KR101174675B1 - Combination structure of precast concrete beam and precast concrete column - Google Patents

Abstract

PURPOSE: A coupling structure of a precast concrete beam and a precast concrete column is provided to improve the strength of a precast concrete beam by forming a housing groove in the end of the precast concrete beam. CONSTITUTION: A coupling structure of a precast concrete beam and a precast concrete column is composed as follows. The end of a precast concrete beam(20) is located at an installation groove formed in a precast concrete column(10). Fixing members(32) are inserted into through holes(26) of the precast concrete beam and holes(17) of the precast concrete column to stably fix the precast concrete beam. Upper main bars(34) are installed through an upper bar arrangement hole(13). Lower main bars(36) are installed through a lower bar arrangement hole and can be curved along the inclined surface of the precast concrete beam. Concrete is placed in the installation groove of the precast concrete column and a housing groove of the precast concrete beam.

Description

Combination Structure of Precast Concrete Beam and Precast Concrete Column {COMBINATION STRUCTURE OF PRECAST CONCRETE BEAM AND PRECAST CONCRETE COLUMN}

The present invention relates to a precast concrete method, more specifically, it is possible to proceed with the skeleton and slab work at different layers at the same time, the precast concrete beam and precast concrete pillars and to ensure the integrity of the column and beam and It relates to a coupling structure of these.

The precast concrete method is a method of constructing a building by producing pillars, beams, slabs, etc., which are the main components of the building, in the form of unit units in the factory in advance, and bringing them to the site and simply assembling and placing them.

This precast concrete method can minimize the field work can improve the construction efficiency, greatly shorten the construction period and has the advantage of ensuring a certain quality. Therefore, in recent years, the buildings that are constructed by the precast concrete construction method is increasing rapidly, especially when framing the underground parking lot among buildings.

In general, there are two methods of joining pillars and beams when framing construction of underground parking lots are the joint main exposure method and the hunch method.

Among these, the joint part exposure method is a method of strengthening the integrity of the joint part by exposing a part of the column root of the column and joining the beam to the exposed part. The joint root exposure method is excellent in continuity by integrating the joint between the pillar and the beam, but the safety is lowered due to the exposed part during the assembly of the pillar, and the construction of the different layers cannot be performed at the same time.

The haunch method is a method of forming a haunch on a pillar and joining the beam to the haunch to improve safety and workability. This haunting method has the advantage of being able to construct different layers at the same time by supporting the beam using the haunting, but there is a disadvantage that the column and the beam are disconnected from each other, so that a crack occurs at the joint of the column and the beam when an external force is applied.

In this way, it is possible to simultaneously perform frame work and slab work on different floors, and a technology for the construction method of a building using a precast concrete column that can secure the integrity of a column and a beam has been filed and registered. Patent 10-0937745)

4 to 6 is a view showing a conventional precast concrete method.

The method comprises a precast concrete column 100, a precast concrete beam 200.

Precast concrete pillar 100 is formed in the same shape as a conventional reinforced concrete pillar, the installation groove 110 is formed in the portion where the precast concrete beam 200 is installed, the reinforcement hole in the installation groove 110 120 and 130 are formed.

The installation groove 110 formed in the precast concrete pillar 100 is a portion into which one end of the precast concrete beam 200 is inserted and seated. The installation groove 110 is formed to a predetermined depth along the circumference of the precast concrete pillar 100, that is, within the range that the reinforcing bar of the precast concrete pillar 100 is not exposed of the precast concrete beam 200 It is formed to a depth at which the end can be seated.

A support angle 150 is provided below the installation groove 110 of the precast concrete pillar 100. The support angle 150 is a member for supporting the partial precast concrete beam 200 until the concrete is completely cured to prevent the dropping. The support angle 150 is a temporary member to be removed when the concrete is completely cured, and can be selectively applied according to the needs of the user, but is almost used in the field is causing the cost increase.

The precast concrete beam 200 is a partial precast concrete beam which is empty inside so that concrete is additionally poured in a state in which the concrete pillar 100 is installed, and a cross section thereof is formed in a U shape. While the conventional partial precast concrete beam 200 is very long in length, the inside is made of a hollow shape as a whole, so that the ability to counter shear forces is not good. Therefore, the crack may occur when an unexpected additional load is applied, and this silicification has a problem of acting as a weak point in the construction process. On the other hand, in order to prevent such a problem in the case of installing a number of separate temporary struts in the lower portion of the precast concrete beam, there is a problem that additional costs occur.

When the installation of the precast concrete beams 200 is completed as described above, the upper and lower main roots 140 in the longitudinal direction of the precast concrete beams 200 through the first and second reinforcement holes 120 and 130 as shown in FIG. ) Through.

In the conventional method, both the back muscles 120 and 130 were formed as round holes in accordance with the shape of each head 140, but there were many difficulties in the process of installing a plurality of very long heads in the upper back muscles.

Finally, as shown in FIG. 6, the concrete 300 is poured into the joints of the precast concrete column 100 and the precast concrete beam 200, and the inside and the upper portion of the precast concrete beam 200, and the concrete When the curing is removed, the support angle 150 is removed.

In addition, technical efforts to solve various problems generated in the process of using the conventional technology continue.

Patent Registration 10-0937745

The present invention is to solve the above problems of the prior art, it is possible to proceed with the frame work and the slab work at different layers at the same time and to solve the various problems occurring in the construction process while ensuring the integrity of the column and beam Its purpose is to provide a precast concrete beam and a precast concrete column and its coupling structure.

Precast concrete beam according to the present invention for achieving the above object, the end is coupled in the horizontal direction to the precast concrete pillars made in the vertical direction elongated, the precast is provided with a plurality of reinforcement in the horizontal longitudinal direction therein In the concrete beam, the precast concrete beam is filled in the interior, the receiving groove into which the concrete to be cast in the field is injected into the coupling end is formed on the upper surface, the receiving groove is inclined surface deeper toward the end of the precast concrete beam It includes, characterized in that the side shape of the coupling end is U-shaped.

The present invention can be fixed to the beam and pillar by placing concrete in the receiving groove by forming a receiving groove empty inside only the end of the precast concrete beam, and by placing the lower portion of the receiving groove in the inclined surface concrete in the field This is easy.

It is preferable that a through hole is formed in a portion overlapping with the precast concrete column on the lower surface of the receiving groove, and an injection groove for injecting a fixing agent into the through hole is formed laterally at an upper portion of the through hole.

If the through-hole is formed in the lower part of the precast concrete beam and the hole is formed at the corresponding position of the precast concrete column, the precast concrete beam can be stably fixed by using the fixing member at the initial stage of installation. If the injection groove is formed in the upper side of the through hole in order to inject the fixing agent into the through hole, the fixing agent can be injected when the inlet of the through hole is blocked by the washer or the head of the bolt.

And if the irregularities are formed on the inclined surface of the receiving groove, the contact surface of the concrete and precast concrete beams cast in the field may have a sufficient friction force.

In addition, the precast concrete pillar according to the present invention for achieving the above object, the precast concrete beam pre-fabricated in the horizontal direction is coupled to the side, the quadrangular pillar provided with a plurality of reinforcement in the longitudinal direction perpendicular to the inside In the precast concrete pillar of the shape, the precast concrete pillar includes an installation groove formed inward along the periphery so that the end of the precast concrete beam is located, and penetrates the precast concrete pillar in four plane directions A box-shaped upper reinforcement hole is formed in the upper portion of the installation groove, and the lower reinforcement hole penetrating the precast concrete column in the X-axis direction and the Y-axis direction is characterized in that formed in the lower portion of the installation groove.

In the precast concrete pillar of the present invention, the installation groove in which the end of the precast concrete beam is located is formed inward along the circumference of the pillar, so that the precast concrete beam can be stably installed. In addition, since the upper reinforcement hole is configured in a box shape or an expansion type that penetrates the precast concrete column in four plane directions, it is easy to install a long upper main root.

At this time, the lower back muscles are preferably formed by varying the height of the first lower back muscles penetrating the precast concrete pillar in the X-axis direction and the second lower back muscles penetrating in the Y-axis direction at the lower portion of the installation groove. The lower main root installed in the lower reinforcement hole is bent from the lower part of the precast concrete beam to be inclined, so that the lower main root is not formed in a box shape, but is preferably formed at different installation heights.

The upper main reinforcement is mainly used for reinforcing bars, and the lower main reinforcement can be inclined upward from the lower part of the precast concrete beam end by using a relatively ductile strand.

And the upper surface of the installation groove and the upper surface of the upper reinforcement is preferably inclined downward toward the inside from the outside of the precast concrete pillar. When using this structure, when placing concrete in the field, there is no problem that the internal air is smoothly discharged to form voids therein.

Further, under the installation groove, the thickness is thickened outward along the circumference of the precast concrete column, and a bracket portion for supporting the end of the precast concrete beam positioned in the installation groove is formed, and is formed downward on the upper surface of the bracket portion. It is preferable to include a hole. The bracket portion extends the lower surface of the installation groove, thereby stably placing the precast concrete beam. The holes correspond to the through-holes formed in the lower surface of the precast concrete beams, thereby making it possible to stably fix the precast concrete beams using a fixing member.

And it is preferable that the outer upper edge of the bracket portion is subjected to an interviewer with the corner cut off. The outer upper edge of the bracket may cause cracks when the precast concrete beam is excessively loaded or when the precast concrete beam is slanted due to sagging. It can be prevented.

Finally, the coupling structure of the precast concrete beam and the precast concrete pillar according to the present invention for achieving the above object is a precast concrete beam provided with a plurality of reinforcement in the horizontal longitudinal direction therein and the longitudinal direction perpendicular to the inside In the coupling structure of the four-column pillar-shaped precast concrete pillar provided with a plurality of reinforcing bars, the precast concrete beam is filled in the receiving groove is formed on the upper surface is filled with the concrete is poured into the coupling end is formed on the upper surface The receiving groove is deeper toward the end of the precast concrete beam, the side shape of the coupling end is U-shaped, the precast concrete column is inward along the circumference so that the end of the precast concrete beam is located Including a groove formed in the precast concrete A box-shaped upper reinforcement hole penetrating the column in four plane directions is formed in the upper portion of the installation groove, and the first lower reinforcement hole penetrating the precast concrete column in the X-axis direction and the second lower reinforcement penetrating in the Y-axis direction. A ball is formed at a lower portion of the installation groove with a different height, and with the coupling end of the precast concrete beam positioned in the installation groove of the precast concrete column, an upper main root is installed through the upper reinforcement hole, and the lower The main root is installed through the lower reinforcement hole, the upper main root is installed a straight line, the lower main root is installed to be bent toward the upper direction along the lower surface of the receiving groove, the installation groove and the receiving groove The concrete is characterized in that the cast in the field.

In the coupling structure of the present invention, the lower main root is bent upward along the inclined surface of the precast concrete beam, and thus, it is possible to sufficiently serve as a reinforcement installed to prevent the continuous collapse of the precast concrete structure. Vulnerabilities that may appear at the ends of cast concrete beams can also be compensated.

Preferably, a strand is used as the lower main root, and the strand is relatively ductile so that the strand may be inclined upward from the bottom of the precast concrete beam end.

At this time, a through hole is formed in the lower surface of the receiving groove of the precast concrete beam, and under the installation groove of the precast concrete beam, the thickness of the precast concrete beam located in the installation groove is thickened to the outside along the circumference of the precast concrete column. It is preferable that the bracket portion is formed to support the end, and a hole corresponding to the through hole is formed on the upper surface of the bracket portion, and further includes a fixing member fitted into the hole through the through hole. Through this structure, the precast concrete beam can be fixed stably in the initial stage of installation.

The present invention configured as described above not only solves the problem of segmentation due to load by forming an accommodating groove having an empty inside at the end of the precast concrete beam to improve the strength of the precast concrete beam, By forming the inclined surface there is an effect of facilitating concrete pouring in the field.

If through holes are formed in the lower part of the precast concrete beams and holes are formed at the corresponding positions of the precast concrete columns, there is an effect of stably fixing the precast concrete beams using a fixing member at the initial stage of installation.

 Forming irregularities on the inclined surface of the receiving groove, there is an effect that can prevent the problem of slipping the contact surface of the concrete and precast concrete beam to be cast in the field.

In addition, the precast concrete pillar of the present invention has an effect that it becomes easy to install a long upper main root by forming a box shape in which the upper reinforcement hole penetrates the precast concrete pillar in four plane directions.

When the upper surface of the installation groove and the upper side of the upper reinforcement hole are inclined downward from the outside of the precast concrete column to the inside, when the concrete is placed in the field, the internal air is discharged smoothly. There is an effect that can prevent the problem of forming voids.

The bracket part extends the lower surface of the installation groove to stably mount the precast concrete beam, and the hole corresponds to the through hole formed on the lower surface of the precast concrete beam, and can effectively fix the precast concrete beam by using a fixing member. There is.

In addition, the outer upper edge of the bracket portion by performing an interviewer cut off the corner, there is an effect to prevent the occurrence of cracks or cracks in the corner.

In addition, the coupling structure of the precast concrete beam and the precast concrete column of the present invention is installed by bending the upper end along the inclined surface of the precast concrete beam using a relatively high ductile strand, thereby continuing the precast concrete structure Not only can the role of the installed reinforcement to prevent collapse, but also to compensate for the vulnerability that may appear at the end of the precast concrete beam.

1 is a perspective view and a front sectional view showing the shape of the precast concrete beam according to the present embodiment.
2 is a cross-sectional view showing the shape of the precast concrete pillar according to the present embodiment.
3 is a schematic diagram showing a coupling structure of a precast concrete column and a precast concrete beam according to the present embodiment.
4 to 6 is a view showing a conventional precast concrete method.

With reference to the accompanying drawings will be described embodiments of the present invention;

1 is a perspective view and a front sectional view showing the shape of the precast concrete beam according to the present embodiment, Figure 2 is a cross-sectional view showing the shape of the precast concrete pillar according to the present embodiment.

This embodiment comprises a precast concrete column 10 and a precast concrete beam 20.

The precast concrete beam of this embodiment is described with reference to FIG. 1 as follows.

The precast concrete beam 20 is a member of a horizontal structure that is coupled to the precast concrete column 10 in a horizontal direction to support the load, and is prefabricated with a plurality of reinforcing bars in the horizontal longitudinal direction.

The precast concrete beam 20 has an end thereof joined to a column, and the joining end has a U-shape as in the conventional precast concrete beam. However, unlike the prior art does not have a U-shaped cross section in the entire precast concrete beam 20, the receiving groove 22 for placing concrete in the field only at the end for the coupling of the precast concrete beam 20 It is formed on the upper surface to have a U-shaped side 21.

Since the precast concrete beam 20 of the present embodiment has a U-shaped coupling end, the concrete can be poured after connecting the lower main bar, such as reinforcing bars or strands, to the precast concrete column 10 at the bottom of the beam. In addition, since the receiving grooves 22 are formed only at the ends of the precast concrete beams 20 and the interior is filled, the ability to withstand their own loads is greatly improved as compared to the precast concrete beams that were previously empty. There is no need to install a temporary column in the lower part.

And the lower surface of the receiving groove 22 is made up of the inclined surface 24 is deeper toward the end of the precast concrete beam 20. This structure has the advantage of minimizing the empty space by the receiving groove 22 to prevent damage by the load in the installation process, as well as to compactly fill the concrete in the concrete pouring process in the field.

Furthermore, by forming irregularities on the inclined surface 24 of the receiving groove 22, to increase the friction force between the contact surface of the concrete and the precast concrete beam 20 cast in the field so as not to slip each other. The irregularities of the inclined surface 24 may be formed as a protrusion in addition to the method of forming a plurality of grooves 25 in the width direction as shown, in addition to any form that can increase the frictional force of the inclined surface in the precast process I can make it.

In addition, the through hole 26 is formed in the lower surface of the receiving groove 22 of the precast concrete beam 20 overlapping with the precast concrete pillar 10 during the installation process. A hole corresponding to the through hole 26 is formed in the precast concrete column 10, and the hole is formed using a bolt or reinforcing bar that penetrates the through hole 26 and is inserted into the hole formed in the precast concrete column 10. The cast concrete column 10 and the precast concrete beam 20 can be stably combined.

On the other hand, although the bolt or reinforcing bar is inserted into the through hole 26 and fixed by injecting a fixing agent such as mortar, the inlet of the through hole 26 is blocked by a bolt head or washer, so that the fixing agent is hardly injected. Therefore, the injection groove 27 is formed laterally in the upper portion of the through hole 26 so that the fixing agent can be injected into the through hole 26 even if a bolt head or washer is blocking the inlet of the through hole 26. do.

Hook portion 29 in the drawing is a reinforcing bar protruded on the upper surface of the precast concrete beam 20, the end is bent, the portion that can be added in the field. And the rebar provided in the interior of the precast concrete beam 20 is not shown in the cross-sectional view.

Referring to the precast concrete pillar of the present embodiment through 2 as follows.

The precast concrete column 10 is formed in the same shape as a conventional reinforced concrete column, and is a member of a vertical structure in which the precast concrete beam 20 is coupled in a horizontal direction. Equipped with ready-made.

The concrete pillar 10 of the present embodiment is formed with a mounting groove 11 is thinner along the circumference at the position where the precast concrete beam 20 is coupled. Since the installation groove 11 can put the end of the precast concrete beam 20 on its lower surface, the installation process can be made stable.

In the installation groove 11 of the precast concrete pillar 10, the lower back muscle hole 12 is formed at the lower side and the upper back muscle hole 13 is formed at the bottom so that it can be installed to penetrate the upper and lower main roots at the site. do.

Since the upper main bar uses reinforcing bars or strands that are close to or longer than the length of the precast concrete beam 20, the installation of the upper main bar was very difficult in the case where the upper main bar is installed in a reinforcement hole formed of a small hole embedded with a pipe. . As shown, since the upper reinforcement hole 13 formed in the precast concrete pillar 10 of the present embodiment is configured to expand in a box-shaped all penetrating in all four directions, the upper reinforcement consisting of a long reinforcement or strand Can be installed without difficulty.

On the other hand, since the lower main root used in the present embodiment is not long, the lower back muscle hole 12 may be formed as a small hole in which a pipe or the like is embedded. At this time, by forming the first lower back muscle hole penetrating the pillar in the X-axis direction and the second lower back muscle hole penetrating in the Y-axis direction with different heights to prevent interference between the lower main roots in the installation process.

And the upper surface (13a) of the upper reinforcement hole 13 is formed in a shape inclined downward toward the inside from the outside of the precast concrete pillar (10). The installation groove 11 and the upper reinforcement hole 13 are the parts where concrete is finally poured in the field, and when the upper reinforcement hole 13 is manufactured in a structure that is lowered toward the inner side, air remains inside the pouring part. The problem that voids are formed can be prevented.

In addition, the precast concrete pillar 10 of the present embodiment is formed with a bracket portion 16 is thickened outward along the circumference of the pillar under the installation groove (11). The bracket portion 16 has a lower surface of the installation groove 11 is extended, so that the end of the precast concrete beam 20 can be placed stably.

In particular, by forming a hole 17 corresponding to the through hole 26 of the precast concrete beam 20 on the upper surface of the bracket portion 16, the precast concrete beam using a fixing member such as a bolt or rebar (20) can be fixed stably.

In addition, the outer upper corner of the bracket portion 16 is subjected to the interviewer 18 with the corner cut off. When the load of the precast concrete beam 20 positioned on the bracket portion 16 is excessively installed or is inclined due to the precast concrete beam 20 sagging, cracks or cracks may occur at the corners, but Interviewer 18 treatment can prevent problems.

In the drawings, the rebar provided in the interior of the precast concrete column 10 is not shown in the cross-sectional view.

3 is a schematic diagram showing a coupling structure of a precast concrete column and a precast concrete beam according to the present embodiment.

The coupling structure of the precast concrete column 10 and the precast concrete beam 20 of the present embodiment, the end of the precast concrete beam 20 is located in the installation groove 11 formed in the precast concrete column 10 Let's do it.

At this time, the through-hole 26 formed in the precast concrete beam 20 and the hole 17 formed in the precast concrete column 10 to correspond to the position is positioned.

By inserting the fixing member 32, such as a bolt or rebar, through the through hole 26 and into the hole 17, the precast concrete beam 20 can be stably positioned at the beginning of installation.

In order to increase the stability, a fixing agent 33, such as mortar, is injected between the fixing member 32 and the through hole 26, and the head of the washer or bolt installed with the fixing member 32 is formed in the through hole 26. Even if the inlet is blocked, the fixing agent 33 can be injected into the through hole 26 and the hole 17 through the injection groove 27 formed on the side.

When the end of the precast concrete beam 20 is stably positioned in the installation groove 11, the upper main 34 and the lower main 36 are installed. The main bar is mainly used for reinforcing bars and / or strands excellent in tensile strength, the strand is made of twisted steel wire of several strands is very excellent tensile strength.

  The upper main 34 is installed to extend to both sides of the precast concrete pillar 10 through the upper reinforcement hole 13, it is installed to maintain a straight line. Therefore, the upper reinforcing bar 34 mainly uses a high reinforcing bar.

The lower main rod 36 is installed to extend to both sides of the precast concrete column 10 through the lower reinforcement hole 12, and is bent and installed in an upward direction along an inclined surface of the precast concrete beam 20. . Therefore, it is easy to bend at the end of the precast concrete beam 20 to be inclined from the bottom to the upper side only by using a relatively ductile steel wire having a relatively soft ductility.

In the case where the lower main rod 36 is bent upward from the bottom of the beam, not only can it serve as a reinforcement installed to prevent continuous collapse of the precast concrete structure, but also the end of the precast concrete beam 20 Vulnerabilities that can appear in the system are also effective to compensate.

Meanwhile, although the precast concrete beams are shown coupled to both sides in the X-axis direction in the drawings, in practice, the precast concrete beams are also coupled in the Y-axis direction, and the installation positions of the upper and lower main roots installed in each of them are problematic.

Since the upper main head 34 is installed while maintaining a straight line, it is possible to align the installation height even in the box-shaped upper back muscle 13 where space is not determined separately, and the upper main head in the X-axis direction and the upper main root in the Y-axis direction You can change the position of.

On the other hand, since the lower main 36 is installed to be bent upward along the inclined surface 24 of the precast concrete beam 20, when installed in the box-shaped reinforcement hole, the lower main root in the X-axis direction and the lower in the Y-axis direction It is very likely that the installation location will overlap between the main bars. Since the lower reinforcement hole of the precast concrete pillar 10 of the present embodiment has a different height formed with the first lower reinforcement hole in the X-axis direction and the lower reinforcement hole in the Y-axis direction, it is possible to prevent the installation positions from overlapping between the lower main roots. have.

While the present invention has been described through the preferred embodiments, the above-described embodiments are merely illustrative of the technical idea of the present invention, and various changes may be made without departing from the technical idea of the present invention. Those of ordinary skill will understand. Therefore, the protection scope of the present invention should be interpreted not by the specific embodiments, but by the matters described in the claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

10,100: precast concrete columns
11: mounting groove 12.120: lower back muscle
13, 130: upper back muscle 16: bracket portion
17: Hall 18: Interviewer
20,200: precast concrete beam
22: receiving groove 24: slope
25: groove 26: through hole
27: injection groove 32: holding member
34: upper major 36: lower major
140: upper and lower main root 150: support angle

Claims (12)

In the combined structure of a precast concrete beam having a plurality of reinforcing bar in the horizontal longitudinal direction and a four-column columnar precast concrete column having a plurality of reinforcing bars in the longitudinal direction perpendicular to the inside,
The precast concrete beam is filled in the interior of the receiving groove is formed in the upper surface is injected into the coupling end is poured into the coupling end, the receiving groove includes an inclined surface deeper toward the end of the precast concrete beam, the coupling The side shape of the end is U-shaped,
The precast concrete pillar includes an installation groove formed inwardly along the circumference thereof so that the end of the precast concrete beam is located, and the box-shaped upper reinforcement hole penetrating the precast concrete pillar in four plane directions of the installation groove. It is formed in the upper, the first lower back muscle hole penetrating the precast concrete pillar in the X-axis direction and the second lower back muscle hole penetrating in the Y-axis direction are formed by varying the height of the lower portion of the installation groove,
Through-holes are formed in the lower surface of the receiving groove is formed in the portion where the concrete beam overlaps with the precast column, and an injection groove for injection of a fixing agent into the through-hole formed sideways from the upper portion of the through-hole A combination structure of a precast concrete beam and a precast concrete column. The method according to claim 1,
Combined structure of precast concrete beams and precast concrete pillars, characterized in that irregularities are formed on the inclined surface of the receiving groove. The method according to claim 1,
Combined structure of precast concrete beams and precast concrete pillars characterized in that the upper surface of the upper reinforcement hole inclined downward toward the inside from the outside of the precast concrete pillars. The method according to claim 1,
In the state where the coupling end of the precast concrete beam is located in the installation groove of the precast concrete pillar, the upper main root is installed through the upper reinforcement hole, the lower main root is installed through the lower reinforcement hole, the upper The main root is installed in a straight line, the lower main root is bent so that the end is directed upward along the inclined surface of the receiving groove,
Combined structure of precast concrete beams and precast concrete pillars, characterized in that the installation grooves and the receiving grooves concrete is poured in the field. The method of claim 4,
Combined structure of precast concrete beam and precast concrete pillar, characterized in that the lower main line is a strand. The method according to claim 1,
Under the installation groove of the precast concrete pillar is thickened outward along the circumference of the precast concrete pillar, a bracket portion for supporting the end of the precast concrete beam positioned in the installation groove is formed, the bracket portion Holes corresponding to the through-holes are formed on the upper surface,
The coupling structure of the precast concrete beam and the precast concrete pillar further comprises a fixing member fitted to the hole through the through hole. delete delete delete delete delete delete

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