JP6873302B2 - Complex building - Google Patents

Description

In the present invention, in a complex building having a column-beam structure with RC columns on the upper floor and a column-beam structure with concrete-filled steel pipe CF columns on the lower floor, the RC columns on the upper floor side and the CFT columns on the lower floor side are Regarding the joined complex building.

So-called complex buildings, in which the structural forms of the lower floors and upper floors of the building are different from each other, are widely constructed.
Patent Document 1 discloses a building structure 100 as shown in FIG. In the building structure 100, the concrete-filled steel pipe columns (hereinafter referred to as CFT columns) 102 and the reinforced concrete columns (hereinafter referred to as RC columns) 103 arranged in the lower layer of the CFT columns 102 are in the vertical direction. It is arranged continuously in. The joining of the CFT column 102 and the RC column 103, that is, the switching of the column-beam frame structure is performed near the boundary between the first basement floor (B1FL) and the second basement floor (B2FL).
A tubular reinforcing member 104 is provided around the outer peripheral surface of the head of the RC column 103. The main bar 105 of the RC column 103 protrudes from the upper end surface of the RC column 103 and is fixed inside the CFT column 102 or fixed to the CFT column 102.
The CFT column 102 includes a mounting portion 106 that is joined to the RC column 103. The mounting portion 106 includes a first mounting member 107 and a second mounting member 108. A base plate 109, which also functions as a diaphragm for joining the beams 110, is joined to the lower ends of each of the first mounting member 107 and the second mounting member 108.
Non-Patent Document 1 introduces various joining forms of a beam and a column such as a steel pipe column as shown as the first mounting member 107 as described above.

By the way, in a middle-high-rise building constructed in recent years, the lower floor including the lower floor above the ground and the upper floor may be used for different purposes. For example, middle- and high-rise buildings in which the lower floors are used as commercial facilities such as stores and offices and the upper floors are used as residential facilities such as apartment houses are widely constructed.
It is conceivable that such a middle-high-rise building will be realized as the above-mentioned complex building by adopting an appropriate structural form according to each use of the lower floor and the upper floor. Here, as a commercial facility, in order to reduce the number of columns as much as possible, lengthen the column span, and realize a large-scale space, it is desirable to have a structural form using a column-beam frame using steel frames or CFT columns. On the other hand, as a residential facility, in order to realize a comfortable living environment by suppressing even a slight vibration, a structural form using a rigid column-beam frame such as an RC column is desirable.
From this point of view, the building structure 100 disclosed in Patent Document 1 as described above uses RC columns as columns on the lower floors and CFT columns as columns on the upper floors, respectively. Since the pillar-beam structure is switched near the boundary between the first basement floor (B1FL) and the second basement floor (B2FL), the lower floors including the lower floors above the ground are commercial facilities, and the upper floors are residential. The structure is not suitable for the construction of the complex buildings used as related facilities.

On the other hand, Patent Document 2 discloses a column structure 110 in a composite structure building as shown in FIG. In this structure 110, RC columns 111 are used in the upper layer portion, and CFT columns 112 are used in the lower layer portion.
The steel pipe 114 forming the outer shell of the column 113 of the boundary layer between the upper layer portion and the lower layer portion is joined to the skeleton of the immediately lower floor and is arranged between the floor surface and the beam of the immediately above floor. Stud 117 is installed at least in the lower part of the steel pipe 114. The column main reinforcement 115 is inserted into the steel pipe 114, and the reinforcement is arranged to the vicinity of the floor surface of the boundary layer. Around the column main bar 115, a band bar 118 is wound at least at the position of the stigma. Concrete 116 is cast and filled in the steel pipe 114, and the column main bar 115 and the steel pipe 114 are joined via the concrete 116 and the stud 117. The winding range of the band bar 118 around the column main bar 115 is up to the position of the inflection point of the bending moment, and the installation range of the stud 117 at the lower part in the steel pipe 114 is lower than the winding position of the band bar 118. Limited to.

In the structure 110 disclosed in Patent Document 2 as described above, the boundary layer between the upper layer portion and the lower layer portion is long in the vertical direction, and the structure as a whole is complicated. Further, it is necessary to provide a large number of tads 117 in the steel pipe 114. That is, the RC pillar 111 in the upper layer and the CFT in the lower layer.
The joining structure of 112 was complicated, and construction was not easy.

Japanese Patent No. 5734168 Japanese Unexamined Patent Publication No. 2009-2006

Architectural Institute of Japan, "Design and Construction of Reinforced Concrete Column / Steel Beam Mixed Structure", January 10, 2001, 1st Edition, 1st Edition, p. 3-5

The problem to be solved by the present invention is that in a middle-high-rise building having a column-beam structure with CFT columns on the lower floor and a column-beam structure with RC columns on the upper floor, RC columns at the switching portion of the column-beam structure. It is an object of the present invention to provide a composite building having a high joining strength while having a simple and easy joining method for joining CFT columns.

The present inventors have a CFT column-beam structure in which the lower floors can be relatively easily widened between columns in a middle-high-rise building having commercial facilities on the lower floor side and residential facilities on the upper floor side. The upper floors have an RC column-beam structure with high rigidity and excellent suppression of micro-vibration, and the main bars of the RC columns on the upper floors are the internal horizontal steel plates (inner diaphragm) that make up the CFT columns on the lower floors. A complex building with excellent structural safety performance, focusing on the fact that high adhesion strength can be secured for the main columns of columns and high joint strength can be obtained between RC columns and CFT columns by penetrating them and fixing them inside the CFT columns. Invented.
The present invention employs the following means in order to solve the above problems. That is, the present invention is a composite building in which concrete-filled steel columns and reinforced concrete columns arranged on the upper floors of the concrete-filled steel columns are continuously arranged in the vertical direction, and the upper end of the concrete-filled steel columns. An upper steel plate and a lower steel plate extending in a direction intersecting the inner wall surface of the concrete-filled steel column are provided at intervals in the portion, and the column main bars of the reinforced concrete column are the upper steel plate and the lower steel plate. Provided is a composite building characterized in that it penetrates through a hole for reinforcing bars provided in the above and is fixed inside the concrete-filled steel column.
According to the above configuration, the reinforced concrete columns are arranged on the upper floors of the concrete-filled steel pipe columns. That is, the lower floors are columns and beams using concrete-filled steel pipe columns, which are suitable for realizing a large-scale space by reducing the number of columns as much as possible and lengthening the column span, and the upper floors are few. The lower floors are used as commercial facilities such as stores and offices because the columns and beams are constructed using rigid reinforced concrete columns, which is suitable for suppressing vibration and realizing a comfortable living environment. The upper floors have a structure suitable for buildings used as residential facilities such as apartment buildings.
Further, the main bar of the reinforced concrete column is inserted into the area surrounded by the steel pipe constituting the concrete-filled steel pipe column, the upper steel plate, and the lower steel plate, and is filled in this area and strongly strengthened by the steel pipe and the upper and lower steel plates. It is buried in the restrained concrete, and the adhesive force of the pillar main bar to the concrete is strengthened. Further, the column main bar is provided so as to penetrate the reinforcing bar holes provided in the upper steel plate and the lower steel plate and extend to the inside of the concrete-filled steel pipe column, and is fixed to the concrete. As a result, it is possible to realize a high joint strength between the concrete-filled steel column and the reinforced concrete column, which can resist the bending that occurs in the column base of the reinforced concrete column.
In addition, the joint between the concrete-filled steel pipe column and the reinforced concrete column is integrated via the column reinforcing bar, and has a simple and excellent structure. Further, it has a simple structure in which the main reinforcement of the reinforced concrete column can be directly extended or extended by a mechanical joint or the like to arrange the reinforcement inside the concrete-filled steel tube column. This facilitates construction.

In one aspect of the present invention, a closing steel plate is provided on the upper surface of the upper steel plate so as to cover the upper outer circumference of the steel pipe constituting the concrete-filled steel pipe column.
According to the above configuration, as described above, the steel pipe constituting the concrete-filled steel pipe column, the upper steel plate, and the concrete in the area surrounded by the lower steel plate are strongly restrained by these, but the upper part. By providing a closed steel plate on the upper surface of the steel plate so as to cover the upper outer periphery of the steel pipe constituting the concrete-filled steel pipe column, the steel pipe is shaped as if it is extended upward with the upper steel plate sandwiched, so that it is strongly restrained. The area of the steel is also expanded above the upper steel plate. As a result, the shear strength of the joint portion between the concrete-filled steel pipe column and the reinforced concrete column can be increased, and the adhesive force of the column main bar to the concrete can be further strengthened to increase the joint strength between the columns.
In addition, the closing steel plate can prevent surface defects of concrete.

In another aspect of the present invention, the reinforced concrete column connected to the concrete-filled steel pipe column is a cast-in-place concrete column constructed on-site on the upper surface of the concrete-filled steel pipe column and the cast-in-place concrete column. It is provided with a precast concrete column installed on the upper surface, and the shear strength of the cast-in-place concrete column is higher than the shear strength of the precast concrete column.
According to the above configuration, since the cast-in-place concrete column is provided on the upper surface of the concrete-filled steel pipe column and the precast concrete column is provided on the cast-in-place concrete column, the cast-in-place cocrete column and the precast concrete column are sheared. The relative relationship of strength can be easily adjusted. Here, for example, by using high-strength hoop bars or high-strength concrete for the cast-in-place concrete pillar, the shear strength of the cast-in-place concrete pillar can be made higher than the shear strength of the precast concrete pillar. As a result, the joint portion between the concrete-filled steel pipe column and the reinforced concrete column can be integrated to realize high toughness.
Further, by adjusting the height of the cast-in-place concrete column, the installation accuracy in the height direction can be easily adjusted when the precast concrete column is installed on the concrete-filled steel pipe column.
Further, in the aspect of the present invention, the reinforced concrete columns having a height range substantially equal to that of the floor slab on the upper surface of the upper steel plate have hoop bars arranged at a higher density than the reinforced concrete columns above the floor slab. It is characterized in that a lap winding portion in which a plurality of the hoop muscles are lapped and wound up is embedded. Alternatively, the cast-in-place concrete column having a height range substantially equal to that of the floor slab on the upper surface of the upper steel plate is made of high-strength concrete as compared with the precast concrete column.

According to the present invention, in a middle-high-rise building having a column-beam structure with CFT columns on the lower floor and a column-beam structure with RC columns on the upper floor, the RC columns on the upper floor side and the CFT columns on the lower floor side With respect to the joint portion, it is possible to realize a composite building in which high joint strength is ensured while having a simple joint structure.

It is a vertical sectional view of the complex building in embodiment of this invention. It is a partial perspective view of the joint portion of the CFT column on the lower floor side and the RC column on the upper floor side in the complex building. It is a vertical sectional view of the joint portion of the CFT column on the lower floor side and the RC column on the upper floor side in the complex building (first embodiment). It is a cross-sectional view at different height positions of FIG. 3 (first embodiment). It is a vertical cross-sectional view of the joint portion of the CFT column on the lower floor side and the RC column on the upper floor side according to the first modification. It is a cross-sectional view of FIG. 5 (first modification). It is a vertical cross-sectional view of the joint portion of the CFT column on the lower floor side and the RC column on the upper floor side according to the second modification. It is explanatory drawing which shows the joint part of the upper side CFT column and the lower side RC column by the conventional building structure. It is explanatory drawing of the structure of a column in a conventional complex structure building.

In the present invention, in a complex building having a column-beam structure with RC columns on the upper floor and a column-beam structure with concrete-filled steel pipe CFT columns on the lower floor, the column main bars of the RC columns on the upper floor side are on the lower floor side. This is a composite building in which internal horizontal steel plates (inner diaphragms) that make up CFT columns are penetrated and fixed inside the CFT columns.
Specifically, the main bars of the RC columns on the upper floor side are placed inside the CFT columns by penetrating the internal horizontal steel plates that make up the CFT columns on the lower floor side, and the RC columns cast on site are placed above the CFT columns. The joint structure (first embodiment, FIGS. 3 and 4) in which the precast concrete columns are installed on the upper surface of the columns and the precast concrete columns are joined to each other, and the difference from the first embodiment is that the on-site RC columns are provided. A joint structure with a closed steel plate and vertical ribs around it (first modification, FIGS. 5 and 6) and the lower end of the column main reinforcement of the RC column penetrate the internal horizontal steel plate that constitutes the CFT column on the lower floor side. It is a joint structure (second modification, FIG. 7) in which the columns are fastened and fixed.
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a vertical cross-sectional view of the complex building 1 according to the embodiment of the present invention. The complex building 1 includes a foundation 2, a lower floor 3, and an upper floor 4. Foundation 2 is located below the surface GL. The lower floor 3 is provided on the foundation 2, and has at least one floor located above the ground surface GL, including the basement floor of the complex building 1 and the first floor above ground. The upper floor 4 is provided above the lower floor 3.
On the lower floor 3, the column 5 is a CFT column 5, and a steel beam 7 is erected between the CFT columns 5. As a result, the lower floor 3 is provided with a column-beam frame consisting of CFT columns 5 and steel beams 7. Further, on the upper floor 4, the column 6 is an RC column, and a steel beam 7 is erected between the RC columns 6. As a result, the upper floor 4 is provided with a column-beam frame consisting of RC columns 6 and steel beams 7. In FIG. 1, the CFT column 5 is shown in white, and the RC column 6 is shown hatched.
As described above, in the complex building 1, the CFT columns 5 and the RC columns 6 arranged on the upper floors of the CFT columns 5 are continuously arranged in the vertical direction Z. Further, the joint portion between the CFT column 5 and the RC column 6, that is, the switching portion of the column-beam frame structure is located at a height of two floors or more above the ground.

(First Embodiment)
Hereinafter, the structure of the joint portion between the CFT column 5 and the RC column 6 will be described in detail with reference to FIGS. 2 to 4. FIG. 2 is a perspective view of the portion seen by arrow A in FIG. 1, that is, the joint portion between the CFT pillar 5 and the RC pillar 6 in the complex building 1. FIG. 3 is a vertical cross-sectional view of the BB portion of FIG. 4 (a), 4 (b), 4 (c), and 4 (d) are the CC portion, the DD portion, the EE portion, and the E-E portion of FIG. 3, respectively. It is a cross-sectional view in the FF part.

The CFT pillar 5 includes a general portion 10 and a mounting portion 11.
The general portion 10 includes a steel pipe 10a having a rectangular cross section and concrete 10b filled in the steel pipe 10a.
The mounting portion 11 includes a steel pipe 11a having a cross-sectional shape substantially equivalent to that of the steel pipe 10a of the general portion 10, and concrete 11b filled in the steel pipe 11a. The mounting portion 11 is formed so that its length in the vertical direction Z is substantially the same as that of the steel frame beam 7.

The upper end of the CFT column 5 joined to the RC column 6 extends in directions X and Y intersecting the inner wall surfaces 10c and 11c of the steel pipes 10a and 11a of the general portion 10 and the mounting portion 11 of the CFT column 5. The upper steel plate 15 and the lower steel plate 16 are provided at intervals in the vertical direction Z.
More specifically, the lower steel plate 16 is welded to the upper end of the steel pipe 10a of the general portion 10 of the CFT column 5. On the upper surface of the lower steel plate 16, the steel pipe 11a of the mounting portion 11 of the CFT column 5 is welded at a position where the steel pipe 10a located below the lower steel plate 16 is substantially continuous upward with the lower steel plate 16 sandwiched. ing. The upper steel plate 15 is welded to the upper end of the steel pipe 11a of the mounting portion 11.
As shown in FIG. 3, in the present embodiment, the steel beam 7 is an H-shaped steel, the upper flange 7a of the steel beam 7 is attached to the upper steel plate 15, the lower flange 7b is attached to the lower steel plate 16, and the web 7c is formed. It is joined to the outer wall surface 11d of the steel pipe 11a of the mounting portion 11, respectively.

As shown in FIG. 4B, the upper steel plate 15 includes a circular opening 15a having a size smaller than the cross-sectional shape of the inner wall surface 11c of the steel pipe 11a of the mounting portion 11. Further, the upper steel plate 15 is formed so that its outer shape is larger than the cross-sectional shape of the outer wall surface 11d of the steel pipe 11a of the mounting portion 11. As described above, the upper steel plate 15 is formed in a frame shape, and as shown in FIG. 4B, the opening 15a is located inside the inner wall surface 11c of the steel pipe 11a, and the upper steel plate 15 is formed. The outer edge portion is provided on the mounting portion 11 so as to be located outside the outer wall surface 11d of the steel pipe 11a so as to protrude from the outer wall surface 11d, and is joined by welding as described above.
A plurality of reinforcing bar holes 15b are provided in a portion around the opening 15a, which is located inside the inner wall surface 11c of the steel pipe 11a of the mounting portion 11 when the upper steel plate 15 is joined to the mounting portion 11. There is.
The upper steel plate 15 has a thickness equal to or greater than that of the upper flange 7a of the steel frame beam 7. The upper flange 7a of the steel frame beam 7 is joined to the upper steel plate 15. The upper steel plate 15 has a rectangular shape centered on the opening 15a and is separated by a rectangular shape end edge 15 g shown by a two-point chain line in FIG. 4B, and has a trapezoidal shape in the direction in which the steel beam 7 is joined. It is formed so as to protrude. The width of the trapezoidal beam connecting portion 15c gradually decreases toward the outside, and is terminated at a position having the same width as the upper flange 7a of the steel frame beam 7. The upper flange 7a of the steel beam 7 is joined to the outermost end edge 15d having the same width as the upper flange 7a of the steel beam 7.
On the upper surface 15e of the upper steel plate 15 shown in FIG. 3, a stud bolt 15f (see FIG. 4B) for joining with the floor slab 18 laid on the steel beam 7 is provided. In FIG. 2, the floor slab 18 is not shown for simplification of the drawing.

The lower steel plate 16 is formed in a shape substantially equivalent to that of the upper steel plate 15. That is, as shown in FIG. 3, the lower steel plate 16 also has an opening 16a and a reinforcing bar hole 16b, and the outer shapes of the steel pipes 10a and 11a of the general portion 10 and the mounting portion 11 are as shown in FIG. It is formed so as to be larger than the outer wall surfaces 10d and 11d, and has a frame shape. In the lower steel plate 16, the opening 16a is located inside the inner walls 10c and 11c of the steel pipes 10a and 11a, and the outer edge portion of the lower steel plate 16 is outside the outer walls 10d and 11d of the steel pipes 10a and 11a. It is provided with respect to the general portion 10 and the mounting portion 11 so as to protrude from the outer wall surfaces 10d and 11d, and is joined by welding as described above.
The lower steel plate 16 has a thickness equal to or greater than that of the lower flange 7b of the steel frame beam 7. The lower flange 7b of the steel frame beam 7 is joined to the lower steel plate 16. The lower steel plate 16 has a contour shape substantially equivalent to that of the upper steel plate 15, and the beam connecting portion 16c is provided in the direction in which the steel frame beams 7 are joined. The lower flange 7b of the steel beam 7 is joined to the outermost end side 16d of the beam connecting portion 16c.

Next, the RC column 6 connected to the CFT column 5 will be described. The RC columns 6 are a cast-in-place concrete column (hereinafter referred to as a cast-in-place RC column) 8 constructed on-site on the upper surface of the CFT column 5, that is, the upper surface 15e of the upper steel plate 15, and a cast-in-place RC column 8. It is provided with a precast concrete column (hereinafter referred to as a PCaRC column) 9 installed on the upper surface 8f of the above.

As shown in FIG. 3, the cast-in-place RC pillar 8 is formed by casting concrete 8b so as to have a height substantially equal to that of the floor slab 18.
Column main bars 13 are arranged on the on-site RC columns 8. The column main reinforcement 13 is arranged along the axial direction of the CFT column 5 and the RC column 6, that is, the vertical direction Z. The upper end 13a of the column main bar 13 slightly protrudes from the upper surface 8f of the on-site cast RC column 8. Further, the lower side of the column main bar 13 is attached by penetrating the on-site cast RC column 8 in the vertical direction Z and inserting the reinforcing bar hole 15b of the upper steel plate 15 and the reinforcing bar hole 16b of the lower steel plate 16. It is provided so as to further penetrate the inside of the steel pipe 11a of the portion 11, and the lower end 13b of the column main bar 13 is positioned inside the steel pipe 10a of the general portion 10. As described above, the column main bar 13 has a length that can secure a predetermined fixing length, and is fixed to the concrete 10b and 11b of the general portion 10 and the mounting portion 11 inside the CFT column 5.
The column main bars 13 are arranged in the circumferential direction of the CFT columns 5 and RC columns 6 with a predetermined bar arrangement pitch. The column main bar 13 is provided at the same plane position as the column main bar 9c of the PCaRC column 9, which will be described later.
The cast-in-place RC column 8 is provided with a plurality of hoop bars 8e so as to horizontally surround the column main bar 13. The hoop bar 8e is a hoop bar having a larger diameter or higher strength than the hoop bar 9d of the PCaRC column 9 described later, and the CFT column 5 side has a lap winding portion in which a plurality of reinforcing bars are laid and wound. The hoop muscle 8e is embedded in the concrete 8b.

A column main bar 9c is arranged on the PCaRC column 9. Similar to the column main bar 13, the column main bar 9c is arranged along the axial direction of the RC column 6, that is, the vertical direction Z.
A mechanical joint 9e is embedded in the lower end 9a of the PCaRC column 9 so that one end face thereof is exposed from the lower end 9a, and the column is formed from the other end face of the mechanical joint 9e, that is, the end face side facing upward. The lower end of the main bar 9c is inserted into the mechanical joint 9e and fixed.
A plurality of hoop muscles 9d are provided so as to surround the pillar main muscle 9c. The hoop muscle 9d is embedded in the concrete 9b.

As described above, the PCaRC pillar 9 is installed on the upper surface 8f of the on-site cast RC pillar 8. The upper end 13a of the column main bar 13 provided so as to project from the upper surface 8f of the cast-in-place RC column 8 is mechanical from the end surface of the mechanical joint 9e exposed downward from the lower end 9a of the PCaRC column 9. It is inserted into the joint 9e and fixed.
When the on-site RC columns 8 and PCaRC columns 9 configured as described above are viewed as an integrated RC column 6, the column main bars 9c of the PCaRC columns 9 are connected to the column main bars via the mechanical joint 9e. Since the column 13 is configured to extend downward, the column main bars 9c and 13 of the RC column 6 penetrate the upper steel plate 15 and the reinforcing bar holes 15b and 16c provided in the lower steel plate 16. , The structure is fixed to the concrete 10b and 11b inside the CFT pillar 5.

Here, the shear strength of the cast-in-place RC column 8 is configured to be higher than the shear strength of the PCaRC column 9.
More specifically, in the on-site RC column 8, the high-strength hoop muscles 8e are arranged so as to be denser than the hoop muscles 9d of the PCaRC column 9. Further, as the on-site cast RC column 8, concrete 8b having the same strength or high strength as that of the concrete 9b of the PCaRC column 9 is used.

Next, the construction method of the above-mentioned complex building 1 will be described with reference to FIGS. 1 to 4.

First, the foundation 2 is constructed, and a column-beam frame consisting of CFT columns 5 and steel beams 7 is constructed on the foundation 2, and the lower floor 3 is constructed. Here, as the pillar on the uppermost floor of the lower floor 3, the CFT pillar 5 as described with reference to FIG. 3 is erected. This is because the steel pipe 10a of the general part 10, the steel pipe 11a of the mounting part 11, the upper steel plate 15, and the lower steel plate 16 are welded to each other, and the one integrated is manufactured at the factory and transported to the site to stand. It is done by setting. After that, the steel beam 7 is erected between the CFT columns 5.
Next, the column main reinforcement 13 and the hoop reinforcement 8e of the on-site cast RC column 8 portion are arranged. The column main bar 13 penetrates the upper steel plate 15 and the reinforcing bar holes 15b and 16b provided in the lower steel plate 16, and is sufficiently fixed to the concrete 10b and 11b to be cast later inside the CFT column 5. Reinforcing bars with a length that is as long as possible. Further, the high-strength hoop muscles 8e are arranged so as to be denser than the hoop muscles 9d of the PCaRC column 9 to be erected later.

After that, the hoop reinforcement 8e is surrounded by a formwork, and concrete having a strength higher than that of the concrete 9b of the PCaRC column 9 to be erected later is placed. Specifically, for example, from the space surrounded by the hoop bars 8e, through the opening 15a of the upper steel plate 15, the inside of the steel pipe 11a of the mounting portion 11, and the opening 16a of the lower steel plate 16, a tremie pipe or the like. Is inserted into the steel pipe 10a of the general portion 10, and the concrete 10b is poured from the lower side to the upper side of the general portion 10 while pulling up the tremie pipe or the like. The concrete is cast to the inside of the formwork surrounding the mounting portion 11 and the hoop bar 8e, and the concrete 11b of the mounting portion 11 and the concrete 8b of the on-site cast RC column 8 are formed so as to be integrated. ..
After curing the concrete 8b, 10b, and 11b, the floor slab 18 is formed, and the PCaRC pillar 9 is erected on the upper surface 8f of the on-site cast RC pillar 8. Specifically, the upper end 13a of the column main bar 13 protruding upward from the upper surface 8f is inserted into the mechanical joint 9e from the end surface of the mechanical joint 9e exposed downward from the lower end 9a of the PCaRC column 9. Fix by injecting grout or the like.
In this way, after the joint portion between the CFT pillar 5 and the RC pillar 6 is constructed, the upper floor 4 is constructed further upward.

Next, the effect of the above-mentioned complex building 1 will be described.

According to the above configuration, the RC pillar 6 is arranged on the upper floor 4 above the CFT pillar 5. That is, the lower floor 3 is a column-beam frame using CFT columns 5, which is suitable for realizing a large-scale space by reducing the number of columns as much as possible and lengthening the column span, and the upper floor 4 is slightly. The lower floor 3 is a commercial facility such as a store or office because it is a column-beam frame using rigid RC columns 6 that is suitable for realizing a comfortable living environment by suppressing excessive vibration. The upper floor 4 has a structure suitable for a building used as a residential facility such as an apartment house.
Further, the column main bar 13 of the RC column 6 is inserted into a region surrounded by the steel pipe 11a constituting the CFT column 5, the upper steel plate 15 and the lower steel plate 16, and is filled in this region to fill the steel pipe 11a and the upper portion. It is embedded in the concrete 11b strongly restrained by the lower steel plates 15 and 16, and the adhesive force of the column main bar 13 to the concrete 11b is strengthened. Further, the column main bar 13 is provided so as to penetrate the reinforcing bar holes 15b and 16b provided in the upper steel plate 15 and the lower steel plate 16 and extend to the inside of the CFT column 5 (10, 11). It is fixed to concrete 10b and 11b. As a result, it is possible to realize a high-strength joint between the CFT column 5 and the RC column 6 that can resist the bending that occurs in the column base of the RC column 6.
Further, the joint between the CFT column 5 and the RC column 6 is integrated via the column main bar 13, and has a simple and excellent structure. Further, since the column main bar 9c of the RC column 6 is extended as the column main bar 13 by the mechanical joint 9e and arranged inside the CFT column 5, the construction is easy.

Further, since the on-site cast RC column 8 is provided on the upper surface of the CFT column 5, that is, 15e of the upper steel plate 15, and the PCaRC column 9 is provided on the on-site cast RC column 8, the on-site cast RC column 8 and the PCaRC column 9 are provided. The relative relationship of shear strength can be easily adjusted. Here, in the present embodiment, concrete 8b having the same or higher strength than the concrete 9b of the PCaRC column 9 is used for the cast-in-place RC column 8, and the high-strength hoop bar 8e is used. , The reinforcement is arranged so as to be denser than the hoop muscle 9d of the PCaRC column 9. Thereby, the strength and toughness of the joint portion between the CFT column 5 and the RC column 6 can be increased.
Further, by adjusting the height of the on-site cast RC pillar 8, when the PCaRC pillar 9 is installed on the CFT pillar 5, the installation accuracy in the height direction Z can be easily adjusted.

Further, in the present embodiment, the axial force borne by the RC column 6 is applied to the upper surface of the CFT column 5 by a bearing mechanism via a frame-shaped upper steel plate 15 and a lower steel plate 16 fixed to the upper end of the CFT column 5. By transmitting to the side, the joint structure is such that the load axial force of the RC column 6 can be transmitted to the CFT column 5 without being concentrated. Therefore, damage to the CFT column 5 can be suppressed particularly at the joint between the CFT column 5 and the RC column 6.

Further, a frame-shaped upper steel plate 15 and a lower steel plate 16 are provided at the upper end of the CFT column 5, and these steel plates 15 and 16 also function as a diaphragm for joining the steel frame beam 7. As a result, it is possible to increase the rigidity of the joint portion at the joint portion with the CFT column 5 and suppress deformation due to stress acting on the joint portion.

(First modification)
Next, a first modification of the complex building 1 shown as the above embodiment will be described with reference to FIGS. 5 and 6. FIG. 5 is a vertical cross-sectional view of the joint portion between the CFT columns 5 and the RC columns 6 of the composite building 30 in the first modification. FIG. 6 is a cross-sectional view of the GG portion of FIG. The composite building 30 of the first modification is different from the composite building 1 in the above embodiment in that a closing steel plate 31 and a vertical rib 32 are provided around the on-site cast RC column 8.

The closing steel plate 31 is provided on the upper surface 15e of the upper steel plate 15 at a position so as to cover the upper outer circumference of the steel pipe 11a of the mounting portion 11 constituting the CFT column 5. More specifically, the closing steel plate 31 is provided so as to cover the outer periphery of the cast-in-place RC column 8. The closing steel plate 31 is formed by, for example, installing a steel band having a width equal to or less than the height of the cast-in-place RC pillar 8 so as to surround the outer periphery of the cast-in-place RC pillar 8.
A plurality of vertical ribs 32 are joined to the outer surface 31a or the inner surface 31b of the closing steel plate 31. Each of the vertical ribs 32 has a substantially right-angled triangular shape, and of the two end sides sandwiching the right-angled portion, one is on the outer surface 31a or inner surface 31b of the closing steel plate 31, and the other is on the upper steel plate 15. Each is joined to the upper surface 15e. The thickness and shape of the vertical ribs 32 are appropriately set according to the stress borne by the vertical ribs 32.
As described in the above embodiment, the beam connecting portion 15c is formed so as to project outward in a trapezoidal shape in the direction in which the steel frame beams 7 of the upper steel plate 15 are joined. In the portion of the closing steel plate 31 located on the side where the beam connecting portion 15c is formed, the vertical ribs 32 are in the direction in which the vertical ribs 32 extend on the outer surface 31a of the closing steel plate 31. It is provided so as to protrude from the beam. Further, on the portion of the closing steel plate 31 located on the side where the beam connecting portion 15c is not formed, that is, on the outer peripheral side of the composite building 30, the vertical ribs 32 are formed on the inner surface 31b of the closing steel plate 31 and the vertical ribs 32. Is provided so as to bite into the inside of the on-site cast RC pillar 8 and extend.

Needless to say, the first modification has the same effect as that of the above embodiment.
In particular, in the configuration of the first modification, as described in the above embodiment, the steel pipe 11a constituting the CFT column 5, the upper steel plate 15, and the concrete 11b in the region surrounded by the lower steel plate 16 are Although strongly restrained by these, the steel pipe 11a sandwiches the upper steel plate 15 by providing the closing steel plate 31 on the upper surface 15e of the upper steel plate 15 so as to cover the upper outer periphery of the steel pipe 11a constituting the CFT column 5. Since the shape is extended upward, the strongly restrained concrete area is also expanded above the upper steel plate 15 so as to include the concrete 8b of the cast-in-place RC pillar 8. As a result, the shear strength of the joint portion between the CFT column 5 and the RC column 6 can be increased, and the adhesive force of the column main bar 13 to the concrete 8b can be further strengthened to increase the joint strength between the columns.
Further, since the vertical ribs 32 are joined to the closing steel plate 31, it is possible to strongly resist the horizontal seismic force acting on the closing steel plate 31 in the horizontal direction and to resist shearing.

(Second modification)
Next, a second modification of the complex building 1 shown as the above embodiment will be described with reference to FIG. 7. FIG. 7 is a vertical cross-sectional view of the joint portion between the CFT columns 5 and the RC columns 6 of the composite building 40 in the second modification. In the composite building 40 of the second modification, the column main bar 41 of the CFT column 5 is fixed to the concrete 11b of the mounting portion 11 of the CFT column 5 and the lower steel plate 16 with the composite building 1 in the above embodiment. The difference is that they are.
More specifically, a threaded reinforcing bar or a column main bar 41 of an RC column 6 having a threaded tip portion is provided so as to penetrate a lower steel plate 16 joined to a CFT column 5. The column main bar 41 is fixed to the lower steel plate 16 by fastening the nut 42 to the lower end 41b of the column main bar 41. Examples of the nut 42 for tightening the column main bar 41 include a fixing tool in which the nut and the fixing plate are integrated (for example, a plate nut manufactured by Tokyo Steel Co., Ltd., an EG fixing plate manufactured by Godo Steel, Ltd.), or a hexagon nut. It can be used. In FIG. 7, the nut 42 is provided above and below the lower steel plate 16 so as to sandwich and tighten the lower steel plate 16 from both the upper surface and the lower surface, but the nut 42 may be provided only below the lower steel plate 16. I do not care.

Needless to say, the second modification has the same effect as that of the above embodiment.
In particular, in the configuration of the second modification, the insertion length of the column main bar 41 of the RC column 6 on the upper floor side to be inserted into the CFT column 5 on the lower floor side is short, and the lower end 41b of the column main bar 41 is short. By fastening and fixing the nut 42 to the lower steel plate 16 constituting the CFT column 5, the nut 42 main body and the lower steel plate 16 surface-bonded to the nut 42 main body resist against the withdrawal of the column main bar 41. , The column main bar 41 has a high fixing strength.

The complex building of the present invention is not limited to the above-described embodiment and each modification described with reference to the drawings, and various other modifications can be considered within the technical scope thereof.

For example, in the above-described embodiment and each modification, the shapes of the openings 15a and 16a of the upper steel plate 15 and the lower steel plate 16 are circular, but the shape is not limited to this, and other shapes such as a rectangle may be used.
Further, in the above-described embodiment and modification, the cross-sectional shapes of the CFT columns 5 and RC columns 6 are rectangular, and accordingly, the shapes of the upper steel plate 15 and the lower steel plate 16 are also based on the rectangle. However, the cross-sectional shape of the CFT pillar 5 and the RC pillar 6 may be other shapes such as a circle, and the shapes of the upper steel plate 15 and the lower steel plate 16 are also based on other shapes such as a circle. It may have a rectangular shape.

Further, in the above embodiment and the first modification, a sufficient length is provided from the lower end of the RC column 6 so that a predetermined fixing length can be secured inside the CFT column 5 for the column main bar 13 of the RC column 6. Although the case of projecting has been described, the length (insertion length) of the column main bar 13 inside the CFT column 5 can be shortened by forming the anchoring body at the lower end 13b of the column main bar 13. As a result, the amount of reinforcing bars can be reduced, and the material cost can be reduced.
The anchoring body is, for example, a steel plate having a width dimension larger than the diameter of the column main bar 13 that expands the diameter of the lower end 13b of the column main bar 13 and is welded or welded to the lower end 13b of the column main bar 13. It can be formed by various methods such as screwing a nut or the like to the lower end 13b and fixing the lower end 13b of the column main bar 13 with a tubular member covered.

Further, in the above-described embodiment and each modification, in order to make the shear strength of the cast-in-place RC pillar 8 higher than the shear strength of the PCaRC pillar 9, the high-strength hoop muscle 8e is used in the cast-in-place RC pillar 8. The hoop bars 8e are arranged so as to be denser than the hoop bars 9d of the PCaRC pillar 9, and the on-site RC pillar 8 has the same or higher strength than the concrete 9b of the PCaRC pillar 9. Although high concrete 8b was used, it goes without saying that it is not necessary to carry out all of these at the same time if the target shear strength can be achieved.
Further, as shown in FIG. 3, the on-site cast RC pillar 8 is formed so as to have a height substantially equal to that of the floor slab 18, but the on-site cast RC pillar 8 is not provided with a hoop streak. Only concrete may be a thin layer.

In addition to this, as long as the gist of the present invention is not deviated, the configurations given in the above-described embodiment and each modification can be selected or changed to other configurations as appropriate.

1 Composite building 11 Mounting part 3 Lower floor 11a Steel pipe 4 Upper floor 11b Concrete 5 Concrete-filled steel pipe pillar 11c Inner wall surface 6 Reinforced concrete pillar 13 Pillar main reinforcement 7 Steel beam 15 Upper steel plate 8 Cast-in-place concrete pillar 15b Reinforcement hole 8b Concrete 15e Top surface (Upper surface of concrete-filled steel pipe column)
8f Upper surface 16 Lower steel plate 9 Precast concrete pillar 16b Reinforcing bar hole 9b Concrete 30 Composite building 9c Pillar main reinforcement 31 Closing steel plate 10 General part 32 Vertical rib 10a Steel pipe GL Ground surface 10b Concrete Z Vertical direction 10c Inner wall surface 40 Composite building

Claims (3)

It is a composite building in which concrete-filled steel columns and reinforced concrete columns arranged on the upper floors of the concrete-filled steel columns are continuously arranged in the vertical direction.
At the upper end of the concrete-filled steel pipe column, an upper steel plate and a lower steel plate extending in a direction intersecting the inner wall surface of the concrete-filled steel pipe column are provided at intervals.
The column main bars of the reinforced concrete column penetrate the upper steel plate and the reinforcing bar holes provided in the lower steel plate, and are fixed inside the concrete-filled steel pipe column.
The reinforced concrete columns having a height range substantially equal to that of the floor slab on the upper surface of the upper steel plate are provided with hoop bars at a higher density than the reinforced concrete columns above the floor slab, and a plurality of hoop bars are arranged. composite building, characterized in that the lap-wound portion of the hoop is erected winding superimposed is embedded. It is a composite building in which concrete-filled steel columns and reinforced concrete columns arranged on the upper floors of the concrete-filled steel columns are continuously arranged in the vertical direction.
At the upper end of the concrete-filled steel pipe column, an upper steel plate and a lower steel plate extending in a direction intersecting the inner wall surface of the concrete-filled steel pipe column are provided at intervals.
The column main bars of the reinforced concrete column penetrate the upper steel plate and the reinforcing bar holes provided in the lower steel plate, and are fixed inside the concrete-filled steel pipe column.
The reinforced concrete column includes a cast-in-place concrete column constructed on-site on the upper surface of the concrete-filled steel pipe column and a precast concrete column installed on the upper surface of the cast-in-place concrete column .
A composite building characterized in that the cast-in-place concrete columns having a height range substantially equal to the floor slab on the upper surface of the upper steel plate are made of high-strength concrete as compared with the precast concrete columns. The composite building according to claim 1 or 2, wherein the inside is concrete of a mounting portion constituting the concrete-filled steel pipe column and the lower steel plate.

Images