JP7449880B2 - Steel pipe column base structure - Google Patents

Description

The present invention relates to a column base structure of a steel pipe column.

For example, Patent Document 1 discloses a post-insertion structural column in the reverse driving method in which columns (steel columns) for the basement floor are erected into the concrete of the piles (piles built on site) that have not yet hardened. .
Furthermore, in Patent Document 2, a pile cap joining member having a joined steel pipe with a diameter larger than the pile diameter is attached to the pile head with the lower end of the joined steel pipe overlapping the pile head, and A structure is disclosed in which a column base is inserted inside the upper part of the pile head joint member, and concrete is cast and filled inside the pile head joint member. In such a configuration, the efficiency of transmitting the axial force of the column to the pile installed in the ground is increased by connecting the pile and the column through the pile cap connection member and the concrete filled inside. ing.
In the configurations disclosed in Patent Documents 1 and 2, when the column span is short, the piles and pile cap joint members corresponding to each column may interfere with each other, making construction difficult.

On the other hand, Patent Document 3 discloses a configuration in which the lower ends of a plurality of steel columns (steel frames) are buried in the upper portions of piles (cast-in-place round piles). According to such a configuration, by burying a plurality of steel columns above a single pile, construction of a plurality of steel columns can be easily performed even when the column span is short.
However, in the configuration disclosed in Patent Document 3, the lower end of the steel column is simply buried in the upper part of the pile, so it cannot be applied, for example, when the column span is larger than the diameter of the pile. That is, in such a case, a pile must be provided immediately below each steel column in correspondence with each steel column. Therefore, similarly to Patent Document 2, the pile cap joint members of the piles provided corresponding to each steel column may interfere with each other, making construction difficult.

Japanese Patent Application Publication No. 2003-129502 Japanese Patent Application Publication No. 2007-126877 Japanese Patent Application Publication No. 2011-12415

The problem to be solved by the present invention is to create a column base structure for steel pipe columns that can efficiently transmit the axial force of each adjacent column to the pile and is easy to construct even when the column span is short. It is to provide.

As a column base structure of a steel pipe column, the present inventors provided a column base inclined part on the main bodies of adjacent steel pipe columns, and in the foundation concrete part, the steel pipe column bodies were connected to each other via a connecting steel part and the column base inclined part After joining the steel pipe columns, a part of the steel pipe column main body, the inclined column base part, and the connecting steel part are buried in the foundation concrete including the pile head, thereby reducing the compressive axial force that acts on each steel pipe column. The present invention was developed by focusing on the fact that the tensile force can be efficiently transmitted to one pile.
In order to solve the above problems, the present invention employs the following means.
That is, the column base structure of a steel pipe column of the present invention is a column base structure of a steel pipe column in which a steel pipe column and a pile are joined, and one of the piles is adjacent to the other above the first pile. a first steel pipe column main body and a second steel pipe column main body provided at the base; and a first steel pipe column main body connected to the lower ends of each of the first and second steel pipe column main bodies and provided inclined toward the first pile. joining the first and second column pedestal inclined parts, the first steel pipe column main body and the second steel pipe column main body, and the first column pedestal inclined part and the second column pedestal inclined part; a lower end of each of the first and second steel pipe column bodies, a pile head of the first pile, the connecting steel part, and the slopes of the first and second column bases. It is characterized by that part is buried in the foundation concrete part.
According to such a configuration, the first and second steel pipe column bodies that are adjacent to each other above one pile are connected to one another via the first and second column base inclined parts and the connecting steel part. Connected to the pile. In particular, the first and second steel pipe column bodies and the first and second column pedestal inclined parts are firmly joined by the connecting steel part. Moreover, the load is smoothly transmitted between the adjacent first and second steel pipe column bodies and one pile by the first and second column base inclined parts. Furthermore, the lower end portions of each of the first and second steel pipe column bodies, the pile head of one pile, the connecting steel portion, and the first and second column base inclined portions are buried in the foundation concrete portion. . These factors work together, and the axial forces of the first and second steel pipe column bodies are efficiently transmitted from the connecting steel part to the one pile.
In addition, in the above structure, even if the distance between the first and second steel pipe column bodies is short, it is possible to Since it is not necessary to provide multiple piles as in the case of Therefore, design and construction are easy.
Therefore, it is possible to provide a column base structure for a steel pipe column that can efficiently transmit the axial force of each adjacent column to the pile and is easy to construct even when the column span is short.

In one aspect of the present invention, in the column base structure of the steel pipe column of the present invention, the connecting steel portion includes an upper flange that joins the first steel tube column body and the second steel tube column body, and The present invention includes a lower flange that joins the first column pedestal inclined part and the second column pedestal inclined part, and a web provided between the upper flange and the lower flange.
According to such a configuration, the first and second steel pipe column bodies adjacent to each other are connected by the upper flange of the connecting steel part, and the first and second column base inclined parts are connected by the lower flange of the connecting steel part, respectively. It is joined. Since the connecting steel parts are buried in the concrete part as mentioned above, when a pulling force is applied to the first and second steel pipe column bodies, the bearing pressure of the foundation concrete part in contact with the upper flange will cause Lifting of the first and second steel pipe column bodies is suppressed. In addition, since the lower flange is connected to the first and second inclined parts of the column base, compressive force can be applied to the first pile from the first and second steel pipe column bodies via the lower flange. . Therefore, it is possible to realize a column base structure of a steel pipe column having high earthquake resistance.

In one aspect of the present invention, in the column base structure of a steel pipe column of the present invention, the one pile includes a pile concrete portion and a plurality of pile main reinforcements, and at least a part of the plurality of pile main reinforcements is It protrudes from the upper end of the concrete pile part to a position above the lowermost end of the connecting steel part.
According to such a configuration, at least a portion of the plurality of pile main reinforcements overlaps the connecting steel portion in the vertical direction. Thereby, the pulling force acting on the first and second steel pipe column bodies can be reliably transmitted to the one pile.

According to the present invention, it is possible to provide a column base structure for a steel pipe column that can efficiently transmit the axial force of each adjacent column to the pile and is easy to construct even when the column span is short. It becomes possible.

1 is a plan sectional view showing an example of a building structure to which a column base structure of a steel pipe column according to an embodiment of the present invention is applied. FIG. 2 is a longitudinal cross-sectional view showing the configuration of the column base structure of the steel pipe column in the building structure of FIG. 1. FIG. 3 is a sectional view taken along the line II in FIG. 2. FIG. 3 is a sectional view taken along the line II-II in FIG. 2. FIG. 3 is a sectional view taken along the line III-III in FIG. 2. FIG. It is a longitudinal cross-sectional view showing a method of erecting a steel pipe column with the column base structure of the steel pipe column in this embodiment. FIG. 7 is a longitudinal cross-sectional view showing a state continued from FIG. 6 in the method of erecting a steel pipe column with the column base structure of the steel pipe column according to the present embodiment.

The present invention is a column base structure of a steel pipe column in which two steel pipe columns are supported by one pile. A feature of the steel pipe column is that the steel pipe column main body has a column pedestal inclined part at the bottom, and adjacent steel pipe column bodies and column pedestal inclined parts are joined by a connecting steel part.
EMBODIMENT OF THE INVENTION Hereinafter, with reference to an accompanying drawing, the form for implementing the column base structure of the steel pipe column by this invention is demonstrated based on a drawing.
FIG. 1 is a plan sectional view showing an example of a building structure to which a column base structure of a steel pipe column according to an embodiment of the present invention is applied. FIG. 2 is a longitudinal cross-sectional view showing the configuration of the column base structure of the steel pipe column in the building structure shown in FIG. It is equipped with.
The lower structure 2 includes a plurality of piles 21 built in the ground and a foundation beam 22. In this embodiment, each pile 21 is formed to have a circular cross-sectional shape, and extends in the vertical direction in the ground. As shown in FIG. 2, each pile 21 is made of reinforced concrete, for example, and includes a pile concrete portion 24 and a pile main reinforcement 25 embedded in the pile concrete portion 24. In this embodiment, the pile main reinforcement 25 is provided on the outer peripheral side of the pile 21 (see FIG. 5). The foundation beam 22 connects the upper ends of the plurality of piles 21. As shown in FIG. 1, in this embodiment, the foundation beam 22 is provided so as to extend in a first horizontal direction Dh1 and a second horizontal direction Dh2 that are orthogonal to each other along a horizontal plane. As shown in FIG. 2, the foundation beam 22 includes a foundation concrete portion 27 and various reinforcing bars (not shown) including beam main reinforcements embedded in the foundation concrete portion 27.

The upper structure 3 is provided on the lower structure 2. The upper structure 3 is supported by the lower structure 2. The upper structure 3 includes a plurality of steel pipe columns 5 and a beam (not shown) constructed between adjacent steel pipe columns 5.
The steel pipe column 5 extends in the vertical direction. The steel pipe column 5 is made of concrete-filled steel pipe and includes a steel pipe column body 51. The steel pipe column main body 51 includes a steel pipe section 52 and a concrete section 53. The steel pipe portion 52 has a cylindrical shape extending in the vertical direction. The concrete portion 53 is poured and filled inside the steel pipe portion 52. In this embodiment, the steel pipe column main body 51 is formed to have a square cross-sectional shape.

As shown in FIG. 1, in the vicinity of the corner 1c of the building structure 1 in the first horizontal direction Dh1, above one (one) pile 21C, there is a first steel pipe column main body 51A and a second steel pipe column main body 51A. The steel pipe column main bodies 51B are provided adjacent to each other at intervals in the first horizontal direction Dh1. The first pile 21C is provided so as to be located between the first steel pipe column main body 51A and the second steel pipe column main body 51B when viewed from above.
In addition to each of the first steel pipe column main body 51A and the second steel pipe column main body 51B, the steel pipe column 5 above the first pile 21C provided in the vicinity of the first horizontal direction Dh1 of the corner 1c is It includes a first pedestal inclined portion 54A and a second column pedestal inclined portion 54B. As shown in FIG. 2, a first column base inclined portion 54A and a second column base inclined portion 54B are joined to the lower ends 51d of the first steel pipe column main body 51A and the second steel pipe column main body 51B. ing. The first column pedestal inclined portion 54A and the second column pedestal inclined portion 54B are provided to be inclined so that they approach each other from above to below and the interval in the first horizontal direction Dh1 gradually decreases. The first column base inclined portion 54A and the second column base inclined portion 54B are provided to be inclined toward the first pile 21C. The first inclined column base portion 54A and the second inclined column base portion 54B each include an inclined steel pipe portion 55 and a concrete portion 56. The inclined steel pipe section 55 is provided continuously at the lower end of each steel pipe section 52 of the first steel pipe column main body 51A and the second steel pipe column main body 51B. The inclined steel pipe section 55 is formed into a cylindrical shape and extends at an angle along the extending direction of the first column base inclined part 54A and the second column base inclined part 54B. The concrete portion 56 is cast and filled inside the inclined steel pipe portion 55.
FIG. 3 is a sectional view taken along the line II in FIG. 2.
As shown in FIG. 3, a plurality of studs 57 projecting in the horizontal direction are welded to the outer peripheral surfaces of the inclined steel pipe portions 55 of the first inclined column base portion 54A and the second inclined column base portion 54B. . A plurality of studs 57 are buried in the foundation concrete portion 27.

As shown in FIG. 2, the lower end portion of the first steel pipe column main body 51A and the lower end portion of the second steel pipe column main body 51B are joined by a connecting steel member 60. Similarly, the first column pedestal inclined portion 54A and the second column pedestal inclined portion 54B are joined by a connecting steel portion 60. The connecting steel portion 60 extends in the horizontal first direction Dh1 where the first steel pipe column main body 51A and the second steel pipe column main body 51B are adjacent to each other. The connecting steel part 60 has an upper flange 61, a lower flange 62, and a web 63.
FIG. 4 is a sectional view taken along the line II-II in FIG.
The upper flange 61 is arranged on the upper part of the connecting steel part 60 and is formed along a horizontal plane perpendicular to the up-down direction. The upper flange 61 is arranged above the respective lower ends 51d of the first steel pipe column main body 51A and the second steel pipe column main body 51B. The upper flange 61 joins the lower ends of the first steel pipe column main body 51A and the second steel pipe column main body 51B. As shown in FIGS. 2 and 4, the upper flange 61 has an upper flange intermediate portion 61m and an upper flange side end portion 61s. The upper flange intermediate portion 61m is formed between the first steel pipe column main body 51A and the second steel pipe column main body 51B, and connects the first steel pipe column main body 51A and the second steel pipe column main body 51B. . A diaphragm 51p is provided inside the first steel pipe column main body 51A and the second steel pipe column main body 51B at the same height as the upper flange 61 in the vertical direction. The upper flange side end portion 61s is formed to protrude to both outer sides in the first horizontal direction Dh1 with respect to the first steel pipe column main body 51A and the second steel pipe column main body 51B. As shown in FIGS. 3 and 4, the upper flange intermediate portion 61m and the upper flange side end portion 61s of the upper flange 61 have a width W1 in the second horizontal direction Dh2 that is larger than that of the first steel pipe column main body 51A and the upper flange side end 61s. The width dimension W2 of the second steel pipe column main body 51B in the second horizontal direction Dh2 is smaller than the width W2 of the second steel pipe column main body 51B.

FIG. 5 is a sectional view taken along the line III--III in FIG. 2.
As shown in FIGS. 2 and 3, the lower flange 62 is spaced from the upper flange 61 in the vertical direction. The lower flange 62 is arranged above the upper end of the pile 21C at a distance. The lower flange 62 is disposed at the lower part of the connecting steel part 60 and is formed along a horizontal plane perpendicular to the up-down direction. The lower flange 62 is arranged directly below the lower ends of the first pedestal inclined part 54A and the second pedestal inclined part 54B. , are joined to the upper surface of the lower flange 62. The lower flange 62 joins the first column base inclined portion 54A and the second column base inclined portion 54B. As shown in FIGS. 2 and 5, the lower flange 62 has a lower flange intermediate portion 62m, a column base plate portion 62p, and a lower flange side end portion 62s. The lower flange intermediate part 62m is formed between the lower end of the first column pedestal inclined part 54A and the lower end of the second column pedestal inclined part 54B, and is formed between the lower end of the first column pedestal inclined part 54A and the second column pedestal inclined part 54A. It is connected to the lower end of the leg inclined portion 54B. The pedestal base plate portion 62p has a rectangular shape in a plan view, and is located on both outer sides in the first horizontal direction Dh1, and It is formed to expand in diameter on both outer sides in the second horizontal direction Dh2. The lower flange side end portion 62s is formed to protrude to both outer sides in the first horizontal direction Dh1 with respect to the first column pedestal inclined portion 54A and the second column pedestal inclined portion 54B. The lower flange intermediate portion 62m and lower flange side end portion 62s of the lower flange 62 have a width W3 in the second horizontal direction Dh2 that is equal to the horizontal width of the first column pedestal inclined portion 54A and the second column pedestal inclined portion 54B. It is formed smaller than the width dimension W2 in the second direction Dh2.

The web 63 is formed along a vertical plane connecting the upper flange 61 and the lower flange 62. As shown in FIGS. 2 and 5, the web 63 has a web intermediate portion 63m and a web side end portion 63s. Between the upper flange intermediate portion 61m and the lower flange intermediate portion 62m, the web intermediate portion 63m connects the lower end of the first steel pipe column main body 51A, the lower end of the second steel pipe column main body 51B, and the first The column pedestal inclined portion 54A and the second column pedestal inclined portion 54B are connected to each other. The web side end 63s is arranged in a first direction Dh1 horizontally with respect to the first steel pipe column main body 51A, the first column base inclined part 54A, and the second steel pipe column main body 51B and the second column base inclined part 54B. The upper flange side end 61s and the lower flange side end 62s are connected on both outer sides.

Further, as shown in FIGS. 2 and 3, reinforcing plates 65 and 66 are provided in the web intermediate portion 63m. The reinforcing plates 65 and 66 are formed along a horizontal plane perpendicular to the vertical direction, and are spaced apart from each other in the vertical direction. The reinforcing plates 65 and 66 are each formed to protrude from both sides of the web intermediate portion 63m in the horizontal second direction Dh2. The reinforcing plate 65 is formed to connect the lower end 51d of the first steel pipe column main body 51A and the lower end 51d of the second steel pipe column main body 51B. The reinforcing plate 66 is formed between the reinforcing plate 65 and the upper flange intermediate portion 61m to connect the first steel pipe column main body 51A and the second steel pipe column main body 51B. Inside the first steel pipe column main body 51A and the second steel pipe column main body 51B, diaphragms 51q and 51r are provided at the same height as the reinforcing plates 65 and 66 in the vertical direction.
As shown in FIGS. 3 and 5, a plurality of intermediate rib plates 67 are provided on the column base plate portion 62p of the lower flange 62. As shown in FIGS. The plurality of intermediate rib plates 67 are formed along a vertical plane, extending perpendicularly to each of the lower flange 62 and the web 63. The plurality of intermediate rib plates 67 are formed to protrude from the web intermediate portion 63m on both sides in the second horizontal direction Dh2. The plurality of intermediate rib plates 67 are formed at intervals in the first horizontal direction Dh1.
Further, on the column base plate portion 62p, a plurality of column base rib plates 68 are provided on both outer sides of the first column base inclined portion 54A and the second column base inclined portion 54B in the horizontal second direction Dh2. It is provided. The plurality of column base rib plates 68 are formed parallel to the intermediate rib plate 67 at intervals in the first horizontal direction Dh1.

As shown in FIGS. 2 and 3, main reinforcements 71 and 72 of the foundation beam 22 are joined to the upper and lower surfaces of the upper flange 61, respectively. A plurality of main reinforcements 71 and 72 are provided at intervals in the first horizontal direction Dh1. Each of the main reinforcements 71 and 72 extends along the foundation beam 22 extending in the second horizontal direction Dh2.
Similarly, the main reinforcement 73 of the foundation beam 22 is joined to the upper surface of the column base plate portion 62p of the lower flange 62. A plurality of main reinforcements 73 are provided at intervals in the first horizontal direction Dh1. Each of the main reinforcements 73 extends along the foundation beam 22 extending in the second horizontal direction Dh2.
As shown in FIG. 2, in this embodiment, the above-described connecting steel part 60 is divided into two parts at the intermediate part in the first horizontal direction Dh1 into a first connecting steel part 60A and a second connecting steel part 60B. has been done. The first connecting steel part 60A and the second connecting steel part 60B are joined by a joint plate 69 and bolts (not shown).

The lower ends of each of the first steel pipe column main body 51A and the second steel pipe column main body 51B, the pile head 21t of the first pile 21C, the connecting steel part 60, the first column base inclined part 54A and the second The column base inclined portion 54B is buried in the foundation concrete portion 27.
As shown in FIG. 2, the foundation concrete section 27 includes a first foundation concrete section 27A and a second foundation concrete section 27B. In FIG. 2, the boundary between the first concrete foundation part 27A and the second concrete foundation part 27B is indicated by a broken line.
The first foundation concrete part 27A includes the pile head 21t of the first pile 21C, the lower flange 62 of the connecting steel part 60, and each of the first column base inclined part 54A and the second column base inclined part 54B. The lower part is buried.
The second foundation concrete section 27B includes, above the first foundation concrete section 27A, upper portions of each of the first column pedestal inclined section 54A and the second column pedestal inclined section 54B, and the first steel pipe column main body 51A. It is cast so as to bury the lower end of the second steel pipe column main body 51B, the upper flange 61 of the connecting steel part 60, and the reinforcing plates 65 and 66. The second foundation concrete section 27B uses concrete that has higher fluidity and higher strength than the first foundation concrete section 27A.

As shown in FIG. 3, among the plurality of pile main reinforcements 25 of one pile 21C, some of the pile main reinforcements 25s arranged in a position that does not interfere with the lower flange 62 when viewed in plan as shown in FIG. It protrudes from the upper end 24t of the concrete part 24 to a position above the lowermost end 60z of the connecting steel part 60.
Among the plurality of pile main reinforcements 25, the remaining pile main reinforcements 25t arranged below the lower flange 62 protrude from the upper end 24t of the pile concrete part 24 to a position below the lowest end 60z of the connecting steel part 60. .
As shown in FIG. 5, reinforcing bars 26 are provided inside the pile main bars 25 at positions that do not interfere with the lower flange 62 when viewed in plan. As shown in FIG. 3, the lower end of the reinforcing bar 26 is buried in the concrete pile part 24. The reinforcing bars 26 protrude from the upper end 24t of the pile concrete part 24 to a position above the lowermost end 60z of the connecting steel part 60.
In this embodiment, the pile main bars 25s and the reinforcing bars 26 are provided so that the length L of their upward protrusion from the lowermost end 60z of the connecting steel part 60 is, for example, 2000 mm. The pile main bars 25s and the reinforcement bars 26 vertically extend along the steel pipe column 5, that is, the first steel pipe column main body 51A, the second steel pipe column main body 51B, the first column base inclined portion 54A, and It is provided so as to overlap with the second column base inclined portion 54B.

(Method of constructing column base structure of steel pipe column)
FIG. 6 is a longitudinal sectional view showing a method of erecting a steel pipe column with the column base structure of the steel pipe column in this embodiment. FIG. 7 is a longitudinal sectional view showing a state following FIG. 6 in the method of erecting a steel pipe column with the column base structure of the steel pipe column in this embodiment.
As shown in FIG. 6, in order to erect the steel pipe column 5 with the column base structure of the steel pipe column 5 configured as described above, first, piles 21C are constructed in the ground.
Next, 27 m of concrete or mortar forming the lower part of the foundation concrete part 27 is placed so as to cover the pile head 21t of the pile 21C. Here, the concrete or mortar 27m forming the lower part of the foundation concrete part 27 is poured to the same level as the lower end side of the lower flange 62 of the connecting steel part 60.
In addition, the first steel pipe column main body 51A, the first column pedestal inclined part 54A, and the first connecting steel part 60A, the second steel pipe column main body 51B, the second column pedestal inclined part 54B, and the second Column base units 100A and 100B are manufactured in advance by welding the connecting steel portion 60B together.

Next, the column base unit 100A forming the first steel pipe column main body 51A, the first column base inclined part 54A, and the first connecting steel part 60A is placed on 27 m of concrete or mortar using a crane, chain block, etc. It is erected using a lifting device 200. Subsequently, as shown in FIG. 7, the column base unit 100B forming the second steel pipe column main body 51B, the second column base inclined part 54B, and the second connecting steel part 60B was built first. It is erected using a lifting device 200 on 27 m of concrete or mortar adjacent to the column base unit 100A. Thereafter, the first connecting steel part 60A of the column base unit 100A and the second connecting steel part 60B of the column base unit 100B are joined by a joint plate 69.
After that, concrete 27c is cast on top of the concrete or mortar 27m to a predetermined level that is a predetermined dimension above the upper flange 61 of the connecting steel part 60, thereby forming the upper part of the foundation concrete part 27 of the foundation beam 22, i.e. The upper part of the first foundation concrete part 27A shown in FIG. 2 and the second foundation concrete part 27B are formed. When the concrete 27c hardens after a predetermined curing period and develops a predetermined strength, the column base structure of the steel pipe column 5 as described above is realized.

As shown in FIG. 1, in this embodiment, in the vicinity of the corner 1c of the building structure 1 in the second horizontal direction Dh2, each steel pipe column 5D has a A stake 21D is provided directly below 5D. That is, regarding the steel pipe columns 5D and the piles 21D, unlike the neighboring parts in the first horizontal direction Dh1, they do not have the above-mentioned column base structure, and each steel pipe column 5D has only a steel pipe column main body. It does not have a sloped column base. Adjacent steel pipe columns 5D are joined by a connecting steel part 60D having a vertical cross-sectional shape as shown in FIG. 3, similar to the connecting steel part 60 in the column base structure as described above.

(Effects of column base structure of steel pipe column)
According to the column base structure of the steel tube column 5 as described above, the column base structure of the steel tube column 5 is such that the steel tube column 5 and the pile 21 are joined, and one pile 21C and one pile 21C are connected to each other. A first steel pipe column main body 51A and a second steel pipe column main body 51B provided adjacent to each other in the upper part are joined to the lower ends 51d of each of the first and second steel pipe column main bodies 51A and 51B to form one pile. 21C, the first and second column base inclined parts 54A and 54B, the first steel pipe column main body 51A, the second steel pipe column main body 51B, and the first column base inclined part 54A and a connecting steel part 60 that connects the second column base inclined part 54B, the lower end of each of the first and second steel pipe column bodies 51A and 51B, and the pile head 21t of the first pile 21C. , a connecting steel part 60, and first and second column base inclined parts 54A and 54B are buried in the foundation concrete part 27.
According to such a configuration, the first steel pipe column main body 51A and the second steel pipe column main body 51B that are adjacent to each other above the one pile 21C have the first column base inclined part 54A and the second column base inclined part. It is joined to the first pile 21C via the section 54B and the connecting steel section 60. In particular, for each adjacent steel pipe column 5, the first steel pipe column main body 51A and the first column base inclined part 54A are joined, and the second steel pipe column main body 51B and the second column base are joined. Since the inclined parts 54B are joined and each of them is connected to the connecting steel part 60, the steel pipe column 5 and the foundation concrete part 27 are connected by the first and second column base inclined parts 54A, 54B and the connecting steel part 60. The fixing strength of the steel pipe column 5 to the concrete is increased, and the steel pipe column 5 can be firmly joined to the foundation concrete part 27. In addition, the first column base inclined portion 54A and the second column base inclined portion 54B smoothly transfer the load between the adjacent first steel pipe column main body 51A and second steel pipe column main body 51B and the first pile 21C. is transmitted. Further, the lower end portions of the first and second steel pipe column bodies 51A and 51B, the pile head 21t of the first pile 21C, the connecting steel portion 60, and the first and second column base inclined portions 54A and 54B are , is buried in the foundation concrete part 27. As a result of these effects, the axial forces of the first steel pipe column main body 51A and the second steel pipe column main body 51B are efficiently transmitted from the connecting steel part 60 to the first pile 21C.
In addition, in the above structure, even if the distance between the first and second steel pipe column bodies 51A, 51B is short, the distance between the first and second steel pipe column bodies 51A, 51B is Since it is not necessary to provide multiple piles as in the case of Therefore, design and construction are easy.
Therefore, it is possible to provide a column base structure for the steel pipe column 5 that can efficiently transmit the axial force of each adjacent column to the pile 21 and is easy to construct even when the column span is short. Become.

The connecting steel part 60 also includes an upper flange 61 that connects the first steel pipe column main body 51A and the second steel pipe column main body 51B, and connects the first column base inclined part 54A and the second column base inclined part 54B. and a web 63 provided between the upper flange 61 and the lower flange 62.
According to such a configuration, the first steel pipe column main body 51A and the second steel pipe column main body 51B that are adjacent to each other are connected by the upper flange 61 of the connecting steel part 60, and the first column base inclined part 54A and the second The column pedestal inclined portions 54B are each joined by a lower flange 62 of a connecting steel portion 60. Since the connecting steel part 60 is buried in the concrete part 27 as described above, it comes into contact with the upper flange 61 when a pulling force is applied to the first steel pipe column main body 51A and the second steel pipe column main body 51B. Due to the bearing pressure action of the foundation concrete portion 27, lifting of the first steel pipe column main body 51A and the second steel pipe column main body 51B is suppressed. In addition, since the lower flange 62 is joined to the first column pedestal inclined part 54A and the second column pedestal inclined part 54B, the first steel pipe column main body 51A and the second steel pipe column main body 51A are connected to each other via the lower flange 62. Compressive force can be applied to the first pile 21C from the main body 51B. Therefore, it is possible to realize a column base structure of the steel pipe column 5 having high earthquake resistance.

Further, the connecting steel part 60 includes reinforcing plates 65 and 66 provided above the vertical center of the web 63 and below the upper flange 61 and parallel to the upper flange 61.
According to such a configuration, lifting of the first steel pipe column main body 51A and the second steel pipe column main body 51B is prevented when a pulling force is applied to the first steel pipe column main body 51A and the second steel pipe column main body 51B. , can be suppressed more effectively.

Further, the foundation concrete section 27 includes a first foundation concrete section 27A and a second foundation concrete section 27B, and the first foundation concrete section 27A includes the pile head 21t of the first pile 21C and the lower flange of the connecting steel section 60. 62, and the lower part of each of the first and second column base inclined parts 54A, 54B, and the second foundation concrete part 27B is placed under the first and second column base inclined parts 54A, 54B. The upper portions of the sections 54A and 54B, the lower ends of the first and second steel pipe column bodies 51A and 51B, and the upper flange 61 and reinforcing plates 65 and 66 of the connecting steel section 60 are buried. The second foundation concrete section 27B uses concrete with higher fluidity and higher strength than the first foundation concrete section 27A.
According to such a configuration, in the column base structure of the steel pipe column 5 as in the above embodiment, particularly the upper portion of the connecting steel portion 60 has a complicated structure including the upper flange 61 and the reinforcing plates 65 and 66. At the same time, a large pulling force acts as described above. Here, the second foundation concrete section 27B in which this part is buried is made of concrete that has higher fluidity and higher strength than the first foundation concrete section 27A. For this reason, it is possible to improve the filling performance when filling concrete into a complex structure such as the one described above, and at the same time, it is possible to effectively resist the pulling force.

The first pile 21C includes a pile concrete portion 24 and a plurality of pile main reinforcements 25, and at least a portion 25s of the plurality of pile main reinforcements 25 extends from the upper end 24t of the pile concrete portion 24 to the lowest end of the connecting steel portion 60. It protrudes to a position above 60z.
According to such a configuration, at least a portion 25s of the plurality of pile main reinforcements 25 overlaps the connecting steel portion 60 in the vertical direction. Thereby, the pulling force acting on the first steel pipe column main body 51A and the second steel pipe column main body 51B can be reliably transmitted to the one pile 21C.

Further, reinforcing bars 26 are provided so as to extend in the vertical direction at a position that does not interfere with the lower flange 62 when viewed from above, and the lower ends of the reinforcing bars 26 are buried in the pile concrete part 24. protrudes from the upper end 24t of the pile concrete part 24 to a position above the lowermost end 60z of the connecting steel part 60.
According to such a configuration, the reinforcing bars 26 overlap the connecting steel portion 60 in the vertical direction. Thereby, the pulling force acting on the first steel pipe column main body 51A and the second steel pipe column main body 51B can be reliably transmitted to the one pile 21C.

In a normal configuration in which one pile is provided for one steel pipe column, only the axial force of one steel pipe column acts on one pile. On the other hand, in the column base structure of the steel pipe column 5 having the above-mentioned configuration, it acts on each of at least two steel pipe columns 5, the first steel tube column main body 51A and the second steel pipe column main body 51B. The axial force is transmitted to the first pile 21C. That is, compared to the normal configuration, the axial force acting on the first pile 21C increases, thereby effectively suppressing the uplift of the steel pipe column 5, which is subjected to a large pulling force in the event of an earthquake or the like.
In addition, when the architectural structure 1 is viewed from above, the pull-out force acting on the piles 21 located on the outer edge 1a (see FIG. 1) between the corners 1c is greater than the The pulling force acting on the pile 21C is large. On the other hand, particularly in this embodiment, the first steel pipe column main body 51A and the second steel pipe column main body 51B are joined to one pile 21C arranged near the corner 1c of the building structure 1. The structure is said to be As a result, as described above, the axial force acting on the first pile 21C increases more than usual, and the uplift of the steel pipe column 5, which is subjected to a large pull-out force during an earthquake, can be further effectively suppressed.

Note that the column base structure of the steel pipe column of the present invention is not limited to the above-described embodiment described with reference to the drawings, and various modifications can be made within the technical scope thereof.
For example, in the above embodiment, the first steel pipe column main body 51A and the second steel pipe column main body 51B are connected to one pile 21C arranged near the corner 1c of the building structure 1. However, it is not limited to this. In the building structure 1, the first steel pipe column main body 51A and the second steel pipe column main body 51B may be joined to the pile 21 arranged at a location other than the corner 1c.
Moreover, the first steel pipe column main body 51A and the second steel pipe column main body 51B were connected to the first pile 21C, but three or more steel pipe columns 5 were connected to the first pile 21C in the same way as above. They may be joined by applying a certain configuration.
Further, in the above embodiment, in the vicinity of the corner 1c of the building structure 1 in the second horizontal direction Dh2, each steel pipe column 5D has a pile 21D immediately below the steel pipe column 5D. was provided, but is not limited to this. In addition to applying the column base structure of the steel pipe column as in the above embodiment in the vicinity of the corner 1c of the building structure 1 in the first horizontal direction Dh1, the same method is applied also in the vicinity of the second horizontal direction Dh2. A column base structure of a steel pipe column may also be used.
Further, in the above embodiment, the cross-sectional shape of the pile 21 is circular, but it is not limited to this, and may be formed in other shapes such as a square or a rectangle. Similarly, in the above embodiment, the cross-sectional shape of the steel pipe column main body 51 is square, but it is not limited to this, and may be formed in other shapes such as circular or rectangular.
In addition to this, it is possible to select the configurations mentioned in the above embodiments or to change them to other configurations as appropriate, without departing from the gist of the present invention.

5 Steel pipe column 51B Second steel pipe column main body 21 Pile 51d Lower end 21C One pile 54A First column pedestal inclined part 21t Pile head 54B Second column pedestal inclined part 24 Pile concrete part 60 Connecting steel part 24t Upper end 60z Top Lower end 25 Pile main reinforcement 61 Upper flange 25s At least part of the pile main reinforcement 62 Lower flange 27 Foundation concrete part 63 Web 51A First steel pipe column body

Claims (3)

A column base structure of a steel pipe column in which a steel pipe column and a pile are joined,
one said pile;
A first steel pipe column body and a second steel pipe column body provided adjacent to each other above the one pile;
first and second column base inclined parts connected to the lower ends of each of the first and second steel pipe column bodies and provided to be inclined toward the one pile;
a connecting steel part that joins the first steel pipe column main body and the second steel pipe column main body, and also connects the first column pedestal inclined part and the second column pedestal inclined part,
The lower end portions of each of the first and second steel pipe column bodies, the pile head of the first pile, the connecting steel portion, and the first and second column base inclined portions are buried in a foundation concrete portion. The column base structure of a steel pipe column is characterized by The connecting steel part includes an upper flange that connects the first steel pipe column main body and the second steel pipe column main body, and a lower flange that connects the first column pedestal inclined part and the second column pedestal inclined part. The column base structure of a steel pipe column according to claim 1, further comprising: a web provided between the upper flange and the lower flange. The first pile includes a pile concrete part and a plurality of pile main reinforcements,
The steel pipe column according to claim 1 or 2, wherein at least a part of the plurality of pile main reinforcements protrudes from the upper end of the pile concrete part to a position above the lowest end of the connecting steel part. Column base structure.

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