KR101078991B1 - Precast concreat structure and method of constructing the same - Google Patents

Abstract

PURPOSE: A precast concrete structure and a construction method thereof are provided to reduce the time and cost for manufacturing unit structures because unit structures for the lowest, middle, and uppermost layers of a structure are manufactured in a factory and simply laminated in a construction field. CONSTITUTION: A precast concrete structure comprises a lower unit structure(110), a middle unit structure(130), and an upper unit structure(150). The lower unit structure includes a lowest layer unit structure(111), a middle layer unit structure(112), and an uppermost layer unit structure(113). The middle unit structure includes a lowest layer unit structure(131), a middle layer unit structure(132), and an uppermost layer unit structure(133). The upper unit structure includes a lowest layer unit structure(151), a middle layer unit structure(152), and an uppermost layer unit structure(153).

Description

Precast Concrete Structure and Construction Method {PRECAST CONCREAT STRUCTURE AND METHOD OF CONSTRUCTING THE SAME}

The present invention relates to a precast concrete structure and a construction method thereof, and more particularly, to a precast concrete structure and a construction method that can be ensured while being easily coupled between unit structures.

The precast method is a method of making a large structure or a structure by making a large structure into a unit structure having a size that is easy to manufacture, store, and transport in a factory, and then assemble the unit structures on a site. It is used a lot in.

A typical example of such a precast concrete structure is disclosed in Korean Patent Registration No. 10-0733837 "Multiple Section 1 Precast Concrete Column and Construction Method Using the Same", and its representative configuration is shown in FIGS. 1 and 2.

1 and 2, the multilayer single-section PC column 10 is composed of first and second PC assembly pillars 10a and 10b formed symmetrically, and the first and second PC assembly pillars 10a. Each layer consists of three sections.

In addition, a plurality of vertical reinforcing bars 20 and inclined rebars 30 are formed in the spaced space between the pillars 11, 12, and 13, and the PC beam 40 is coupled to the spaced apart space.

The first and second PC assembly pillars 10a and 10b formed symmetrically are firmly coupled by a plurality of connecting bolts 14 passing through the plurality of bolt holes 15 formed in the transverse direction.

Conventional precast concrete structure having the above-described configuration is the first PC assembly pillar formed in the left and right symmetry by connecting the pillars (11, 12, 13) of each layer in the factory with a plurality of vertical reinforcement 20 and the inclined reinforcement (30) Since 10a) and the second PC assembly pillar 10b had to be manufactured, not only a lot of time and money were required to manufacture the pillars 11, 12, and 13, but also difficulties in storing and transporting them to the site were followed.

In addition, in order to assemble the first PC assembling pillar 10a and the second PC assembling pillar 10b which are symmetrical in the field, the skilled person had to accurately fit the plurality of bolt holes 15 so that the plurality of connecting bolts 14 were fastened well. Even so, it was also difficult to execute these tasks correctly each time.

Korean Patent Registration No. 10-0733837

The present invention was devised to solve the problems of the prior art described above, the problem to be solved of the present invention is to separately manufacture the unit structures of each layer, such as the lowest layer, middle layer and the highest layer of the structure in the factory and to make them according to the size and order in the field It is to provide a precast concrete structure and its construction method that can greatly reduce the time and cost required to manufacture a unit structure by simply stacking.

In addition, another problem to be solved by the present invention is the precast concrete structure and its construction, which can greatly reduce the time and cost required to construct the desired structure by using such unit structures, and can ensure the stability of the assembled (constructed) structure To provide a way.

In order to achieve the above object of the present invention, the present invention is a lower unit structure having a lower layer unit structure 111, an intermediate layer unit structure 112 and the highest layer unit structure 113 are vertically stacked to be wedge-coupled with each other in order ( 110); An intermediate unit structure 130 having a lowest layer unit structure 131, an intermediate layer unit structure 132, and a highest layer unit structure 133 stacked vertically so as to be wedge-coupled with each other in sequence; Precast concrete structure characterized in that it comprises a top unit structure 150 having a lowest layer unit structure 151, the middle layer unit structure 152 and the highest layer unit structure 153 are stacked vertically so as to be wedge-bonded to each other in order to provide.

In the precast concrete structure of the present invention, all the unit structures constituting the lower unit structure 110, the intermediate unit structure 130, and the upper unit structure 150 are guides for guiding the insertion of a plurality of coarse steel bars 2. Characterized in that each 115 is provided, the reinforcement guide 115 is a joint portion connecting the plurality of fitting portions 116 and the plurality of fitting portions 116 into which a plurality of thick rebars 2 are fitted ( 117) is another feature.

In addition, the lower unit structure 110, the intermediate unit structure 130 and the upper unit structure 150 is characterized in that each is more firmly coupled by the tension wire bundle (1) penetrating therein, the lowest layer unit structure (111) ) Is provided in the lower end portion of the wedge-shaped coupling body 114 to which the lower end binder 11, which binds the tension wire bundle 1, is wedge-coupled, and the middle layer unit structure 112 is the tension wire bundle 1 ) Is characterized in that a plurality of reinforcing bar binding body 116 in which a plurality of coarse reinforcing bars 2 are wedge-bound is provided at the lower end of the through-hole through. A plurality of reinforcing bar binder body 116 is another feature that is made of a pair each having a shape of the top is upright and the bottom is upside down.

In addition, the highest layer unit structure 113 is characterized in that it has the same configuration as the intermediate layer unit structure (112).

In the present invention, the lowest layer unit structure 131 is provided in the lower end so that the wedge-shaped coupling body 134 is wedge-coupled to the lower end binding body 31 that binds the tensile wire bundle 1, and the wedge-shaped coupling body ( 134 is characterized in that the upper portion has a straight shape and the lower portion is made up of a pair of upside down shape, the upper portion of the lower end unit 31 is fitted to the lowest floor unit structure 131, the wedge is bound, There is another feature that the upper end binding body 12 that binds the other tension wire bundle (1) protruding above the top layer unit structure 113 is wedge-bonded.

In the present invention, the top layer unit structure 153 is characterized in that the wedge-shaped coupling body 154, in which the upper end binding body 52 which binds the tension wire bundle 1, is wedge-coupled, is provided upside down in the upper end. It is done.

In addition, the present invention (A) step of vertically stacking the lowest layer unit structure 111, the middle layer unit structure 112 and the highest layer unit structure 113 in order to form a lower unit structure (110); (B) stacking the lowest layer unit structure 131, the middle layer unit structure 132, and the highest layer unit structure 133 vertically in order to form an intermediate unit structure 130; (C) stacking the lowest unit structure 151, the middle layer unit structure 152, and the highest layer unit structure 153 vertically in order to form the upper unit structure 150; (D) vertically stacking the intermediate unit structure 130 directly on the lowest layer unit structure 111, and the upper unit structure 150 again stacked on the intermediate unit structure 130, the free, characterized in that Provides a method for constructing cast concrete structures.

The construction method of the present invention is characterized in that the number of the intermediate unit structure 130 varies depending on the height of the structure to be constructed.

According to the precast concrete structure and the construction method of the present invention, the unit structure because it is only required to separately manufacture the unit structures of each floor, such as the lowest floor, the middle floor and the highest floor of the structure in the factory and simply stack them in the field according to size and order. Significantly reduce the time and cost required to build a product.

In addition, by using these unit structures in the field, the time and cost required to construct a desired structure can be greatly reduced, and the stability of the assembled structure can be ensured.

1 is a longitudinal cross-sectional view showing a multilayer ferrous PC pillar of the prior art;
Figure 2 is a longitudinal cross-sectional view showing a PC beam-column coupling structure of a conventional multi-layer ferrous PC pillar.
3 is a schematic exploded view of a precast concrete structure according to a preferred embodiment of the present invention;
4 is a schematic longitudinal sectional view of the lower unit structure of FIG. 3;
5 is a schematic longitudinal sectional view of the intermediate unit structure of FIG.
6 is a schematic longitudinal sectional view of the upper unit structure of FIG.
FIG. 7 is a schematic cross-sectional view of a unit structure of any one layer obtained along line AA of FIGS. 4 to 6; And
8 is a schematic cross-sectional view of a unit structure of any one layer obtained in a modification of the structure.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the precast concrete structure and its construction method according to a preferred embodiment of the present invention.

3 is a schematic exploded perspective view of a precast concrete structure according to a preferred embodiment of the present invention.

As shown in FIG. 3, the precast concrete structure 100 according to the exemplary embodiment of the present invention is stacked on top of each of the unit structures stacked in a bundle of three again. For better understanding of the description, each unit structure stacked in a bundle of three below is a 'lower unit structure', and each unit structure stacked in a bundle of three in the middle is a 'middle unit structure', and the other three bundles Each unit structure stacked as is referred to as an 'upper unit structure'. Accordingly, the lower unit structure 110, the middle unit structure 130, and the upper unit structure 150 have the lowest layer, the middle layer, and the highest layer unit structure. It is okay.

Figure 3 is shown as described in order to illustrate a typical construction method, a specific construction method will be described later after the description of each unit structure with reference to FIGS.

First, the lower unit structure will be described with reference to FIG. 4. 4 is a schematic longitudinal cross-sectional view of the lower unit structure of FIG. 3.

As shown in FIG. 4, the lower unit structure 110 has the lowest layer unit structure 111, the middle layer unit structure 112, and the highest layer unit structure 113 stacked vertically in order.

The lowest layer unit structure 111 is located at the bottom and is provided in the lower end so that the wedge-shaped coupling body 114 to which the lower end binding body 11 which binds the tension wire bundle 1 is wedge-coupled. The wedge-shaped coupling member 114 is formed in a cylindrical shape corresponding to the lower end binding body 11 formed in a cylindrical shape and is formed somewhat longer than the lower end binding body 11 so that the entire outer circumferential surface of the lower end binding body 11 can be wedge-coupled. .

In addition, the lowest floor unit structure 111 is provided with a guide bar 115 for guiding the insertion of a plurality of coarse bars (2) in the upper end and the lower end located on the wedge-shaped coupling body 114, respectively. The reinforcing bar guide 115 is installed so that a number of thick rebar (2) is vertically erected. At this time, the upper end of the plurality of thick reinforcing bar (2) is protruded out of the top of the lowest floor unit structure (111).

Such a structure is located at a desired position of the wedge-shaped coupling body 114, the plurality of rebar guides 115, and the plurality of coarse steel bars 2 in a manufacturing frame (not shown) for manufacturing the lowest unit structure 111. It is obtained by stiffening by pouring concrete to it. Although not shown, a plurality of thin bars are, of course, planted between the plurality of coarse bars 2. Since the intermediate layer unit structure 112 and the highest layer unit structure 113 described below are also obtained in the same manner, the manufacturing method for them will not be described any more.

The middle layer unit structure 112 is provided with a plurality of reinforcing rods 116 in which a plurality of coarse steel bars 2 are wedge-bonded to a lower end thereof so as to be positioned around the through hole through which the tensile wire bundle 1 passes. The plurality of reinforcing rods 116 has a shape in which the upper part is erected upright, and the lower part is formed upside down in an integral or detachable pair. In the upper portion, the thick reinforcing bar 2 planted in the unit structure 112 is wedge-bound, and in the lower portion, the thick reinforcing bar 2 protruding over the other unit structure, that is, the lowest layer unit structure 111, is wedge-bound.

In addition, the intermediate layer unit structure 112 is provided with a reinforcing bar guide 115 for guiding the insertion of the plurality of coarse bars 2 in the upper end and the lower end located on the plurality of reinforcing bar 116. The reinforcing bar guide 115 is installed so that a number of thick rebar (2) is vertically erected. At this time, the upper end of the plurality of coarse reinforcing bars 2 is protruded out of the upper end of the intermediate layer unit structure 112.

Since the highest unit structure 113 has the same configuration as the intermediate unit structure 112, description thereof will be omitted in order to avoid duplication of description.

As shown in FIG. 4, the lowest layer unit structure 111, the middle layer unit structure 112, and the highest layer unit structure 113 stacked vertically are firmly coupled to each other by the tensile wire bundle 1. The lower end binder 11 bound to the lower end of the tension wire bundle 1 is wedge-coupled vertically by heavy weight to the wedge-shaped coupling body 114 provided in the lowest layer unit structure 111, and the tension wire bundle 1 The upper end binding body 12 is bound to the upper end of the top layer unit structure 113 is to be spread over the upper end.

At this time, the upper end binder 12 bound to the upper end of the tension wire bundle (1) is provided with a binding plate 13 having a size enough to span the upper surface of the top layer unit structure 113, the upper end binder 12 Is located outside the highest unit structure 113. In addition, in order for each of the unit structures 111, 112, and 113 to be firmly coupled by the tension wire bundle 1, the length of the tension wire bundle 1 that is put therein is slightly shorter than the total length of the stacked unit structures 111, 112, and 113, and the tensile force is increased. The tensile force of the line bundle 1 is applied to the unit structures 111, 112 and 113 perpendicularly.

Next, the intermediate unit structure will be described with reference to FIG. 5. FIG. 5 is a schematic longitudinal cross-sectional view of the intermediate unit structure of FIG. 3.

As shown in FIG. 5, the intermediate unit structure 130 has a lowest layer unit structure 131, an intermediate layer unit structure 132, and a highest layer unit structure 133 stacked vertically in order.

In FIG. 5, the lowest layer unit structure 131 is provided in the lower end so that the wedge-shaped coupling body 134 in which the lower end binding body 31 which binds the tensile wire bundle 1 is wedge-coupled is located at the center. In this case, the wedge-shaped coupling body 134 is formed in a pair so that the upper part has a straight shape and the lower part has an upside down shape, which is somewhat different from that applied to the lowest layer unit structure 111 of FIG. 4. At the upper end, the lower end binding body 31, which binds the tension line bundle 1 fitted to the unit structure 131, is wedge-bonded, and the lower portion binds another tension line bundle 1 protruding from the top in FIG. The upper end binder 12 is wedge-bound.

Since the intermediate layer unit structure 132 and the highest layer unit structure 133 stacked on the lowest layer unit structure 131 have the same configuration as the intermediate layer unit structure 112 and the highest layer unit structure 113 described with reference to FIG. In order to avoid the description thereof will be omitted.

The lowest layer unit structure 131, the middle layer unit structure 132, and the highest layer unit structure 133 stacked vertically are firmly coupled to each other by the tensile wire bundle 1. The lower end binder 31, which is bound to the lower end of the tension wire bundle 1, is wedge-coupled vertically by heavy weight to the wedge-shaped coupling body 134 provided in the lowest layer unit structure 131, and the tension wire bundle 1 The upper end binding body 32 is coupled to the upper end of the top layer unit structure 133 is to be spread over.

At this time, the upper end binder 32 bound to the upper end of the tension wire bundle (1) is provided with a binding plate 33 having a size enough to span the upper surface of the unit structure 133, the upper end binder 32 is The outermost unit structure 133 is located outside. In addition, in order for each unit structure (131, 132, 133) to be firmly coupled by the tension wire bundle (1), the length of the tensile wire bundle (1) to be put therein rather than the total length of the stacked unit structures (131, 132, 133) to tension The tensile force of the line bundle 1 is applied to the unit structures (131, 132, 133) perpendicularly.

The intermediate unit structure 130 thus obtained is later stacked vertically on the lower unit structure 110 shown in FIG. At this time, the empty portion of the wedge-shaped coupling body 134 provided in the lowest layer unit structure 131 of the intermediate unit structure 130 of FIG. 5 is the highest unit structure of the lower unit structure 110 of FIG. (113) Strongly wedge-coupled to the top end binder 12 protruding above the top.

Finally, the upper unit structure will be described with reference to FIG. 6. FIG. 6 is a schematic longitudinal cross-sectional view of the upper unit structure of FIG. 3.

As shown in FIG. 6, the upper unit structure 150 has a lowest layer unit structure 151, an intermediate layer unit structure 152, and a highest layer unit structure 153 that are sequentially stacked vertically.

Since the lowest layer unit structure 151 and the middle layer unit structure 152 have the same configuration as the lowest layer unit structure 131 and the middle layer unit structure 132 described with reference to FIG. 5, description thereof will be omitted to avoid duplication of description.

The top layer unit structure 153 is provided in the upper end so that the wedge-shaped coupling body 154 in which the upper end binding body 52 which binds the tensile wire bundle 1 is wedge-coupled is located at the center. At this time, the wedge-shaped coupling body 154 has the same configuration as that applied to the lowest layer unit structure of FIG.

The lowest layer unit structure 151, the middle layer unit structure 152, and the highest layer unit structure 153 stacked vertically are firmly coupled to each other by the tensile wire bundle 1. The lower end binding body (51), which is bound to the lower end of the tension wire bundle (1), is wedge-coupled vertically by heavy weight to the wedge-shaped coupling body (154) provided in the lowest layer unit structure (151), and the tension wire bundle (1). The upper end binding body 52, which is bound to the upper end of the upper end unit structure 153 is to be spread over the top.

At this time, the upper end binder 52 bound to the upper end of the tension wire bundle (1) is provided with a binding plate 53 having a size enough to span the upper surface of the unit structure 153, the lower end binding member 51 is It is in the unit structure 153. In addition, in order to ensure that the unit structures 151, 152 and 153 are firmly coupled by the tension wire bundle 1, the length of the tensile wire bundle 1 that is put therein is slightly shorter than the length of the stacked unit structures 151, 152 and 153. Tensile force of the bundle 1 is applied to each unit structure (151, 152, 153).

FIG. 7 is a schematic cross-sectional view of a unit structure of any one layer which may be obtained along the line A-A of FIGS. 4 to 6.

As shown in FIG. 7, four reinforcing bars 2 are positioned near four corners of the rectangular unit structure. The rebar guide 115 is composed of a circular fitting portion 116 into which the thick reinforcing bars 2 are fitted and a joint portion 117 connecting the fitting portions 116 to each other. Reinforcing bars (3) going around the thick rebar (2) can be seen planted.

7 illustrates a unit structure having a rectangular cross section, in contrast, the unit structure may have a circular cross section as shown in FIG. 8.

As shown in FIG. 8, the reinforcing bar guide 115 is provided so that four coarse bars 2 may be located in the circular unit structure. The rebar guide 115 is composed of a circular fitting portion 116 into which the thick reinforcing bars 2 are fitted and a joint portion 117 connecting the fitting portions 116 to each other. Reinforcing bars (3) going around the thick rebar (2) can be seen planted.

The method of constructing the precast concrete structure of the present invention will be briefly described with reference to FIG. 1 again.

First, as shown in FIG. 4, the lowest unit structure 111, the middle layer unit structure 112, and the highest layer unit structure 113 are stacked vertically in order to form the lower unit structure 110.

Next, as shown in FIG. 5, the lowest unit structure 131, the middle layer unit structure 132, and the highest layer unit structure 133 are vertically stacked in order to form the intermediate unit structure 130.

Next, as shown in FIG. 6, the lowest unit structure 151, the middle layer unit structure 152, and the highest layer unit structure 153 are stacked vertically in order to form the upper unit structure 150.

Finally, the middle unit structure 130 is vertically stacked directly on the lowest layer unit structure 111, and the upper unit structure 150 is stacked again on the middle unit structure 130.

Here, only one intermediate unit structure 130 is applied, but the number of intermediate unit structures 130 may vary according to the height of the structure to be constructed.

As described above with reference to the preferred embodiment of the present invention with respect to the concrete pile head reinforcement, it will be apparent to those skilled in the art that various changes, modifications or modifications are possible without departing from the spirit of the present invention.

100: precast concrete structure 110: subunit structure
111, 131, 151: lowest floor unit structure 112, 132, 152: middle floor unit structure
113, 133, 153: highest layer unit structure 114, 134, 154: wedge-shaped assembly
115: reinforcing bar guide 116: reinforcing bar binder
130: intermediate unit structure 150: upper unit structure

Claims (13)

A lower unit structure (110) having a lowest layer unit structure (111), an intermediate layer unit structure (112), and a highest layer unit structure (113) stacked vertically so as to be wedge-coupled with each other;
An intermediate unit structure 130 having a lowest layer unit structure 131, an intermediate layer unit structure 132, and a highest layer unit structure 133 stacked vertically so as to be wedge-coupled with each other in order; And
Including the upper unit structure 150 having the lowest layer unit structure 151, the middle layer unit structure 152 and the highest layer unit structure 153 are stacked vertically to be wedge-coupled with each other in order,
The intermediate unit structure 130 is vertically stacked directly on the lower unit structure 110, and the upper unit structure 150 is vertically stacked directly on the intermediate unit structure 130, and the lower unit structure 110 is disposed. ), The intermediate unit structure 130 and the upper unit structure 150 is a precast concrete structure, characterized in that more tightly coupled by the tension wire bundle (1) penetrating therein, respectively.
According to claim 1, wherein all the unit structures constituting the lower unit structure 110, the intermediate unit structure 130 and the upper unit structure 150 is a guide for guiding the insertion of a plurality of coarse bars (2) ( Precast concrete structure, characterized in that each 115 is provided.
According to claim 2, The reinforcing bar guide 115 is a plurality of fitting portion 116 into which the plurality of thick reinforcing bars (2) and the fitting portion 117 connecting the plurality of fitting portions 116 to each other Precast concrete structure, characterized in that configured.
delete According to claim 1, wherein the lowest layer unit structure (111) is provided in the lower end so that the wedge-shaped coupling body (114) is wedge-coupled to the lower end binder (11) for binding the tension wire bundle (1). Precast concrete structure characterized in.
According to claim 1, The intermediate layer unit structure 112 is a plurality of reinforcing rods 116, the wedge-bonded a plurality of coarse reinforcement (2) at the lower end to be located in the periphery of the through hole through which the tension wire bundle (1) passes Precast concrete structure, characterized in that is provided.
7. The precast concrete structure according to claim 6, wherein the plurality of reinforcing bar binders (116) have a shape in which the upper part is erected upright and the lower part is inverted.
The precast concrete structure according to claim 1, wherein the highest layer unit structure (113) has the same configuration as the middle layer unit structure (112).
According to claim 1, The lowest layer unit structure 131 is provided in the lower end so that the wedge-shaped coupling body 134 is wedge-coupled to the lower end binding body 31 for binding the tension wire bundle (1), The wedge-shaped coupling body 134 is a precast concrete structure, characterized in that the upper portion has a straight shape and the lower portion is made up of a pair each upside down.
10. The method of claim 9, wherein the upper end of the lower binding unit 31 is fitted to the bottom layer unit structure 131 is wedge-bound, the lower portion of the other bundle line protruding above the upper layer unit structure 113 Precast concrete structure, characterized in that the upper end binding body (12) binding the wedge binding.
According to claim 1, wherein the top layer unit structure 153 is provided to stand upside down in the upper end so that the wedge-shaped coupling body 154, the upper end binding body 52 for binding the tension wire bundle (1) is located at the center. Precast concrete structure, characterized in that.
(A) forming a lower unit structure 110 by vertically stacking the lowest layer unit structure 111, the middle layer unit structure 112, and the highest layer unit structure 113 in order;
(B) forming a middle unit structure 130 by vertically stacking the lowest layer unit structure 131, the middle layer unit structure 132, and the highest layer unit structure 133 in order;
(C) forming the upper unit structure 150 by vertically stacking the lowest layer unit structure 151, the middle layer unit structure 152, and the highest layer unit structure 153 in order; And
(D) vertically stacking the intermediate unit structure 130 directly on the lower unit structure 110, and the upper unit structure 150 again stacked on the intermediate unit structure 130, free Construction method of cast concrete structure.
The method of claim 12, wherein the number of the intermediate unit structures 130 is varied according to the height of the structure to be constructed.

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