JP2000282578A - Structure of column - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide the structure of a column in which changeover from steel-pipe reinforced concrete construction to reinforced concrete construction is carried out on the lower-layer floor of a mid-to-high-rise building having large stress. SOLUTION: In the structure of a section continuously changed over from steel-pipe reinforced concrete construction to reinforced concrete construction in a column 10 in which an upper section is formed of reinforced concrete construction and a lower section of steel-pipe reinforced concrete construction by jointly using steel-pipe reinforced concrete construction and reinforced concrete construction, a plate-shaped rib plate 17 is arranged onto an interior-wall surface near to the upper end section of a steel pipe 12 by fixing the outer circumferential section of the rib plate 17 onto the inner circumferential surface of the steel pipe 12 so that an opening is bored at the central section of the steel pipe 12 on a plane orthogonally crossed with the longitudinal axis of the steel pipe 12, a large number of holes 17b are formed on the rib plate 17, main reinforcements 15a constituted in a column section 10b in reinforced concrete construction are inserted into holes 17b formed on the rib plate 17, and extended and arranged in concrete 13 in the upper end section of the steel pipe 12, and bearing members 19 are installed on the interior-wall surface of the steel pipe 12 in the lower section of the rib plate 17.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a column structure, and more particularly, to a combination of a steel tube concrete structure and a reinforced concrete structure. It relates to the structure of the switching part.

[0002]

2. Description of the Related Art Generally, almost no construction has been carried out in a middle-to-high-rise building or the like by using a combination of a steel pipe concrete structure and a reinforced concrete structure. But,
As a similar structure, in a steel-framed reinforced concrete building, there is a case where the construction is switched from the steel-framed reinforced concrete structure to the reinforced concrete structure on the lower floors of the third to fourth floors from the top floor.

[0003] Such a switch is considered to have a considerably small column stress in the upper floors of the building, to be relatively easy to treat the stress, and to be considered to be sufficient in strength even in the case of reinforced concrete, so that material can be saved. In order to reduce the cost and reduce the cost, it was common practice to use the upper floor part with a relatively small load.

[0004] In this case, the pillar is made of ordinary reinforced concrete for the upper floor and the steel reinforced concrete for the lower floor, and the steel frame built in the steel reinforced concrete pillar is directly extended upward at the switching portion. It was arranged almost all the way to the middle of the pillar.

[0005]

By the way, if it is possible to switch from steel pipe concrete to reinforced concrete in the lower part of a high-rise or super-high-rise building where the stress is extremely large, the cost of the whole building can be greatly reduced, or Speeding up of the construction can be realized.

However, in the case of a column in a building using a combination of a steel pipe concrete structure and a reinforced concrete structure, a switching portion between the reinforced concrete column portion and the steel tube concrete column portion, in other words, a structure for sufficiently transmitting the stress in the continuous portion is required. In addition, a structure that alleviates the concentration of stress in the vicinity of the end of the steel pipe concrete column is required. Also, it is necessary to ensure sufficient strength and deformation performance in the switching section between the reinforced concrete column portion and the steel tube concrete column portion.

In view of the above, the present invention has been made in view of the above-described problems, and has a column structure which enables switching from steel pipe concrete to reinforced concrete on a lower floor of a high-rise building having a large stress, for example. The task is to provide

[0008]

Means for Solving the Problems In order to achieve the above object, the structure of the pillar of the present invention employs the following means. That is, the structure of the column of the present invention is a portion where a steel pipe concrete structure and a reinforced concrete structure are used in combination, and a portion of the column having an upper portion made of a reinforced concrete structure and a lower portion made of a steel tube concrete structure is continuously switched from the steel tube concrete structure to the reinforced concrete structure. The inner peripheral wall near the upper end of the steel pipe, the outer peripheral portion of a flat rib plate on a plane perpendicular to the longitudinal axis of the steel pipe so as to open an opening in the center of the steel pipe. The rib plate is fixedly disposed on the inner peripheral surface of the steel pipe, and a large number of holes are formed in the rib plate, and a main reinforcing bar formed in the reinforced concrete pillar portion is inserted through the hole formed in the rib plate. And it is characterized in that it is arranged so as to extend to the concrete inside the upper end of the steel pipe.

<Additional Configuration in the Present Invention> The structure of the pillar according to the present invention is composed of the above-mentioned essential components, but is established even if the following configuration is further added to the components. . The additional component is to provide an additional bearing member on the inner wall surface of the steel pipe below the rib plate.

In the column structure according to the present invention, the supporting member is constituted by a plurality of rod-shaped members, and these rod-shaped members are circumferentially spaced from each other on the inner wall surface of the steel pipe and are arranged in a plurality of steps in the longitudinal direction. It can be provided over. The supporting member functions together with the rib plate to assist in transmitting the axial force from the upper reinforced concrete column portion.

In this case, the height h ₁ from the inner wall surface of the steel pipe to the tip of the supporting member is a distance h ₃ between the inner wall surface of the steel pipe and the main reinforcing bar extending from the upper reinforced concrete column. It is preferable to set it to 1/3 to 2/3 of the above. The interval h _2, and the bearing capacity member spacing h ₂ between each other and the bearing capacity member at the bottom of the rib plate and the rib plate, wherein the said steel pipe inner wall Bearing member distal end to the height h It is preferably 7.5 to 15 times ₁ . Further, the main rebar arranged to be extended from the upper reinforced concrete column portion has a fixing length of the tip of the main rebar beyond the position of the lowermost supporting member at least 15 times the main rebar diameter. It is preferable that

In the column structure according to the present invention, an auxiliary plate is erected on the surface of the rib plate, and the auxiliary plate is fixed to the inner wall surface of the steel pipe so as to increase the rigidity of the rib plate. Is also preferred. By increasing the mounting rigidity of the rib plate by this auxiliary plate, the strength of the switching portion can be increased.

<Operation of the present invention> In the column structure according to the present invention, when the upper portion is a reinforced concrete column portion and the lower portion is a steel tube concrete column portion, the shear force from the upper reinforced concrete column portion is large. Is concentrated on the switching portion of the steel pipe concrete column portion, that is, near the upper end of the steel pipe, and is transmitted to the steel pipe. For this reason, the vicinity of the upper end of the steel pipe concrete column is deformed out of the plane by a large concentrated stress.

In view of this concentrated stress, a rib plate is arranged near the upper end of the steel pipe in the switching section between the steel pipe concrete column portion and the reinforced concrete column portion. Out-of-plane deformation can be alleviated, and deterioration of the concrete inside can be reduced, thereby improving the deformation performance of the column.

Further, in the column structure according to the present invention, the rib plate and the steel pipe cooperate to restrain the internal concrete, so that the strength of the internal concrete is increased, and the binding performance of the main rebar is increased by the restraining force. As a result, the deterioration of the adhesion performance can be reduced. Also,
The rib plate is arranged on a cross section perpendicular to the longitudinal direction of the steel pipe, so that the steel pipe and the internal concrete can be reliably integrated, and the anchoring performance of the steel pipe can be secured. The performance of concrete can be surely exhibited.

Further, in the column structure according to the present invention, a hole is formed in the rib plate disposed in the switching portion, and the main reinforcing bar is inserted into the hole to extend to the steel pipe concrete column portion, thereby making the rib plate extend. Alternatively, the supporting force of the rib plate and the supporting member, and the adhesive force between the steel pipe inner surface and the concrete cooperate to reduce a part of the compressive axial force or the entire tensile axial force from the upper reinforced concrete column part to the lower part. It can be reliably transmitted to the steel pipe.

Incidentally, as a result of conducting a tensile test on the column structure according to the present invention, it has been confirmed that the following fracture surfaces are generated. That is, (1) When a large tensile force acts on a main reinforcing bar extending from a reinforced concrete column portion, an adhesive fracture surface is generated so as to connect the main reinforcing bars to each other. (2) On the other hand, when the stress transmitted to the concrete is transmitted from the concrete to the bearing member, if the spacing between the bearing members is small, a shear fracture surface occurs to connect the tips of the bearing members. . (3) Therefore, when the height of the supporting member tip reaches the vicinity of the main reinforcing bar, the adhesion fracture surface connecting the main reinforcing bars and the shear fracture surface connecting the bearing member distal end affect each other, and the main reinforcing bar is affected. Greatly degrades the fixing performance.

[0018] Therefore, in the structure of the column according to the present invention, the distance h ₂ between Bearing member at the bottom of the rib plate and the rib plate, and the distance h ₂ between the bearing capacity member mutually, from steel pipe inner wall surface By taking 7.5 to 15 times as large as the height h _{1 to} the tip of the bearing member, the shear rupture strength connecting the tip of the bearing member is increased, and the compressive fracture of concrete immediately below the bearing member (so-called bearing pressure) (Destruction).

Further, the height h ₁ from the inner wall surface of the steel pipe to the tip of the supporting member is set to be _１ ／ to ／ times the distance h ₃ between the inner wall surface of the steel pipe and the main reinforcing bar, so that the main reinforcing bars can be separated. By separating the position of the adhesive fracture surface connecting the two and the shear fracture surface connecting the tip of the supporting member, mutual influence is prevented and deterioration of the fixing performance of the main reinforcing bar is avoided.

Further, when the column reaches the maximum proof stress, the main reinforcing bar yields in tension, the adhesive force starts to deteriorate from the yield position, and the position where the adhesive force is applied gradually moves to the back of the main reinforcing bar fixing portion. For this reason, if the length of the main reinforcing bars is short, it is expected that the fixing of the main reinforcing bars will be lost soon after the column yields, and in that case, there will be no deformation performance. Therefore, in the column structure according to the present invention, the main reinforcing bar extending from the upper reinforced concrete column portion has a fixing length of the tip of the main reinforcing bar exceeding the position of the lowermost supporting member, and the main reinforcing bar diameter. By making it 15 times or more, it is possible to obtain the required deformation performance of the column.

[0021]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The structure of a pillar according to an embodiment of the present invention will be described below in detail with reference to FIGS. FIG.
The structure of a column in a building using a combination of a steel pipe concrete structure and a reinforced concrete structure according to an embodiment of the present invention, particularly the structure of a switching portion between a steel pipe concrete column portion and a reinforced concrete column portion is schematically illustrated. I have.

The pillar 10 in such a building using a combination of a steel pipe concrete structure and a reinforced concrete structure is formed of a steel tube concrete column portion 10a on the lower floor and a reinforced concrete column portion 10b on the upper floor. 11 is a steel pipe concrete column part 10a
To the reinforced concrete column portion 10b. The present invention is the structure of the switching section 11 of such a pillar 10.

The steel tube concrete pillar portion 10a on the lower floor of the steel tube concrete structure is formed by placing concrete 13 into a steel tube 12 having a mainly circular or square cross section. This steel pipe concrete column part 10
The steel concrete beams 14 installed on each floor are connected to a. This steel concrete beam 1
Reference numeral 4 denotes H as a beam steel frame 14b inside the concrete 14a.
It is configured with a section steel.

On the other hand, in the reinforced concrete column portion 10b on the upper floor of the reinforced concrete structure, reinforcing bars 15 are arranged in a conventional manner, and then the inside of the form matches the outer peripheral surface of the steel pipe 12 in the steel tube concrete column portion 10a on the lower floor. It is formed by placing concrete 13 in the interior.

Generally, a reinforced concrete column portion 10b
The reinforcing bars 15 arranged in the manner described above are tightly assembled with a plurality of main reinforcing bars 15a arranged in the longitudinal direction thereof and a plurality of shear reinforcing bars 15b arranged in the transverse direction so as to include these main reinforcing bars 15a. It is composed of A reinforced concrete beam 16 usually installed at each floor is connected to the reinforced concrete pillar portion 10b.

The reinforced concrete beam 16 has a main reinforcing bar 16b and a shear reinforcing bar 16 which includes the main reinforcing bar 16b inside the concrete 16a similarly to the reinforced concrete column portion 10b.
c is inserted. By the way, in the building as described above, a suitable position where the switching portion 11 between the steel pipe concrete pillar portion 10a on the lower floor and the reinforced concrete pillar portion 10b on the upper floor is formed is directly below the reinforced concrete beam 16, or It is preferable that the position be separated from the lower surface of the reinforced concrete beam 16 by a maximum of approximately 30 mm.

That is, the upper end of the steel pipe 12 constituting the steel pipe concrete pillar portion 10a on the lower floor is located immediately below at least the lowest reinforced concrete beam 16 in the reinforced concrete structure on the upper floor, or the reinforced concrete beam 16 Is preferably designed so as to be spaced at a maximum of approximately 30 mm from the lower surface of the.

In the switching section 11 between the steel pipe concrete column portion 10a and the reinforced concrete column portion 10b located at such a position, as shown in FIGS.
A flat rib plate 17 having an opening 17a at the center thereof is disposed on a plane perpendicular to the longitudinal axis of the steel pipe 12 at a position within a range of 50 to 200 mm from the upper edge of the steel pipe 12. It is fixed to the inner peripheral surface by welding or the like. The rib plate 17 may be used by combining a plurality of divided plate-like bodies, or may be a single member having an opening at the center.

On the upper surface of the rib plate 17, a plate-like auxiliary plate 18 as a vertical reinforcing rib is provided to increase the rigidity of the rib plate 17 attached to the steel pipe 12. That is, the plate-shaped auxiliary plate 18 has two sides extending in a direction orthogonal to each other or orthogonal to each other, and one side thereof is mounted on the surface of the rib plate 17 and fixed by welding or the like.

The other side of the auxiliary plate 18 contacts the inner wall surface of the steel pipe 12 and is similarly fixed by welding or the like. As a result, the rib plate 17 is firmly fixed to the inner surface of the steel pipe 12. Become. As described above, since the auxiliary plate 18 mainly increases the mounting rigidity of the rib plate 17 to the steel pipe 12, the auxiliary plate 18 may be provided on the lower surface side of the rib plate 17.

The rib plate 17 has a large number of holes 17b.
Is formed, and the main reinforcing bar 15a formed in the reinforced concrete pillar portion 10b is inserted through the hole 17b to form the steel pipe 12a.
Is extended to the concrete 13 in the upper end portion of the steel. As described above, the main reinforcing bar 15a from the reinforced concrete pillar portion 10b extends into the rear end of the steel pipe 12 so as to reach near the upper side of the steel reinforced concrete beam 14.

As shown in FIGS. 1 and 3, a supporting member made of a rod-shaped member 19 having a square cross section is fixed to the inner wall surface of the steel pipe 12 below the rib plate 17. That is, in the embodiment shown in FIGS. 1 to 3, the cross section of the steel pipe concrete column portion 10 a is square, and the rod-shaped members 19 as the bearing members are the respective sides of the square cross section of the steel pipe 12. Are mounted in a plurality of stages (three stages in this embodiment).

The height h ₁ from the inner wall surface of the steel pipe 12 to the tip of the bar member 19 is the same as that of the inner wall surface and the main reinforcing bar 1.
It is ２ of the distance h _{3 from} the distance 5a. The interval h _2, and the rod-like member 19 spacing h ₂ between each other and the rod-like member 19 with a rib plate 17 below the rib plate 17, the height h up to the rod-like member 19 distal from the inner wall surface
_It is ten times as large as _one .

As a result, a number of projections are formed on the inner wall surface below the rib plate 17 installed near the upper end of the steel pipe 12, that is, on the side in the longitudinal center direction of the steel pipe 12. .

The main reinforcing bar 15a extending from the reinforced concrete column portion 10b is connected to the lowermost bar-shaped member 1a.
The fixing length of the tip of the main reinforcing bar 15a beyond the position 9 is at least 15 times the diameter of the main reinforcing bar.

According to the switching section 11 of the steel pipe concrete column portion 10a and the reinforced concrete column portion 10b configured as described above, the out-of-plane rigidity of the steel pipe 12 is secured against the stress concentrated near the upper end of the steel pipe 12. At the same time, it is possible to enhance the integrity of the concrete 13 and the steel pipe 12 inside and obtain good deformation capacity and strength as the column 10.

That is, when considered mechanically, the shearing force from the reinforced concrete column portion 10b on the upper floor is
Most of them are steel pipe concrete pillars 10 on lower floors.
a, which is transmitted to the steel pipe 12 in a concentrated manner near the upper end of the steel pipe 12. Therefore, it is considered that the vicinity of the upper end portion of the steel pipe 12 in the steel pipe concrete column portion 10a tends to deform out of the plane due to a large concentrated stress.

However, according to the column structure according to the present invention described above, in response to this concentrated stress, the switching portion 11 between the steel pipe concrete column portion 10a and the reinforced concrete column portion 10b is provided near the upper end portion of the steel pipe 12. Since the rib plate 17 having the opening 17a is arranged, the steel pipe 1
The stress concentration in the vicinity of the upper end of the column 2 can be reduced, and the deformation of the column can be improved by alleviating local deformation.

The rib plate 17 and the steel pipe 12 cooperate to restrain the concrete 13 inside, so that the strength of the internal concrete 13 is increased. Further, since the main reinforcing bar 15a from the reinforced concrete column portion 10b is inserted into the hole 17a of the rib plate 17, the rib plate 17 restrains the tensile force of the reinforcing bar via concrete. These effects cooperate to improve the fixing performance of the main reinforcing bar 15a from the reinforced concrete pillar portion 10b on the upper floor.

Further, since the rib plate 17 and the rod-like member 19 as described above are arranged near the upper end of the steel pipe 12 on a cross section orthogonal to the longitudinal direction of the steel pipe 12, the steel pipe 1
2 and the internal concrete 13 are satisfactorily integrated, and the strength of the switching portion 11 of the pillar 10 is increased.
The leg of the switching unit 11 is a steel pipe concrete column 1
0a can be reliably exhibited.

In addition, in the column structure according to the present invention, the main rebar 15 of the reinforced concrete column portion 10b is inserted into the hole 17b of the rib plate 17 disposed near the upper end of the steel pipe 12.
Since a is inserted, the position of the main reinforcing bar 15a of the reinforced concrete pillar portion 10b can be easily secured. Moreover, in the switching part 11 of such a pillar 10, since the steel pipe 12 of the outer peripheral part bears the shearing force,
The shear reinforcement can be omitted.

Incidentally, as a result of conducting a tensile test on the column structure according to the present invention, it has been confirmed that the following fracture surface is generated. That is, (1) the main reinforcing bar 15a extending from the reinforced concrete column portion 10b.
When a large tensile force acts on the main reinforcing bars 15a, an adhesion failure surface M is generated to connect the main reinforcing bars 15a to each other, as shown in FIG. (2) On the other hand, when the stress transmitted to the concrete 13 is transmitted from the concrete 13 to the bar member 19,
When the interval between the rod-shaped members 19 is small, as shown in FIG. 5, a shear fracture surface N is generated so as to connect the tips of the rod-shaped members 19. (3) Therefore, when the height of the tip of the rod-shaped member 19 reaches the vicinity of the main reinforcing bar 15a, the adhesive fracture surface M connecting the aforementioned main reinforcing bars 15a and the shear fracture surface N connecting the tip of the rod-shaped member 19 affect each other. As a result, the fixing performance of the main reinforcing bar 15a is greatly deteriorated.

Therefore, in the column structure according to the present invention, the rib
The plate 17 and the bar below the rib plate 17
Interval h with member 19_Two, And between the rod-shaped members 19
H _TwoFrom the inner wall surface of the steel pipe 12 to the tip of the rod-shaped member 19.
Height h₁By taking 10 times as large as
Increase the shear fracture strength connecting the ends, just below the rod-shaped member 19
Compressive failure of concrete (so-called bearing failure, see Fig. 6)
Ref) Q. Note that this interval h_Two
Is the height h up to the tip of the rod-shaped member 19.₁7.5 to 15 times
Preferably, it is designed to be doubled.

In the column structure according to the present invention, the steel pipe 1
The height h ₁ from the inner wall surface of the steel pipe 2 to the tip of the rod-shaped member 19 is set to about １ ／ of the distance h ₃ between the inner wall surface of the steel pipe 12 and the main reinforcing bar, and the stick-shaped fracture surface M connecting the main reinforcing bars 15a to the rod-shaped member. Member 1
By constructing such that it is separated from the shear fracture surface N connecting the tips 9, mutual influence is prevented and deterioration of the fixing performance of the main reinforcing bar 15a is avoided. In addition, the rod-shaped member 19
The height h ₁ to the tip is preferably designed to be よ う to ／ times the distance h ₃ between the inner wall surface of the steel pipe 12 and the main rebar.

Further, when the column 10 reaches the maximum yield strength, the main reinforcing bar 15a pulls down and yields, the adhesive force starts to deteriorate from the yield position, and the position where the adhesive force is applied gradually moves to the back of the main reinforcing bar fixing portion. For this reason, if the length of the main reinforcing bar is short, it is expected that the fixing of the main reinforcing bar 15a will be lost soon after the column yields, and in that case, there will be no deformation performance. Therefore, in the column structure according to the present invention, the main reinforcing bar 15a extending from the reinforced concrete column portion 10b has the anchoring length of the main reinforcing bar tip beyond the position of the lowermost bar-like member 19, 15 times the main reinforcing bar diameter. By extending the above, the deformation performance required for the column 10 is obtained.

[0046]

As described above, according to the column structure according to the present invention, for example, a steel tube concrete column portion can be used for a high-load portion of a lower floor in a middle-high-rise building or a super-high-rise building. It is possible to construct and construct a pillar having a switching part to the pillar portion.

Further, since the steel pipe can be used as a concrete formwork during construction, there is an advantage that the formwork of the pillar can be omitted. In addition, at the time of construction, a steel pipe on the lower floor is erected, and concrete is cast in the steel pipe, and a reinforced concrete structure on the upper floor is constructed. Therefore, these columns function as temporary columns. Therefore, simultaneous construction of the upper layer and the lower layer of the building becomes possible, and the construction period can be shortened.

Further, according to the column structure according to the present invention, it is possible to sufficiently cope with a column switching portion using a combination of a steel pipe concrete structure and a reinforced concrete structure, for which an appropriate construction method has not been established so far. The degree of freedom in design can be expanded.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view schematically showing a structure of a switching portion of a column using both a steel pipe concrete structure and a reinforced concrete structure according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view showing a switching portion of the pillar shown in FIG. 1 cut along line 2-2.

FIG. 3 is a cross-sectional view showing the switching unit of the pillar shown in FIG. 1 cut along line 3-3.

FIG. 4 is an explanatory view of an adhesion fracture surface generated when a tensile force acts on a main reinforcing bar.

FIG. 5 is an explanatory view of a shear fracture surface generated when a distance between rod-shaped members (supporting members) is small.

FIG. 6 is an explanatory view of compressive failure (bearing failure) of concrete immediately below a rod-shaped member (bearing member).

[Explanation of symbols]

Reference numeral 10: a column using a combination of a steel pipe concrete structure and a reinforced concrete structure 10a: a steel pipe concrete column part 10b: a reinforced concrete column part 11 ... a switching part 12 ... a steel pipe 13 ... concrete 14 ... a steel frame concrete beam 14a ... concrete 14b ... a steel frame 15 ... a reinforcing steel 15a ... Main reinforcement 15b ... Shear reinforcement 16 ... Reinforced concrete beam 16a ... Concrete 16b ... Main reinforcement 16c ... Shear reinforcement 17 ... Rib plate 18 ... Auxiliary plate 19 ... Bar-shaped member as a bearing member h ₁ ... Height to the tip of the bearing member is h ₂ ... rib plates and spacing between the rod-like member, and spacing M ... attached fracture surface N ... shear plane Q ... compression fracture of the distance h ₃ ... steel pipe inner wall surface of the bar-like member each other and the main reinforcement (Bearing destruction )

Claims (7)

[Claims] 1. A structure in which a steel tube concrete structure and a reinforced concrete structure are used in combination, and a portion of a column having an upper portion made of a reinforced concrete structure and a lower portion made of a steel tube concrete structure is continuously switched from the steel tube concrete structure to the reinforced concrete structure. On the inner wall surface in the vicinity of the upper end of the steel pipe, the outer peripheral portion is formed on the inner periphery of the steel pipe so that a flat rib plate opens an opening at the center of the steel pipe on a plane perpendicular to the longitudinal axis of the steel pipe. A plurality of holes are formed in the rib plate, and a main reinforcing bar formed in the reinforced concrete column portion is inserted through the hole formed in the rib plate to form the steel pipe. A column structure characterized by being reinforced and extended to concrete at the upper end. 2. The column structure according to claim 1, wherein a supporting member is further provided on an inner wall surface of the steel pipe below the rib plate. 3. The supporting member is composed of a plurality of rod-shaped members, and each of the rod-shaped members is provided on an inner wall surface of the steel pipe at intervals in a circumferential direction and over a plurality of stages in a longitudinal direction. The column structure according to claim 2. 4. A height h ₁ from the inner wall surface of the steel pipe to the tip of the supporting member is a distance h between the inner wall surface of the steel pipe and the main reinforcing bar extending from the upper reinforced concrete column. structure according to claim 2 or claim 3, wherein the pillar to 2/3 from 1/3 of _3. 5. The distance h ₂ between the distance h _2, and the bearing capacity member cross with the bearing capacity member at the bottom of the rib plate and the rib plate, until the bearing capacity member distal from the steel pipe inner wall surface structure of the pillars according to claims 2 to claim 4 of from 7.5 times the height h ₁ and 15 times. 6. The main reinforcing bar, which is disposed extending from the upper reinforced concrete column portion, determines the anchoring length of the tip of the main reinforcing bar beyond the position of the lowermost supporting member. The column structure according to any one of claims 2 to 5, wherein the column structure is 15 times or more of the following. 7. The column structure according to claim 1, wherein an auxiliary plate is erected on the surface of the rib plate, and the auxiliary plate is fixed to an inner wall surface of the steel pipe.