JP2003064901A - Boundary beam damper - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a boundary beam damper capable of rationally controlling vibration in a steel framed structure without interfering with a space in a building. SOLUTION: The boundary beam damper 1 is constituted of a pair of H- shaped steels 2 arranged between columns 3 of the building in parallel, one ends 2d of them are fastened to the sides of the columns 3 in advance by welding, the other ends 2e are connected to each other with a fastening means such as a bolt 5 or the like through a splice plate 4 to form a boundary beam of a short span erecting over between the columns 3. The H-shaped steels 2 constituting the boundary beam damper 1 are so constituted that upper flange 2a as an upper member and a web 2b are made of a high tension steel and that a lower flange 2c as a lower member is made of a different member such as an extreme soft steel with low yield point. An RC slab 6 can be directly provided to the upper flange 2a of the boundary beam damper 1 constituted by such a method, and the boundary beam damper 1 and the RC slab 6 are integrally constituted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a boundary beam damper capable of reasonably suppressing vibration in a steel frame structure without obstructing the space inside the building.

[0002]

2. Description of the Related Art At present, a vibration control structure is attracting attention as a technique for reducing damage during an earthquake, and various energy absorbing devices (hereinafter referred to as dampers) have been developed and adopted in most high-rise buildings. Has been done. However, most of the dampers are used for braces, walls and studs that are effective for displacement between layers, and there is a demand for dampers that do not obstruct space.

Under such circumstances, a method of incorporating a damper function into a large beam and eliminating the need for an extra vertical member has been studied. This method is intended to function as a damper by incorporating a shear-yield part conventionally used for a stud into a part of a beam and effectively absorbing energy.

[0004]

However, in such a method, as shown in FIG. 4, the shear deformation concentrates on a part of the beam 21 having the damper 23 that is bridged between the columns 22,
Since the RC slab 24 attached thereto is cracked, there is a problem that a slab receiver is required in addition to the beam 21, and a more rational beam type damper is required.

In view of the above circumstances, it is an object of the present invention to provide a boundary beam damper capable of reasonably suppressing vibration in a steel frame structure without obstructing the space inside the building. .

[0006]

A boundary beam damper according to claim 1 is a boundary beam damper for suppressing vibration in a steel frame structure, and an upper member made of a steel material connecting adjacent columns, A lower member that is fastened to the lower end of the upper member and has a yield point lower than that of the upper member, at least the end of which is on the column side is connected to the side of the column. I am trying.

A boundary beam damper according to a second aspect of the present invention is characterized by being made of H-section steel having an upper flange and a web forming the upper member and a lower flange forming the lower member.

The boundary beam damper according to claim 3 is the H
The shaped steel web is characterized by using a steel material having a lower yield point than the upper flange.

A boundary beam damper according to a fourth aspect is the H-beam
The upper and lower flanges at the ends of the shaped steel are
It is characterized by having a larger cross-sectional area than the central portion of the shaped steel.

The boundary beam damper according to claim 5 is the H
The shaped steel is characterized in that the web length gradually increases from the central portion toward the end portion, and the lower flange has a slope with respect to the upper flange.

A boundary beam damper according to a sixth aspect of the present invention is characterized in that an H-shaped steel is used for the upper member and a shaped steel having a flange at a lower end is used for the lower member.

A boundary beam damper according to a seventh aspect is characterized in that the shaped steel is divided at a central portion and an opening is provided.

The boundary beam damper according to claim 8 is characterized in that a plurality of rib plates having substantially the same length as the web are attached to the web of the shaped steel in a direction perpendicular to the web.

In the boundary beam damper according to a ninth aspect of the present invention, the section steel has a web length gradually increasing from a web located at a central portion of the H-section steel to a web located at an end on a column side.
It is characterized in that the flange of the shaped steel has a slope with respect to the lower flange of the H-shaped steel.

A boundary beam damper according to a tenth aspect is characterized in that a floor slab is integrally provided on the upper flange of the H-section steel.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a boundary beam damper according to the present invention will be described below with reference to FIGS. 1 to 3.

FIG. 1 shows an overall view of the boundary beam damper 1.
1A is a front view of the boundary beam damper 1, FIG. 1B is a cross-sectional view of the boundary beam damper 1, and FIG. 1C is a view seen from above the boundary beam damper 1.

The boundary beam damper 1 of the present invention is a steel frame structure and is effectively used as a short span beam in a portion where the span between adjacent columns 1 is short. In addition, the pillar 3 on which the boundary beam damper 1 is bridged
Is a steel frame structure or a steel pipe concrete column in which the inner space of the steel pipe column is filled with concrete, and is formed of a member using a steel material.

(First Embodiment of the Invention) FIG. 1 shows a first embodiment of a boundary beam damper 1. As shown in FIG. 1A, the boundary beam damper 1 is made of a pair of H-shaped steels 2 arranged in parallel between columns 3 of a building, and one end 2d of the column 3 is previously formed. Is fastened to the side portions of the columns by welding, and the other ends 2e are connected to each other by fastening means such as bolts 5 via the splice plate 4 to form a short span boundary beam bridging the columns 3. There is. In addition, since almost no moment is generated in the center portion of the boundary beam, the H-shaped steels 2 forming a pair are connected only to the webs 2b, and the upper flanges 2a and the lower flanges 2c are not joined. .

H-shaped steel 2 constituting the boundary beam damper 1
The upper flange 2a and the web 2b, which are upper members, are made of different members such as high-tensile steel and the lower flange 2c, which is a lower member, are extremely mild steel having a low yield point. This allows the upper flange 2a and the web 2b to have a function as a beam for supporting a floor load, and at the time of an earthquake, only the lower flange 2c yields from the end portion to absorb energy and have a function as a damper. It is intended for. The boundary beam damper 1 of the present invention achieves both the function as the boundary beam and the function as the damper by properly using the steel materials for the upper and lower flanges 2d, 2e using such a configuration.

The lower flange 2c is the upper flange 2
If the yield point is lower than that of the steel material used for a, the steel material is not limited to the type of steel material, and a steel material such as mild steel may be used. Further, high tensile strength steel may be used only for the upper flange 2a, and a steel material having a lower yield point than the steel material used for the upper flange 2a may be used for the web 2b, similarly to the lower flange 2c.

An RC slab 6 is directly provided on the upper flange 2a of the boundary beam damper 1 having such a structure as shown in FIG. 1 (b).
And the RC slab 6 are integrated.

In the boundary beam damper 1 described above, in the first embodiment of the present invention, the H-shaped steel 2 constituting the boundary beam damper 1 is divided into two, and one end of the divided H-shaped steel 2 is divided. 2d is welded to the side of the pillar 3 in advance in a factory,
The other end portions 2e of the divided H-section steels 2 are bolted on site. However, this structure is not particular about this, and without dividing the H-shaped steel 2, the both ends of the H-shaped steel 2 are welded and fastened to the side portions of the column 3 at the site to form the boundary beam damper 1. May be.

If it is expected that the deformation level of the boundary beam damper 1 will be large when an earthquake occurs, one end 2d of the H-shaped steel 2 and the column 3 which compose the boundary beam damper 1 will be described. As shown in FIG. 1 (c), the cross-sectional area of one end 2d of the upper flange 2a and the lower flange 2c is greatly increased as compared with the central portion 1a for the purpose of preventing the welded portion from being damaged. Also, a so-called drop haunch may be provided.

Further, for the purpose of yielding a yield which tends to concentrate on one end 2d of the lower flange 2c when the boundary beam damper 1 is deformed, to yield in a wide range of the lower flange 2c. The web 2 located at one end 2d of the H-section steel 2 that constitutes the boundary beam damper 1
The length of b may be set to be sufficiently longer than that of the central portion 1a, and the lower flange 2c may have a slope with respect to the upper flange 2a.

According to the above-mentioned configuration, the boundary beam damper 1
Since the upper and lower flanges 2a and 2c may be configured to use only different steel materials, it is possible to perform the work procedure similar to that of a normal steel-framed building without requiring special work for processing and assembling or on-site construction.

Further, by properly using the steel materials for the upper and lower flanges 2a, 2c of the H-shaped steel 2 constituting the boundary beam damper 1, the upper flange 2a has a function as a boundary beam and the lower flange 2c serves as a damper. Since the lower flange 2c is configured to bend and deform over the entire length by providing the function of, the boundary beam damper 1 itself does not cause a local angle change even at the time of an earthquake, so the boundary beam damper 1 and the RC slab are not changed. 6 can be integrated with each other, the construction is easy, and it is not necessary to separately attach a member for receiving the RC slab 6, which can greatly contribute to cost reduction.

H-shaped steel 2 constituting the boundary beam damper 1
By dividing the two into two, the construction of the boundary beam damper 1
One end 2d of each of the divided H-shaped steels 2 is welded to the side of the column 3 in advance in a factory or the like, and the other ends 2e of the divided H-shaped steels 2 are fastened to each other with bolts 5 on site. Therefore, the construction can be simplified and the construction period and cost can be greatly reduced.

H-shaped steel 2 constituting the boundary beam damper 1
Has excellent weldability because it uses extremely mild steel as a member used for the lower flange 2c, and is welded to a column when welding the high-strength steel used for the upper flange 2a or a general steel structure. Since the low-hydrogen welding rod used can be used together, welding of the H-section steel 2 having the upper and lower flanges 2a, 2c of different steel materials to the pillar 3 does not need to incorporate a special construction method, and a normal steel frame can be used. The same construction as is possible.

Since the steel material having a lower yield point than that of the steel material used for the upper flange 2a is also used for the web 2b of the H-shaped steel 2 constituting the boundary beam damper 1, the lower flange 2 is used.
Since the lower end of the web 2b also yields when c yields, the constraint from the web 2b to the lower flange 2c can be reduced, and the boundary beam damper 1 can smoothly absorb energy.

By providing drop haunches to the upper flange 2a and the lower flange 2c, even if the deformation level of the boundary beam damper 1 is large, the one end 2d of the H-shaped steel 2 and the pillar 3 are not separated. It is possible to prevent breakage in the welded portion.

The web 2b of the boundary beam damper 1 is gradually lengthened from the central portion 1a toward one end 2d,
By making the lower flange 2c of the H-shaped steel 2 have an inclination with respect to the upper flange 2a, one end 2d of the lower flange 2c when the boundary beam damper 1 is deformed.
It is possible to yield the yield that tends to concentrate on the lower flange 2c over a wide range.

(Second Embodiment of the Invention) A boundary beam damper 1 shown in FIG. 3 includes an upper member composed of a pair of H-shaped steels 2 arranged in parallel between columns 3 of a building, and It is composed of a T-shaped steel 7 which is a lower member attached to the lower end of the H-shaped steel 2.

As in the first embodiment of the present invention, the pair of H-section steels 2 have columns 3 each having one end 2d in advance.
The other end portions 2e adjacent to each other are connected to each other by welding means such as bolts 5 via the splice plate 4 to form a short span boundary beam bridging the columns 3. is doing. In addition, as in the first embodiment of the present invention, since almost no moment is generated in the central portion 1a of the boundary beam damper 1, the pair of H-section steels 2 are connected only by the webs 2b. Yes, the upper flanges 2a and the lower flanges 2c are not joined.

The boundary beam damper 1 described above is the first
Similarly to the embodiment of the present invention, the H-shaped steel 2 forming the boundary beam damper 1 is divided into two, and one end 2d of the divided H-shaped steel 2 is previously attached to the side portion of the pillar 3 in a factory or the like. After welding, the other adjacent end portions 2e of the H-shaped steel 2 are joined by bolts on site. But,
The structure is not limited to this, and both ends of the H-section steel 2 may be welded and fastened to the side portions of the column 3 in the field without dividing the H-section steel 2.

On the lower flange 2c of the H-section steel 2, a web 7b of T-section steel 7 made of extremely mild steel is fixed by fastening means such as welding, and the flange 7a is arranged at the lower end. There is. The web 7b of the T-shaped steel 7 is provided with a plurality of rib plates 7c. The rib plate 7c is made of ordinary steel.
It is provided at right angles to b and connects the flange 7a of the T-shaped steel 7 and the lower flange 2c of the H-shaped steel 2. The member forming the T-section steel 7 is not limited to ultra-soft steel, and may be a steel material such as mild steel as long as it has a lower yield point than the H-section steel 2.

This makes the upper H-section steel 2 have a function as a beam for supporting a floor load, and the T-section attached to the lower flange 2c of the H-section steel 2 at the time of an earthquake.
The shaped steel 7 is intended to yield from one end 7d to absorb energy and to have a function as a damper. As described above, the boundary beam damper 1 according to the second embodiment of the present invention has a function as a boundary beam and a damper as a damper by providing the T-shaped steel 7 made of extremely mild steel under the H-shaped steel 2 as a beam. It is to achieve both functions.

In FIG. 3 (a), the T-section steel 7 has a member length equal to that of the H-section steel 2, and one end 7 d of the T-section steel 7 on the column 3 side is located on the side of the column 3. Although they are fastened, the other ends 7e are not connected to each other. The upper portion of the T-section steel 7 is connected to the boundary beam formed by the H-section steel 2, and one end portion 7d on the side of the column 3 is fastened to the side portion of the column 3, Need not be provided over the entire length of. Therefore, as shown in FIG. 3C, the member length of the T-shaped steel 7 is shortened, and the opening 8 is provided between the other adjacent end portions 7e.
May be provided.

Boundary beam damper 1 having such a configuration
3B, the stud 9 is provided on the upper flange 2a of the H-shaped steel 2 and the RC slab 6 is directly provided, and the boundary beam damper 1 and the RC slab 6 are provided.
Are integrated.

When the deformation level of the boundary beam damper 1 is expected to be large when an earthquake occurs, one end 2d of the H-shaped steel 2 forming the boundary beam damper 1,
For the purpose of preventing breakage at the welded portion between the one end 7d of the T-shaped steel 7 and the column 3, the upper flange 2a, the lower flange 2c, and the flange 7a are cross-sections at positions close to the central portion 1a. A so-called drop haunch having a large cross-sectional area may be provided.

Further, for the purpose of yielding a yield which tends to concentrate on one end 7d of the T-section steel 7 when the boundary beam damper 1 is deformed, to a wide range of the T-section steel 7. The length of the web 7b located on one end 7d side of the T-section steel 7 is set to be sufficiently longer than that of the web 7b located on the other end 7e of the T-section steel 7 close to the central portion 1a. The flange 7a of the steel 7 may be configured to have a gradient with respect to the lower flange 2c of the H-shaped steel 2.

According to the structure described above, the boundary beam damper 1
Is composed of an upper member made of H-shaped steel 2 and a lower member made of T-shaped steel 7 provided at the lower end thereof,
With a simple structure, no special work is required for processing and assembling or on-site construction, good workability and no cost burden.

The H-shaped steel 2 forming the boundary beam damper 1 has a function as a boundary beam, and the T-shaped steel 7 provided at the lower end portion thereof has a function as a damper. Since 7 is configured to bend and deform over the entire length, the H-shaped steel 2 itself does not cause a local angle change even during an earthquake, so the H-shaped steel 2 and RC slab placed above the boundary beam damper 1 6 can be integrated with each other, the construction is easy, and it is not necessary to separately attach a member for receiving the RC slab 6, which can greatly contribute to cost reduction.

The boundary beam damper 1 is constructed by dividing the H-shaped steel 2 constituting the boundary beam damper 1 and the T-shaped steel 7 connected to the lower end of the boundary beam damper 1 into two parts. One end 2d, 7d of each T-shaped steel 7 is welded to the side of the column 3 in advance in a factory or the like, and the other adjacent end 2e of the H-shaped steel 2 that is divided on the spot is connected by a bolt 5. Since they are all fastened, the construction is simple and can greatly contribute to shortening the construction period and cost.

T-shaped steel 7 constituting the boundary beam damper 1
Has excellent weldability because it uses ultra-soft steel as a member, and the welding to the column 3 is the low-strength steel used for welding the high-strength steel used for the H-section steel 2 and general steel structures. A hydrogen-based welding rod can be used together, and upper members made of different steel materials,
The welding of the boundary beam damper 1 having the lower member to the column 3 does not need to incorporate a special construction method, and the construction similar to that of a normal steel beam can be performed.

By providing a drop haunch to the upper flange 2a and the lower flange 2c of the H-section steel 2 and the flange 7a of the T-section steel 7 even when the deformation level of the boundary beam damper 1 is large, It is possible to prevent breakage at the welded portion between the end portion of the boundary beam damper 1 and the column 3.

T-shaped steel 7 constituting the boundary beam damper 1
Flange 7a of the H-shaped steel 2 to the lower flange 2c,
By gradually increasing the length of the web 7b as it moves from the other end 2e close to the central portion 1a of the boundary beam damper 1 to the one end 2d, each of which has a slope,
When the boundary beam damper 1 is deformed, it is possible to yield over a wide range of the T-section steel 7 so that the T-section 7 is easily concentrated at one end 7d of the T-section steel 7.

By providing the rib plate 7c on the web 7b of the T-shaped steel 7, local buckling of the web 7b and the flange 7a can be prevented.

T-shaped steel 7 constituting the boundary beam damper 1
Since the upper part thereof is connected to the boundary beam formed by the H-shaped steel 2 and one end 7d on the side of the column 3 is fastened to the side part of the column 3, the boundary beam damper Since the opening 8 can be provided in the central portion 1a of the No. 1, the amount of steel material used can be reduced, and it can be utilized as a storage space for piping equipment and the like.

[0050]

According to the boundary beam damper of the first aspect of the present invention, there is provided a boundary beam damper for suppressing vibration in a steel frame structure, comprising an upper member made of a steel material for connecting adjacent columns, and the upper part. A lower member that is fastened to the lower end of the member and is made of a steel material having a lower yield point than the upper member, at least the end of which is on the pillar side is connected to the side of the pillar. The rational structure allows the upper member to function as a boundary beam and the lower member to function as a damper, and the boundary beam damper causes a local angle change. Since there is no RC slab, the RC slab can be integrated, construction is easy, and it is not necessary to separately attach a member for receiving the RC slab, which greatly contributes to cost reduction. Door can be.

According to the boundary beam damper of the second aspect,
Since it is composed of an H-shaped steel having an upper flange and a web forming the upper member and a lower flange forming the lower member, a general steel beam and its structure do not change, and therefore, work assembling and field construction. It requires no special work, and can be constructed in the same work procedure as a normal steel building.

According to the boundary beam damper of the third aspect,
Since a steel material having a lower yield point than the upper flange is used for the H-section steel web, the lower end of the web also yields when the lower flange yields, so that the constraint on the lower flange from the web is small. The boundary beam damper can smoothly absorb energy.

According to the boundary beam damper of the fourth aspect,
Since the upper and lower flanges at the ends of the H-section steel have larger cross-sectional areas than the central portion of the H-section steel, even when the deformation level of the boundary beam damper is large when an earthquake occurs, It is possible to prevent breakage at the welded portion between the end of the H-section steel and the column.

According to the boundary beam damper of the fifth aspect,
Since the web length is gradually longer from the central portion toward the end portion, the lower flange has a slope with respect to the upper flange,
When the boundary beam damper is deformed, the yield that tends to concentrate on the end portion of the lower flange can be expanded to a wide range of the lower flange.

According to the boundary beam damper of the sixth aspect,
Since the H-shaped steel is used for the upper member and the shaped steel having a flange at the lower end is used for the lower member, no special work is required for processing and assembling or on-site construction with a simple structure. It is good and does not incur costs.

Further, the H-shaped steel constituting the boundary beam damper is made to have a function as a boundary beam, and the shaped steel provided at the lower end portion thereof is made to have a function as a damper so that the shaped steel is provided over the entire length. Since it is configured to bend and deform,
Since the H-section steel itself does not cause a local angle change even during an earthquake, it is possible to integrate the H-section steel and the RC slab placed above the boundary beam damper, and the construction is easy. , It is not necessary to separately attach a member for receiving the RC slab, which can greatly contribute to cost reduction.

According to the boundary beam damper of the seventh aspect,
Since the shaped steel is divided at the central portion and the opening is provided, the amount of steel material can be reduced, and it can be utilized as a storage space for piping equipment and the like.

According to the boundary beam damper of the eighth aspect,
Since a plurality of rib plates having substantially the same length as the web are attached to the shaped steel web vertically to the web, local buckling of the web and the flange can be prevented.

According to the boundary beam damper of the ninth aspect,
In the section steel, the web length gradually increases from the web located near the central portion of the H section steel toward the web located at the end on the column side, and the flange of the section steel is the lower flange of the H section steel. Since it has a gradient with respect to the boundary beam damper, it becomes possible to yield over a wide range of the T-section steel, which is likely to concentrate at the end of the T-section steel when the boundary beam damper is deformed.

According to the boundary beam damper of the tenth aspect, since the floor slab is integrally provided on the upper flange of the H-section steel, the construction is easy and the RC
It is not necessary to separately install a member for receiving the slab, which can greatly contribute to cost reduction.

[Brief description of drawings]

FIG. 1 is a diagram showing a first embodiment of a boundary beam damper according to the present invention.

FIG. 2 is a view showing a modified example of the first embodiment of the boundary beam damper according to the present invention.

FIG. 3 is a diagram showing a second embodiment of the boundary beam damper according to the present invention.

FIG. 4 is a view showing a conceptual diagram of a conventional boundary beam damper.

[Explanation of symbols]

1 Boundary beam damper 1a central part 2 H section steel 2a Upper flange 2b web 2c Lower flange 2d One end 2e The other end Three pillars 4 splice plate 5 Volts 6 RC Slab 7 T-section steel 7a flange 7b web 7c rib plate 7d One end 7e The other end 8 openings 9 studs 21 Boundary beam 22 pillars 23 damper 24 RC Slab

Claims (10)

[Claims] 1. A boundary beam damper for suppressing vibration in a steel frame structure, comprising: an upper member made of a steel material connecting adjacent columns; and a lower part of the upper member fastened to at least the column side. A boundary beam damper comprising: a lower member made of a steel material having a lower yield point than the upper member, an end portion of which is connected to a side portion of a column. 2. The boundary beam damper according to claim 1, wherein the boundary beam damper is made of an H-shaped steel having an upper flange and a web forming the upper member and a lower flange forming the lower member. Boundary beam damper. 3. The boundary beam damper according to claim 2, wherein a steel material having a lower yield point than that of the upper flange is used for the H-shaped steel web. 4. The boundary beam damper according to claim 2, wherein the upper flange and the lower flange of the end portion of the H-section steel have a larger cross-sectional area than the central portion of the H-section steel. Boundary beam damper. 5. The boundary beam damper according to any one of claims 2 to 4, wherein the H-section steel has a web length gradually increasing from a central portion toward an end portion, and the lower flange is larger than the upper flange. A boundary beam damper characterized by having a slope. 6. The boundary beam damper according to claim 1, wherein an H-shaped steel is used for the upper member, and a shaped steel having a flange at a lower end is used for the lower member. Boundary beam damper. 7. The boundary beam damper according to claim 6, wherein the shaped steel is divided at a central portion and an opening is provided. 8. The boundary beam damper according to claim 7 or 8, wherein a plurality of rib plates having substantially the same length as the web are attached to the web of the shaped steel vertically to the web. Boundary beam damper. 9. The boundary beam damper according to claim 6, wherein the shaped steel is directed from a web located at a central portion of the H-shaped steel toward a web located at a column-side end portion. The web length is gradually longer, and the flange of the shaped steel is
A boundary beam damper characterized by having a slope with respect to the lower flange of the section steel. 10. The boundary beam damper according to claim 1, wherein the upper flange of the H-section steel is
A boundary beam damper characterized in that a floor slab is integrally provided.