertical members. Brackets made of reinforced concrete are arranged in the direction perpendicular to the vertical member at the upper and lower parts of the bracket, and a plurality of beam reinforcing bars forming the main reinforcement of the bracket are spanned between the adjacent vertical members. Longer member length is arranged to connect the paired brackets, and both ends thereof are embedded in the vertical member, so the structure is rational, simple and easy to work with It is possible to effectively absorb energy during an earthquake.
[0060]
According to the boundary beam damper according to claim 2, since a reinforcing bar with a head is used as the beam reinforcing bar, fixing strength can be secured while shortening the embedding length in the RC core wall, It becomes possible to reduce the material cost.
[0061]
The boundary beam damper according to claim 3 is a short-span boundary beam damper incorporating a damping damper spanned between adjacent vertical members, and the side portions of the adjacent vertical members are opposed to each other. Brackets made of reinforced concrete are arranged, the main bars of the brackets are arranged at the upper and lower parts of the brackets, and the ends of the main bars on the vertical member side are embedded in the vertical members so that the brackets face each other A damping damper is provided on the end face so as to connect the brackets to each other. The damping damper includes an H-section steel using a steel material having a lower yield point than the upper and lower flanges, and both ends of the H-section steel A pair of steel plates joined on one side to the part, and a plurality of stud gibels fixed to the center of the other side of the paired steel plates, the end of the bracket The other surfaces of the steel plates are joined to each other, and one end of the main bar of the bracket is fixed to the other surface of the steel plate, and the other end of the main bar is in the vertical member. Therefore, the structure is rational, simple and easy to work with, and it is possible to effectively absorb energy during an earthquake.
[0062]
According to the boundary beam damper according to claim 4, a plurality of short reinforcing bars are used in place of the H-shaped steel and the stud gibber, and the short reinforcing bars connect the brackets facing each other. A plurality of them are arranged in parallel so as to be connected, and the end portions are embedded in the bracket. Therefore, the structure is rational, simple, easy to work, and effectively absorbs energy during an earthquake. It becomes possible. Moreover, since the expense concerning a member is held down, it becomes possible to reduce cost.
[0063]
6. The boundary beam damper according to claim 5, wherein a steel plate panel made of mild steel is joined to the damping damper in place of the H-shaped steel and the stud gibber, and one surface is joined to both end portions of the steel plate panel. A panel damper comprising: a pair of steel plates; a pair of connecting plates provided so as to form a plane parallel to the steel plate panel at an end of the other surface of the steel plate; and Since the connecting plate forming a pair of panel dampers is arranged so as to sandwich both side surfaces of the bracket and is fastened by bolts penetrating the connecting plate and both side surfaces of the bracket, the panel damper can be easily removed. It is possible to easily perform replacement work even when the battery is damaged.
[0064]
According to the boundary beam damper according to claim 6, the seismic damper is a steel pipe having a central axis directed in a direction of connecting adjacent vertical members in place of the H-shaped steel, the steel plate, and the stud gibber. A steel pipe concrete damper comprising a plurality of steel pipe rebars arranged along the inner peripheral surface of the steel pipe and projecting from both ends of the steel pipe, and concrete in which the hollow portion of the steel pipe is embedded. In addition, since the end of the steel pipe rebar is embedded in the bracket and the both ends of the steel pipe are joined to the end faces of the brackets face to face, the structure is rational, simple, and easy to work with. In addition to being good, it is possible to effectively absorb energy during an earthquake.
[0065]
According to the boundary beam damper according to claim 7, the seismic damper includes, in place of the H-shaped steel, the stud gibber, one steel plate arranged in parallel so as to face each other, and the other steel plate, A fixed plate fixed so that the surface is orthogonal to one surface of one steel plate, a cylindrical tube having a substantially central portion fixed to one steel plate via the fixed plate, and an end portion of the cylindrical tube A pair of torsion plates with surfaces near one end fixed so as to cover each other, a steel rod connecting the vicinity of the other end of the pair of torsion plates, and the steel rod to the other end A torsional damper configured to engage with one surface of the steel plate and a torsional damper are used, and the other surface of each of the one steel plate and the other steel plate constituting the torsional damper is an end surface of the bracket. One side of the steel plate The end of each of the other steel plates is fixed to the other side of the other steel plate, and the reinforcing bars are embedded in the bracket, so that compared with the case where a conventional steel damper is applied. The cross section of the bracket can be made small and can be produced at low cost. The torsional damper can be attached to the bracket by tightening the bolt against the female screw embedded in the bracket in advance, so it can be easily removed and can be easily replaced when the torsional damper is damaged. It becomes possible.
[0066]
The boundary beam damper according to claim 8, wherein, in place of the H-shaped steel and the stud gibber, the seismic damper has a pair of steel plates in which the other surface is fixed to the end surface of the bracket, and the steel plate One end is fixed to be parallel to each other with a certain interval, and a pair of side plates that face each other in a direction perpendicular to the vertical axis, and both ends between the paired side plates Steel plates forming a pair constituting a coil spring damper using a connection plate arranged so that each portion is sandwiched, a plurality of coil springs connecting the connection plate and the side plate, and a coil spring damper The other side of the steel plate has a plurality of reinforcing bars fixed at its ends, and since the reinforcing bars are embedded in the bracket, the structure is rational, simple, easy to work and effective. It is possible to reduce the energy absorption at the time of the earthquake in. Moreover, since the expense concerning a member is held down, it becomes possible to reduce cost. The coil spring damper can be attached to the bracket by tightening a bolt with respect to the female screw embedded in the bracket in advance, so that it can be easily removed and can be easily replaced when the coil spring damper is damaged. It becomes possible.
[0067]
In the boundary beam damper according to claim 9, since a reinforcing bar with a head is used as the main reinforcing bar of the bracket, it is possible to ensure the fixing strength while shortening the embedding length in the vertical member and the bracket. This can reduce the material cost.
[Brief description of the drawings]
FIG. 1 is a diagram showing a fifth embodiment using a beam reinforcing bar of a boundary beam damper according to the present invention.
FIG. 2 is a diagram showing a first embodiment using a steel plate panel damper of a boundary beam damper according to the present invention.
FIG. 3 is a view showing a second embodiment using a steel plate panel damper of a boundary beam damper according to the present invention.
FIG. 4 is a diagram showing a third embodiment using a short rebar of a boundary beam damper according to the present invention.
FIG. 5 is a diagram showing a fourth embodiment using a steel pipe concrete damper of a boundary beam damper according to the present invention.
FIG. 6 is a diagram showing a sixth embodiment using a torsional damper of a boundary beam damper according to the present invention.
FIG. 7 is a diagram showing a seventh embodiment using a coil spring damper of a boundary beam damper according to the present invention.
[Explanation of symbols]
1 Boundary beam damper
2 RC core wall
3 Bracket
3 a main muscle
3b Stirrup
3c concrete
3d end face
3 e side
4 Beam reinforcement
4 a end
5 H-shaped steel damper
6 H-section steel
6 a Flange
6b Web
7 Steel plate
7 a One side
7 b The other side
8 Stud Giber
9 Panel damper
10 Panel damper body
11 Connecting plate
12 Female thread
13 volts
14 Short rebar
15 Steel pipe concrete damper
16 Steel pipe
17 Steel pipe reinforcement
18 Concrete
19 Torsional damper
20 One steel plate
20 a One side
20 b other side
21 The other steel plate
21 a One side
21 b The other side
22 fixed plate
22a hole
23 Cylindrical tube
24 Twist plate
24 a One end
24 b the other end
25 steel bars
26 Locking member
26 a groove
27 Coil spring damper
28 Coil spring
29 Connecting plate
30 side plate
30 a one end
30 b The other end

Claims (9)

A short-span boundary beam damper that incorporates a damping damper that spans between adjacent vertical members,
Brackets made of reinforced concrete are arranged on the sides of the adjacent vertical members so as to face each other,
A plurality of beam reinforcing bars, which are respectively arranged in the direction perpendicular to the vertical member at the upper and lower portions of the bracket, have a member length longer than the span between the adjacent vertical members, and the paired brackets are paired with each other. A boundary beam damper, wherein both ends of the boundary beam damper are embedded in the vertical member. 2. The boundary beam damper according to claim 1, wherein a rebar with a head is used as the beam reinforcing bar. A short-span boundary beam damper that incorporates a damping damper that spans between adjacent vertical members,
Brackets made of reinforced concrete are arranged on the sides of the adjacent vertical members so as to face each other, and the main bars of the brackets are arranged at the upper and lower parts of the bracket, and the ends of the main bars on the vertical member side The part is embedded in the vertical member, and on the opposite end face of the bracket, a damping damper is provided to connect the brackets,
The damping damper includes an H-section steel using a steel material having a lower yield point than the upper and lower flanges for the web;
A pair of steel plates joined on one side to both ends of the H-shaped steel;
A plurality of stud gibels fixed to the central portion of the other surface of the steel plate forming the pair, and
While the other surface of the steel plate is joined to the end surface of the bracket between the surfaces, one end of the main bar of the bracket is fixed to the other surface of the steel plate, the other end of the main bar is the Boundary beam damper characterized by reaching in a vertical member. The boundary beam damper according to claim 3,
In place of the H-shaped steel and the stud gibber, a plurality of short reinforcing bars are used for the damping damper.
The boundary beam damper is characterized in that a plurality of the short reinforcing bars are arranged in parallel so as to connect the brackets facing each other, and end portions thereof are embedded in the brackets. The boundary beam damper according to claim 3,
In place of the H-shaped steel and the stud gibber, the damping damper includes a steel plate panel made of mild steel,
A pair of steel plates joined on one side to both ends of the steel plate panel; and
A panel damper comprising a pair of connecting plates provided to form a plane parallel to the steel plate panel at the end of the other surface of the steel plate, and
A boundary beam damper, wherein a connecting plate forming a pair of the panel dampers is disposed so as to sandwich both side surfaces of the bracket and is fastened by bolts penetrating the connecting plate and both side surfaces of the bracket. The boundary beam damper according to claim 3,
In place of the H-shaped steel, the steel plate, and the stud gibber, the seismic damper has a steel pipe with a central axis directed in a direction connecting adjacent vertical members;
A plurality of steel pipe rebars that are arranged along the inner peripheral surface of the steel pipe and whose both ends protrude from the steel pipe;
Concrete embedding the hollow portion of the steel pipe, and a steel pipe concrete damper composed of it is used,
The boundary beam damper is characterized in that end portions of the steel pipe internal reinforcing bars are embedded in the bracket, and both end portions of the steel pipe are joined to surfaces of the end surfaces of the brackets. The boundary beam damper according to claim 3,
In the damping damper, instead of the H-shaped steel, the stud gibber, one steel plate arranged in parallel to face each other, and the other steel plate,
A fixed plate fixed so that the surface is orthogonal to one surface of the one steel plate;
A cylindrical tube having a substantially central portion fixed to one steel plate via the fixing plate;
A torsion plate forming a pair in which a surface near one end is fixed so as to cover each end of the cylindrical tube;
A steel rod that connects the vicinity of the other end of the pair of twisted plates;
A locking member configured to lock the steel bar to one surface of the other steel plate, and a torsion damper composed of the locking member,
The other surface of each of the one steel plate and the other steel plate constituting the torsion damper is joined to the end surface of the bracket face to face, and the other surface of each of the one steel plate and the other steel plate A boundary beam damper, wherein a plurality of reinforcing bars are fixed at their ends, and the reinforcing bars are embedded in the bracket. The boundary beam damper according to claim 3,
In the damping damper, in place of the H-shaped steel and the stud gibber, a pair of steel plates having the other surface fixed to the end surface of the bracket;
Side plates that are paired with one end fixed to the steel plate so as to be parallel to each other at a predetermined interval and that face in a direction perpendicular to the vertical axis,
A connecting plate arranged such that both end portions are sandwiched between the pair of side plates;
A plurality of coil springs that connect the connecting plate and the side plate, and a coil spring damper composed of a plurality of coil springs are used.
A boundary beam damper characterized in that a plurality of reinforcing bars are fixed to the other surface of the pair of steel plates constituting the coil spring damper, and the reinforcing bars are embedded in the bracket. . The boundary beam damper according to any one of claims 3 to 8, wherein a rebar with a head is used as a main reinforcing bar of the bracket.

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