JP2001040768A - Column base structure of steel framed reinforced concrete - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a column base structure of steel framed reinforced concrete almost equal in workability to a non-embedded type column base structure and higher in strength. SOLUTION: This column base structure of steel framed reinforced concrete is constructed by embedding, in concrete, an underground beam; a base plate 6 disposed almost flush with the tip end of the underground beam; a column steel frame 21 erected on the upper face of the base plate 6, a plurality of column main reinforcements 12 erected around the column steel frame 2; a hoop 14 arranged surrounding a plurality of column main reinforcements 12; and auxiliary hoops 34 engaged with the hoop 14. Connecting reinforcements 32 piercing the base plate 6 to transmit stress applied to the upper part of the base plate 6, to the lower part of the base plate 6 are arranged at the base plate 6, and the column steel frame 2 is provided with connecting reinforcement through-holes 30, auxiliary hoop through-holes, and the like.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a column base structure made of steel reinforced concrete.

[0002]

2. Description of the Related Art As a steel reinforced concrete column base,
An embedded steel reinforced concrete column base and a non-embedded steel reinforced concrete column base are known. An embedded steel reinforced concrete column base (hereinafter referred to as an embedded column base) is an underground beam 20 as shown in FIGS.
A column steel frame 2 erected from the inside, a plurality of column main bars 12 arranged around the column steel frame 2, and a band bar 14 surrounding and encircling the column main bars 12 are surrounded by a formwork. Concrete is cast in the formwork, and the column steel frame 2, the column main bar 12, the band bar 1
4 is a column base made by burying concrete in concrete. That is, a column base structure in which the lower portion of the column steel frame 2 extends to the bottom of the underground beam 20.

[0003] The underground beam 20 here is a beam composed of the underground beam main reinforcement 16 and the underground beam shear reinforcement 18, and is a part which becomes a foundation of a structure. A base plate 6 is welded to a lower end of the column steel frame 2, and the base plate 6 is fastened with a nut to an anchor bolt 10 rising on a base footing 8 serving as a base of the column base. Further, a plurality of stud bolts 4 projecting below the flange surface of the column steel frame 2 to enhance the integration between the reinforced concrete 3 and the column steel frame 2.

A non-embedded steel reinforced concrete column base (hereinafter referred to as a non-embedded column base) is made of the same components as the above-mentioned embedded column base, but as shown in FIGS. A base plate 6 fixed to the lower end of the column steel frame 2 is disposed at substantially the same height as the top end 20a of the underground beam 20, and the base plate is attached to an anchor bolt 10 rising from the foundation footing 8 to the top end 20a of the underground beam 20. 6 are concluded. That is, the column steel frame 2 in the non-embedded column base
Is a column base structure that stands upright from near the top end 20a of the underground beam 20. The column main bar 12 has an underground beam 20 like the embedded column base.
It is erected from inside and arranged around the column steel frame 2. The stirrups 14 also surround and are arranged around the plurality of column main bars 12 similarly to the embedded column base. And they are pillar bases made by embedding them in concrete.

[0005]

In the meantime, the embedded column base is composed of an underground beam main reinforcement 16 and an underground beam shear reinforcement 18 which are arranged in the underground beam 20 at the time of construction, and the column steel frame 2. It is necessary to prevent crossing and engagement, and as a countermeasure, it is necessary to provide a horizontal haunch 22 as shown in FIG. However, when the horizontal haunch 22 is provided, the work of arranging the underground beams 20 and the work of arranging the concrete formwork are troublesome, and the workability is deteriorated. Furthermore, since it is necessary to arrange the column steel frame 2 before embedding the underground beam 20 in concrete, the construction process is complicated and the workability is deteriorated.

On the other hand, in the non-embedded column base structure, the column steel frame 2 can be provided outside the underground beam 20, so that the column main reinforcement 12 and the band reinforcement 14 can be accommodated in the underground beam 20 and arranged well. it can. Therefore, the non-embedded column base is easier to construct than the embedded column base. However, the construction of the non-embedded column pedestal is better than that of the embedded column pedestal, but when examined in terms of strength, the strength is slightly lower than that of the embedded column pedestal. There's a problem. As a cause of this, a large compressive force, tensile force and bending stress due to the earthquake are repeatedly applied to the column main reinforcement 12 and the anchor bolt 10 located below the column steel frame 2, and the rebar and the anchor bolt 1
It is thought that concrete breaks when 0 buckles or breaks.

Therefore, in order to increase the strength of the non-embedded column base, the number of column main bars 12 arranged around the column steel frame 2 or the number of anchor bolts 10 is increased to connect with the base plate 6. Attempts to increase power have been made to date. However, these attempts had some disadvantages in the following points.

In an attempt to increase the strength of the column base by increasing the number of column main bars 12, the column main bars 12 are arranged avoiding a base plate welded to the lower end of the column steel frame 2, so that the column main bars 12 increase. The cross-sectional area of the column base also increases.
More specifically, in arranging the column main reinforcements 12, it is necessary to arrange a certain interval between the adjacent column main reinforcements 12 so that concrete can easily flow into the column main reinforcements 12. is there. Therefore, when the column main bars 12 are densely provided, a defect occurs. Therefore, in this attempt, the area occupied by the column base with respect to the floor surface is inevitably increased, which is not suitable for building construction.

In an attempt to increase the strength by increasing the number of anchor bolts 10, it is easy to increase the number of anchor bolts 10, but it is very difficult to fasten a nut near the column steel frame 2. The workability was poor. Furthermore, the anchor bolt 10 is relatively expensive compared to the reinforcing rod, and is not suitable from the viewpoint of cost.

Accordingly, the present invention provides a steel reinforced concrete column base structure which can have not only the same workability as a non-embedded column base structure but also an increase in proof stress during an earthquake. That is the task.

[0011]

According to the present invention, in order to solve the above-mentioned problems, an underground beam, a base plate disposed at substantially the same height as the top end of the underground beam, and an upright standing on an upper surface of the base plate. The column steel frame to be installed, the plurality of column main bars standing around the column steel frame, the stirrups surrounding the plurality of column main bars, and the sub stirrups engaging with the stirrups are buried in concrete. Steel reinforced concrete column base structure, wherein the base plate is provided with connecting reinforcing bars that penetrate through the base plate and transmit stress acting on the base plate below the base plate. Structured.

That is, according to the present invention, in addition to the conventional non-embedded column base structure, connecting reinforcing bars penetrating the base plate and extending upward and downward are arranged, and then these reinforcing bars and the steel frame are embedded in the concrete. Structured. In addition, as a method of penetrating the connecting reinforcing bar through the base plate, it is very difficult to form a plurality of connecting reinforcing bar through holes having a diameter larger than that of the connecting reinforcing bar in the base plate, and insert the connecting reinforcing bar into the connecting reinforcing bar through hole to arrange the reinforcing bars. It is suitable.

Therefore, it is possible to greatly increase the reinforcing bar without increasing the cross-sectional area of the column base on which the connecting reinforcing bar is arranged, and to transmit the stress acting on the column base by the connecting reinforcing bar into the underground beam to thereby increase the base plate. It is possible to prevent stress concentration in the vicinity, thereby increasing the tensile strength of the column base. Therefore, the column base can have high strength. In addition, the construction can be performed by a simple operation such as providing a connecting reinforcing bar extending above and below the base plate, so that the same level of workability as the conventional non-embedded column base can be secured. The workability referred to herein means workability, cost, practicality, and the like, which are problems when constructing a steel reinforced concrete column base.

Further, the column steel frame may be provided with a plurality of through holes for sub-cortical muscles, and the sub-cortical muscles may be inserted from both sides of the through-holes. Furthermore, in that case, the insertion amount of the accessory stigma into the through hole is 5 to the diameter of the accessory stirrup.
It is very preferable to set the insertion amount to 10 times.

In this structure, since the sub-bar is laid through the steel column, the integration between the steel column and the reinforced concrete portion is high, and a large tensile force or bending stress acting on the column base during an earthquake or the like is obtained. Demonstrate strong drag against That is, a strong column base that does not collapse even with a small crack can be obtained. In addition, the construction can be carried out by a simple operation such as inserting sub-bars into a plurality of through holes provided in the column steel frame. Accordingly, it is possible to obtain a steel reinforced concrete column base structure having high resistance to earthquakes and excellent workability.

A plurality of sub-ligament through-holes may be formed in the web of the column steel frame, and a plurality of the sub-ligaments may be inserted into the sub-ligament through-holes. The web of the columnar steel frame has a margin in the proof stress, and the through-hole of the accessory ligament can be provided without lowering the strength of the columnar frame. Furthermore, if a plurality of sub-ligaments can be inserted into the sub-ligament through-holes, the sub-ligaments can be efficiently arranged using a technique such as a lap joint.

According to the present invention, there is provided a steel reinforced concrete column base structure in which connecting reinforcing bars laid through the base plate are embedded in concrete, and a sub-band laid through the column steel frame in addition to the column base structure. The steel reinforced concrete column base structure with the bars buried in the concrete makes it possible to obtain a stronger steel reinforced concrete column base structure while ensuring the same workability as the conventional non-embedded column base. it can. Therefore, the resistance to earthquakes can be increased. The steel reinforced concrete column base structure of the present invention can of course be applied to a root-wound steel column base similar to the non-embedded column base structure.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A steel reinforced concrete column base structure according to the present invention will be described below with reference to the drawings. In the present embodiment, the same portions as those of the conventional non-embedded column base structure shown in FIGS. 9 and 10 are denoted by the same reference numerals, and description thereof will be omitted. <Embodiment 1> In Embodiment 1, as shown in FIG. 1, in addition to the conventional non-embedded column base structure, a connecting reinforcing bar 32 penetrating through base plate 6 and extending above and below base plate 6 is provided. After the reinforcing bars 34 penetrating through the column steel frame 2 are arranged, they are buried in concrete to form a steel reinforced concrete column base structure.

First, starting from the base plate 6, the base plate 6 is connected by welding to the lower end of a column-shaped steel frame 2 having a cross-shaped cross section having a web 2a and a flange 2b as shown in FIGS. A plurality of connecting reinforcing bar through holes 30 (hereinafter, referred to as through holes 30) are formed in the base plate 6 at positions surrounded by the flanges of the column steel frames 2. The inner diameter of the through hole 30 is formed so as to be about 10 to 20 mm larger than the diameter of the connecting rebar, and the connecting rebar 32 can be easily inserted.

The connecting rebars 32 are inserted into a plurality of through holes 30 provided in the base plate 6 and extend above and below the base plate 6. In addition, the anchoring length (the length required to prevent the rebar buried in concrete from moving or pulling out) is compared with the anchoring length of the column main bar 12 (30 to 40 times the rebar diameter). About half (about 20 times the rebar diameter). Since the place where the connecting rebar 32 is arranged is surrounded by the web 2a and the flange 2b of the column steel frame 2, the concrete is restrained by the steel frame. Therefore, the concrete strength in this portion is very high, and the bonding strength between the connecting reinforcing bar 2 and the concrete is high. Therefore, the fixing length of the connection reinforcing bar 2 can be shortened.

Further, it is preferable that the connecting reinforcing bar 32 be a deformed reinforcing bar. The deformed reinforcing bar referred to here is a reinforcing bar provided with projections and knurls on its surface for increasing the mechanical bonding strength, and is a reinforcing steel having a high bonding strength to concrete.

The connecting reinforcing bars 32 arranged in parallel to the longitudinal direction of the column base thus exert a strong resistance against a large tensile force or bending stress acting on the column base during an earthquake or the like. More specifically, the bending stress concentrated near the base plate 6 can be efficiently transmitted into the underground beam 20 by the connecting reinforcing bar 32.

The tensile force acting on the column pedestal is affected by the adhesion between the connecting reinforcing bar 32 and the concrete and the tensile strength of the connecting reinforcing bar 32. In this way, it is possible to obtain a steel reinforced concrete column base structure that does not easily collapse even during an earthquake or the like.

As described above, according to the present invention, the base plate 6
32 extending through and extending above and below
, The column main reinforcement 1 is provided only on the outer periphery of the base plate 6.
As compared with the conventional non-embedded column base in which the reinforcing bars 2 are arranged, it is possible to greatly increase the amount of rebar without increasing the cross-sectional area of the column base.

Next, a description will be given of the accessory girdle muscle arranged to penetrate the column steel frame. First, a description will be given of the accessory ligament through hole 31 (hereinafter, referred to as a through hole 31) provided in the column steel frame 2. As shown in FIG. 3, the through holes 31 are provided in the web 2 b of the column steel frame 2, and are arranged in a line in the longitudinal direction of the column steel frame 2. Further, the inner diameter is formed larger than the diameter of the auxiliary stirrup 34 inserted into the through hole 31. More specifically, the diameter is about 2.5 to 3 times larger.

The auxiliary stirrup 3 arranged through the through hole 31
4 is a deformed reinforcing bar. The appearance is U-shaped,
Both ends are arranged in the same direction. In other words, the sub-band streaks 34 are provided with two bent portions 35 that are bent at right angles. The muscle 34 has been inserted. At this time, since one set of sub-strut is inserted into one through-hole 31 from both sides thereof, two sub-stitches 34 are inserted into one through-hole 31. . Therefore, both ends of the set of sub-ligaments 34 inserted into the through-holes 31 are arranged in an overlapping manner.

Incidentally, when the insertion amount of the sub-ligament 34 into the through hole 31 is about 5 to 10 times the diameter of the sub-ligament 34, an appropriate fixing length can be obtained. The concrete in the vicinity of the through hole 31 is restrained by the web 2a and the flange 2b of the column steel frame 2, and the bonding strength between the sub-stirrup 34 and the concrete is further increased. In the experiment, when the concrete strength was set to 600 kg / cm 2 and the insertion amount of the sub stirrup was set to 5 times the diameter of the sub stirrup, 8000 kg
/ Cm2. The fixing length may be determined based on empirical rules in consideration of not only the fixing length described above but also the strength of the concrete and the strength of the auxiliary stirrup 34.

At this time, a part of the auxiliary stirrup 34, that is, between the bent portions 35 provided at two places, is securely bound to the stirrup 14 by a binding wire such as a number line. In the first embodiment, the U-shaped secondary stirrup 34 is used.
In addition to this shape, for example, a sub-shaped streak such as a letter-shaped or a J-shaped may be used, and one sub-shaped streak 34 may be arranged for one through-hole 31. Such a construction is suitable for the construction of a column base having a relatively small cross section. Further, depending on the case, three or more auxiliary stirrups 34 may be arranged in one through hole.

As described above, the sub-strut 3 penetrating the column steel frame 2
The column base provided with 4 has high integration between the column steel frame 2 and the reinforced concrete portion, and exhibits strong resistance to a large tensile force or bending stress acting on the column base during an earthquake or the like. That is,
A strong column base that does not easily collapse even with a small crack can be obtained. Moreover, the construction can be performed by a simple operation such as inserting a set of sub-strips 34 from both sides into the through hole 31 provided in the column steel frame 2.

In the first embodiment, the base plate 6
And a connecting bar 32 extending above and below the base plate and reinforcing the column base by strengthening the column base structure, and a through hole 31 in the column steel frame 2.
And a steel reinforced concrete column base structure in which sub-bars 34 penetrating through the through-hole 31 are arranged, so that the strength of the column pedestal can be further enhanced by a synergistic effect thereof.

It goes without saying that a steel reinforced concrete column base structure that does not use the two column base structures described above but relies only on one of the column base structures has an earthquake resistance.

<Embodiment 2> Embodiment 2 shows an example in which the present invention is applied to a steel reinforced concrete column base provided with a column-shaped steel frame having a substantially T-shaped cross section shown in FIGS. . Since the second embodiment has substantially the same structure as the first embodiment, the same portions are denoted by the same reference numerals and description thereof will be simplified.

The column steel frame 36 in the second embodiment is composed of two webs 36a orthogonal to each other and a flange 36b formed at an end of each web 36a, and has a substantially T-shaped cross section. It is. The base plate 6 connected to the lower end of the column steel frame 36 has a substantially trapezoidal shape. As in the first embodiment, the connection reinforcing bar through hole 30 (hereinafter, referred to as the base plate 6) is provided at a position surrounded by the flange of the column steel frame 36 in the base plate 6. A plurality of through-holes 30 are provided, and connection reinforcing bars 32 are inserted into the through-holes 30.

Further, as in the first embodiment, a through-hole 31 (hereinafter, referred to as a through-hole 31) for the auxiliary stirrup 34 is formed in the web 36a. Are arranged through. In the second embodiment, the U-shaped sub-stripes 34 and the L-shaped sub-strips 34 are used, and one end of the sub-strips 34 is securely connected to the strips 14 by a binding wire or the like. Is engaged. The above is the non-embedded column base structure shown in the second embodiment, and the same effect as in the first embodiment can be obtained in the column base structure having this configuration.

[0035]

According to the present invention, a steel reinforced concrete column base structure having not only the same workability as the non-embedded column base structure but also an increase in proof stress during an earthquake can be obtained. Can be provided.

In particular, in the case of a column base structure provided with a connecting reinforcing bar penetrating the base plate, the amount of reinforcing bar can be greatly increased without increasing the cross-sectional area of the column base, and the stress concentrated near the base plate can be reduced. It can efficiently transmit to the foundation and increase the tensile strength. Also,
In the column base structure in which the sub-girdle is laid through the column steel, the sub-girder is laid out by penetrating the column, so that the integrity of the column and the reinforced concrete can be increased. As described above, it is possible to provide a steel reinforced concrete column base structure having a high strength against a large tensile force or bending stress acting on the column base during an earthquake or the like.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a first embodiment according to the present invention.

FIG. 2 is a view taken along the line II-II in FIG.

FIG. 3 is an enlarged view of a portion indicated by a symbol A of a circle in FIG. 1;

FIG. 4 is a longitudinal sectional view showing a second embodiment according to the present invention.

FIG. 5 is a view taken along line VV of FIG. 4;

FIG. 6 is a vertical cross-sectional view showing a column structure of a conventional embedded steel reinforced concrete structure.

FIG. 7 is a view taken along line VII-VII of FIG. 6;

FIG. 8 is a plan view showing a horizontal haunch which has been a problem in the embedded type steel frame reinforced concrete column base structure.

FIG. 9 is a longitudinal sectional view showing a conventional non-embedded steel reinforced concrete column base structure.

FIG. 10 is a view taken along line XX of FIG. 9;

[Explanation of symbols]

 2 Column Steel 2a Web 2b Flange 3 Reinforced Concrete 6 Base Plate 8 Foundation Footing 10 Anchor Bolt 12 Column Main Reinforcement 14 Band Reinforcement 16 Underground Beam Main Reinforcement 18 Underground Beam Shear Reinforcement 20 Underground Beam 20a Underground Beam Top End 30 Connection Rebar Penetration Hole 31 Sub-band muscle penetration hole 32 Connection bar 34 Sub-band bar 35 Bend 36 Column steel 36a Web 36b Flange

Claims (5)

[Claims] 1. An underground beam, a base plate disposed at substantially the same height as the top end of the underground beam, a column steel frame erected on the upper surface of the base plate, and erected around the column steel frame. A steel reinforced concrete column base structure in which a plurality of pillar reinforcements, a stirrup surrounding the plurality of pillar reinforcements, and a sub-strut engaging with the reinforcements are buried in concrete, wherein the base plate In, through the base plate,
A steel reinforced concrete column base structure comprising a connecting bar for transmitting a stress acting above the base plate below the base plate. 2. The base plate has a plurality of through-holes formed therein, the through-holes being larger in diameter than the through-holes.
The steel column reinforced concrete column base structure according to claim 1, wherein the connection reinforcing bars are arranged through the connection reinforcing bar through holes. 3. The pillar-shaped steel frame according to claim 1, wherein a plurality of through-holes are provided in the column steel frame, and the at least one of the through-holes is inserted from both sides of the through-hole. Column base structure made of steel reinforced concrete. 4. The steel reinforced concrete structure according to claim 3, wherein the amount of insertion of the minor stirrup into the through hole of the minor stirrup is 5 to 10 times the diameter of the minor stirrup. Column base structure. 5. A plurality of the sub-ligament through holes are formed in the web of the columnar steel frame, and the plurality of sub-ligaments are inserted into the sub-ligament through holes. Or the column base structure of steel reinforced concrete structure according to 4.