JP7291001B2 - Brace structure - Google Patents

Description

In the present invention, a plurality of braces are installed in a grid pattern on a vertical structural surface formed between upper and lower steel beams, and the braces that intersect in the vertical structural surface are displaced in the out-of-plane direction of the vertical structural surface. Regarding the brace structure that is placed in the state.

In a brace structure in which multiple braces are installed in a grid pattern on a vertical structural surface formed between upper and lower steel beams, the out-of-plane direction of the vertical structural surface is arranged so that the crossing braces do not contact each other on the vertical structural surface. are arranged in a shifted state (see, for example, Patent Document 1).

JP-A-53-001923

In such a conventional brace structure, a torsional force is generated in the steel beam due to the axial force transmitted from the brace. In order to suppress the deformation of the steel frame beams due to the torsional force, for example, if the steel frame beams are constructed to be sufficiently strong, there are problems such as deterioration of the design and an increase in cost.
In view of this situation, the main object of the present invention is to provide a brace structure in which a plurality of braces are laid out in a grid-like manner in a state in which a plurality of braces are shifted in the out-of-plane direction. It is to provide a technology capable of suppressing the torsional deformation of

In a first characteristic configuration of the present invention, a plurality of braces are installed in a grid pattern on a vertical structure surface formed between upper and lower steel beams,
A brace structure in which the braces that intersect in the vertical structural plane are arranged in a state of being displaced in the out-of-plane direction of the vertical structural plane,
A torsional deformation preventing means for preventing torsional deformation of the steel beam ,
The torsional deformation prevention means is configured by arranging a pair of reinforcing ribs on both sides of the connection position of the brace along the longitudinal direction of the steel beam.

According to this configuration, even if a torsional force is generated in the upper and lower steel beams due to the axial force transmitted from the braces arranged in a state of being displaced in the out-of-plane direction of the vertical structural surface, the torsional deformation prevention means prevents torsional deformation of the steel frame beam. In other words, torsional deformation of the steel beam can be suitably suppressed without constructing the steel beam excessively strongly.
Therefore, according to the present invention, it is possible to suppress torsional deformation of the upper and lower steel beams while avoiding deterioration of design and cost increase as much as possible in a brace structure in which a plurality of braces are displaced in the out-of-plane direction. technology can be provided.

Furthermore, according to this configuration, since the pair of reinforcing ribs are provided at the joints of the braces in the steel beam, the axial force can be transmitted well from the braces to the steel beam, and the torsion of the steel beam can be reduced. Local deformation due to force can be suppressed.

In the second characteristic configuration of the present invention, at least one of the upper and lower steel beams has a round steel pipe, and in the steel beam, the reinforcing rib cuts above the round steel pipe. It is in that it is provided in the missing notch portion.

According to this configuration, in the case where a pair of reinforcing ribs are provided side by side on both sides of the connection position of the brace along the longitudinal direction of the steel beam configured with the round steel pipe. If a notch is formed by notching the upper part of the round steel pipe, the pair of reinforcing ribs can be easily provided in the notch.

A third characteristic configuration of the present invention is that a plurality of braces are installed in a grid pattern on a vertical structure surface formed between upper and lower steel beams,
A brace structure in which the braces that intersect in the vertical structural plane are arranged in a state of being displaced in the out-of-plane direction of the vertical structural plane,
A torsional deformation preventing means for preventing torsional deformation of the steel beam,
In at least one of the upper and lower steel beams, the torsional deformation preventing means is configured by laterally joining the steel beam to a steel plate slab.

According to this configuration, even if a torsional force is generated in the upper and lower steel beams due to the axial force transmitted from the braces arranged in a state of being displaced in the out-of-plane direction of the vertical structural surface, the torsional deformation prevention means prevents torsional deformation of the steel frame beam. In other words, torsional deformation of the steel beam can be suitably suppressed without constructing the steel beam excessively strongly.
Therefore, according to the present invention, it is possible to suppress torsional deformation of the upper and lower steel beams while avoiding deterioration of design and cost increase as much as possible in a brace structure in which a plurality of braces are displaced in the out-of-plane direction. technology can be provided.
Furthermore, according to this configuration, the means for preventing torsional deformation of the steel beam fixed to the steel plate slab can be configured by joining the steel beam to the steel plate slab from the side by welding or the like. The torsional deformation of the beam can be effectively prevented by the steel plate slab.

A fourth characteristic configuration of the present invention is that a plurality of braces are installed in a grid pattern on a vertical structure surface formed between upper and lower steel beams,
A brace structure in which the braces that intersect in the vertical structural plane are arranged in a state of being displaced in the out-of-plane direction of the vertical structural plane,
A torsional deformation preventing means for preventing torsional deformation of the steel beam,
In at least one of the upper and lower steel beams, the torsional deformation prevention means is a plate portion joined to an upper flange portion of the steel beam and an edge portion of the upper flange portion in abutting state with respect to the concrete slab. The point is that it is configured by embedding the stud bolts arranged in the

According to this configuration, even if a torsional force is generated in the upper and lower steel beams due to the axial force transmitted from the braces arranged in a state of being displaced in the out-of-plane direction of the vertical structural surface, the torsional deformation prevention means prevents torsional deformation of the steel frame beam. In other words, torsional deformation of the steel beam can be suitably suppressed without constructing the steel beam excessively strongly.
Therefore, according to the present invention, it is possible to suppress torsional deformation of the upper and lower steel beams while avoiding deterioration of design and cost increase as much as possible in a brace structure in which a plurality of braces are displaced in the out-of-plane direction. technology can be provided.
Furthermore, according to this configuration, the means for preventing torsional deformation of the steel beam fixed to the concrete slab includes the stud bolts arranged on the upper flange portion of the steel beam and the plate portion joined to the upper flange portion. If configured to be embedded in a concrete slab, the torsional deformation of the steel beam can be effectively prevented by the concrete slab.

Front view showing the overall configuration of the brace structure of the present embodiment Enlarged front view of brace intersection Side view of the brace intersection shown in FIG. Enlarged front view of the brace connection position of the upper steel beam Plan view of the brace connection position of the upper steel frame beam shown in FIG. Side cross-sectional view of the cutout portion of the upper steel frame beam shown in FIG. Side cross-sectional view of the non-notched portion of the upper steel frame beam shown in FIG. Enlarged front view of the brace connection position of the lower steel beam Plan view of the brace connection position of the lower steel frame beam shown in FIG. Side sectional view of the brace connection position of the lower steel beam shown in FIG.

An embodiment of a brace structure according to the present invention will be described based on the drawings.
The brace structure shown in FIG. A plurality of braces 30a and 30b are arranged between the upper and lower steel beams 10 and 20 to form a structure.
In this embodiment, as shown in FIG. 1, the lower steel beam 20 extends horizontally, whereas the upper steel beam 10 extends in a direction slightly inclined with respect to the horizontal direction. It is set in a posture. However, the postures of these upper and lower steel beams 10, 20 may be changed by providing the upper steel beam 10 in a posture extending in the horizontal direction, or providing the lower steel frame beam 20 in a posture extending in a direction slightly inclined with respect to the horizontal direction. You may change it as appropriate.
Further, in the present embodiment, as shown in FIG. 1, the pillar 3 is inclined, but the pillar 3 may be erected in the vertical direction.

As the plurality of braces 30a and 30b, a plurality of first braces 30a are arranged parallel to each other at equal intervals along the in-plane direction of the vertical structural surface 4, and a plurality of first braces 30a are vertically arranged in a posture intersecting the first braces 30a. A plurality of second braces 30b are arranged parallel to each other at regular intervals along the in-plane direction of the structural surface 4 .
Further, the first brace 30a is provided in a posture extending obliquely upward to the right from the lower end connected to the lower steel frame beam 20 to the upper end connected to the upper steel frame beam 10 in plan view shown in FIG. , the plurality of second braces 30b are provided in a posture extending obliquely upward to the left from the lower end connected to the lower steel frame beam 20 to the upper end connected to the upper steel frame beam 10 in plan view shown in FIG.

The upper steel beam 10 and the lower steel beam 20 are configured by welding upper flange portions 11 and 21 and lower flange portions 12 and 22 to upper and lower ends of a web 13 made of flat steel. The upper ends of the braces 30a and 30b are connected to the lower flange portion 12 of the upper steel beam 10, and the lower ends of the braces 30a and 30b are connected to the upper flange portion 21 of the lower steel beam 20.
The connection position of the braces 30a and 30b to the lower flange portion 12 of the upper steel beam 10 is called a brace upper end connection position P1, and the connection position of the braces 30a and 30b to the upper flange portion 21 of the lower steel beam 20 is called a brace lower end connection. Call it position P2.

The first brace 30a and the second brace 30b, which intersect on the vertical structure surface 4, are arranged on the vertical structure surface so that the first brace 30a is on the front side and the second brace 30b is on the back side in the plan view shown in FIG. 4 are displaced in the out-of-plane direction (the depth direction in FIG. 1).
As shown in FIGS. 2 and 3, the first brace 30a and the second brace 30b, which are displaced in the out-of-plane direction of the vertical structural surface 4, are connected by a brace connecting portion 32 at their intersection. ing. The brace connecting portion 32 is constructed by welding and joining both ends of a bar inserted in the gap at the intersection of the first brace 30a and the second brace 30b to the side surfaces of the first brace 30a and the second brace 30b. there is By providing such a brace connecting portion 32, the occurrence of buckling due to compressive force in one of the first brace 30a and the second brace 30b is suppressed by the tension of the other brace whose posture is maintained by tensile force. is prevented by the connection via the brace connection portion 32 to the .

A plurality of clearance braces 30c are arranged on both sides of the vertical structural surface 4. As shown in FIG. The gap braces 30c are arranged parallel to the braces 30a and 30b at the same pitch, and obliquely extend parallel to the braces 30a and 30b from the upper end to the lower end connected to the column 3, and They are arranged at the same pitch as the braces 30a and 30b. In addition, the lower end of the gap brace 30c is in a state of being slightly lifted from the lower steel frame beam 20. As shown in FIG. Further, the gap brace 30c is also provided with the brace connecting portion 32 at the intersection of the first brace 30a and the second brace 30b.

In the brace structure as described above, the axial force transmitted from the braces 30a and 30b generates a torsional force on the steel beams 10 and 20, and the torsional force may cause torsional deformation of the upper and lower steel beams 10 and 20. Therefore, in the brace structure of this embodiment, torsional deformation of the upper and lower steel beams 10, 20 can be suppressed while avoiding deterioration of design and cost increase as much as possible. A torsional deformation prevention means X is provided. Hereinafter, detailed configurations related to the torsional deformation prevention means X in each of the upper steel beam 10 and the lower steel beam 20 will be described in order.

First, the configuration of the torsional deformation prevention means X in the upper steel beam 10 will be described with reference to FIGS. 1 and 4 to 7. FIG.
As shown in FIGS. 6 and 7, the upper steel beam 10 is composed of an upper flange portion 11 made of flat steel, a lower flange portion 12 made of a round steel pipe, and a flat steel connecting them. It is configured by integrating with the web 13 by welding. Further, as shown in FIG. 4, the lower flange portion 12 has a first lower flange portion 12a having a lower semicircular shape with a cutout portion 14 in the upper half, and a cutout portion 14 as the cutout portion 14. The circular second lower flange portions 12 b having no ridges are alternately arranged along the longitudinal direction of the upper steel frame beam 10 . The portion of the lower flange portion 12 that becomes the brace upper end connection position P1 is a semicircular first lower flange portion 12a having a notch portion 14, and the other portion has the notch portion 14. The second lower flange portion 12b has a full circular shape.

Furthermore, in the torsional deformation prevention means X, as shown in FIGS. A plurality of reinforcing ribs 15 are arranged side by side in a stiffener-like state in which their outer peripheries are welded to the lower surface of the upper flange portion 11, the upper surface of the first lower flange portion 12a and the side surface of the web 13. As shown in FIG. As for the arrangement position of the reinforcing ribs 15 on the upper steel beam 10, a pair of reinforcing ribs 15 are arranged on both sides of the brace upper end connection position P1 along the longitudinal direction of the upper steel beam 10, respectively.

In this way, since the reinforcing rib 15 is provided at the brace upper end connection position P1 of the upper steel beam 10, the axial force transmitted from the braces 30a and 30b to the first lower flange portion 12a of the upper steel beam 10 is applied to the brace. The force is well transmitted to the web 13 of the upper steel frame beam 10 and the upper flange portion 11 through the pair of reinforcing ribs 15 positioned on both sides of the width direction of the 30a and 30b. Therefore, local torsional deformation of the first lower flange portion 12a to which the braces 30a and 30b are connected in the upper steel beam 10 is suppressed by the entire upper steel beam 10 and the like.

Furthermore, in the upper steel beam 10, as shown in FIGS. It is configured by joining from the side.

Specifically, the steel plate slab 40 is configured by sandwiching a plurality of beam members (not shown) made of shaped steel arranged side by side between an upper steel plate 41 and a lower steel plate 44 and joining them by welding or the like. It is In this steel plate slab 40, the upper steel plate 41 is welded to the upper surface of the upper flange portion 11 of the upper steel beam 10 in a state of being arranged on the side of the upper steel beam 10, and the edge of the lower steel plate 44 is attached to the lower steel beam 10. It is welded to the lower flange portion 12 of the upper steel beam 10 via a lower steel plate joint bracket 45 extending along the steel plate 44 .
With such a configuration of the torsional deformation prevention means X, the torsional deformation of the entire upper steel frame beam 10 is satisfactorily prevented by the steel plate slab 40 .

Next, the configuration of the torsional deformation prevention means X in the lower steel beam 20 will be described with reference to FIGS. 1 and 8 to 10. FIG.
The lower steel beam 20 is constructed as an H-section steel having a flat upper flange portion 21, a flat lower flange portion 22, and a flat web 23 connecting them.

Further, in the torsional deformation prevention means X, as shown in FIGS. A plurality of reinforcing ribs 25 are arranged side by side in a stiffener-like state in which the outer periphery is welded to the lower surface of the upper flange portion 21 , the upper surface of the lower flange portion 22 and the side surface of the web 23 . 1, 8 and 9, the positions of the reinforcing ribs 25 on the lower steel beam 20 are arranged on both sides of the brace lower end connection position P2 along the longitudinal direction of the lower steel beam 20. A pair of reinforcing ribs 25 are arranged side by side.

In this way, since the reinforcing rib 25 is provided at the brace lower end connection position P2 of the lower steel beam 20, the axial force transmitted from the braces 30a and 30b to the upper flange portion 21 of the lower steel beam 20 is applied to the brace. The force is well transmitted to the web 23 and the lower flange portion 22 of the lower steel frame beam 20 through the pair of reinforcing ribs 25 located on both sides in the width direction of 30a and 30b. Therefore, local torsional deformation of the upper flange portion 21 to which the braces 30a and 30b are connected in the lower steel beam 20 is suppressed by the entire lower steel beam 20 and the like.

Furthermore, in the lower steel beam 20, as shown in FIG. Stud bolts 28 are embedded in a plate portion 27 joined to the edge of the flange portion 21 and the upper flange portion 21 in abutting state.

Specifically, the concrete slab 50 is constructed along the upper surface of the upper flange portion 21 of the lower steel beam 20 .
On the other hand, on the upper flange portion 21 of the lower steel beam 20, a plate portion 27 made of flat steel is attached to the side end portion of the upper flange portion 21 in a state in which the upper flange portion 21 extends sideways. They are welded together in a butt-to-face state. In addition, a plurality of stud bolts 28 are arranged on the upper surface of the upper flange portion 21 of the lower steel beam 20 and on the upper surface of the plate portion 27 extending laterally therefrom in such a manner as to protrude upward. A stud bolt 28 is embedded in the concrete portion 50 a of the concrete slab 50 .
With such a configuration of the torsional deformation preventing means X, the torsional deformation of the entire lower steel frame beam 20 is effectively prevented by the concrete slab 50 through the plurality of stud bolts 28 .

Furthermore, in addition to the reinforcing ribs 25, plate reinforcing ribs 29 for preventing twisting of the plate portion 27 are provided at the mounting portion of the plate portion 27 in the lower steel frame beam 20. As shown in FIG.
Similar to the reinforcing ribs 25, the plate reinforcing ribs 29 are made of flat steel arranged parallel to the cross section of the lower steel frame beam 20. and a stiffener-like state welded to the upper surface of the lower flange portion 22 and the side surface of the web 23 . As a result, torsional deformation of the plate portion 27 extending laterally from the upper flange portion 21 of the lower steel frame beam 20 is more effectively prevented.

[Another embodiment]
Another embodiment of the present invention will be described. It should be noted that the configuration of each embodiment described below is not limited to being applied alone, and can be applied in combination with the configurations of other embodiments.

(1) In the above embodiment, a plurality of reinforcing ribs 15, 25, 29 are provided on the upper and lower steel beams 10, 20, respectively. It can be changed as appropriate, and part or all of these reinforcing ribs 15, 25, 29 may be omitted as long as the torsional deformation occurring in the steel beams 10, 20 does not pose a problem.

(2) In the above embodiment, the shapes of the upper and lower steel beams 10 and 20 can be changed as appropriate. For example, in the above-described embodiment, the lower flange portion 12 of the upper steel beam 10 is configured using a round steel pipe. You can configure it with

(3) In the above embodiment, the upper steel frame beam 10 is laterally joined to the steel plate slab 40 to realize the torsional deformation preventing means X for preventing the torsional deformation of the upper steel frame beam 10. However, this upper steel frame The structure of the torsional deformation prevention means X in the beam 10 can be changed as appropriate.
On the other hand, in the above embodiment, the torsional deformation preventing means X for preventing torsional deformation of the lower steel beam 20 is realized by joining the lower steel beam 20 to the concrete slab 50 via the stud bolts 28. However, the configuration of the torsional deformation prevention means X in the lower steel frame beam 20 can be changed as appropriate.

4 Vertical structural surface 10 Upper steel beam 14 Notch portion 15 Reinforcement rib 20 Lower steel beam 21 Upper flange portion 25 Reinforcement rib 27 Plate portion 28 Stud bolt 30a First brace 30b Second brace 32 Brace connecting portion 40 Made of steel plate Slab 50 Concrete slab 50a Concrete portion P1 Brace upper end connection position P2 Brace lower end connection position X Deformation preventing means

Claims (4)

Multiple braces are installed in a grid pattern on the vertical structural plane formed between the upper and lower steel beams.
A brace structure in which the braces that intersect in the vertical structural plane are arranged in a state of being displaced in the out-of-plane direction of the vertical structural plane,
A torsional deformation preventing means for preventing torsional deformation of the steel beam,
A brace structure in which the torsional deformation prevention means is configured by arranging a pair of reinforcing ribs in parallel on both sides of the connection position of the brace along the longitudinal direction of the steel beam. At least one of the upper and lower steel beams has a round steel pipe, and in the steel beam, the reinforcing rib is provided in a cutout portion obtained by cutting an upper portion of the round steel pipe. 2. The brace structure of claim 1 . Multiple braces are installed in a grid pattern on the vertical structural plane formed between the upper and lower steel beams.
A brace structure in which the braces that intersect in the vertical structural plane are arranged in a state of being displaced in the out-of-plane direction of the vertical structural plane,
A torsional deformation preventing means for preventing torsional deformation of the steel beam,
A brace structure in which, in at least one of the upper and lower steel beams, the torsional deformation preventing means is configured by laterally joining the steel beam to a steel plate slab. Multiple braces are installed in a grid pattern on the vertical structural plane formed between the upper and lower steel beams.
A brace structure in which the braces that intersect in the vertical structural plane are arranged in a state of being displaced in the out-of-plane direction of the vertical structural plane,
A torsional deformation preventing means for preventing torsional deformation of the steel beam,
In at least one of the upper and lower steel beams, the torsional deformation prevention means is a plate portion joined to an upper flange portion of the steel beam and an edge portion of the upper flange portion in abutting state with respect to the concrete slab. A brace structure constructed by embedding stud bolts placed in the

Images