JP7362455B2 - frame structure - Google Patents

Description

TECHNICAL FIELD The present invention relates to frame-based structures.

Large columns are sometimes used in buildings to increase rigidity. However, in this case, the portion of the pillar that protrudes from the wall surface becomes large, which may restrict the use of indoor space. For example, Patent Document 1 can be cited as a technique for suppressing the overhang of columns from the wall surface. Patent Document 1 describes a connecting column that includes a pair of connected H-shaped steels.

Unexamined Japanese Patent Publication No. 2016-69839

By the way, various loads such as a horizontal load, a vertical load, and a bending moment act on the two connected columns. The load acting on the two connected columns needs to be transferred to the lower floor.

The present disclosure has been made in view of the above problems, and an object of the present disclosure is to provide a frame structure that can transmit the load acting on two connected columns to the lower floor.

In order to achieve the above object, a frame structure according to one aspect of the present disclosure includes a first column made of steel, a second column made of steel disposed adjacent to the first column, and a second column made of steel disposed adjacent to the first column. A connecting member that connects the second pillar, and a third pillar that is disposed below the first pillar and the second pillar, and the third pillar includes a core material that is a steel material, and a connecting member that connects the core material to the second pillar. and a pillar body made of concrete covering the core material, and the core material is connected to the first pillar and the second pillar.

As a desirable aspect of the above-mentioned frame type structure, the core material includes a core material main body that is an H-beam steel,
The core body includes two flanges and a first reinforcing member joined to the web.

In a desirable aspect of the above-mentioned frame structure, the core material includes a first core body connected to the first pillar, a second core body connected to the second pillar, and the first core body connected to the first pillar. It includes a main body and a second reinforcing member joined to the second core main body.

In a desirable aspect of the above-mentioned frame type structure, the pillar body includes a first pillar main body and a second pillar main body that is disposed below the first pillar main body and has a smaller outer circumference than the outer circumference of the first pillar main body. and.

As a desirable aspect of the above-mentioned frame type structure, the structure extends in a direction perpendicular to the direction in which the first column and the second column are lined up and the longitudinal direction of the first column and the second column, and is connected to the third column. A connected beam is provided, and the beam has a plurality of main reinforcements and a band reinforcement surrounding the plurality of main reinforcements, and at least a part of the main reinforcements penetrates the core material.

As a desirable aspect of the above-mentioned frame type structure, the structure extends in a direction perpendicular to the direction in which the first column and the second column are lined up and the longitudinal direction of the first column and the second column, and is connected to the third column. A connected beam is provided, and the beam has a plurality of main reinforcing bars and a tie bar surrounding the plurality of main reinforcing bars, and at least a part of the main reinforcing bars are connected to the first core body and the second core body. The second reinforcing member is disposed at a position shifted from the main reinforcement in the longitudinal direction of the first column and the second column.

According to the frame structure of the present disclosure, the load acting on two connected columns can be transmitted to the lower floor.

FIG. 1 is a front view of the frame structure of the embodiment. FIG. 2 is a front view of the frame structure of the embodiment. FIG. 3 is a sectional view taken along line AA in FIG. FIG. 4 is a sectional view taken along line BB in FIG. FIG. 5 is a sectional view taken along line CC in FIG. FIG. 6 is a front view of the frame type structure of the first modification. FIG. 7 is a cross-sectional view of the frame type structure of the second modification. FIG. 8 is a front view of the frame type structure of the third modification. FIG. 9 is a front view of the frame structure of the fourth modification.

Hereinafter, the present invention will be explained in detail with reference to the drawings. Note that the present invention is not limited to the modes for carrying out the present invention (hereinafter referred to as embodiments). Furthermore, the constituent elements in the embodiments below include those that can be easily imagined by those skilled in the art, those that are substantially the same, and those that are within the so-called equivalent range. Furthermore, the components disclosed in the embodiments below can be combined as appropriate.

(Embodiment)
FIG. 1 is a front view of the frame structure of the embodiment. FIG. 2 is a front view of the frame structure of the embodiment. FIG. 3 is a sectional view taken along line AA in FIG. FIG. 4 is a sectional view taken along line BB in FIG. FIG. 5 is a sectional view taken along line CC in FIG. In FIGS. 1 and 2, the internal structure of the third pillar 30 is also shown. The frame type structure 100 of this embodiment is used as a structure of a building. The frame type structure 100 is a structure in which a floor and the like are supported by columns and beams.

As shown in FIG. 1, the frame structure 100 includes a first pillar 10, a second pillar 20, a connecting member 90, a beam 98, an intermediate connecting member 60, a rib 15, a rib 25, and a third pillar. It includes a pillar 30, a beam 40, and a beam 40a. The longitudinal direction of the first pillar 10, the second pillar 20, and the third pillar 30 is parallel to the vertical direction. The first pillar 10 and the second pillar 20 are arranged side by side in the horizontal direction. The frame type structure 100 is a structure that includes a plurality of columns including a first column 10 and a second column 20 that are connected, and a plurality of beams that connect the columns.

In the following description, XYZ orthogonal coordinate axes are used. The X-axis is an axis parallel to the direction in which the first pillar 10 and the second pillar 20 are lined up. The Z axis is an axis parallel to the longitudinal direction of the first pillar 10 and the second pillar 20. The Y-axis is an axis perpendicular to the X-axis and the Z-axis. A direction parallel to the X axis is described as an X direction. A direction parallel to the Y axis is described as a Y direction. A direction parallel to the Z axis is referred to as a Z direction. Among the X directions, the direction from the first pillar 10 to the second pillar 20 is defined as the +X direction. The right direction when facing the +X direction is the +Y direction. The upper direction of the Z direction is defined as the +Z direction.

As shown in FIG. 1, the first pillar 10 extends along the Z direction. The longitudinal direction of the first pillar 10 is the Z direction. The first pillar 10 is an H-section steel. The horizontal cross section of the first pillar 10 is H-shaped. The first pillar 10 includes a flange 11, a flange 12, and a web 13. The thickness direction (plate thickness direction) of the flange 11 is parallel to the X direction. The thickness direction means the direction perpendicular to the surface with the largest area in the plate member, and is used in the same meaning in the following description. The thickness direction of the flange 12 is parallel to the X direction. Flange 12 is parallel to flange 11. The thickness direction of the web 13 is parallel to the Y direction. The web 13 is perpendicular to the flanges 11 and 12.

As shown in FIG. 1, the second pillar 20 extends along the Z direction. The longitudinal direction of the second pillar 20 is the Z direction. The second pillar 20 is an H-shaped steel. The horizontal cross section of the second pillar 20 is H-shaped. The second pillar 20 is arranged adjacent to the first pillar 10 in the X direction. The second pillar 20 includes a flange 21, a flange 22, and a web 23. The thickness direction of the flange 21 is parallel to the X direction. The flange 21 faces the flange 12 of the first column 10. The thickness direction of the flange 22 is parallel to the X direction. Flange 22 is parallel to flange 21. The thickness direction of the web 23 is parallel to the Y direction. The web 23 is perpendicular to the flanges 21 and 22.

In the first column 10 and the second column 20, the rigidity against a bending moment around the Y-axis is higher than the rigidity against a bending moment around the X-axis. In the first pillar 10 and the second pillar 20, the bending moment around the Y axis is called the bending moment around the strong axis. In the first pillar 10 and the second pillar 20, the bending moment around the X axis is called the bending moment around the weak axis.

In a building to which the frame structure 100 is applied, walls are provided along a plane perpendicular to the Y-axis. That is, the walls of the building are parallel to the XZ plane. The thickness direction of the building wall is parallel to the Y direction.

As shown in FIG. 1, the connecting member 90 connects the first column 10 and the second column 20. A beam 98, which is an H-shaped steel extending in the Y direction, is joined to the connecting member 90. The connecting member 90 includes a diaphragm 91, a diaphragm 92, a diaphragm 93, a diaphragm 94, an intermediate column 95, an intermediate column 96, and a connecting beam 50.

As shown in FIG. 1, the diaphragms 91 to 94 are flat members. The thickness direction of the diaphragm 91 to the diaphragm 94 is parallel to the Z direction. The diaphragm 91 and the diaphragm 92 overlap the entire first column 10 in the XY plane view. The diaphragm 91 is joined to one end surface (the end surface in the −Z direction) of the first column 10 by, for example, welding. The diaphragm 92 is joined to the other end surface (the end surface in the +Z direction) of the first column 10 by, for example, welding. The diaphragm 93 and the diaphragm 94 overlap the entire second pillar 20 in the XY plane view. The diaphragm 93 is joined to one end surface (the end surface in the −Z direction) of the second column 20 by, for example, welding. The diaphragm 94 is joined to the other end surface (the end surface in the +Z direction) of the second column 20 by, for example, welding.

As shown in FIG. 1, the shape of the intermediate column 95 in a horizontal cross section is the same as the shape of the first column 10 in a horizontal cross section. The intermediate pillar 95 connects the diaphragm 91 and the diaphragm 92. The intermediate column 95 is joined to the diaphragm 91 and the diaphragm 92 by, for example, welding. Note that the shape of the intermediate column 95 in the horizontal cross section is not limited to the above-mentioned shape. For example, it is preferable that the web of the intermediate pillar 95 is thicker than the web of the first pillar 10, since this can improve the shear strength of the joint.

As shown in FIG. 1, the shape of the intermediate column 96 in a horizontal cross section is the same as the shape of the second column 20 in a horizontal cross section. Intermediate column 96 connects diaphragm 93 and diaphragm 94. The intermediate column 96 is joined to the diaphragm 93 and the diaphragm 94 by, for example, welding. Note that the shape of the intermediate column 96 in the horizontal cross section is not limited to the above-mentioned shape. For example, it is preferable that the web of the intermediate pillar 96 is thicker than the web of the second pillar 20 because this can improve the shear strength of the joint.

As shown in FIG. 1, the connecting beam 50 is an H-beam. The vertical cross section of the connecting beam 50 is H-shaped. The connecting beam 50 includes a flange 51, a flange 52, and a web 53. The thickness direction of the flange 51 is parallel to the Z direction. The thickness direction of the flange 52 is parallel to the Z direction. Flange 52 is parallel to flange 51. The flange 52 overlaps with the flange 51 in the XY plane view. The thickness direction of the web 53 is parallel to the Y direction. Web 53 is perpendicular to flanges 51 and 52.

The connecting beam 50 is arranged between the intermediate column 95 and the intermediate column 96. The length of the connecting beam 50 in the X direction is shorter than the length in the X direction of a beam connecting the columns including the first column 10 and the second column 20. In other words, a connecting beam is a beam between one set of first pillars 10 and second pillars 20 and another set of first pillars 10 and second pillars 20 arranged next to the set. It is a beam that is spanned. The flange 51 is joined to the diaphragm 91 and the diaphragm 93 by, for example, welding. Flange 52 is joined to diaphragm 92 and diaphragm 94, for example by welding. The web 53 is joined to the intermediate column 95 and the intermediate column 96, for example by welding.

As shown in FIG. 1, the intermediate connecting member 60 is an H-section steel. The vertical cross section of the intermediate connecting member 60 is H-shaped. The intermediate connecting member 60 includes a flange 61, a flange 62, and a web 63. The thickness direction of the flange 61 is parallel to the Z direction. The thickness direction of the flange 62 is parallel to the Z direction. Flange 62 is parallel to flange 61. The thickness direction of the web 63 is parallel to the Y direction. Web 63 is perpendicular to flanges 61 and 62.

As shown in FIG. 1, the intermediate connecting member 60 is arranged between the first column 10 and the second column 20. The intermediate connecting member 60 is arranged at a different position from the connecting member 90 in the Z direction. The position of the intermediate connecting member 60 in the Z direction is different from the position in the Z direction of the beam that connects the columns including the first column 10 and the second column 20. The intermediate connecting member 60 connects the first column 10 and the second column 20 at a height different from that of the beam. The intermediate connecting member 60 is joined to the first column 10 and the second column 20 by, for example, welding.

As shown in FIG. 1, the rib 15 is a flat member. The thickness direction of the rib 15 is parallel to the Z direction. The ribs 15 are orthogonal to each of the flanges 11, 12 and webs 13. The rib 15 is joined to the flange 11, flange 12 and web 13, for example by welding.

As shown in FIG. 1, the position of one of the plurality of ribs 15 in the Z direction is the same as the position of the flange 61 of the intermediate connecting member 60 in the Z direction. The position of one of the plurality of ribs 15 in the Z direction is the same as the position of the flange 62 of the intermediate connecting member 60 in the Z direction. That is, the rib 15 overlaps with the flange 61 or 62 in the YZ plane view.

As shown in FIG. 1, the rib 25 is a flat member. The thickness direction of the rib 25 is parallel to the Z direction. The rib 25 is orthogonal to each of the flanges 21, 22, and webs 23. Rib 25 is joined to flange 21, flange 22 and web 23, for example by welding.

As shown in FIG. 1, the position of one of the plurality of ribs 25 in the Z direction is the same as the position of the flange 61 of the intermediate connecting member 60 in the Z direction. The position of one of the plurality of ribs 25 in the Z direction is the same as the position of the flange 62 of the intermediate connecting member 60 in the Z direction. That is, the rib 25 overlaps with the flange 61 or 62 in the YZ plane view.

As shown in FIG. 2, the third pillar 30 extends along the Z direction. The longitudinal direction of the third pillar 30 is the Z direction. The third pillar 30 is arranged below the first pillar 10 and the second pillar 20. The third column 30 includes a core material 70, a column main body 31, main reinforcements 32, and tie reinforcements 33.

As shown in FIG. 2, the core material 70 includes a first core body 71, a second core body 73, and a second reinforcing member 75.

As shown in FIG. 2, the first core body 71 is connected to the first pillar 10. The first core body 71 is formed integrally with the first pillar 10. The first core body 71 is a part of the first pillar 10. In other words, the first pillar 10 is a part of the third pillar 30. The first core body 71 is an H-shaped steel. The first core body 71 extends along the Z direction. The longitudinal direction of the first core body 71 is the Z direction. As shown in FIG. 3, the first core body 71 includes a first flange 711, a second flange 712, a web 713, and a first reinforcing member 717. The thickness direction of the first flange 711 is parallel to the X direction. The thickness direction of the second flange 712 is parallel to the X direction. The second flange 712 is parallel to the first flange 711. The thickness direction of the web 713 is parallel to the Y direction.

As shown in FIG. 5, the first reinforcing member 717 is a plate-shaped member. The first reinforcing member 717 is also called a stiffener. The thickness direction of the first reinforcing member 717 is parallel to the Z direction. The first reinforcing members 717 are arranged on both sides of the web 713. The first reinforcing member 717 is joined to the first flange 711, the second flange 712, and the web 713. For example, the first reinforcing member 717 is welded to the first flange 711, the second flange 712, and the web 713. The length of the first reinforcing member 717 in the Y direction is smaller than the distance in the Y direction from the web 713 to the tip of the first flange 711 (second flange 712). That is, the tip of the first reinforcing member 717 in the Y direction is arranged closer to the web 713 than the tip of the first flange 711 (second flange 712) in the Y direction. For example, the length of the first reinforcing member 717 in the Y direction is less than half the width of the first flange 711 (second flange 712) in the Y direction. This makes it easier to fill the space under the first reinforcing member 717 with concrete when pouring concrete. That is, a gap is less likely to be formed under the first reinforcing member 717. The first reinforcing member 717 includes a scallop. The scallop is a hole provided at the intersection between the first flange 711 and the web 713 and the intersection between the second flange 712 and the web 713. This makes it easier for air to escape when the concrete is filled.

As shown in FIG. 2, the second core body 73 is connected to the second pillar 20. The second core main body 73 is formed integrally with the second pillar 20. The second core body 73 is a part of the second pillar 20. In other words, the second pillar 20 is a part of the third pillar 30. The second core body 73 is an H-beam steel. The longitudinal direction of the second core body 73 is the Z direction. As shown in FIG. 3, the second core body 73 includes a first flange 731, a second flange 732, and a web 733. The thickness direction of the first flange 731 is parallel to the X direction. The thickness direction of the second flange 732 is parallel to the X direction. The second flange 732 is parallel to the first flange 731. The thickness direction of the web 733 is parallel to the Y direction.

As shown in FIG. 5, the first reinforcing member 737 is a plate-shaped member. The first reinforcing member 737 is also called a stiffener. The thickness direction of the first reinforcing member 737 is parallel to the Z direction. The first reinforcing members 737 are arranged on both sides of the web 733. The first reinforcing member 737 is joined to the first flange 731, the second flange 732, and the web 733. For example, the first reinforcing member 737 is joined to the first flange 731, second flange 732, and web 733 by welding. The length of the first reinforcing member 737 in the Y direction is smaller than the distance in the Y direction from the web 733 to the tip of the first flange 731 (second flange 732). That is, the tip of the first reinforcing member 737 in the Y direction is arranged closer to the web 733 than the tip of the first flange 731 (second flange 732) in the Y direction. For example, the length of the first reinforcing member 737 in the Y direction is less than half the width of the first flange 731 (second flange 732) in the Y direction. This makes it easier to fill the space under the first reinforcing member 737 with concrete when pouring concrete. That is, a gap is less likely to be formed under the first reinforcing member 737.

As shown in FIG. 5, the second reinforcing member 75 is a plate-shaped member. The thickness direction of the second reinforcing member 75 is parallel to the Y direction. The second reinforcing member 75 is joined to the first core body 71 and the second core body 73. For example, the second reinforcing member 75 is joined to the second flange 712 of the first core body 71 and the first flange 731 of the second core body 73 by welding. The second reinforcing member 75 is arranged over substantially the entire length of the first core body 71 and the second core body 73 in the Z direction.

The column body 31 is made of concrete. The pillar body 31 covers the entire core material 70 . In a cross section of the column body 31 taken along a plane perpendicular to the longitudinal direction (horizontal cross section of the column body 31), the column body 31 has a rectangular shape. The main reinforcement 32 and the tie reinforcement 33 are embedded in the column main body 31. The main reinforcement 32 is, for example, a deformed steel bar. The main reinforcement 32 extends along the Z direction. The longitudinal direction of the main reinforcement 32 is parallel to the Z direction. The plurality of main reinforcements 32 are arranged so as to surround the first core body 71 and the second core body 73, respectively. The tie reinforcement 33 is, for example, a deformed steel bar. The tie reinforcements 33 are arranged so as to surround the plurality of main reinforcements 32. The straps 33 are also called hoops.

As shown in FIG. 2, the beam 40 extends along the X direction. The longitudinal direction of the beam 40 is the X direction. The beam 40a extends along the Y direction. The longitudinal direction of the beam 40a is the Y direction. Beam 40 and beam 40a are made of reinforced concrete. The beam 40 and the beam 40a are formed integrally with the column main body 31. As shown in FIG. 4, the vertical cross section of the beam 40 is rectangular. The vertical cross section of the beam 40a is rectangular like the beam 40. The beam 40 includes main reinforcements 42 and tie reinforcements 43. The main reinforcement 42 and the tie reinforcement 43 are embedded in the column main body 31. The main reinforcement 42 is, for example, a deformed steel bar. The main reinforcement 42 extends along the X direction. The longitudinal direction of the main reinforcement 42 is parallel to the X direction. The tie reinforcement 43 is, for example, a deformed steel bar. The tie reinforcements 43 are arranged so as to surround the plurality of main reinforcements 42.
The beam 40a includes main reinforcements 42a and tie reinforcements 43a. The main reinforcement 42a and the tie reinforcement 43a are embedded in the column main body 31. The main reinforcement 42a is, for example, a deformed steel bar. The main reinforcement 42a extends along the Y direction. The longitudinal direction of the main reinforcement 42a is parallel to the Y direction. The tie reinforcement 43a is, for example, a deformed steel bar. The tie reinforcements 43a are arranged so as to surround the plurality of main reinforcements 42a. As shown in FIG. 3, most of the main reinforcements 42a pass between the first core body 71 and the second core body 73. The main reinforcement 42a passes through the first core body 71, the second core body 73, or the second reinforcing member 75. A fixing plate 421 is provided at the tip of the main reinforcement 42a. Note that the main reinforcing bars 42a may be fixed using fixing hardware or the like without penetrating the first core body 71, the second core body 73, and the second reinforcing member 75. In this case, there is no need to make the main reinforcement 42a penetrate the first core body 71, the second core body 73, and the second reinforcing member 75.

As described above, the frame type structure 100 includes the first pillar 10 and the second pillar 20 that are connected. In the frame type structure 100, the cross-sectional shape of the pillars (first pillar 10 and second pillar 20) is flat compared to the case where one large pillar is used, and it is possible to suppress the overhang from the wall surface. Therefore, according to the frame type structure 100, it is possible to use the indoor space more freely.

In the frame structure 100, the connecting members 90 and the intermediate connecting members 60 improve the bending rigidity of the first column 10 and the second column 20 around the Y axis (around the strong axis). The frame type structure 100 can suppress deformation of the first column 10 and the second column 20 when a horizontal force is applied to the building due to an earthquake. The frame structure 100 can improve earthquake resistance.

Note that the third pillar 30 does not necessarily have to have the structure described above. The third column 30 only needs to include at least a core material 70 made of steel, and a column body 31 made of concrete that covers the core material 70.

The position of the third pillar 30 in the Z direction is not particularly limited. For example, the third pillar 30 may be arranged above the floor level of the first floor.

As explained above, the frame type structure 100 of this embodiment includes the first pillar 10, the second pillar 20, the connecting member 90, and the third pillar 30. The first pillar 10 is made of steel. The second pillar 20 is a steel material placed next to the first pillar 10. The connecting member 90 connects the first pillar 10 and the second pillar 20. The third pillar 30 is arranged below the first pillar 10 and the second pillar 20. The third column 30 includes a core material 70 made of steel, and a column body 31 made of concrete that covers the core material 70. The core material 70 is connected to the first pillar 10 and the second pillar 20.

Thereby, the load acting on the first column 10 and the second column 20 is received by the third column 30. Since the first column 10 and the second column 20 are connected to the core material 70 covered by the column main body 31, the load acting on the first column 10 and the second column 20 is transferred to the lower floor (the first column 10 and the second column 20). This makes it easier for the signal to be transmitted to the floor below the floor where the two pillars 20 are installed. The frame structure 100 can transfer the load acting on two connected columns to the lower floor.

In the frame structure 100, the core 70 includes a core body (first core body 71 or second core body 73) made of H-beam steel. The core body includes a first reinforcing member (first reinforcing member 717 or first reinforcing member 737) that is joined to the two flanges and the web.

Thereby, the integrity of the core body and the third pillar 30 can be ensured. Therefore, the frame type structure 100 can efficiently transmit the axial force acting on the first column 10 and the second column 20 to the third column 30.

In the frame structure 100, the core 70 includes a first core main body 71 connected to the first pillar 10, a second core main body 73 connected to the second pillar 20, a first core main body 71, and a second core main body 73 connected to the second pillar 20. A second reinforcing member 75 joined to the second core main body 73 is provided.

Thereby, the frame type structure 100 can improve the shear strength of the intersection portions of the first column 10, second column 20, and third column 30, which are vertical members, and the beam 40, which is a horizontal member.

The frame type structure 100 is arranged in the direction (X direction) in which the first pillar 10 and the second pillar 20 are lined up and in the direction (Y direction) perpendicular to the longitudinal direction (Z direction) of the first pillar 10 and the second pillar 20. A beam 40a is provided which extends and is connected to the third pillar 30. The beam 40a includes a plurality of main reinforcements 42 and a band reinforcement 43 surrounding the plurality of main reinforcements 42. At least a portion of the main reinforcement 42 passes through the core material 70.

Thereby, in the frame type structure 100, the portion of the main reinforcement 42 that is embedded in the column body 31 can be made longer.

(First modification)
FIG. 6 is a front view of the frame type structure of the first modification. In FIG. 6, the internal structure of the third pillar 30A is also shown. Note that the same components as those described in the embodiments described above are given the same reference numerals and redundant explanations will be omitted.

As shown in FIG. 6, the frame type structure 100A of the first modification includes a third pillar 30A. The third pillar 30A includes a first core material 70A, a second core material 80, a joining plate 85, a fixing member 86, and a pillar body 31A. The first core material 70A includes a first core body 71, a second core body 73, a reinforcing plate 74 joined to the first core body 71 and the second core body 73, and a bearing plate 76. Equipped with. The bearing pressure plate 76 is a plate-shaped member. The thickness direction of the bearing pressure plate 76 is parallel to the Z direction. The bearing plate 76 is joined to the lower end of the first flange 711 and the lower end of the second flange 732. Thereby, it is possible to transmit a part of the axial force borne by the first flange 711 and the second flange 732 to the column main body 31A (concrete).

As shown in FIG. 6, the second core material 80 is arranged below the first core material 70A. The second core material 80 is joined to the first core material 70A. The second core material 80 is an H-beam steel. The second core material 80 extends along the Z direction. The longitudinal direction of the second core material 80 is the Z direction. The second core material 80 includes a first flange 81, a second flange 82, and a web 83. The thickness direction of the first flange 81 is parallel to the X direction. The thickness direction of the second flange 82 is parallel to the X direction. The second flange 82 is parallel to the first flange 81. The web 83 connects the first flange 81 and the second flange 82. The thickness direction of the web 83 is parallel to the Y direction.

As shown in FIG. 6, the second core material 80 is joined to the first core material 70A by a joining plate 85 and a fixing member 86. The joining plate 85 is, for example, a gusset plate. The fixing member 86 is, for example, a bolt and a nut. The first flange 81 and the second flange 712 are joined by the joining plate 85 and the fixing member 86 . The second flange 82 and the first flange 731 are joined by the joining plate 85 and the fixing member 86 . The web 83 and the reinforcing plate 74 are joined by the joining plate 85 and the fixing member 86 .

The column main body 31A includes a first column main body 311 and a second column main body 312. The first pillar body 311 is formed of concrete placed around the first core material 70A. The second column main body 312 is formed of concrete placed around the second core material 80. The second pillar main body 312 is arranged below the first pillar main body 311. The outer periphery (cross-sectional area) of the second pillar main body 312 is smaller than the outer periphery (cross-sectional area) of the first pillar main body 311.

As explained above, in the frame type structure 100A of the first modification, the column body 31A is arranged below the first column body 311 and from the outer periphery of the first column body 311. and a second pillar main body 312 having a smaller outer circumference.

As a result, in addition to transmitting the load acting on the first column 10 and the second column 20 to the lower floor, a portion of the third column 30A becomes thinner. Therefore, the frame type structure 100A can suppress the third pillar 30A from protruding from the wall surface on the floor constituted by the third pillar 30A. According to the frame type structure 100A, it is possible to use the indoor space of the floor formed by the third pillar 30A more freely.

(Second modification)
FIG. 7 is a cross-sectional view of the frame type structure of the second modification. Note that the same components as those described in the embodiments described above are given the same reference numerals and redundant explanations will be omitted.

As shown in FIG. 7, the first core body 71B of the core 70B of the second modification includes a stud 718. Studs 718 are located on both sides of web 713. Stud 718 is joined to web 713. By providing the studs 718, it is possible to transmit vertical force from the first flange 711 and the second flange 712 to the column body 31 (concrete).

As shown in FIG. 7, the second core body 73B of the core 70B includes a stud 738. Studs 738 are located on both sides of web 733. Stud 738 is joined to web 733. By providing the studs 738, it is possible to transmit vertical force from the first flange 731 and the second flange 732 to the column body 31 (concrete).

(Third modification)
FIG. 8 is a front view of the frame type structure of the third modification. Note that the same components as those described in the embodiments described above are given the same reference numerals and redundant explanations will be omitted.

As shown in FIG. 8, the third pillar 30C of the frame structure 100C in the third modification includes a core material 70C. The core material 70C includes a second reinforcing member 75C. The second reinforcing member 75C is a plate-shaped member. The thickness direction of the second reinforcing member 75C is parallel to the Y direction. The second reinforcing member 75C is joined to the first core body 71 and the second core body 73. The second reinforcing member 75C is arranged at a position overlapping the beam 40 when viewed from the X direction. The second reinforcing member 75C is arranged so as not to overlap the main reinforcement 42a of the beam 40a when viewed from the Y direction. That is, the second reinforcing member 75C is arranged at a position shifted in the Z direction (vertical direction) with respect to the main reinforcement 42a. At least a portion of the main reinforcement 42a passes between the first core body 71 and the second core body 73. That is, at least a portion of the main reinforcement 42a penetrates the space between the first core body 71 and the second core body 73, but does not penetrate the second reinforcing member 75C.

As explained above, the frame type structure 100C of the third modification example is arranged in the direction in which the first column 10 and the second column 20 are lined up (X direction) and in the longitudinal direction of the first column 10 and the second column 20 (Z direction). ) and is provided with a beam 40a extending in a direction (Y direction) perpendicular to the direction (Y direction) and connected to the third pillar 30. The beam 40a includes a plurality of main reinforcements 42a and a band reinforcement 43a surrounding the plurality of main reinforcements 42a. At least a portion of the main reinforcement 42a passes between the first core body 71 and the second core body 73. The second reinforcing member 75C is arranged at a position shifted from the main reinforcement 42a in the longitudinal direction (Z direction) of the first column 10 and the second column 20.

Thereby, in the frame type structure 100C of the third modification, there is no need to provide a through hole in the second reinforcing member 75C in order to arrange the main reinforcement 42a of the beam 40a. Therefore, the frame structure 100C can improve workability.

(Fourth modification)
FIG. 9 is a front view of the frame structure of the fourth modification. Note that the same components as those described in the embodiments described above are given the same reference numerals and redundant explanations will be omitted.

As shown in FIG. 9, the third pillar 30D of the frame structure 100D in the third modification includes a core member 70D. The core material 70D includes a plurality of second reinforcing members 75D. The second reinforcing member 75D is a plate-shaped member. The thickness direction of the second reinforcing member 75D is parallel to the Y direction. The second reinforcing member 75D is joined to the first core body 71 and the second core body 73. The plurality of second reinforcing members 75D are arranged at intervals in the Z direction. The second reinforcing member 75D is arranged so as not to overlap the main reinforcement 42a of the beam 40a when viewed from the Y direction. That is, the second reinforcing member 75D is arranged at a position shifted in the Z direction (vertical direction) with respect to the main reinforcement 42a. At least a portion of the main reinforcement 42a passes between the first core body 71 and the second core body 73. That is, at least a portion of the main reinforcement 42a penetrates the space between the first core body 71 and the second core body 73, but does not penetrate the second reinforcing member 75D.

As explained above, the frame type structure 100D of the fourth modification is arranged in the direction in which the first pillar 10 and the second pillar 20 are lined up (X direction) and in the longitudinal direction of the first pillar 10 and the second pillar 20 (Z direction). ) and is provided with a beam 40a extending in a direction (Y direction) perpendicular to the direction (Y direction) and connected to the third pillar 30. The beam 40a includes a plurality of main reinforcements 42a and a band reinforcement 43a surrounding the plurality of main reinforcements 42a. At least a portion of the main reinforcement 42a passes between the first core body 71 and the second core body 73. The second reinforcing member 75D is arranged at a position shifted from the main reinforcement 42a in the longitudinal direction (Z direction) of the first column 10 and the second column 20.

Thereby, in the frame type structure 100D of the fourth modification, it is not necessary to provide a through hole in the second reinforcing member 75D in order to arrange the main reinforcement 42a of the beam 40a. Therefore, the frame structure 100D can improve workability.

10 First columns 11, 12 Flange 13 Web 15 Ribs 21, 22 Flange 23 Web 25 Ribs 30, 30A, 30C, 30D Third columns 31, 31A Column body 32 Main reinforcement 33 Straps 40, 40a Beams 42, 42a Main reinforcement 43, 43a Stir reins 50 Connecting beams 51, 52 Flange 53 Web 60 Intermediate connecting members 61, 62 Flange 63 Webs 70, 70B, 70C, 70D Core materials 71, 71B First core body 73, 73B Second core body 74 Reinforcement plate 75, 75C, 75D Second reinforcing member 80 Second core material 81 First flange 82 Second flange 83 Web 85 Joint plate 86 Fixing member 90 Connecting members 91, 92, 93, 94 Diaphragm 95, 96 Intermediate column 98 Beam 100, 100A, 100C, 100D Frame structure 421 Fixing plate 711 First flange 712 Second flange 713 Web 717 First reinforcing member (stiffener)
718 Stud 731 First flange 732 Second flange 733 Web 737 First reinforcing member (stiffener)
738 Stud

Claims (6)

The first pillar is made of steel,
a second pillar made of steel arranged next to the first pillar;
a connecting member connecting the first pillar and the second pillar;
a third pillar located below the first pillar and the second pillar;
Equipped with
The third pillar includes a core material made of steel, and a pillar body made of concrete covering the core material,
The core material is connected to the first pillar and the second pillar,
The pillar main body includes a first pillar main body, and a second pillar main body that is disposed below the first pillar main body and has a smaller outer circumference than the outer circumference of the first pillar main body.
Frame structure. The first pillar is made of steel,
a second pillar made of steel arranged next to the first pillar;
a connecting member connecting the first pillar and the second pillar;
a third pillar located below the first pillar and the second pillar;
Equipped with
The third pillar includes a core material made of steel, and a pillar body made of concrete covering the core material,
The core material is connected to the first pillar and the second pillar,
A beam extending in a direction perpendicular to the direction in which the first pillar and the second pillar are lined up and the longitudinal direction of the first pillar and the second pillar, and connected to the third pillar,
The beam has a plurality of main reinforcements and a tie bar surrounding the plurality of main reinforcements,
At least a portion of the main reinforcement passes through the core material.
Frame structure. The core material is joined to a first core body connected to the first pillar, a second core body connected to the second pillar, and the first core body and the second core body. The frame type structure according to claim 1 or 2, comprising a second reinforcing member. The first pillar is made of steel,
a second pillar made of steel arranged next to the first pillar;
a connecting member connecting the first pillar and the second pillar;
a third pillar located below the first pillar and the second pillar;
Equipped with
The third pillar includes a core material made of steel, and a pillar body made of concrete covering the core material,
The core material is connected to the first pillar and the second pillar,
The core material includes a first core body connected to the first pillar, and a second core body connected to the second pillar,
A beam extending in a direction perpendicular to the direction in which the first pillar and the second pillar are lined up and the longitudinal direction of the first pillar and the second pillar, and connected to the third pillar,
The beam has a plurality of main reinforcements and a tie bar surrounding the plurality of main reinforcements,
At least a portion of the main reinforcement passes between the first core body and the second core body.
Frame structure. The first pillar is made of steel,
a second pillar made of steel arranged next to the first pillar;
a connecting member connecting the first pillar and the second pillar;
a third pillar located below the first pillar and the second pillar;
Equipped with
The third pillar includes a core material made of steel, and a pillar body made of concrete covering the core material,
The core material is connected to the first pillar and the second pillar,
The core material is joined to a first core body connected to the first pillar, a second core body connected to the second pillar, and the first core body and the second core body. a second reinforcing member,
A beam extending in a direction perpendicular to the direction in which the first pillar and the second pillar are lined up and the longitudinal direction of the first pillar and the second pillar, and connected to the third pillar,
The beam has a plurality of main reinforcements and a tie bar surrounding the plurality of main reinforcements,
At least a portion of the main reinforcement passes between the first core body and the second core body,
The second reinforcing member is arranged at a position shifted from the main reinforcement in the longitudinal direction of the first column and the second column.
Frame structure. The core material includes a core material body that is an H-beam steel,
The frame type structure according to any one of claims 1 to 5, wherein the core main body includes a first reinforcing member joined to two flanges and a web.

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