KR101984292B1 - Building Core System using Precast Concrete Panel with Column - Google Patents

Abstract

The present invention relates to a core system using a variable PC module integrated with a column and a wall, and more specifically, relates to a core system using a variable PC module integrated with a column and a wall, wherein a PC wall block is formed so as to integrally constitute a column having a wall and a step on both sides of a wall body, and enables construction by laminating without joining the column, the wall, and the like. According to one preferred embodiment of the present invention, the variable PC module integrated with a column and a wall has: a wall; and a column which is integrated with the wall on both sides of the wall and having one side or both sides formed to be shorter than the height of the wall so as to have a different height from the wall.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a core system using a flexible PC module,

The present invention relates to a core system using a variable type PC module in which a pillar and a wall are integrated. More specifically, a PC wall block is formed on both sides of a wall so that a pillar having a step and a step is integrally formed, The present invention relates to a core system using a variable-type PC module in which a column and a wall are integrated so that the construction can be performed without laminating without performing a joining process.

Typically, the core of a building is a structural element that concentrates the vertical traffic system and the energy supply system to form one or several cores as a concrete shear wall structure to stabilize the horizontal stability of the building.

The member that transfers the lateral force to the core acts as a structure and a bottom plate slab to act as a large concrete pipe-like core and surrounding frame as a structure. The core part of the building is an integral structure using reinforced concrete and concrete, and the RC method suitable for the refractory structure is widely applied.

However, such an RC method has problems such as difficulty in securing quality and delay in air due to difficulty in precision construction compared to the PC method. In order to solve the problems of the RC method, a precast wall is manufactured and a core is constructed , The horizontal connection between the wall made by PC and the horizontal connection at the time of construction of the PC wall is excessive due to the excessive joining part because of the excessive joining process at the time of construction of the PC wall and the installation time is long and it is difficult to secure the construction quality and the fireproof performance. There was a weak point in stability.

As a background of the present invention, Patent Publication No. 2012-0003172 entitled " Method of constructing a structure core part of a module lamination method " (patent document 1) is known. In the background art, a core structure 10 including an elevator chamber 11 and a staircase 12 having an inclined plate 13a and a staircase 13b is formed in the form of a standardized module, And the supporting beams 14 of the respective core structures 10 are fastened and assembled to each other by fastening members. The present invention is also directed to a method of constructing a core structure of a module lamination type.

However, the background art has a problem in that it is not utilized as a lateral force resisting element because it has a problem such as a remarkable decrease in the lateral force resistance performance and a lack of reliability of the connection strength of the PC unit.

Patent Publication No. 2012-0003172 " Method of constructing a core part of a module laminated structure &

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems, and it is an object of the present invention to provide a PC wall block so that columns having walls and steps are integrally formed on both sides of a wall, It is possible to minimize the follow-up process, and it is possible to increase the structural stability by allowing the construction of the PC wall blocks to be laminated, and the construction period of the core system can be drastically shortened because the column and the wall can be simultaneously constructed. , It is possible to construct core structures of various shapes without any restriction, and it is also possible to secure the vertical passage of the operator through early construction of the core and to secure the core system using the variable type PC module in which the column and the wall are integrated to resist the lateral force The purpose is to provide.

In the variable PC module in which the pillars and the wall are integrated, the pillars 11 are formed on the lower end of both side ends of the wall body 12, A movable PC module 10b in which a column and a wall are integrated up to a predetermined height of the height of the wall 12 at the upper end of both side ends of the wall 12, And the column 11 on the other side of the wall 12 is formed at the upper end of the other end of the wall 12 at the lower end of the wall 12, A variable PC module 10c in which a column and a wall formed up to a predetermined height of a height of the wall 12 are formed integrally and a column 11 on one side of the wall 12 is formed to be shorter than a height of the wall 12 by a predetermined height, Two variable PC modules 10d and a wall 12 formed by integrating a column and a wall formed so as to have a step with the wall 12 and the wall 12, And a variable PC module 10e (10f) in which a column and a wall, in which a column 11 is integrally formed, are integrally formed on the outer surface of each of the walls 12, And the core (1) is formed by stacking the pillars (11) by selecting two or more PC modules. The core system using the variable PC module in which the pillars and the wall are integrated is provided.

delete

delete

delete

delete

delete

delete

delete

The joining buryment 30 composed of the joining sleeve 31 and the reinforcing bar 32 perpendicularly formed on the upper end of the joining sleeve 31 is formed by joining the reinforcement 32 in the vertical direction of the column 11, A plurality of reinforcing bars 32 protruding from the lower column 11 at the time of laminating the columns 11 are inserted into the joining sleeves 31 of the upper columns 11 Shrinkage mortar 33 is filled in the inside of the sleeve 31 for joining and joining the shrinkage mortar 33. The present invention provides a core system using a variable PC module in which a pillar and a wall are integrated.

The core system using the variable-type PC module in which the pillars and walls of the present invention are integrated forms a PC wall block so that pillars having steps and steps are integrally formed on both sides of the wall, , It is possible to minimize the follow-up process, and it is possible to increase the structural stability by allowing the construction of the PC wall blocks to be stacked, and the construction period of the core system can be shortened because the column and the wall can be constructed at the same time It is possible to construct core structures of various shapes regardless of the shape, and it is also very effective to secure the vertical passage of the operator through the early construction of the core, secure safety, and resist the lateral force.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention, Shall not be construed as limiting.
1 is a perspective view of a variable-type PC module in which a pillar and a wall of the present invention are integrated.
FIGS. 2-6 are perspective views of various embodiments of the variable PC module in which the pillars and walls of the present invention are integrated. FIG.
7 is a cross-sectional view taken along line AA of FIG. 1A.
8 to 9 are diagrams showing a construction procedure of an embodiment of a core system using a variable type PC module in which a pillar and a wall of the present invention are integrated.
10 is a sectional view taken along the line BB in Fig.
11 and 12 are perspective views showing an example of construction of a core system using a variable type PC module in which a pillar and a wall of the present invention are integrated.

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.

Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

FIG. 1 is a perspective view of a variable-type PC module in which a pillar and a wall of the present invention are integrated, and FIGS. 2 to 6 are perspective views of various embodiments of a variable-type PC module in which a pillar and a wall of the present invention are integrated.

The variable PC module in which the pillars and walls of the present invention are integrated includes a wall 12; And a column 11 formed integrally with the wall 12 on both sides of the wall 12 and formed so as to have a step smaller than the height of the wall 12 at one side or both sides thereof.

Particularly, in the present invention, the column 11 on one side or both sides of the wall 12 is formed to be shorter than the height of the wall 12 so as to have a step with the wall 12, The column 11 and the column 11 are laminated in the horizontal direction coupling and the vertical direction coupling of the PC module to facilitate the construction.

The cross section of the column 11 is formed to be larger than the thickness of the wall 12 so that one side of the column 11 is aligned with the inside or outside side of the wall 12, The wall 12 may be formed at the side of the center of the side wall 11.

1, the variable type PC module 10a, in which the column and the wall are integrated, has a structure in which the column 11 is divided into the column 11 and the column 11, The pillars 11 can be formed on the lower side of the wall body 12 on both sides of the wall body 12 by forming the wall body 12 up to a certain height of the height of the wall body 12 at the lower end portions of both side ends thereof, The height at which the pillars 11 are formed on the base 12 can be varied.

At this time, the wall 12 may be formed long as shown in FIG. 1A or may be formed as short as shown in FIG.

2, the variable PC module 10b in which the pillars and the wall are integrated allows the pillars 11 to be formed up to a certain height of the height of the wall 12 at the upper end of both side ends of the wall 12, The pillars 11 may be formed on the upper portion of the wall 12 on both sides of the wall 12. [

3, the variable type PC module 10c in which the pillars and the wall are integrated has a structure in which the pillars 11 on one side of the wall 12 are fixed at a predetermined height of the wall 12 at the lower end of one end of the wall 12 And the column 11 on the other side of the wall 12 is formed up to a certain height of the height of the wall 12 at the upper end of the other end of the wall 12 so that the pillars 11 Can be formed to be staggered at the upper part and the lower part.

4, the pillars 11 on one side of the pillars 11 formed on both sides of the wall 12 are formed to be shorter than the height of the wall 12 so as to have a step with the wall 12 The column 11 on the other side may be formed at the same height as the wall 12.

Particularly, as shown in FIG. 5, two walls 12 may be formed, and the pillars 11 may be integrally formed between the wall 12 and the wall 12 and on the outer surfaces of the walls 12 . 6, the column 11 may be formed to a predetermined height of the wall 12 at the lower end of the wall 12, or may be formed at the upper end of the wall 12 of the column 11 as shown in FIG. So that the wall 12 can be formed up to a certain height.

7 is a cross-sectional view taken along the line A-A in Fig.

The variable type PC module in which the column and the wall are integrated can be laminated with the column 11 and the column 11 at the time of horizontal or vertical bonding and can be bonded through various known methods. Can be embedded in the column 11 of the variable-type PC module in which the column and the wall are integrated in advance, and the column 11 and the column 11 vertically stacked can be easily joined to each other.

As shown in Fig. 7, the filling material 30 for bonding is composed of a reinforcing bar 32 which is formed perpendicularly to the joining sleeve 31 and the upper end of the joining sleeve 31. As shown in Fig.

The joining sleeve 31 can be made of a variety of known joining sleeves and can be made of a structural steel pipe or the like. The joining sleeve 31 has an outlet port and an inlet port formed at the upper portion and the lower portion thereof, So as to be exposed to the outside of the column 11. A reinforcing bar 32 having a predetermined length is joined to the upper end of the bonding sleeve 31 by various methods known for welding or the like.

The joining sleeve 31 to which the reinforcing bars 32 are joined is formed such that the lower end of the joining sleeve 31 is exposed at the lower end of the column 11 in the vertical direction of the column 11, A reinforcing bar 32 protruding from the lower column 11 is inserted into the bonding sleeve 31 at the time of stacking the columns 11 and the reinforcing bars 31 Shrinkage mortar may be filled in the inside of the shrinkage mortar for bonding.

8 to 9 are diagrams showing a construction procedure of an embodiment of a core system using a variable type PC module in which a pillar and a wall of the present invention are integrated.

As shown in FIG. 8, the core system using the variable type PC module in which the pillars and the walls of the present invention are integrated, the pillars 11 are formed on both sides of the wall 12 and the wall 12, And a column 11 integrally formed with the wall 12 so as to have a step with the wall 12. The variable PC module is assembled such that the pillars 11 are laminated to form a core 1), and the core 1 is vertically stacked.

Particularly, when forming the core 1, it is possible to construct an efficient configuration by stacking variable-type PC modules in which various shapes of pillars and walls are integrated.

In other words, the variable PC module in which the pillars and the wall are integrated is disposed in the column 11, and the variable PC module 10a (10a), in which the pillars and the wall formed up to a certain height of the height of the wall 12 from the lower end of both ends of the wall 12, The pillars 11 are composed of a variable PC module 10b in which pillars and walls are integrated up to a certain height of the height of the wall 12 at the upper end of both side ends of the wall 12, The column 11 on the other side of the wall 12 is formed at a position corresponding to the wall 12 at the upper end of the other end of the wall 12 And a column 11 formed at one side of the wall 12 is formed to be shorter than a height of the wall 12 so as to be shorter than the height of the wall 12, Two variable PC modules 10d and a wall 12 which are integrally formed with a column and a wall formed so as to have a stepped portion are formed and the wall 12 and the wall 12 And a variable PC module 10e (10f) in which a column and a wall integrally formed with a column 11 having a step with the wall 12 are formed on the outer surface of each of the walls 12, Two or more variable-type PC modules integrated with the wall may be selected and the pillars 11 may be stacked so as to form the core 1.

10, 10 (10), 10 (10), 10 (10), 10 (10), and 10 (10f) in which a column and a wall are integrated with each other are integrally formed on the core 1 as shown in FIG. (1) is repeated to complete the core system using the variable PC module in which the column and the wall are integrated.

10 is a cross-sectional view taken along line B-B of FIG.

Particularly, in the case where the embedding material 30 is formed, horizontal joining of the flexible PC modules 10a, 10b, 10c, 10d, 10e, 10f, in which the columns and the wall are integrated, The reinforcing bar 32 protruded from the lower column 11 is inserted into the bonding sleeve 31 of the upper column 11 and the non-contracting mortar 33 is filled in the bonding sleeve 31 So as to be joined.

11 and 12 are perspective views showing an example of construction of a core system using a variable type PC module in which a pillar and a wall of the present invention are integrated.

11 and 12, while the core system using the variable PC module having the above-described column and wall integrated therein is installed to ensure the vertical passage of the operator through the early construction of the core 1 and the safety of the operator, The stairs 3 and the stairs 4 formed by the PC are connected by using the reinforcing bars 32 exposed on the upper part of the column 11 by placing the PC beam 2 on the upper part of the column 11, You can complete the core system by doing the work.

As shown in Fig. 11, the landing 3 and the stairs 4 are separately manufactured, and the landing 3 is installed and the stairs 4 are connected to the upper and lower sides of the landing 3, , The step 3 and the step 4 may be integrally manufactured to be installed in the core system of the present invention.

In this embodiment, the beam 2, the landing 3, and the step 4 made of a PC (Precast Concrete) are used. However, steps and beams can be applied to the core system by using members having various structures and shapes .

In the core system using the variable PC module in which the pillar and the wall are integrated as described above, a PC wall block is formed on both sides of the wall such that pillars having a step with the wall are integrally formed, and the pillar- It is possible to minimize the follow-up process by eliminating the need for separate joining hardware, and it is possible to increase the structural stability by allowing the construction of PC wall blocks to be stacked, and to construct the columns and walls at the same time. It is possible to construct a core structure of various shapes regardless of the shape, and it is also very effective to secure the vertical passage of the operator through the early construction of the core, secure safety, and resist the lateral force.

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.

1: Core
10a, 10b, 10c, 10d, 10e, and 10f: a variable-type PC module in which a column and a wall are integrated
11: Column
12: Wall
30: Fill for joint
31: Sleeve for bonding
32: Rebar
33: Non-shrink mortar
2:
3: Landing
4: Stairs

Claims (9)

delete delete delete delete delete delete delete The variable-type PC module, in which the column and the wall are integrated,
The pillars 11 include a flexible PC module 10a in which pillars and walls are integrated up to a certain height of the height of the wall 12 at the lower end of both side ends of the wall 12,
The pillars 11 include a variable type PC module 10b in which pillars and walls formed up to a certain height of the height of the wall body 12 at the upper end of both side ends of the wall body 12 are integrated,
The column 11 at one side of the wall 12 is formed to a predetermined height of the height of the wall 12 at the lower end of one end of the wall 12 and the column 11 at the other side of the wall 12 is formed in the wall 12, A variable type PC module 10c in which a column and a wall formed up to a predetermined height of the height of the wall 12 at the upper end of the other end are integrated,
A variable PC module 10d in which a column 11 at one side of the wall 12 is formed to be shorter than a height of the wall 12 by a predetermined height so that a column and a wall formed to have a step with the wall 12 are integrated,
Two variable wall PC units 10e (10e, 10e, 10e, 10e, 10e, 10e, 10e, 10e, 10e, and 10e) in which a column and a wall are integrally formed are integrally formed on the outer surface of the wall 12 and between the wall 12 and the wall 12, ) 10f,
Wherein the core (1) is formed by stacking the pillars (11) by selecting at least two variable-type PC modules in which the pillars and the wall are integrated, thereby forming the core (1). The method of claim 8,
The joining filler 30 formed of the joining sleeve 31 and the reinforcing bar 32 formed perpendicularly to the upper end of the joining sleeve 31,
A plurality of reinforcing bars 32 protrude by a predetermined length from the upper end of the column 11 in the vertical direction of the column 11,
The reinforcing bars 32 protruding from the lower column 11 are inserted into the joining sleeves 31 of the upper columns 11 at the time of stacking the columns 11 and non-shrinking mortars 33 ) Is filled and joined to each other. The core system using the variable-type PC module in which the pillars and the wall are integrated.

Images