KR20130040652A - Precast concrete frame and its construction method for buildings using precast concrete slab continued by post tensioning - Google Patents

Abstract

PURPOSE: A precast concrete frame for a building using a precast concrete slab continued in a post tension method and a construction method thereof are provided to improve an internal force by evenly dispersing loads with a prestressing force. CONSTITUTION: A plurality of precast concrete columns(10) is installed, and a precast concrete girder(12) is placed on an upper end of the column. A rib type precast concrete slab(20B) is placed on an upper section of the girder. Reinforcing bars are arranged on an upper surface of the slab, and concrete is placed. The slab forms a lattice groove and comprises a plurality of sheath pipes(24) embedded into a rib. Tendons of the sheath pipes are stressed, and the rib type precast concrete slabs comprise a continuous frame.

Description

Precast concrete frame and its construction method for buildings using precast concrete slab continued by post tensioning}

The present invention relates to a concrete frame for a building and its construction method, and more particularly to a building precast concrete frame using a precast concrete slab having a continuous precast concrete slab using post-tensioning and a construction method thereof.

Concrete is classified into cast-in-place concrete and precast concrete according to the time of pouring. Precast concrete refers to concrete that is poured into molds produced in various forms at the factory. The cast precast concrete member is transported to the site by the transport vehicle after curing and assembled in the final position.

Precast concrete is called PC, and the method of building structures using PC is called PC method. Unlike the site casting method, which installs formwork at the construction site, reinforces steel, and places concrete to complete the building, the PC method is an all-weather facility in which structural members such as columns, beams, slabs, and walls are not affected by weather or season. It is a construction method that is manufactured under strict quality control in a factory equipped with a steel pipe and then transported and assembled to a site to complete a building. Therefore, it is a representative industrialization method that maximizes the use of equipment and machines throughout the entire process from production to assembly.

In Korea, the PC method is markedly developed by the government's 2 million housing construction plan and policy support for prefabricated houses.In the 2000s, the PC method was applied to stadiums, underground parking lots, large discount stores, factories, and warehouses. Is getting wider.

Taking the underground parking lot as an example, the construction process using the PC method shows that the columns, beams, and slabs are manufactured at the factory and then transported to the site. At the site, the anchors are first installed, the columns are assembled, After mounting, installing the slab, reinforcement to the slab and the slab and the slab and the beam, and then reinforce the upper reinforcement to the beam and the bottom plate, and put the overlay concrete is constructed in the step of integrating the column, beam and slab. The pillars are mainly end-mounted to pillars having a rectangular cross-sectional shape and integrated with the pillars by overlay concrete.

The constructed slab transfers the load to the column. However, because the reinforcement must be worked on-site during the construction of the slab, workability is reduced and economics due to the addition of the reinforcement are reduced.

As a background technology of the present invention, the Republic of Korea Patent No. 10-0439685 (2004.06.30) is known as the 'bottom slab reinforcement method using a wire tensioning device.

This method is to install the wire anchorages on both sides of the bottom side of the slab in order to increase the strength of the slab, the wires are tensioned and then fixed to the wire anchorage so that the strength of the slab is generated. That is, the process of fixing the L-shaped bracket in the middle of the two pillars, the process of mounting the bi-directional wire tensioning device using the T-shaped bracket bolted to the L-shaped bracket, and the fixing unit bracket in the position adjacent to both pillars Fixing the bolts, bolting the one or more wire anchorages provided with the load cells to the anchorage brackets, and coupling one end of the two wires to the wire mounting holes provided with the load cells, respectively; And a step of tensioning each of the wires by a hydraulic jack.

However, in the background art, it is possible to generate a load capacity in one unit slab, but it is not a structure capable of continuously stretching two neighboring slabs, and thus it is not possible to distribute the load of the entire slab evenly.

Republic of Korea Patent Publication No. 10-2006-0028828 (2006.04.04) is a slab-integrated prefabricated precast concrete that allows the bridge to be installed without the need to install a separate slab on the top of the girder in the field Girder '. It is a slab-integrated prefabricated concrete girder, in which a plurality are continuously arranged side by side to form a superstructure of a bridge. The slab is a prefabricated precast concrete girder. And a transverse reinforcing part integrally formed across the wall at both ends and the inner central portion of the precast girder, and the upper slab and the transverse reinforcing part are provided with a tension material installation hole in a direction perpendicular to the axial axis. There is provided a slab-integrated prefabricated precast concrete girder, characterized in that the tension member is arranged to introduce the prestress in the axially orthogonal direction to the girders arranged side by side. However, when the technique of Patent Document 1 is to be applied to a precast concrete building, it is difficult to continuously install the beam by the shear connector installed on the beam. Therefore, there is a problem that can not increase the internal strength by introducing a tension force to the continuous slab as a whole.

An object of the present invention is to provide a precast concrete frame for a building using a precast concrete slab having a continuous precast concrete slab using post-tensioning, and a construction method thereof.

One suitable embodiment according to the precast concrete frame for buildings using the precast concrete slab of the present invention,

A plurality of precast concrete columns installed in a vertical direction with a predetermined distance from each other to support the building;

A precast concrete large beam having two adjacent to each other of the precast concrete columns selected and mounted in a right angle on the top;

A lattice groove arranged at a predetermined depth on the bottom side, ribs for partitioning the lattice grooves, and a plurality of sheath pipes embedded in the ribs and exposed at both ends thereof. A plurality of rib-shaped precast concrete slabs mounted on the top surface in two directions in width and width;

The plurality of rib-shaped precast concrete slabs are characterized in that each tension member introduced into the plurality of sheath pipes is fixed by post-tensioning to have a continuous frame structure.

Another suitable embodiment according to the precast concrete framework for buildings using the precast concrete slab of the present invention,

A plurality of precast concrete columns installed in a vertical direction with a predetermined distance from each other to support the building;

A precast concrete large beam having two adjacent to each other of the precast concrete columns selected and mounted in a right angle on the top;

One or more small beams coupled at right angles to a pair of precast concrete large beams facing each other;

The precast concrete large beam includes a lattice groove arranged to have a predetermined depth on the bottom side, a rib for partitioning the lattice groove, and a plurality of sheath pipes embedded in the rib and exposed at both ends thereof. A plurality of rib-shaped precast concrete slabs mounted on the top surface of the precast concrete small beams in two directions in a horizontal direction;

The plurality of rib-shaped precast concrete slabs are characterized in that each tension member introduced into the plurality of sheath pipes is fixed by post-tensioning to have a continuous frame structure.

Another suitable embodiment according to the precast concrete framework for buildings using the precast concrete slab of the present invention,

A plurality of precast concrete columns installed in a vertical direction with a predetermined distance from each other to support the building;

A precast concrete large beam having two adjacent to each other of the precast concrete columns selected and mounted in a right angle on the top;

A lattice groove arranged at a certain depth on the bottom side, a rib for partitioning the lattice groove, and a plurality of sheath pipes embedded in the rib and exposed at both ends thereof upward and perpendicular to the precast concrete large beam. A plurality of ribbed precast concrete slabs mounted in one direction;

The plurality of rib-shaped precast concrete slabs are characterized in that the tension member respectively introduced into the plurality of sheath pipes by the post-tensioning to have a continuous frame structure.

On the other hand, in each embodiment, it is preferable that the overlay concrete is poured on the upper surface of the precast concrete slab, and the tension member fixing groove for fixing the tension member is formed on the side end surface of the overlay concrete where both ends of the sheath pipe are positioned.

The preferred embodiment according to the construction method of the precast concrete frame for buildings using the precast concrete slab of the present invention,

Installing a plurality of precast concrete columns in a vertical direction with a predetermined distance from each other to support the building;

Selecting two adjacent neighbors of the precast concrete columns and placing the precast concrete beams in a right angle on the top;

The precast concrete slab includes a rib-shaped precast concrete slab having a lattice groove arranged at a predetermined depth on the bottom side, and a plurality of sheath pipes which are embedded in ribs for partitioning the lattice groove, and both ends thereof are exposed upward. Placing the horizontally in two directions on the top surface thereof;

Placing reinforcement concrete after finishing reinforcement on the upper surface of the rib-type precast concrete slab;

A plurality of rib-shaped precast concrete slabs are characterized in that the construction is carried out through the step of tensioning each tension material introduced into the plurality of sheath pipes to have a continuous frame.

Another suitable embodiment according to the construction method of the precast concrete frame for buildings using the precast concrete slab of the present invention,

Installing a plurality of precast concrete columns in a vertical direction at predetermined intervals to support the building;

Selecting two adjacent neighbors of the precast concrete columns and placing the precast concrete beams in a right angle on the top;

Installing at least one small beam in a direction perpendicular to the precast concrete large beam facing each other;

The precast concrete slab includes a rib-shaped precast concrete slab having a lattice groove arranged at a predetermined depth on the bottom side, and a plurality of sheath pipes which are embedded in ribs for partitioning the lattice groove, and both ends thereof are exposed upward. And mounted on the upper surface of the precast concrete small beam in two directions in a horizontal direction;

Placing reinforcement concrete after finishing reinforcement on the upper surface of the rib-type precast concrete slab;

And tensioning each tension member introduced into the plurality of sheath pipes so that the plurality of rib-type precast concrete slabs have a continuous frame.

Another suitable embodiment according to the construction method of the precast concrete frame for buildings using the precast concrete slab of the present invention,

Installing a plurality of precast concrete columns in a vertical direction with a predetermined distance from each other to support the building;

Selecting two adjacent neighbors of the precast concrete columns and placing the precast concrete beams in a right angle on the top;

The precast concrete slab includes a rib-shaped precast concrete slab having a lattice groove arranged at a predetermined depth on the bottom side, and a plurality of sheath pipes which are embedded in ribs for partitioning the lattice groove, and both ends thereof are exposed upward. Mounting in a direction perpendicular to each other;

Placing reinforcement concrete after finishing reinforcement on the upper surfaces of the plurality of rib-type precast concrete slabs;

The plurality of rib-shaped precast concrete slabs are characterized in that the construction through the step of tensioning the tension material respectively introduced into the plurality of sheath pipes to have a continuous frame.

In these embodiments, tension of the tension member may be made in the tension member anchoring groove formed in the side cross-section of the overlaid concrete in which both ends of the sheath pipe are located.

According to the precast concrete frame for buildings using the precast concrete slab continuous post-tension method of the present invention and its construction method, the continuous slab is strengthened by the tension force by the tension material, so reinforced reinforcement of the slab and interpolation in the field This eliminates the need for drastically reducing field reinforcement, resulting in increased field and economic efficiency.

In addition, it is possible to manufacture the slab to be constructed in the neighboring columns and columns as a single unit slab can facilitate the production and assembly construction.

In addition, the slab has a strength to withstand the external force by the tension material is improved seismic performance of the present skeleton structure.

In addition, the present frame structure is a post-tensioning action in the opposite direction to the working load to distribute the use load, thereby improving the stability of the structure.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
Figure 1a is a perspective view of a building precast concrete frame using a precast concrete slab continuous in the post-tension method according to the first embodiment of the present invention.
Figure 1b is a perspective view of the concrete frame shown in Figure 1a seen from the bottom.
FIG. 2 is a cross-sectional view taken along line AA of FIG. 1. FIG.
3 is a view showing a state in which the tension material is fixed after the addition concrete is poured into the slab and the beam of FIG.
4 is a bottom perspective view of a building precast concrete frame using a precast concrete slab continuous in a post-tension method according to a second embodiment of the present invention.
5 is a perspective view of the concrete before the cast concrete is poured in the precast concrete frame for the building using the precast concrete slab continuous in the post-tension method according to the third embodiment of the present invention.
6 is a perspective view of a precast concrete slab applied to the third embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

Precast concrete frame for buildings using ribbed PC slab continuous post-tension method according to the present invention is a two-way frame structure in which the beams are orthogonal to the beams on the column and one direction in which the beam is installed in only one direction in the horizontal or vertical direction. The slab structure is divided into a case in which a small beam is installed in a large beam in a two-way frame structure and a case in which only a large beam is installed without a small beam, and thus, a continuous slab frame can be implemented in all three types of embodiments.

≪ Embodiment 1 >

The precast concrete frame for buildings according to the first embodiment of the present invention is a case where only the large beam 12 is used without the small beam in the two-way frame structure as shown in Figures 1a to 3.

As shown in FIGS. 2 and 3, a plurality of precast concrete columns 10 installed in a vertical direction with a predetermined distance from each other are provided to support a building. Precast concrete column 10 is configured as a rectangular cross section in this embodiment, but is not limited to such a cross-sectional structure may be configured in a circular example.

 The precast concrete large beam 12 is mounted on the top at right angles by selecting two adjacent neighbors of the precast concrete columns 10. Therefore, the four precast concrete pillars 10 are mounted with four precast concrete large beams 12 in two directions in two directions, as illustrated.

On the upper surface of the precast concrete large beam 12, a rib-shaped precast concrete slab 20B supported in two directions in both directions is mounted.

Rib-type precast concrete slab 20B is precast from reinforced concrete. At this time, the rib-type precast concrete slab 20B may include a shear connector (not shown) that is partially exposed on the upper surface. The rib-shaped precast concrete slab 20B is a plurality of ribs having a predetermined depth on the bottom side and embedded in the ribs 22 partitioning the lattice grooves 21 so that both ends thereof are exposed upward. Two sheath tubes 24 are provided. In this embodiment, four ribs 22 are formed in parallel to each other in one direction, so that the sheath tube 24 is also provided on the four ribs 22 (see Fig. 2).

In the first embodiment, the grating groove 21 is preferably configured in a rectangular shape, but the present invention is not necessarily limited to such a shape or an arrangement method.

The plurality of rib-shaped precast concrete slabs 20B and 20B are framed in a continuous structure by fixing the tension members 26 introduced into the plurality of sheath pipes 24 to the anchorage 27 by post-tensioning as shown in FIG. Has a structure.

In addition, after the reinforcing bar is placed on the upper surface of the precast concrete slab 20A, the overlaid concrete 100 is poured, and the tension member 26 is provided at the side surface of the overlaid concrete 100 at which both ends of the sheath tube 24 are located. Tension material fixing groove 102 is formed for the settlement of.

The construction method for having such a precast concrete frame for a building is demonstrated.

First, a plurality of precast concrete pillars 10 are installed in the vertical direction at predetermined intervals to support a building as shown in FIGS. 1A to 2. In this case, the precast concrete column 10 may be assembled through anchor bolts installed on the floor as is well known when located at the lowest floor of the building, and the upper floor may be assembled through the connection of the fixing bars and the coupler.

Next, two adjacent neighbors of the precast concrete pillars 10 are selected, and the precast concrete large beam 12 is mounted on the top at right angles.

Next, a rib-shaped precast concrete slab 20B having a plurality of sheath pipes 24 is mounted on the upper surface of the precast concrete large beam 12 in two directions in the width and width direction.

Thereafter, the rib-shaped precast concrete slabs 20B adjacent to each other are connected to each other by pipes of the same material additionally for the continuation of the sheath tube 24. At this time, the pipe to be connected is transversely curved in a convex shape on the upper surface of the large beam 12 to be present on the lower side according to its position.

Next, the overcast concrete 100 is poured on the upper surface of the rib-shaped precast concrete slab 20B.

When the curing of the overlaid concrete 100 is completed, each tension member 26 is introduced into the plurality of sheath pipes 24, and the tension members 26 are tensioned. At this time, the tension member 26 is fixed by the fixing unit 27 located in the tension member fixing groove 102.

The precast concrete frame for buildings produced by the precast concrete frame construction method as described above does not require reinforcement of the slab and interpolation because the slab and the slab are bound and strengthened by the tension force by the tension member 26. Significantly reduced field reinforcement improves field performance and economy.

In addition, it is possible to manufacture the slab which is constructed on the adjacent pillars and columns to each other as one unit slab can facilitate the production and assembly construction.

In addition, since the slab has a compressive stress applied by the tension member 26 to withstand the external force, the seismic performance of the present skeleton structure is improved.

In addition, the present frame structure is a post-tensioning action by the tension member 26 in the opposite direction to the working load to distribute the use load, thereby improving the stability of the structure.

Second Embodiment

The precast concrete framework for buildings according to the second embodiment of the present invention is a case where the large beam 12 and the small beam 14 are used in the two-way frame structure as shown in FIG.

That is, a plurality of precast concrete pillars 10 installed in the vertical direction at predetermined intervals to support the building as shown in FIG. 4 and two neighboring two of the precast concrete pillars 10 are selected at the top thereof. Precast concrete large beams 12 mounted in a right angle direction, at least one small beam 14 synthesized in a direction perpendicular to a pair of precast concrete large beams 12 facing each other, and the precast concrete It consists of a plurality of rib-shaped precast concrete slabs 20A mounted on the upper surface of the large beam 12 and the precast concrete small beam 14 in two directions.

The rib-shaped precast concrete slab 20A is provided with ribs 22 for partitioning the grating groove 21 and the grating groove 21 which are arranged with a predetermined depth on the bottom side in the same manner as in Fig. 1A showing the first embodiment. It is provided with the some sheath pipe | tube 24 buried in the both ends and upwardly exposed. In addition, the rib-shaped precast concrete slab 20A has a shear connector protruding from the upper surface thereof.

In the second embodiment, the grating groove 21 is preferably configured in a square shape, but the present invention is not necessarily limited to such a shape or an arrangement structure.

The plurality of rib-shaped precast concrete slabs 20A have a frame structure that is continuous by fixing each tension member 26 introduced into the plurality of sheath pipes 24 by post-tensioning.

At this time, after the reinforcing bar is placed on the upper surface of the precast concrete slab 20A as in the first embodiment, the overlaid concrete 100 is poured, and the side end surface of the overlaid concrete 100 on which both ends of the sheath pipe 24 are positioned. The tension member fixing groove 102 for fixing the tension member 26 is formed.

Precast concrete frame for buildings having such a configuration is constructed through the same method as the construction process of the first embodiment. Therefore, the same effect as that of the first embodiment can be obtained.

Third Embodiment

Precast concrete framework for buildings according to the third embodiment of the present invention is applied to the case of one direction with a large beam as shown in Figs.

That is, as shown in FIGS. 5 and 6, a plurality of precast concrete pillars 10 installed in a vertical direction at predetermined intervals to support a building, and two adjacent neighbors of the precast concrete pillars 10, respectively. A precast concrete beam 12 placed at right angles on the top and a rib 22 partitioning the grating groove 21 and the grating groove 21 arranged at a predetermined depth on the bottom side thereof. A plurality of rib-type precast concrete slabs 20C which are embedded in a plurality of sheath pipes 24 whose ends are exposed upwards and are mounted in one direction perpendicular to the precast concrete large beams 12. It includes, a plurality of rib-shaped precast concrete slab 20C has a continuous frame by fixing the tension member 26 introduced into each of the plurality of sheath tube 24 by post-tensioning The.

Here, the grating groove 21 is formed long along the longitudinal direction of the rib-type precast concrete slab 20C, but is not limited thereto.

Precast concrete frame for buildings having such a configuration is constructed in the same manner as the construction process of the first embodiment as one case having only a large beam, it is possible to obtain the same effect as the first embodiment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: Columns
12: big show
14: little boy
21: lattice groove
20A, 20B, 20C: Ribbed Precast Concrete Slab
22: rib
24: Sheath tube
26: tension
100: overlay concrete
102: tension material settlement home

Claims (8)

A plurality of precast concrete columns 10 installed in a vertical direction with a predetermined distance from each other to support the building;
Precast concrete large beams (12), which are selected from each other adjacent to each other of the precast concrete pillars (10) and mounted at right angles to the top;
A lattice groove 21 arranged with a predetermined depth on the bottom side, a rib 22 for partitioning the lattice groove 21, and a plurality of sheaths embedded in the rib 22 and exposed at both ends upwards. A plurality of rib-shaped precast concrete slabs (20B) provided with pipes (24) mounted on the top surface of the precast concrete large beams (12) in two directions;
The plurality of rib-type precast concrete slabs (20B) is a post-tensioning method characterized in that each tension member 26 introduced into the plurality of sheath pipes 24 are fixed by post-tensioning to have a continuous frame structure. Precast concrete framing for buildings using continuous precast concrete slabs. A plurality of precast concrete columns 10 installed in a vertical direction with a predetermined distance from each other to support the building;
Precast concrete large beams (12), which are selected from each other adjacent to each other of the precast concrete pillars (10) and mounted at right angles to the top;
One or more small beams 14 coupled to the pair of precast concrete large beams 12 facing each other at right angles;
A lattice groove 21 arranged with a predetermined depth on the bottom side, a rib 22 for partitioning the lattice groove 21, and a plurality of sheaths embedded in the rib 22 and exposed at both ends upwards. A plurality of rib-shaped precast concrete slabs 20A are mounted on the upper surfaces of the precast concrete large beam 12 and the precast concrete small beam 14 in two directions in a horizontal direction. Including;
The plurality of rib-type precast concrete slabs (20A) is a post-tensioning method characterized in that each tension member 26 introduced into the plurality of sheath pipes 24 are fixed by post-tensioning to have a continuous frame structure. Precast concrete framing for buildings using continuous precast concrete slabs. A plurality of precast concrete columns 10 installed in a vertical direction with a predetermined distance from each other to support the building;
Precast concrete large beams (12), which are selected from each other adjacent to each other of the precast concrete pillars (10) and mounted at right angles to the top;
A plurality of sheath pipes, each of which includes a lattice groove 21 arranged at a predetermined depth on the bottom side, a rib 22 for partitioning the lattice groove 21, and a plurality of sheaths embedded in the ribs 22 and exposed at both ends thereof. A plurality of rib-shaped precast concrete slabs (20C) provided with (24) mounted in one direction perpendicular to the precast concrete large beams (12);
The plurality of rib-shaped precast concrete slabs 20C have a post-tensioning structure characterized in that the tension members 26 respectively introduced into the plurality of sheath pipes 24 are fixed by post-tensioning to have a continuous frame structure. Precast concrete framing for buildings using continuous precast concrete slabs. 4. The method according to any one of claims 1 to 3,
The tension concrete fixing groove 102 for fixing the tension member 26 on the side surface of the overlay concrete 100, in which both ends of the sheath tube 24 are placed, and the concrete 100 is poured on the upper surface of the precast concrete slab. Precast concrete framework for buildings using precast concrete slab continuous by post-tension method, characterized in that is formed. Installing a plurality of precast concrete columns 10 in a vertical direction with a predetermined distance therebetween to support the building;
Selecting two adjacent neighbors of the precast concrete pillars 10 and placing the precast concrete large beams 12 at right angles on the top;
A rib having a lattice groove 21 arranged on the bottom side with a predetermined depth and a plurality of sheath pipes 24 embedded in ribs 22 partitioning the lattice grooves 21 and both ends thereof exposed upwards. Placing a precast concrete slab (20B) in two directions on the upper surface of the precast concrete large beam (12);
Placing reinforcement concrete after finishing reinforcement on the upper surface of the rib-type precast concrete slab 20B;
A plurality of rib-shaped precast concrete slabs 20B are constructed by a step of tensioning each tension member 26 introduced into the plurality of sheath pipes 24 so as to have a continuous frame. Construction method of building precast concrete frame using continuous precast concrete slab. Installing a plurality of precast concrete pillars 10 in a vertical direction at predetermined intervals to support the building;
Selecting two adjacent neighbors of the precast concrete pillars 10 and placing the precast concrete large beams 12 at right angles on the top;
Installing at least one small beam 14 at right angles to the precast concrete large beam 12 facing each other;
A rib having a lattice groove 21 arranged on the bottom side with a predetermined depth and a plurality of sheath pipes 24 embedded in ribs 22 partitioning the lattice grooves 21 and both ends thereof exposed upwards. Placing a precast concrete slab (20A) in two directions on the upper surfaces of the precast concrete large beams (12) and the precast concrete small beams (14);
Placing reinforcement concrete 100 after completing the reinforcement on the upper surface of the rib-shaped precast concrete slab 20A;
Post-tensioning method characterized in that the construction through; the step of tensioning each tension member 26 introduced into the plurality of sheath tube 24 to have a plurality of rib-shaped precast concrete slab 20A continuous structure Construction method of building precast concrete frame using continuous precast concrete slab. Installing a plurality of precast concrete columns 10 in a vertical direction with a predetermined distance therebetween to support the building;
Selecting two adjacent neighbors of the precast concrete pillars 10 and placing the precast concrete large beams 12 at right angles on the top;
A rib having a lattice groove 21 arranged on the bottom side with a predetermined depth and a plurality of sheath pipes 24 embedded in ribs 22 partitioning the lattice grooves 21 and both ends thereof exposed upwards. Mounting a precast concrete slab (20C) in one direction perpendicular to the precast concrete large beam (12);
Placing reinforcement concrete (100) after completing the reinforcement on the upper surface of the plurality of rib-type precast concrete slabs (20C);
A plurality of rib-type precast concrete slabs 20C are sequentially constructed by a step of tensioning the tension members 26 respectively introduced into the plurality of sheath pipes 24 so as to have a continuous frame. Method of building precast concrete frame using precast concrete slab. The method according to any one of claims 5 to 7,
The tension of the tension member 26 is a pre-tensioned continuous slab precast concrete slab, characterized in that made in the tension member fixing groove 102 formed on the side end surface of the overlay concrete 100, both ends of the sheath tube 24 Construction method of precast concrete frame using building.

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