KR102149662B1 - Method for constructing transfer layer of building using precast concrete slab - Google Patents

Abstract

According to the present invention, a method of constructing a transition layer between the pillar structure of the lower layer and the wall structure of the upper layer, comprising: a pillar installation step of installing and erecting a plurality of pillars on the foundation or floor of each layer in the lower layer; A girder installation step of installing a plurality of girders on the plurality of columns installed through the column installation step; A PC slab installation step of mounting and installing a plurality of pre-fabricated PC slabs for a transition layer on the plurality of girders installed through the girder installation step; A first pouring step of forming a first pouring concrete layer by pouring concrete over a plurality of PC slabs for a transition layer installed through the PC slab installation step; And a second pouring step of forming a second poured concrete layer by additionally pouring concrete over the first poured concrete layer to include a wall-type structure of the upper layer.

Description

Construction method of transfer layer of building using PC slab {METHOD FOR CONSTRUCTING TRANSFER LAYER OF BUILDING USING PRECAST CONCRETE SLAB}

The present invention relates to a method of constructing a transition layer of a building, and more particularly, to a method of constructing a transition layer on the ground between a lower layer of a column structure and an upper layer of a wall structure.

In the case of an apartment complex or multi-purpose building equipped with an underground parking lot, it is generally composed of a columnar structure (ramen structure) under the ground, and a wall structure without columns on the ground. A transition layer is formed between the columnar structure and the wall structure to transfer to the lower part of the columnar structure.

In general, the transfer layer is constructed by reinforcing reinforcing bars at the site, forming a formwork surrounding the reinforced reinforcing bars using plywood or timber, and then installing a system support or movable bar at the bottom, and then pouring concrete inside the formwork.

However, in such a general construction method, a lot of manpower and working time are saved by the operator performing the process of tying the reinforcing bars with a binding line, the process of installing and removing formwork, and installing and removing a number of supports that support the slab at the construction site. in need. In addition, as the formwork is maintained until the poured concrete is cured with sufficient strength, the construction period is inevitably extended due to the work schedule.

In particular, in the process of installing and removing a formwork, a number of formwork panels are damaged and need to be repaired or disposed of, so not only is a large amount of material loss, but also a large number of industrial wastes are generated, reinforcement process, formwork installation and dismantling process, plastering process, etc. It takes a lot of time and, accordingly, requires a number of skilled workers, such as carpenters and plasterers who install and dismantle reinforcing bars and formwork.

Korean Registered Patent Publication No. 10-1826094 (2018.03.22.)

An object of the present invention is to provide a transfer layer construction method capable of simply constructing a transfer layer on the ground between a lower layer of a column structure and an upper layer of a wall structure and shortening the construction period.

In order to achieve the object of the present invention as described above, according to an aspect of the present invention, a method of constructing a transition layer between the pillar structure of the lower layer and the wall structure of the upper layer, wherein a plurality of pillars are formed on the lower layer Post installation step to install and erect above; A girder installation step of installing a plurality of girders on the plurality of columns installed through the column installation step; A PC slab installation step of mounting and installing a plurality of pre-fabricated PC slabs for a transition layer on the plurality of girders installed through the girder installation step; A first pouring step of forming a first pouring concrete layer by pouring concrete over a plurality of PC slabs for a transition layer installed through the PC slab installation step; And a second pouring step of forming a second poured concrete layer by additionally pouring concrete over the first poured concrete layer to include a wall-type structure of the upper layer.

According to the present invention, all the objects of the present invention described above can be achieved. Specifically, pillars for a ramen structure are installed underground, a girder is installed on the pillar, a pre-fabricated PC slab is mounted on the girder, and a transfer layer is formed through the steps of first and second pouring, It is possible to easily construct a transition layer on the ground between the basement layer of the column structure and the ground layer of the wall structure and shorten the construction period.

1 is a flow chart showing the main steps of a method for constructing a transition layer of a building according to an embodiment of the present invention.
FIG. 2 schematically shows a state in which a pillar is installed by a pillar installation step among the steps of FIG. 1.
3 schematically shows a state in which the girder is installed by the girder installation step among the steps of FIG. 1.
Figure 4 is a perspective view of the girder shown in Figure 3;
5 is a plan view of the girder shown in FIG. 3.
6 is a plan view showing a state in which a girder is installed on a column in FIG. 3.
7 is a side view showing a state in which the girder is installed on the column in FIG. 3.
8 schematically shows a state in which PC slabs are installed by the PC slab installation step among the steps of FIG. 1.
9 is a plan view of the PC slab shown in FIG. 8.
10 is a cross-sectional view taken along line A-A' of the PC slab shown in FIG. 9.
11 is a cross-sectional view taken along line B-B' of the PC slab shown in FIG. 9.
12 is a side view showing a state in which the PC slab is installed in FIG. 8.
13 is a diagram showing a state in which a first pouring step is performed among the steps of FIG. 1.
14 is a view showing a state in which the upper reinforcement step is performed among the steps of FIG. 1.
15 is a diagram illustrating a state in which a second pouring step is performed among the steps of FIG. 1.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a flow chart showing the main steps of a method for constructing a transition layer of a building according to an embodiment of the present invention. Referring to FIG. 1, the method of constructing a transfer layer of a building according to an embodiment of the present invention includes a column installation step (S10), a girder installation step (S20), a PC slab installation step (S30), and a first pouring step. It includes (S40), an upper reinforcement step (S50), and a second pouring step (S60).

In the pillar installation step (S10), a plurality of pillars are installed and erected on the foundation in the basement floor. FIG. 2 shows a state in which a plurality of pillars are installed by the pillar installation step S10. 2, a plurality of pillars 200 are installed and erected on the foundation 100. The pillar 200 is a reinforced concrete structure, and a plurality of pillar reinforcements 210 protrude upward by a predetermined height at the top of the pillar 200. In this embodiment, it will be described that the pillar 200 is pre-fabricated in PC and assembled and installed on the foundation 100 at the site.

In the girder installation step (S20), a plurality of girders are installed on the plurality of pillars 200 installed in the basement through the pillar installation step (S10). 3 shows a state in which a plurality of girders are installed by performing a girder installation step (S20). Referring to FIG. 3, a plurality of girders 300 are installed on tops of a plurality of pillars 200 erected on a foundation 100.

4 and 5 shows the structure of the girder 300 in detail. 4 and 5, the girder 300 is a reinforced concrete structure, and includes a girder concrete body 310 having a generally rod shape, and reinforcing bars formed integrally with the girder concrete body 310. The girder concrete body 310 includes a base plate part 320 having a flat upper and lower surface formed thereon, and a wall part 330 extending upward from one side in the width direction of the base plate part 320. Accommodating grooves 340 are formed at both ends of the girder concrete body 310 in the longitudinal direction in which the reinforcing pillars 210 formed by protruding from the top of the pillar 200 can be accommodated. A plurality of front exposed reinforcing bars 370 protrude and extend upward on the upper surface of the base plate part 320 to be formed. The plurality of front exposed reinforcing bars 370 are sequentially arranged in a row along the length direction of the base plate part 320. A plurality of side exposed reinforcing bars 350 protrude at both ends of the base plate part 320 in the longitudinal direction, extending along the longitudinal direction, and being bent upward. A plurality of upper exposed reinforcing bars 360 protrude from the upper end of the wall portion 330 and are formed to extend upward. In this embodiment, it will be described that the girder 300 is pre-fabricated with PC and assembled and installed on the pillar 200 in the field.

6 is a plan view showing a state in which two girders 300 are installed on one pillar 200. Referring to FIG. 6, both ends of the two girders 300 are placed on the top of the column 200 to be coupled, and a plurality of column reinforcement bars 210 are formed through the receiving groove 340 formed in each of the two girders 300. Pass through. In addition, the side exposed reinforcing bars 350 of each of the two girders 300 are disposed together with the column reinforcing bars 210 on the top of the column 200, and among the two girders 300 placed on the top of the column 200 Each of the plurality of side exposed reinforcing bars 350 provided in the other girder 300 is positioned between the plurality of side exposed reinforcing bars 350 provided in one girder 300.

Referring to FIG. 7, the two girders 300 are disposed such that the wall portion 330 of each of the two girders 300 faces outward.

After the girders 300 are installed by the girder installation step (S20), the PC slab installation step (S30) is performed.

FIG. 8 schematically shows a state in which the PC slabs are installed by the PC slab installation step S30 among the steps of FIG. 1. Referring to FIG. 8, a plurality of PC slabs 400 for transition layers are installed including a region in which a wall-type building is located (a region in which a transition layer is formed). Other types of PC slabs may be installed in the remaining areas where the above-ground buildings are not located.

9 to 11, the PC slab 400 for the transfer layer is a reinforced concrete structure, pre-fabricated with PC, and installed at both ends of the two girders 300 facing each other at the site. The PC slab 400 includes a slab concrete body 410 and a reinforcing reinforcement structure 420 integrally formed with the slab concrete body 410.

The slab concrete body 410 is generally in the form of a flat plate and is made of a flat cement concrete material. The reinforcing reinforcing bar structure 420 is formed integrally with the slab concrete body 410, and a plurality of slab end exposed reinforcing bars 430 extending by protruding and extending at both ends in the longitudinal direction and bent upward from the end, and the slab concrete body ( It includes a plurality of upper protruding reinforcing bars 440 formed by protruding above the upper surface of the 410).

12 shows a state in which the PC slab 400 is installed by the PC slab installation step (S30). Referring to FIG. 12, the PC slab 400 is mounted on the base plate portion 320 of the two girders 300 disposed opposite to both ends of the slab concrete body 410. At this time, the slab end exposed reinforcing bars 430 of the PC slab 400 are located between the end of the slab concrete body 410 and the wall portion 330 of the girder 300, and the upper protruding reinforcing bars 440 are the slab concrete body ( 410). A plurality of front exposed reinforcing bars 370 of the girder 300 are located outside the end of the slab concrete body 410. After the PC slab installation step S30 is performed and the PC slabs 400 are all installed, the first pouring step S40 is performed.

13 illustrates a state in which the first pouring step S40 has been performed among the steps of FIG. 1. 13, the cement concrete over the PC slab 400 by the first pouring step (S40) covers the whole of the PC slab 400, the girder concrete body 310, and the whole of the plurality of front exposed reinforcing bars 370. It is poured to cover. The concrete poured in the first pouring step (S40) extends to the outside area of the PC slab 400 (ie, the area where the transition layer is not formed). The plurality of upper exposed reinforcing bars 360 of the girder 300 are exposed by protruding over the first poured concrete layer 500. After the first pouring step (S40) is completed and curing of the concrete 500 poured in the first pouring step (S40) is completed, the upper reinforcement step (S50) is performed. Before the first pouring step (S40) is performed, the on-site reinforcement step is performed if necessary. A plurality of reinforcing bars connecting the plurality of front exposed reinforcing bars 370 and the plurality of upper exposed reinforcing bars 360 of the girder 300 in the field reinforcing reinforcement step performed before the first pouring step (S40) is performed ( 380) are added.

14 is a view showing a state in which the upper reinforcement step (S50) has been performed among the steps of FIG. 1. Referring to FIG. 14, an upper reinforcing bar 600 is reinforced in correspondence with a region in which a transition layer is formed on the first poured concrete layer 500 poured through the first pouring step (S40). The upper reinforcing bar 600 is connected by a plurality of upper exposed reinforcing bars 360 of the girder 300 and a prosthetic bar 380 and a binding line. After the upper reinforcing reinforcement 600 is reinforced in the transition layer region through the upper reinforcement step (S50), a second pouring step (S60) is performed.

FIG. 15 shows a state in which the second pouring step S60 is performed among the steps of FIG. 1. Referring to FIG. 15, cement concrete is poured in a region corresponding to the transition layer above the first poured concrete layer 500 by the second pouring step (S60). The second pouring concrete layer 700 poured by the second pouring step (S60) is formed to cover both the upper exposed reinforcing bar 600 and the upper exposed reinforcing bar 360 and the prosthesis bar 380 of the girder 300 and It forms a step with the first poured concrete layer 500.

Although not shown, after the second pouring step (S60), a wall-type above-ground building is constructed over the second pouring concrete layer 700.

In the above embodiment, a case of forming a transition layer between the basement layer of the ramen structure and the ground layer of the wall structure has been described, but the present invention is not limited to the formation of the transition layer between the basement layer and the ground layer. The present invention includes all cases of forming a transition layer between a lower layer having a ramen structure and an upper layer having a wall structure, wherein the basement layer is an example of the lower layer having the ramen structure described in the claims, and the ground layer is described in the claims. This is just one example of an upper layer with a wall structure.

Although the present invention has been described through the above embodiments, the present invention is not limited thereto. The above embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes also belong to the present invention.

100: foundation 200: column
210: column reinforcement 300: girder
310: girder concrete body 320: foundation plate
330: wall portion 340: receiving groove
350: side exposed reinforcement 360: upper exposed reinforcement
400: PC slab 410: slab concrete body
420: reinforcing bar structure 430: exposed reinforcing bar at the slab end
440: reinforcing bar protruding above the slab 500: first poured concrete layer
600: upper reinforcing bar 700: second cast concrete layer

Claims (10)

As a method of constructing a transition layer between the column structure of the lower layer and the wall structure of the upper layer,
A pillar installation step of installing and erecting a plurality of pillars on the lower layer on the foundation or on each floor;
A girder installation step of installing a plurality of girders on the plurality of columns installed through the column installation step;
A PC slab installation step of mounting and installing a plurality of pre-fabricated PC slabs for a transition layer on the plurality of girders installed through the girder installation step;
A first pouring step of forming a first pouring concrete layer by pouring concrete over a plurality of PC slabs for a transition layer installed through the PC slab installation step; And
Including a second pouring step of forming a second poured concrete layer by additionally pouring concrete over the first pouring concrete layer so as to include a wall-type structure of the upper layer,
The girder is a reinforced concrete structure pre-fabricated with a PC having a girder concrete body and rebars integrally formed with the girder concrete body,
The girder concrete body,
And a base plate portion having a flat top and bottom surface, and a wall portion formed by extending upward from only one of both sides in the width direction of the base plate portion,
At both ends of the girder concrete body in the longitudinal direction, each receiving groove is formed to accommodate the reinforcing pillars protruding from the top of the pillar, and the receiving groove is formed so as to be introduced into the base plate. It is formed to be inserted to some depth,
The reinforcing bars integrally formed with the girder concrete body include a plurality of upper exposed reinforcing bars protruding upward from the wall part and exposed, a plurality of front exposed reinforcing bars protruding upward from the base plate part,
In the girder installation step, the girder is installed so that the wall portion is located on the outside,
In the step of installing the PC slab, the PC slab for the transition layer is mounted on the base plates of the two girders disposed to face each other,
A transfer layer construction method of a building in which the first pouring step is performed so that the entire girder concrete body is buried in the first poured concrete layer. The method according to claim 1,
Before performing the first pouring step or before performing the second pouring step, it further comprises an upper reinforcing step of installing an upper reinforcing bar on the first pouring concrete layer,
A transfer layer construction method of a building in which the second pouring step is performed so that the upper reinforcing bar is buried in the second poured concrete layer. The method according to claim 2,
The first pouring step is performed so that the plurality of upper exposed rebars protrude above the first pouring concrete layer,
In the upper reinforcing step, the upper reinforcing bar is connected to the upper exposed reinforcing bar. The method of claim 3,
The first pouring step is performed so that the plurality of front exposed reinforcing bars are all buried in the first poured concrete layer,
Before the first pouring step is performed, the step of connecting the plurality of front exposed reinforcing bars and the plurality of upper exposed reinforcing bars by using a plurality of prostheses. The method according to claim 1,
The girder includes a plurality of side exposed reinforcing bars extending by being bent after protruding from both ends in the longitudinal direction of the girder concrete body,
In the girder installation step, the transfer layer construction method of a building is installed by placing the ends of the two girders so that the side exposed reinforcing bars are located on the top of the column. The method of claim 4,
A transfer layer construction method of a building in which a plurality of side exposed reinforcing bars provided in another girder are located between a plurality of side exposed reinforcing bars provided in one of two girders placed on the top of the column. delete The method according to claim 1,
The PC slab for the transition layer is a reinforced concrete structure, and includes a slab concrete body and a plurality of end exposed reinforcing bars extending by being bent after protruding from both ends in the longitudinal direction of the slab concrete body,
In the step of installing the PC slab, the transfer layer construction method of a building in which the PC slab for the transfer layer is installed so that the plurality of end exposed reinforcing bars are placed on the girder. The method according to claim 1,
The PC slab for the transition layer is a reinforced concrete structure, and includes a slab concrete body and a plurality of upper protruding reinforcements protruding upward from the slab concrete body,
A transfer layer construction method of a building in which the first pouring step is performed so that the upper protruding reinforcing bars are buried in the second pouring concrete layer. The method according to claim 1,
The second pouring concrete layer is a transfer layer construction method of a building in which the second pouring step is performed to form a step with the first poured concrete layer.

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