JPH0762731A - Joining method of pillar and beam - Google Patents

Abstract

PURPOSE:To prevent a stress center distance from being shortened at forming a lap joint. CONSTITUTION:Pillar main forcements 11a fixedly provided along the inside of a pillar formwork projecting from a pillar 11 at longest up to the slab face of an upper storey are inserted into belt reinforcements 14b of a previously assembled reinforcement 14 formed into the same sized square sleeve as the pillar main reinforcements 11a of a hollow precast pillar 11, so as to form a lap joint out of the pillar main reinforcements 11a and vertical reinforcements 14a. Concrete is placed in a panel zone, semi-precast concrete beams 12, 13, and the pillar 11, and the hollow precast pillar 18 of the upper storey is built in the upper half of the previously assembled reinforcement 14 so as to form a lap joint. In this way, the pillar main reinforcements 11a of the pillar 11 and the vertical reinforcements 14a of the previously assembled reinforcement 14 are arranged on the side of the same square sleeve, and hence the stress center distance is prevented from being shortened at forming a lap joint.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for joining columns and beams made of reinforced concrete.

[0002]

2. Description of the Related Art Conventionally, for a concrete structure, a construction method for pouring concrete to construct the entire structure on site is adopted. However, this construction method has the drawback that the work of assembling the formwork and the reinforcing bar is complicated and that the construction accuracy tends to vary depending on the skill of the operator. Therefore,
In the case of high-rise buildings, etc., where repetitive work is frequent, the structural members such as columns, beams, and slabs are divided and manufactured at other places such as factories, and the manufactured structural members are joined and assembled on site. The precast method is adopted.

According to the above precast method, each structural member is manufactured in advance in a factory or the like, so that there is an advantage that the reliability of quality is high. However, when the weight of each structural member is large, it is necessary to use a high-capacity hoist at the time of delivery to the site or assembly work. Therefore, it is necessary to consider the size of each structural member so as to reduce the weight.

By the way, when the beam and the precast pillars on the upper and lower floors are joined in the above precast method, a sleeve is buried in the bottom of the precast pillar, and the main pillar of the precast pillar on the lower floor is inserted into this sleeve. It is common to join them. At that time, if the entire pillar is made of precast concrete, the weight becomes large, and a large capacity heavy machine is required. In order to avoid this, a method of precasting only the part that hits the outer shell of the column to form a hollow precast column formwork (hereinafter simply referred to as hollow precast column), and after assembling on site, pouring the remaining concrete is taken. To be

At this time, the precast columns on the upper and lower floors are joined by the following two lap joints.

(1) A hollow precast column is built in which main pillar bars and stirrups are built in, and the main pillar bars are projected from the stigma beyond the slab surface of the upper floor. Then, the end of the precast beam is mounted on this hollow precast column, and the column-beam joint is mounted.
A beam bottom main bar, a column main bar and a beam top main bar are laid in (hereinafter referred to as a panel zone), and concrete is placed to join the column and the beam together. Next, the hollow precast pillars on the upper floor are inserted into the pillar main bars protruding above the slab surface to form a lap joint.

(2) As shown in FIG. 8, a precast beam B is mounted on a hollow precast column A containing the column main bars 1a and the stirrups 2a. Then, the pre-assembled rebar C for joining the upper and lower columns is composed of a vertical bar 1c having a length penetrating the panel zone in the height direction and a band bar 2c wound around the middle part thereof.
The vertical bar 1c is inserted into the hollow portion of the hollow precast column A so that the band bar 2c is located in the panel zone, and the bar is laid, and concrete is poured. Thus
After the pillars and beams are integrally joined, a hollow precast pillar (not shown) on the upper floor is inserted into the pre-assembled reinforcing bar C protruding above the slab surface to form a lap joint.

[0008]

However, the lap joint in the above-mentioned conventional precast method has the following problems. (B) In the case of the lap joint of the above (1), the column main bar protruding from the hollow precast column on the lower floor is in contact with the hollow precast column on the upper floor. Therefore, it is necessary to bend the column main bar of the hollow precast column on the lower floor inward so that it can be easily inserted into the hollow portion of the hollow precast column on the upper floor. Since the column main reinforcement is bent inward as described above, it is necessary to change the outer diameter of the reinforcement in accordance with the attachment position when attaching the column reinforcement of the panel zone. In addition to the length for forming the lap joint with the hollow precast column on the upper floor, the length of the column main bar protruding from the stigma needs to be increased by the length of the beam. Therefore, the protruding portion of the column main bar of the hollow precast column becomes large, and workability is poor when the hollow precast column is transported or when the precast beam or floor is arranged. In the lap joint part of the column main bar of the hollow precast column of the lower floor and the column main bar of the hollow precast column of the upper floor, the column main bar of the hollow precast column of the lower floor is inside the column main bar of the hollow precast column of the upper floor. Since it is inserted, the stress center distance becomes shorter. Therefore, it is necessary to reinforce (increase the diameter or increase the strength) the lap joints of the hollow precast columns on the lower floor located inside and the column main bars in the panel zone.

(B) In the case of the lap joint of the above (2), one hollow precast pillar A has a vertical bar 1c of the upper pre-assembled rebar C which is inserted from the upper side and a lower end which is inserted from the lower side. A lap joint is formed by the vertical bars of the braided bars (not shown). Therefore, the hollow precast column A requires at least twice the length of the lap joint. The length of this lap joint is 40 when the rebar diameter "d" is 25 mm.
d or more is required, resulting in a floor height of 2 m or more. Hollow precast pillar A that is combined from the design side
The outer surface of the precast beam B and the outer surface of the precast beam B may be flush with each other. At that time, the overburden thickness of the main beam of the precast beam B and the vertical bar 1c of the pre-assembled reinforcing bar C in the panel zone
Since the covering thickness of the sheet becomes thicker, it is necessary to provide a reinforcing bar in order to prevent the risk of peeling. At the position of the lap joint, the longitudinal center line 1c of the pre-assembled rebar C is inserted inside the column main bar of the hollow precast column A, so that the stress center distance becomes short. Therefore, it is necessary to reinforce the column main bars of the hollow precast column A (increase the diameter or increase the strength).

Therefore, an object of the present invention is to shorten the length of the column main bar protruding from the hollow precast column, to reduce the floor height, and to connect the outer surface of the joined hollow precast column and the outer surface of the beam without reinforcing bars. An object of the present invention is to provide a method for joining columns and beams that can be formed on the same surface and the stress center distance does not become short when forming a lap joint.

[0011]

In order to achieve the above object, the method of joining pillars and beams of the invention according to claim 1 is such that the inner wall surface of the pillar formwork projects from the stake to the slab surface of the upper floor at the longest. A hollow precast column with a built-in column main bar and stirrups that is fixed in a tubular shape along the slab is built on the slab, and the end of the semi-precast concrete beam with the bottom main bar and stirrup bar embedded is After being placed on a pillar, the pillar-beam joint is pierced horizontally and the lower end connecting bar is bridged between the semi-precast concrete beams, and the pillar-beam joint has a length that penetrates in the height direction. Inside the above-mentioned strip of the pre-assembled rebar consisting of the vertical reinforcement and the reinforcement that is fixed at the lower side to form a cylinder having the same size as the cylinder formed by the main reinforcement of the hollow precast column The hollow plexi in the joint Insert the column main bar of the cast column to arrange the bar,
Penetrating the column-beam joint along the semi-precast concrete beam, and arranging the upper end main bar inside the upper side of the stirrup bar, inside the hollow precast column, in the semi-precast concrete beam and column-beam joint The feature is that the pillar and the beam are integrated by placing concrete in the part.

The invention according to claim 2 is, in the column-beam joining method of the invention according to claim 1, a cylinder formed by the longitudinal bars of the pre-assembled rebar and a cylinder formed by the column main bars of the hollow precast pillar. Is a square tube, and the longitudinal vertical bars of the corners of the pre-assembled rebar are double-laid so as to sandwich the column main bars of the corners of the precast column formwork.

[0013]

The present invention will be described in detail below with reference to the embodiments shown in the drawings. The pillar / beam joining method in the present embodiment is a pillar / beam joining method for joining the hollow precast pillars on the upper and lower floors and the beam with the pre-assembled reinforcing bars.

FIG. 1 and FIG. 2 show pillars in this embodiment.
It is explanatory drawing of the joint structure of the pillar and the beam formed by the beam joining method. As shown in FIG. 1 and FIG. 2, the column main bars 11a of the hollow precast columns 11 are fixed to the square tube along the inner wall surface of the column form, and project from the column head 11b to the slab surface of the upper floor at the longest. . Further, the two beams 12 and 13 having one end placed on the stigma 11b of the hollow precast column 11 to form a panel zone are semi-precast concrete beams in which a lower end main bar and stirrup bars 12b and 13b are embedded. Is.

The pre-assembled rebar used in this embodiment is
As shown in FIG. 2, the lower half of the vertical streak 14a having a length that penetrates the panel zone in the height direction is fixed by the stirrup 14b to form a rectangular tube. And this vertical stripe 14a
The size of the square cylinder formed by is the same as the size of the square cylinder formed by the column main bar 11a of the hollow precast column. The stirrup 14 of the front braided bar 14 formed in this way
Hollow precast pillar 1 in the above panel zone in b
Insert the column main bar 11a of 1 and the column main bar 11a of the hollow precast column 11 along with the vertical bar 14a of the pre-assembled rebar, and the protrusion of the column main bar 11a and the lower side of the vertical bar 14a of the pre-assembled bar 14 Form a lap joint. On the other hand, the lower half of a hollow precast column (not shown) on the upper floor is covered on the upper half of the front-end rebar 14 projecting upward from the slab surface on the upper floor to form a lap joint. Thus, the two beams are joined to the hollow precast pillars on the upper and lower floors.

A hook 14c is provided at the upper end of the vertical bar 14a in the above-mentioned rebar assembly 14. In this way, workability is improved when inserting the pre-assembled rebar 14 into the upper hollow precast column.

In the column-beam connection structure as described above, as shown in FIG. 3 (a), the protruding portion of the column main bar 11a of the hollow precast column 11 on the lower floor and the lower half of the pre-assembled rebar 14 are connected to each other. Most of the lap joints are formed within the panel zone. Here, the length of the lap joint varies depending on the thickness of the column main bar 11a of the hollow precast column 11 and the like. Therefore, the lap joint of the lower half of the pre-assembled rebar 14 and the column main bar 11a of the hollow precast column 11 may be extended into the hollow precast column without being contained in the panel zone. However, even in that case,
Since most of the lap joint is formed in the panel zone, the length of the portion extending into the hollow precast column 11 is much shorter than the total lap joint length. Therefore, the length of the hollow precast column 11 in this embodiment is at least twice the length of the lap joint minus the height of the panel zone, and is longer than the case where the conventional pre-assembled rebar is used. Can lower the floor height.

3 (b) is a sectional view taken along the line AA in FIG. 3 (a), and FIG. 3 (c) is a sectional view taken along the line BB in FIG. 3 (a). 3 (d) is a sectional view taken along the line CC of FIG. 3 (a), and FIG. 3 (e) is a sectional view taken along the line D-D of FIG. 3 (a).

As described above, in this embodiment, the column main bars 11a of the hollow precast column 11 are fixed in a square tube shape along the inside of the column form, and the hollow precast column 11 is formed.
Of the square cylinder formed by the column main bars 11a of the column and the pre-assembled rebar 14
The size of the rectangular cylinder formed by the vertical stripes 14a is the same. Further, the positional relationship between the column main reinforcement 11a and the vertical reinforcement 14a is such that they are in sliding contact with each other when forming the lap joint, as shown in FIGS. 3 (b) and 3 (e). Therefore, the longitudinal bars 14a of the front-end rebar 14 and the column main bars 11a of the hollow precast columns are arranged so that the rectangular cylinders formed by them are coaxial. As a result, the longitudinal bar 14a and the column main bar 1
1a will be laid on the same surface of a rectangular cylinder, and the stress center distance will not be shortened due to the formation of the lap joint. Therefore, according to the present embodiment, it is not necessary to reinforce the column main bar 11a of the hollow precast column 11.

In addition, since the position of the reinforcing bar 14 of the pre-assembled rebar 14 inserted into the panel zone in this embodiment also serves as the lap joint forming site, the pre-assembled rebar 14 is shortened by that amount and formed lightly. it can. Therefore, when the hollow precast columns 11 and the beams 12 and 13 are joined, the pre-assembled rebar 14 can be manually transported, and the joining work can be easily performed.

Further, according to the column / beam joint structure of this embodiment, the following effects can be obtained. FIG. 4 is a vertical sectional view in the panel zone. Incidentally, FIG. 4 (a) is a vertical sectional view according to this embodiment, and FIG. 4 (b) is a vertical sectional view in the conventional example.

According to the column / beam joint structure obtained by the conventional column / beam joint construction method shown in FIG. 4 (b), the panel zone 3
Reinforcing bars inserted in 1 are the longitudinal bars 34a of the pre-assembled reinforcing bars 34.
Only. Then, the pre-assembled rebar 34 is inserted into the hollow portion of the hollow precast column 32, and the upper end main bar 35a and the lower end connecting bar 35b located at the outermost part of the beam 35 are the pre-assembled rebar 34.
It is located inward of the vertical streaks 34a. for that reason,
The upper end main bar 35a, the lower end connecting bar 35b, and the vertical bar 34a of the front reinforcing bar 34 are located at positions far away from the concrete outer surface 31a of the panel zone 31. Therefore, the overlying thickness d _{1 of} the uppermost main bar 35a, the lower end connecting bar 35b and the overlying thickness d ₂ of the vertical bar 34a of the pre-assembled reinforcing bar 34 are large, and when the value exceeds 100 mm, the peeling-off occurs. Due to the danger, it is necessary to insert the reinforcing bar 36.

On the other hand, in FIG. 4 (a), the column main bar 22b of the lower hollow precast column 22 projects into the panel zone 21, and the vertical bar 24a of the front bracing bar 24 is the column main bar 22b. They are arranged in the same row. Therefore, the column main bar 22b and the vertical bar 24a are located outside the position of the vertical bar 34a in the conventional example shown in FIG. 4 (b). As a result, of the upper end main bar 25a and the lower end connecting bar 25b that are bridged over the beam 25, the uppermost main bar 2 located at the outermost position
5a and the lower end connecting line 25b can be located outwardly of the case of FIG. 4 (b). Therefore, the outer surface of the beam 25 and the outer surfaces 22a, 23a of the hollow precast columns 22, 23 are formed.
When the and are in the same plane, the covering thickness "d ₁ " of the uppermost main reinforcement 25a and the lowermost connection reinforcement 25b located at the outermost part of the beam 25
Can be made smaller. Similarly, concrete is poured into the panel zone 21 so that the concrete outer surface 21a of the panel zone 21 and the outer surfaces 22a, 2 of the hollow precast columns 22, 23 are formed.
When making 3a and the same plane, the covering thickness "d ₂ " of the outermost reinforcing bar (that is, the column main bar 22b) in the panel zone 21 also becomes small, and the hollow precast columns 22, 2
It has the same normal value as 3. That is, according to the present embodiment, it is not necessary to insert the reinforcing bar.

The pillar / beam joint structure according to this embodiment as described above can be realized by the following pillar / beam joint construction method. Hereinafter, the method of joining columns and beams in this embodiment will be described in detail with reference to FIG.

As shown in FIG. 5 (a), from the stigma to the main bar 11
Hollow precast columns 11 and 11 'with protruding a and 11a' are built. Next, as shown in FIG. 5 (b), a semi-precast concrete beam 13 is installed between the hollow precast columns 11 and 11 '.

Next, as shown in FIG. 5 (c), the lower end connecting bars 15 and 15 'are arranged between the semi-precast concrete beams 13 through the panel zone. Next, as shown in FIG. 5 (d), the stirrup bars 14b, 14 of the front braided bars 14, 14 'are
hollow precast pillars 11 in the panel zone in b ',
The lower side of the pre-assembled reinforcing bar 14 is inserted into the panel zone so that the column main bars 11a and 11a 'of 11' are inserted. At that time, the lowermost stirrups 14b and 14b ′ are connected to the lower end connecting streaks 15 and 1.
By abutting against 5 ', as shown in FIG. 5 (e), the front-end rebars 14 and 14' do not fall and are positioned with the upper half protruding upward from the panel zone. Next, as shown in Fig. 5 (e), the panel zones are penetrated along the semi-precast concrete beams 13, 13 ', ..., and the stirrup bars 13b, 13 of the semi-precast concrete beams 13, 13' ,.
The upper end main bar 16 is arranged inside the upper side of b '....

Next, as shown in FIG. 5 (f), concrete 17 is placed in the space of the hollow precast columns 11, 11 ', the space of the semi-precast concrete beam 13 and the panel zone to slab the upper floor. To form. Next, FIG.
As shown in (g), the hollow precast pillars 18 and 18 'of the upper floor are built in the pre-assembled rebars 14 and 14' whose upper half projects upward from the slab surface. In this way, the hollow precast columns 11 and 18 on the upper and lower floors are joined to the semi-precast concrete beams 13.

As described above, in this embodiment, the hollow precast column 11 having the column main bars 11a protruding from the column head 11b to the slab surface of the upper floor at the longest is built on the slab. And this hollow precast pillar 11,11, ...
The semi-precast concrete beams 12 and 13 are installed between them, and the column main bar 11a of the hollow precast column 11 projecting into the formed panel zone is inserted into the band bar 14b wound around the lower half of the pre-assembled rebar 14. As described above, the column main bar 11a of the hollow precast column 11 and the vertical bar 14a of the front bracing bar 14 form a lap joint. Furthermore, a hollow precast column of the upper floor is built in the upper half of the above-mentioned pre-assembled rebar 14 to form a lap joint.

As described above, the hollow precast pillar 11 is used.
Most of the lap joint of the upper pre-assembled rebar 14 is formed in the panel zone, and the lap joint of the hollow precast column 11 and the lower pre-assembled rebar 14 is formed in the hollow precast column 11. Therefore, the length of the hollow precast column 11 may be at least twice the length of the lap joint minus the height of the panel zone. Therefore, according to the present embodiment, the floor height can be made lower than that of the conventional column-beam joining construction method in which the length of the hollow precast column is required to be at least twice the length of the lap joint.

At this time, the stirrup bar 14b of the pre-assembled rebar 14 inserted into the panel zone also serves as a lap joint forming part with the column main bar 11a of the hollow precast column 11, so that the pre-assembled rebar is formed. 14 can be shortened by that amount and lightly formed.

Further, the column main bars 11a of the hollow precast columns 11 are fixed along the inner wall surface of the column form, and the rectangular cylinders formed by the column main bars 11a of the hollow precast columns 11 and the vertical reinforcing bars 14 are formed. It has the same dimensions as the square tube formed by the line 14a. And since both square cylinders are arranged so as to be coaxial within the panel zone, the longitudinal bars 14a and the column main bars 11a are arranged on the same square tube surface,
The stress center distance is not shortened by the insertion of the front braces 14. Therefore, the column main bar 11 of the hollow precast column 11
There is no need to reinforce a.

Further, since the column main bar 11a of the hollow precast column 11 projects in the panel zone, the outer surfaces of the semi-precast concrete beams 12, 13 and the panel zone and the outer surface of the hollow precast column 11 are separated from each other. When making the same plane, the outermost upper reinforcing bars 16 and the lower end connecting bars 15 placed on the semi-precast concrete beams 12 and 13 and the outermost reinforcing bars in the panel zone (column main bars 11a) The covering thickness of) can be reduced. Therefore, when making the concrete surface of the panel zone flush with the surface of the hollow precast pillar 11,
There is no need to arrange reinforcing bars to prevent falling off.

In addition, the above-mentioned reinforcing bar 14 is composed of a plurality of vertical bars 1.
It is formed by fixing 4a in a tubular shape by means of a band 14b. Therefore, when the pre-assembled rebar 14 is inserted into the panel zone, the lowermost belt bar 14b of the pre-assembled rebar 14 comes into contact with the lower end connecting bar 15 arranged between the semi-precast concrete beams 12 and 13, The position of the front bracing bar 14 in the panel zone is set correctly. Further, the upper end of the vertical bar 14a of the above-mentioned rebar 14 is bent at its tip to form a hook 14c. Therefore, the pre-assembled rebar 14 is easy to insert into the upper hollow precast column.

As described above, since the column main bar 11a of the hollow precast column 11 and the vertical bar 14a of the pre-assembled rebar 14 are arranged on the surface of the same rectangular cylinder, the hollow bar is formed by inserting the pre-assembled rebar 14. The stress center distance of the precast column 11 does not become short. However, when the reinforcement of the vertical reinforcement 14a of the pre-assembled rebar 14 is examined more strictly, the following improvements are hidden. FIG. 6 is an example of a cross-sectional view taken along the line DD in FIG. 6 (a) and 6 (b),
The vertical bar 14a ′ located at the corner of the square tube formed by the vertical bar 14a of the front-end rebar 14 is one side of the column main bar 11a ′ located at the corner of the rectangular tube formed by the column main bar 11a of the hollow precast column 11. I can only accompany you. Therefore, the balance of the stress generated in the hollow precast column 11 is unbalanced with respect to the X axis and the Y axis of the hollow precast column 11.

Next, an embodiment for eliminating the imbalance of the stress balance occurring in the hollow precast column 11 will be described. In the vertical bar 41a of the pre-assembled rebar 41 in the present embodiment, as shown in FIG. 7, the vertical bar 41a "is added to the corner of the square tube formed by the vertical bar 14a, and the column of the corner of the square tube is added. The longitudinal bars are doubly arranged so that the main bars 11a 'can be sandwiched.Therefore, the pre-assembled rebar 41 shown in Fig. 7 (a) is inserted into the hollow precast column 11 shown in Fig. 7 (b). When
As shown in FIG. 7 (c), the column main bar 11a 'at the corner of the hollow precast column 11 is sandwiched by two vertical bars 41a', 41a "that are doubly arranged at the corner of the pre-assembled rebar 41. As a result, the rebars on the two adjacent side faces of the rectangular tube formed by the front-end rebar 14 become the same, and as a result, according to the present embodiment, the balance of the stress generated in the hollow precast column 11 is The effect is that the hollow precast columns 11 are even with respect to the X axis and the Y axis.

In each of the above-mentioned embodiments, the stirrup bar 14b of the pre-assembled rebar 14 installed in the panel zone is arranged by arranging a plurality of rectangular stirrup bars 14b at a predetermined interval. It is not something that will be done. For example, one rebar may be spirally wound around the vertical bar 14a of the pre-assembled rebar 14.

[0037]

As is clear from the above, in the method of joining pillars and beams according to the first aspect of the present invention, the pillar main bar which is fixed along the inner wall surface of the pillar form and has a cylindrical shape is used. After building a hollow precast column that projects from the capital to the slab surface of the upper floor at the longest, erection of a semi-precast concrete beam, then the column-beam joint is pierced horizontally and the bottom connecting bar between the semi-precast concrete beams is installed. The column main beam of the hollow precast column existing in the column-beam joint part in the strip bar of the pre-assembled rebar, and the column-beam joint part is penetrated along the semi-precast concrete beam. One hollow precast column because the columns and beams are integrated by placing the upper main bars and placing concrete inside the hollow precast columns, semi-precast concrete beams and column-beam joints. Forms most of the lap joint with the upper pre-assembly rebar in the column-beam joint, while forming the lap joint with the lower pre-assembly rebar in the hollow precast column. Therefore, according to the present invention, the length of the hollow precast column to be used should be at least twice the length of the lap joint minus the height of the panel zone, and the floor height should be lowered. Is possible.

Furthermore, since the protrusion amount of the column main bar of the hollow precast column is up to the slab surface of the upper floor at the longest, the protrusion amount of the column main bar can be made shorter than before. Further, the column main bars of the hollow precast column project into the panel zone. Therefore, when the outer surface of the semi-precast concrete beam and the outer surface of the panel zone concrete outer surface and the outer surface of the hollow precast column are flush with each other, the outermost upper end bar arranged along the semi-precast concrete beam is located, The covering thickness of the lower end connecting bar and the covering thickness of the outermost reinforcing bar in the panel zone become thin,
There is no need to arrange reinforcements.

Further, the column main bar of the hollow precast column is fixed in a cylindrical shape along the inner side of the column form, while the vertical bar of the pre-assembled rebar is a tube formed by the column main bar of the hollow precast column. Since the cylinders having the same dimensions are formed, when the above vertical bars are inserted into the column main bars so that the tubes formed by them are coaxial, the vertical bars are arranged on the same cylinder surface as the column main bars. To be done. Therefore, the stress center distance does not become short when forming the lap joint by inserting the column main bar of the hollow precast column into the band of the above-mentioned pre-assembled rebar, and it is not necessary to reinforce the column main bar of the hollow precast column. .

According to the pillar-beam joining method of the present invention as defined in claim 2, the vertical bars located at the corners of the pre-assembled rebar forming the square cylinder form the corners of the hollow precast pillar forming the square cylinder. Since the reinforcement is doubly arranged so that the main pillars can be sandwiched, the reinforcements on the two adjacent side faces in the rectangular cylinder formed by the vertical reinforcement of the above-mentioned pre-assembled reinforcement can be the same. Therefore, the stress distribution generated in the hollow precast columns can be kept in balance with respect to the center line perpendicular to the side surface of the hollow precast columns.

[Brief description of drawings]

FIG. 1 is an explanatory diagram of a pillar / beam joint structure formed by a pillar / beam joint construction method of the present invention.

FIG. 2 is an explanatory view of a pillar / beam joint structure subsequent to FIG.

FIG. 3 is a cross-sectional view of the column-beam joint structure shown in FIGS. 1 and 2.

FIG. 4 is an enlarged sectional view of a panel zone in a column / beam joint structure different from that of FIG. 3;

FIG. 5 is a diagram showing a method of joining columns and beams according to the present invention.

6 is an example of a cross-sectional view taken along the line DD in FIG. 3 (a).

FIG. 7 is a view showing an example different from that of FIG. 6 of a reinforcing bar structure of a pre-assembled rebar and a view showing a relationship with a column main bar of a hollow precast column.

FIG. 8 is an explanatory diagram of a conventional pillar-beam joint structure.

[Explanation of symbols]

11,22,23 ... Hollow precast columns, 11a, 22b ...
Column main bars, 12, 13, 25 ... Semi-precast concrete beams, 14, 24, 41 ... Pre-assembled reinforcing bars, 14a, 24
a, 41a ... vertical stripes, 14b, 24b, 41b ... stirrups,
14c ... hook, 15,25b ... lower end connecting bar,
16,25a ... Main bar at the top.

Claims (2)

[Claims] 1. A hollow precast pillar formwork having column main bars and stirrups that are fixed in a tubular shape along the inner wall surface of the pillar form projecting from the stigma to the slab surface of the upper floor at the longest and on the slab. After placing the end of the semi-precast concrete beam with the bottom main reinforcement and the stirrup embedded in it on the hollow precast column formwork, the column-beam joint is pierced in the horizontal direction and the semi-precast The lower end connecting bar is bridged between the concrete beams, and the vertical bar having a length that penetrates the column-beam joint in the height direction and the column bar of the hollow precast column are formed by fixing the vertical bar on the lower side. Inside the above-mentioned bar of the pre-assembled rebar consisting of the bar that forms a tube of the same size as the tube, the column main bar of the hollow precast column formwork that exists in the above-mentioned column-beam joint is arranged and arranged. Semi-precast concrete The pillar-beam joints are penetrated along the girders, and the upper main bars are arranged inside the upper side of the stirrup bar, in the hollow precast column formwork, in the semi-precast concrete beams and in the column-beam joints. A method of joining columns and beams, in which concrete is poured into the concrete to integrate the columns and beams. 2. The column-beam joining method according to claim 1, wherein the cylinder formed by the vertical bars of the pre-assembled rebar and the cylinder formed by the column main bars of the hollow precast pillar formwork are square tubes. A column-beam joining method, wherein the vertical angle bar of the braided bar is double-laid so that the main bar of the corner of the precast column form can be sandwiched.