JP7377186B2 - Joint structure of steel braces with H-shaped cross section, mixed frame of reinforced concrete columns and steel beams - Google Patents

Description

The present invention relates to a joint structure of steel braces with an H-shaped cross section, and a mixed frame of reinforced concrete columns and steel beams.

BACKGROUND OF THE INVENTION In order to increase the rigidity of a beam-column frame including columns and beams that constitute the frame of an architectural structure, it is widely used to provide braces within the beam-column structure. In a column-beam frame provided with braces, it is necessary to efficiently transmit the axial force generated in the braces to the column-beam frame.

For example, Patent Documents 1 and 2 disclose a structure in which a bar-shaped brace is joined to a column-beam joint.
In Patent Document 1, a gusset plate (brace installation member) provided at the end of a rod-shaped brace is joined to a steel beam and a reinforcing steel plate provided to surround a joint joint of a column (column frame). ing.
Further, in Patent Document 2, the end of a rod-shaped brace is attached to an upper flange of a steel beam via a gusset plate (splint plate), and a part of the gusset plate is buried in a column made of reinforced concrete.
In the configurations disclosed in Patent Documents 1 and 2, the gusset plate has a plate shape disposed along the structural surface of the column and beam, and has a cross section different from that of the rod-shaped brace. Therefore, it cannot be said that all of the axial force of the brace is efficiently transmitted to the joint joint through the gusset plate.
In particular, when compressive force is applied to the brace, the bending stiffness in the out-of-plane direction (weak axis direction) perpendicular to the column-beam structural surface is greater than that in the in-plane direction (strong axis direction) along the column-beam structural surface. It cannot be said that the bending rigidity is high.

Further, Patent Document 3 discloses a configuration using H-beam steel as a brace. More specifically, in Patent Document 3, the ends of the H-shaped steel constituting the brace are coaxially butted and joined to the joining member made of the H-shaped steel, and the joining member is connected to the column through a gusset plate. It is attached to the joint of the beam frame member.
Further, FIG. 7 shows a conventional configuration different from that of Patent Document 3, in which steel braces having an H-shaped cross section are joined using gusset plates. The column-beam frame 1 shown in FIG. 7 includes columns 2 made of reinforced concrete, beams 3 made of steel, and braces 4 made of H-shaped steel. The brace 4 is connected to the joint between the column 2 and the beam 3 via a bracket 5 made of H-beam steel. A gusset plate 6 is provided between the bracket 5 and the pillar 2 and beam 3. The gusset plate 6 has a plate shape along the column-beam structure including the columns 2 and beams 3. A portion 6c of the gusset plate 6 is buried in the column 2 made of reinforced concrete.
Even in these configurations, the gusset plate is plate-shaped along the column-beam structural surface, so at the joint of the brace, the bending rigidity in the in-plane direction (strong axis direction) along the column-beam structural surface is It cannot be said that the bending rigidity in the out-of-plane direction (weak axis direction) is high compared to the above.

Japanese Patent Application Publication No. 7-331739 JP2016-98586A Japanese Patent Application Publication No. 7-42234

The problem to be solved by the present invention is to provide a joint structure for steel braces with an H-shaped cross section, which can increase the buckling strength in the weak axis direction at the joint of steel braces with an H-shaped cross section, and a mixed reinforced concrete column/steel beam structure. The goal is to provide a framework.

In order to solve the above problems, the present invention employs the following means.
That is, the joining structure of a steel brace with an H-shaped cross section of the present invention is a joint structure of a steel brace with an H-shaped cross section to a joint between a reinforced concrete column and a steel beam with an H-shaped cross section, and the flange of the steel beam a first flange provided at a distance from the first flange; a bracket for joining the steel brace to the flange of the steel beam, the bracket having a web joined to the first flange; a reinforcing rib plate vertically connected to the flange and joined to the web of the bracket, one end of the first flange being connected to a side of the steel brace opposite to the steel beam. The other end is fixed to the inside of the concrete constituting the reinforced concrete column, and the end of the web of the bracket on the other side is also fixed to the inside of the concrete. Features.
According to such a configuration, the steel brace having an H-shaped cross section is joined to the flange of the steel beam via the bracket. The first flange of the bracket has one end joined to a flange on the opposite side of the steel beam in the steel brace, and the other end of the first flange and the end of the web of the bracket on the other side of the first flange. It is anchored inside the concrete that makes up the reinforced concrete column. Further, a reinforcing rib plate is provided to connect the flange of the steel beam and the first flange in the vertical direction and to be joined to the web of the bracket. The first flange and the reinforcing rib plate resist bending stress of the bracket in an out-of-plane direction perpendicular to the column-beam structural surface. In particular, since the other end of the first flange and the end of the web of the bracket are fixed inside the concrete that constitutes the reinforced concrete column, they are supported by the concrete and can withstand the above bending stress. It has strong resistance and can transmit stress directly to the reinforced concrete column. Therefore, it is possible to realize a column-beam frame with steel braces and an H-shaped cross section that has high bending rigidity even in the out-of-plane direction.
In addition, due to the reinforcing rib plate, when bending stress or compressive axial force in an out-of-plane direction acts on the bracket, these forces are transmitted from the steel brace with an H-shaped cross section to the bracket, and further via the reinforcing rib plate. It is dispersed and transmitted from the concrete of the joint joint to its interior. This prevents concrete from cracking and crushing around the bracket.
Therefore, at the joint of the steel brace with the H-shaped cross section, it is possible to increase the buckling strength in the direction of the weak axis, which is an out-of-plane direction orthogonal to the column-beam structural surface.

In one aspect of the present invention, the joining structure of a steel frame brace with an H-shaped cross section of the present invention is such that the bracket further includes a second flange provided at a position closer to the steel beam than the first flange, and One end of the second flange was joined to the flange of the steel beam on the steel beam side, and the other end was welded to the flange of the steel beam, and the reinforcing rib plate of the steel beam was joined. A first reinforcing plate is provided at a position extending between the upper and lower flanges of the steel beam to vertically connect them, and a first reinforcing plate is provided at a position of the steel beam at a position where the second flange is welded. A second reinforcing plate is provided that extends between the upper and lower flanges of the steel beam and connects them in the vertical direction.
According to such a configuration, one end of the second flange of the bracket is joined to the flange on the steel beam side of the steel brace, and the other end is joined to the second reinforcing plate via the flange of the steel beam. . This second flange resists the bending stress of the bracket in an out-of-plane direction perpendicular to the column-beam structural surface, thereby further increasing the bending rigidity of the bracket in the out-of-plane direction. Further, the bending stress and compressive axial force transmitted from the steel beam-side flange of the H-shaped cross-sectional steel brace to the bracket are transmitted to the second reinforcing plate of the steel beam via the second flange of the bracket.
Further, the first reinforcing plate is provided at the position of the steel beam where the reinforcing rib plate is joined, extending between the upper and lower flanges of the steel beam and connecting these in the vertical direction. The bending stress and compressive axial force that are transmitted to the reinforcing rib plate via the steel brace and the bracket are distributed and transmitted from the concrete of the joint joint to the inside of the reinforcing rib plate through this first reinforcing plate. be done. This prevents concrete from cracking and crushing around the bracket.
Therefore, it is possible to further increase the buckling strength in the out-of-plane direction of the column-beam structural surface, which is the weak axis direction.

The reinforced concrete column/steel beam mixed frame of the present invention includes a reinforced concrete column, a steel beam with an H-shaped cross section that is joined to the reinforced concrete column, and an H-shaped cross section as described above at the joint between the reinforced concrete column and the steel beam. A steel brace with an H-shaped cross section joined by a joint structure of steel braces with a cross section.
According to such a configuration, it is possible to provide a reinforced concrete column/steel beam mixed frame that can increase the buckling strength in the weak axis direction at the joint portion of the steel brace with an H-shaped cross section.

According to the present invention, it is possible to increase the buckling strength in the weak axis direction at the joint portion of a steel brace with an H-shaped cross section.

BRIEF DESCRIPTION OF THE DRAWINGS It is a perspective view which shows the joint structure of the steel frame brace of H-shaped cross section, and the structure of a reinforced concrete column/steel beam mixed frame according to an embodiment of the present invention. It is a perspective view which shows the joint structure of the steel frame brace of H-shaped cross section, and the structure of the reinforced concrete column and steel beam mixed frame based on the 1st modification of embodiment of this invention. It is a perspective view which shows the joint structure of the steel frame brace of H-shaped cross section, and the structure of the reinforced concrete column/steel beam mixed frame according to the second modification of the embodiment of the present invention. It is a perspective view which shows the joint structure of the steel frame brace of H-shaped cross section, and the structure of the reinforced concrete column/steel beam mixed frame based on the 3rd modification of embodiment of this invention. It is a perspective view which shows the joint structure of the steel frame brace of H-shaped cross section, and the structure of the reinforced concrete column/steel beam mixed frame based on the 4th modification of embodiment of this invention. It is a perspective view which shows the joint structure of the steel frame brace of H-shaped cross section, and the structure of the reinforced concrete column/steel beam mixed frame based on the 5th modification of embodiment of this invention. FIG. 2 is a perspective view showing the configuration of a joining structure of a steel brace with an H-shaped cross section using a conventional gusset plate.

In the joint structure of a steel brace with an H-shaped cross section in the present invention, the end of the steel brace with an H-shaped cross section is arranged at the joint of a column-beam frame between a reinforced concrete column and a steel beam with an H-shaped cross section, and the steel brace is The flange of the bracket and the first flange of the bracket (the upper flange if the bracket is on the upper side of a steel beam) are joined, and the first flange of the bracket and the web are extended to the inside of the reinforced concrete column and fixed.
In the present invention, by embedding a bracket having a first flange joined to a steel brace with an H-shaped cross section in the joint between an RC column and an S-beam frame, the first flange of the bracket constituting the joint structure of the steel brace is , the web extending from the first flange, and the reinforcing rib plate provided vertically between the flange of the steel beam and the first flange of the bracket increase the bending strength and bending rigidity in the out-of-plane direction. Therefore, the degree of fixation of the material end of the H-shaped cross-section steel brace in the out-of-plane weak axis direction is increased, so the buckling strength in the out-of-plane weak axis direction is increased, and the H-shaped cross-section has excellent structural performance. A joint structure of steel braces is realized.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, with reference to the accompanying drawings, a joint structure for steel braces with an H-shaped cross section and a form for implementing a reinforced concrete column/steel beam mixed frame according to the present invention will be described based on the drawings.

FIG. 1 is a perspective view showing a joint structure of steel braces with an H-shaped cross section and a configuration of a reinforced concrete column/steel beam mixed frame according to an embodiment of the present invention.
As shown in FIG. 1, the reinforced concrete column/steel beam mixed frame 10A includes a reinforced concrete column 20, a steel beam 30, and a steel brace 40.
The reinforced concrete column 20 extends in the vertical direction. The reinforced concrete column 20 includes a plurality of main bars 21 extending in the vertical direction, a plurality of shear reinforcing bars 22 provided to surround these main bars 21, and concrete 24 in which the main bars 21 and shear reinforcing bars 22 are buried. , is equipped with.
The steel beams 30 extend horizontally and are constructed between adjacent reinforced concrete columns 20. In this embodiment, the steel beams 30 are provided on each of the four sides of the reinforced concrete column 20. The four steel beams 30 are joined to each other within the concrete 24 of the reinforced concrete column 20. The steel beam 30 has an H-shaped cross section, and includes upper and lower flanges 31 and 32 arranged at intervals in the vertical direction, and a web 33 provided between the upper and lower flanges 31 and 32. ing. The web 33 is formed along a vertical plane that includes the extending direction of the steel beam 30. The upper and lower flanges 31 and 32 are each formed along a horizontal plane that includes the extending direction of the steel beam 30.

The steel brace 40 extends diagonally within a vertical plane (which is appropriately referred to as a column-beam structural plane) that includes the extending direction (center axis) of the reinforced concrete column 20 and the extending direction of the steel beam 30. The steel brace 40 has an H-shaped cross section, and includes a flange 41 on the opposite side to the steel beam 30, a flange 42 on the steel beam 30 side, and a web 43 provided between the flanges 41 and 42. have. The ends of the steel braces 40 are connected via brackets 50 to joint joints J where the reinforced concrete columns 20 and steel beams 30 are joined.
In this embodiment, since the steel brace 40 is joined to the upper side of the steel beam 30, the flange 41 on the opposite side to the steel beam 30 is located higher than the flange 42 on the side of the steel beam 30. . Further, the flange 41 on the opposite side to the steel beam 30 is located closer to the reinforced concrete column 2 than the flange 42 on the steel beam 30 side.

The bracket 50 joins the steel brace 40 to the flange 31 of the steel beam 30. The bracket 50 has a first flange 51, a second flange 52, and a web 53.
The web 53 is provided in the same column-beam structural surface as the web 43 of the steel brace 40 and the web 33 of the steel beam 30 in which the column-beam frame is constructed. The first flange 51 and the second flange 52 are positioned so that their width directions are perpendicular to the column and beam structural surfaces.
The first flange 51 is provided apart from the flange 31 of the steel beam 30, particularly above in this embodiment. The second flange 52 is provided at a position closer to the steel beam 30 than the first flange 51, that is, further below. The web 53 of the bracket 50 is provided to connect the first flange 51 and the second flange 52. An end 50a of the bracket 50 on the steel brace 40 side is disposed on the same axis as the steel brace 40. At the end portion 50a, the bracket 50 has the same H-shaped cross-sectional shape as the steel beam 30. At the end 50a of the bracket 50, one end 51a of the first flange 51 is joined to the flange 41 of the steel brace 40 on the opposite side to the steel beam 30. At the end portion 50a, one end 52a of the second flange 52 is joined to the flange 42 of the steel brace 40 on the steel beam 30 side. At the end 50a, the web 53 of the bracket 50 is joined to the web 43 of the steel brace 40.

The first flange 51 extends diagonally downward toward the reinforced concrete column 20 from the flange 41 of the steel brace 40 on the opposite side to the steel beam 30. The other end 51b side of the first flange 51 extends in the horizontal direction. The other end 51b of the first flange 51 is fixed inside the concrete 24 that constitutes the reinforced concrete column 20. The first flange 51 has a curved portion 51c between one end 51a and the other end 51b. The curved portion 51c of the first flange 51 is provided with a first reinforcing rib 54 that extends toward the second flange 52 side. The first reinforcing rib 54 is welded to the web 53.
The second flange 52 extends diagonally downward toward the reinforced concrete column 20 from the flange 42 of the steel brace 40 on the steel beam 30 side. The other end 52b side of the second flange 52 extends in the vertical direction. The other end 52b of the second flange 52 is welded to the flange 31 of the steel beam 30. The second flange 52 has a curved portion 52c between one end 52a and the other end 52b. The curved portion 52c of the second flange 52 is provided with a second reinforcing rib 55 that extends toward the first flange 51 side. The second reinforcing rib 55 is welded to the web 53.
The web 53 of the bracket 50 has an upper end welded to the first flange 51 and a lower end welded to the flange 31 of the steel beam 30 in a portion closer to the reinforced concrete column 20 than the other end 52b of the second flange 52. . An end 53b of the web 53 of the bracket 50 on the other end 51b side of the first flange 51 is fixed inside the concrete 24 together with the other end 51b.

The steel beam 30 is provided with a first reinforcing plate 61, a second reinforcing plate 62, and a reinforcing rib plate 63.
The reinforcing rib plate 63 vertically connects the flange 31 of the steel beam 30, particularly located on the upper side in this embodiment, and the first flange 51 of the bracket 50, and is joined to the web 53 of the bracket 50. ing.
The first reinforcing plate 61 extends between the upper and lower flanges 31 and 32 of the steel beam 30 and connects them in the vertical direction. The first reinforcing plate 61 is provided at a position where the reinforcing rib plate 63 is joined when viewed from above.
The first reinforcing plate 61 and the reinforcing rib plate 63 are formed along the side surface 24s of the concrete 24 facing the steel beam 30 and the steel brace 40 in the reinforced concrete column 20. These first reinforcing plates 61 and reinforcing rib plates 63 function as bearing plates that receive axial force input from the steel braces 40 and the steel beams 30. The first reinforcing plate 61 and the reinforcing rib plate 63 have the same width as the first flange 51.
The second reinforcing plate 62 extends vertically between the upper and lower flanges 31 and 32 of the steel beam 30 at a position where the second flange 52 is welded to the flange 31 of the steel beam 30. The second reinforcing plate 62 vertically connects the upper and lower flanges 31 and 32 of the steel beam 30.

According to the connection structure of the steel brace 40 with an H-shaped cross section as described above, the connection structure of the steel brace 40 with an H-shaped cross section has an H-shaped connection structure with respect to the joint between the reinforced concrete column 20 and the steel beam 30 with an H-shaped cross section. A joint structure of a steel brace 40 in a cross section, which includes a first flange 51 provided apart from a flange 31 of a steel beam 30 and a web 53 joined to the first flange 51, and connects the steel brace 40 to a steel beam. 30, and a reinforcing rib plate 63 that connects the flanges 31, 32 of the steel beam 30 and the first flange 51 in the vertical direction and is joined to the web 53 of the bracket 50. One end 51a of the first flange 51 is joined to the flange 41 of the steel brace 40 on the opposite side to the steel beam 30, and the other end 51b is fixed inside the concrete 24 constituting the reinforced concrete column 20. At the same time, the end 53b of the web 53 of the bracket 50 on the other end 51b side is also fixed inside the concrete 24.
According to such a configuration, the steel brace 40 having an H-shaped cross section is joined to the flange 31 of the steel beam 30 via the bracket 50. The first flange 51 of the bracket 50 has one end 51 a joined to the flange 41 on the opposite side of the steel beam 30 in the steel brace 40 , and the other end 51 b of the first flange 51 and the first flange 51 of the web 53 of the bracket 50 . An end 53b of the flange 51 on the other end 51b side is fixed inside the concrete 24 that constitutes the reinforced concrete column 20. Further, a reinforcing rib plate 63 is provided to connect the flange 31 of the steel beam 30 and the first flange 51 in the vertical direction and to be joined to the web 53 of the bracket 50. The first flange 51 and the reinforcing rib plate 63 resist bending stress of the bracket 50 in an out-of-plane direction perpendicular to the column-beam structural surface. In particular, since the other end 51b of the first flange 51 and the end 53b of the web 53 of the bracket 50 are fixed inside the concrete 24 constituting the reinforced concrete column 20, by being supported by the concrete 24, the above-mentioned It is possible to strongly resist bending stress such as, and furthermore, the stress can be directly transmitted to the reinforced concrete column 20. Therefore, it is possible to realize a column-beam frame with steel braces 40 having an H-shaped cross section and having high bending rigidity even in the out-of-plane direction.
In addition, when bending stress or compressive axial force in an out-of-plane direction is applied to the bracket 50 by the reinforcing rib plate 63, these forces are transmitted from the steel brace 40 with an H-shaped cross section to the bracket 50, and the reinforcing rib plate 63, it is dispersed and transmitted from the concrete 24 of the joint J to its interior. This suppresses cracking of the concrete 24 and crushing of the concrete 24 around the bracket 50.
Therefore, at the joint of the steel brace 40 having an H-shaped cross section, it is possible to increase the buckling strength in the direction of the weak axis, which is an out-of-plane direction orthogonal to the column-beam structural surface.

The bracket 50 further includes a second flange 52 provided at a position closer to the steel beam 30 than the first flange 51, and one end 52a of the second flange 52 is connected to the steel beam 30 side of the steel brace 40. The other end 52b is welded to the flange 31 of the steel beam 30, and the reinforcing rib plate 63 of the steel beam 30 is connected between the upper and lower flanges 31 and 32 of the steel beam 30. A first reinforcing plate 61 is provided that extends to connect these in the vertical direction, and the upper and lower flanges 31 and 32 of the steel beam 30 are provided at the position where the second flange 52 of the steel beam 30 is welded. A second reinforcing plate 62 is provided that extends between them and vertically connects them.
According to such a configuration, the second flange 52 of the bracket 50 has one end 52a joined to the flange 32 of the steel beam 30 of the steel brace 40, and the other end 52b connected to the flange 31 of the steel beam 30. It is joined to the second reinforcing plate 62. The second flange 52 resists the bending stress of the bracket 50 in an out-of-plane direction perpendicular to the column-beam structural surface, thereby further increasing the bending rigidity of the bracket 50 in an out-of-plane direction. Further, the bending stress and compressive axial force transmitted from the flange 32 on the steel beam 30 side of the steel brace 40 having an H-shaped cross section to the bracket 50 are transferred to the second reinforcement of the steel beam 30 via the second flange 52 of the bracket 50. is transmitted to plate 62.
Further, the first reinforcing plate 61 extends between the upper and lower flanges 31 and 32 of the steel beam 30 at the position where the reinforcing rib plate 63 is joined to the steel beam 30, and connects these in the vertical direction. It is set up like this. The bending stress and compressive axial force transmitted to the reinforcing rib plate 63 via the steel brace 40 and the bracket 50 are transferred from the concrete 24 of the joint joint through the first reinforcing plate 61 as well as the reinforcing rib plate 63. Distributed and transmitted internally. This suppresses cracking of the concrete 24 and crushing of the concrete 24 around the bracket 50.
Therefore, it is possible to further increase the buckling strength in the out-of-plane direction of the column-beam structural surface, which is the weak axis direction.

In particular, in this embodiment, the reinforcing rib plate 63 and the first reinforcing plate 61 are formed along the side surface 24s of the concrete 24 facing the steel brace 40 side.
According to such a configuration, the reinforcing rib plate 63 and the first reinforcing plate 61 can effectively transmit the axial force input from the steel brace 40 and the steel beam 30 to the reinforced concrete column 20.

For example, in the conventional configuration as shown in FIG. 7, in order to share and transmit the axial force generated in the cross section of the brace 4 to the column 2 and the beam 3, the cross-sectional area of the gusset plate 6, that is, the product of the thickness and width, must be It needs to be equal to or larger than the cross-sectional area of the brace 4. However, the thickness of the gusset plate 6 must be less than or equal to the thickness of the web of the beam 3. Therefore, the width of the gusset plate 6 increases as the cross-sectional area of the brace 4 increases. Then, it is necessary to arrange the shear reinforcing bars of the columns 2 so as to penetrate the gusset plates 6, which takes time and effort.
On the other hand, especially in this embodiment, the bracket 50 is provided with a first flange 51, a second flange 52, and a web 53 and has an H-shaped cross section. Thus, the cross-sectional area of the bracket 50 can be made equal to or greater than the cross-sectional area of the brace 4 without making the width of the web 53 excessively large. Thereby, the number of shear reinforcing bars 22 penetrating the web 53 of the bracket 50 can be suppressed, and construction can be facilitated.
Furthermore, in this embodiment, a reinforcing rib plate 63 is provided closely on the side surface 24s of the concrete 24 facing the steel brace 40 side. Further, the reinforcing rib plate 63 has the same width as the first flange 51 and is joined to the first flange 51. As a result, the portion of the bracket 50 that contacts the concrete 24 has a simple rectangular shape. Therefore, when pouring the concrete 24 of the reinforced concrete column 20 during construction, processing of the formwork becomes easy.

The bracket 50 also includes a web 53 provided in the same plane as the web 43 of the steel brace 40 and the web 33 of the steel beam 30, and the web 53 of the bracket 50 is connected to the flange 31 of the steel beam 30 and An end 53b of the web 53 of the bracket 50 on the other end 51b side of the first flange 51 is fixed inside the concrete 24 together with the other end 51b.
According to such a configuration, the steel beam 30 and the steel brace 40 having an H-shaped cross section are welded to the web 53 of the bracket 50, the first flange 51, and the second flange 52 at a plurality of locations, so that the bracket 50 Through this, the steel beam 30 and the steel brace 40 having an H-shaped cross section can be firmly joined.

The first flange 51 has a curved portion 51c between one end 51a and the other end 51b, and the curved portion 51c is provided with a first reinforcing rib 54 extending toward the second flange 52. There is.
Further, the second flange 52 has a curved portion 52c between one end 52a and the other end 52b, and the curved portion 52c is provided with a second reinforcing rib 55 extending toward the first flange 51 side. There is.
According to such a configuration, the bracket 50 can be made even stronger and its bending rigidity can be increased.

According to the reinforced concrete column/steel beam mixed frame 10A as described above, at the reinforced concrete column 20, the steel beam 30 with an H-shaped cross section that is joined to the reinforced concrete column 20, and the joint between the reinforced concrete column 20 and the steel beam 30, According to such a configuration, the steel brace 40 with an H-shaped cross section is joined by the above-described joining structure of the steel brace 40 with an H-shaped cross section. It is possible to provide a reinforced concrete column/steel beam mixed frame 10A that can increase buckling strength in the axial direction.

(First modification of the embodiment)
The joint structure of steel braces with an H-shaped cross section and the reinforced concrete column/steel beam mixed frame of the present invention are not limited to the above-described embodiments described with reference to the drawings, but can be applied in various ways within the technical scope. Variations are possible.
For example, in the above embodiment, the steel brace 40 and the bracket 50 are provided only above one of the four steel beams 30 connected to the reinforced concrete column 20, but the invention is not limited to this. .
For example, as in the reinforced concrete column/steel beam mixed frame 10B shown in FIG. 2, a steel brace 40 and a bracket 50 may be provided above each of the four steel beams 30 connected to the reinforced concrete column 20. In this case, the first flanges 51 of the four brackets 50 and the webs 53 may be joined to each other within the concrete 24 of the reinforced concrete column 20. Moreover, the first flanges 51 and the webs 53 of the four brackets 50 may be arranged at intervals within the concrete 24 of the reinforced concrete column 20 without being joined to each other.

(Second modification of embodiment)
Furthermore, as in the reinforced concrete column/steel beam mixed frame 10C shown in FIG. A steel brace 40 and a bracket 50 may be provided on the upper and lower sides, respectively.
In this case, regarding the steel brace 40C joined to the lower flange 32 of the steel beam 30, the flange 41 on the opposite side to the steel beam 30 is located below the flange 42 on the steel beam 30 side. are doing.
Regarding the bracket 50C that connects the steel brace 40C to the joint joint where the reinforced concrete column 20 and the steel beam 30 are joined, the first flange 51 is provided spaced downward from the flange 32 of the steel beam 30. ing. The second flange 52 is provided at a position closer to the steel beam 30 than the first flange 51, that is, higher than the first flange 51.

(Third modification of embodiment)
Further, in the above embodiment, the first flange 51 and the second flange 52 have curved portions 51c and 52c between the one end 51a and 52a and the other end 51b and 52b, but the invention is not limited to this. .
For example, like the reinforced concrete column/steel beam mixed frame 10D shown in FIG. Then, one end 51a, 52a side and the other end 51b, 52b side may be joined by welding at welded portions 51d, 52d so that these are bent.

(Fourth modification of the embodiment)
Further, in the above embodiment, the first reinforcing plate 61 and the reinforcing rib plate 63 are arranged along the side surface 24s of the concrete 24 of the reinforced concrete column 20, but the present invention is not limited to this.
For example, a reinforced concrete column/steel beam mixed frame 10E shown in FIG. 5 may include a closing plate 28 made of a thin steel plate that surrounds the concrete 24 of the reinforced concrete column 20 on all four sides. In this case, a portion 28a of the closing plate 28 functions as a first reinforcing plate and a reinforcing rib plate.
By providing such a closing plate 28, the shear reinforcing bars 22 inside the closing plate 28 can be omitted.
In particular, by providing the closing plate 28, the closing plate 28 can be used as a disposable formwork when pouring the concrete 24 of the reinforced concrete column 20. This makes construction easier because there is no need to assemble or demold the formwork.
Even when such a closing plate 28 is provided, the steel braces 40 and brackets 50 may be arranged above the steel beams 30 on all four sides, as in the reinforced concrete column/steel beam mixed frame 10F shown in FIG. However, it may also be provided at other locations.
In addition to this, it is possible to select the configurations mentioned in the above embodiments or to change them to other configurations as appropriate, without departing from the gist of the present invention.

10A to 10F Steel beam mixed frame 51b Other end of first flange 20 Reinforced concrete column 52, 52D Second flange 24 Concrete 52a One end of second flange 28 Closing plate (first reinforcing plate, reinforcing rib plate)
30 Steel beam 52b Other end of second flange 31, 32... Flange of steel beam (upper and lower flanges of steel beam)
40, 40C Steel brace 53 Bracket web 41 Flange on the opposite side to the steel beam 53b End portion on the other end side of the web 42 Flange on the steel beam side 61 First reinforcing plate 50, 50C, 50D Bracket 62 Second reinforcing plate 51 , 51D first flange 63 reinforcing rib plate 51a one end of first flange

Claims (3)

A joint structure of a steel brace with an H-shaped cross section for a joint between a reinforced concrete column and a steel beam with an H-shaped cross section,
a bracket that connects the steel brace to the flange of the steel beam, comprising a first flange provided apart from the flange of the steel beam; and a web joined to the first flange;
a reinforcing rib plate that connects the flange of the steel beam and the first flange in the vertical direction and is joined to the web of the bracket;
One end of the first flange is joined to a flange of the steel brace on the opposite side to the steel beam, and the other end is fixed inside concrete constituting the reinforced concrete column,
A joining structure for a steel brace with an H-shaped cross section, wherein the other end of the web of the bracket is also fixed inside the concrete. The bracket further includes a second flange provided at a position closer to the steel beam than the first flange,
One end of the second flange is joined to the flange of the steel beam on the steel beam side, and the other end is welded to the flange of the steel beam,
A first reinforcing plate is provided at a position of the steel beam where the reinforcing rib plate is joined, extending between the upper and lower flanges of the steel beam and connecting them in the vertical direction,
A second reinforcing plate is provided at a position of the steel beam where the second flange is welded, and extends between the upper and lower flanges of the steel beam and connects them in the vertical direction. The joining structure of a steel brace with an H-shaped cross section according to claim 1. reinforced concrete columns,
a steel beam with an H-shaped cross section connected to the reinforced concrete column;
At the joint between the reinforced concrete column and the steel beam, an H-shaped cross-section steel brace joined by the H-shaped cross-section steel brace joint structure according to claim 1 or 2;
A mixed reinforced concrete column/steel beam structure characterized by comprising: