KR101041435B1 - Slab constructure using integrated girders for arched slabes - Google Patents

Abstract

PURPOSE: A slab structure using an integrated girder for an arch-shaped slab is provided to improve assembling efficiency and constructability by applying an arch-shaped slab to a precast concrete construction method and to improve waterproofing efficiency using a precast panel. CONSTITUTION: A slab structure(100) using an integrated girder for an arch-shaped slab contains: a floor slab(110); plural outer columns(104) arranged on the edge of the floor slab; plural precast inner columns(102) arranged on the inside of the floor slab; an inner girder(112) arranged on the upper side of the precast inner column and formed lengthy in the longitudinal direction; an outer girder(114) arranged parallel to the inner girder on the upper part of the outer column and formed lengthy in the longitudinal direction; an arch-shaped slab(116) arranged between the inner girder and the outer girder, or, the inner girder and the inner girder; a longitudinal side wall(108) arranged parallel to the inner girder between the outer columns; a horizontal side wall(106) arranged perpendicular to the inner girder between the outer columns; and an integral placing portion formed by coupling the precast inner column, the inner girder and the end of the arch-shaped slab, or, the outer column, the outer girder and the arch-shaped slab integrally using concrete.

Description

Slab constructure using integrated girders for arched slabes

The present invention relates to a slab structure using an integrated girder for an arcuate slab, and more particularly, to a technique that can improve the assembly and workability by applying the arcuate slab to the PC method.

In the case of slab structures that are installed underground, such as rainwater storage tanks and underground parking lots, there is a horizontal slab, and the construction of columns, slabs, and girders depends on site casting by formwork.

Such a site casting method has a problem in that construction time is long because it has to go through curing process by formwork. On the contrary, in the case of a PC method that can be easily assembled, even though the workability is excellent, the reliability of waterproofness is low.

In addition, although the arcuate slab is structurally advantageous to the load over the horizontal slab, the construction method using the same in the PC method has not yet been disclosed.

An object of the present invention devised to solve the above problems, relates to a technique that can improve the assembly and workability by applying the arcuate slab to the PC method.

Still another object of the present invention is to propose a construction method which can improve waterproofness using a PC panel.

The present invention for achieving the above object, the floor slab forming a floor; A plurality of outer columns disposed at edges of the floor slab; A plurality of PC inner pillars disposed inside the bottom slab; A longitudinally long inner girder disposed on the upper portion of the PC inner pillar; An outer girder arranged in parallel with the inner girder and extending in a longitudinal direction on an upper side of the outer column; An arcuate slab disposed between the inner girder and the outer girder or between the inner girder and the inner girder adjacent to each other; A longitudinal wall disposed in parallel with the inner girder between the outer columns; A transverse wall disposed at right angles to the inner girder between the outer columns; And a slab structure using an integral girder for an arched slab including an integral placing portion in which the PC inner pillar and the inner girder and the end of the arcuate slab or the outer pillar and the outer girder and the end of the arcuate slab are integrally combined with concrete. to be.

In addition, another form of the slab structure, the bottom slab to form a floor; A plurality of PC inner pillars disposed inside the bottom slab; A longitudinally long inner girder disposed on the upper portion of the PC inner pillar; A vertical wall disposed at an edge of the floor slab in parallel with the inner girder; A transverse wall disposed at an edge of the floor slab in a direction perpendicular to the inner girder; An outer girder disposed parallel to the inner girder and extending in a longitudinal direction on an upper portion of the lateral wall; An arcuate slab disposed between the inner girder and the outer girder or between the inner girder and the inner girder adjacent to each other; The PC inner pillar and the inner girder and the end of the arcuate slab, or the outer girder and the end of the arcuate slab includes an integral casting portion integrally coupled to the concrete.

The inner girder includes a junction formed in contact with the upper portion of the PC inner pillar in the longitudinal direction; A communication port formed at the junction and communicating with the hollow of the PC inner pillar; A girder placing portion formed on an upper side of the junction portion and having a space communicating with the communication hole; And an inner slab seat formed on both sides of the girder placing portion to support the end of the arcuate slab in contact with the end.

In addition, the outer girder, the junction formed long in the longitudinal direction; A girder placing portion having a space therein formed above the junction portion; And an outer slab seat formed at one side of the girder placing part and supporting the end of the arcuate slab.

In addition, the column reinforcing bar installed in the hollow of the PC inner pillar is characterized in that it extends to the girder placing portion through the communication port.

In addition, the slab reinforcing bar exposed at the end of the adjacent arcuate slabs are characterized in that they are connected to each other by a connecting bar on the upper side of the inner girder.

In addition, the lateral side wall or the longitudinal side wall is formed between the L-shaped support portion fixed to the bottom slab, the PC panel disposed at intervals with a fixing bolt with respect to the L-shaped support portion, and formed between the PC panel and the L-shaped support portion Characterized in that it comprises a wall pour portion to form the concrete in the space to be cast.

In the slab structure, a rainwater storage tank may be configured by including a rainwater induction part installed on the horizontal wall or the vertical wall.

And, the filtering plate for dividing the space inside the slab structure to primarily filter the rainwater supplied from the rainwater induction portion is disposed, or connected to the rainwater induction portion and includes a filter box disposed in the interior space of the slab structure Can be.

Through the present invention, it is possible to construct slab structures such as rainwater storage tanks and underground parking lots that have been relied on site casting by formwork until now.

In addition, by presenting a construction method of integrating an arcuate slab with a PC column and a PC girder, it is possible to improve the assembly and workability while increasing the structural strength of the slab structure.

1 is an exploded perspective view of a slab structure having an arcuate slab according to the first embodiment of the present invention.
Figure 2 is a schematic diagram showing the arrangement of the floor slab and the PC pillar of the slab structure of FIG.
3 is a partially enlarged cross-sectional view illustrating a coupling relationship between an arcuate slab, a PC column, and a PC girder in the slab structure of FIG. 1.
FIG. 4 is a partially enlarged cross-sectional view of an arched slab, a PC pillar, and a PC girder that are cured by concrete in the slab structure of FIG. 1.
5 is a cross-sectional view of the transverse wall in the slab structure of FIG. 1.
6 is a cross-sectional view of the longitudinal wall in the slab structure of FIG. 1.
7 is an exploded perspective view of a rainwater storage tank having an arcuate slab according to the second embodiment of the present invention.
8 is an exploded perspective view of a rainwater storage tank having an arcuate slab according to the third embodiment of the present invention.
9 is an exploded perspective view of a rainwater storage tank having an arcuate slab according to the fourth embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In adding reference numerals to components of the following drawings, it is determined that the same components have the same reference numerals as much as possible even if displayed on different drawings, and it is determined that they may unnecessarily obscure the subject matter of the present invention. Detailed descriptions of well-known functions and configurations will be omitted.

1 is an exploded perspective view of a slab structure 100 having an arcuate slab 116 according to the first embodiment of the present invention.

The slab structure 100 is characterized by the structure of the girders 112 and 114 capable of supporting the arcuate slab 116 and the waterproof construction method of the transverse side wall 106 and the longitudinal side wall 108.

The slab structure 100 having such a characteristic includes a bottom slab 110 forming a floor, a plurality of outer pillars 104 disposed at an edge of the bottom slab 110, and an inner side of the bottom slab 100. A plurality of PC inner pillars 102 to be disposed, an inner girder 112 longitudinally disposed above the PC inner pillars 102, and the inner girder 112 on the outer pillars 104. Arranged slab 116 disposed in parallel to the longitudinal and the longitudinal longitudinal girder 114, the inner girder 112 and the outer girder 114 adjacent to each other or between the inner girder 112 and the inner girder 1120 ), A vertical side wall 108 disposed in parallel with the inner girder 112 between the outer column 104 and the inner girder 112 at right angles between the outer column 104. The transverse side wall 106, the PC inner pillar 102, the inner girder 112 and the arched chain An end portion of the slab 116 or the outer pillar 104 and the outer girder 114 and the end of the arcuate slab 116 includes an integral casting portion 150 integrally coupled to the concrete.

As shown in FIG. 2, the bottom slab 110 is provided with a PC inner pillar 102 and an outer pillar 104. That is, the outer column 104 is disposed along the peripheral edge of the bottom slab 110, and the inner PC column 102 is disposed inside. The inner column 102 of the PC has the advantage of having a high strength and light weight by having a hollow inside by forming a circular cross section by centrifugal casting. However, in the case of the edge, it is preferable to arrange the outer column 104 having a rectangular cross section so as to advantageously form a wall.

When the PC inner pillar 102 is circular, a quadrangular girder portion 103 may be formed on the upper side thereof so as to easily mount the inner girder 112. As shown in FIGS. 1 and 3, the girder portion 103 has a through hole communicating with the hollow 105 of the PC inner pillar 102.

The outer column 104 may use a product previously produced at the factory in the form of a PC column, or may be poured by formwork in the field.

The inner girder 112 is in contact with the girder portion 103 formed on the upper portion of the PC inner pillar 102 and formed in the longitudinal direction and the junction portion 128 formed in the junction portion 128 to the PC inner pillar 102 Girder placing portion 132 and the girder placing portion 132 having a space in communication with the communication hole 130, the communication port 130 and the communication hole 130 formed on the upper side of the hollow 105 It is formed on both sides of the 132 and comprises an inner slab seat 126 in contact with and supported by the end of the arcuate slab 116.

Accordingly, the inner girder 112 is formed in a substantially U shape, as shown in FIG. 3, and the inner slab seat 126 is formed to be inclined to both upper sides thereof.

In addition, the column reinforcement 124 installed in the hollow 105 of the PC inner pillar 102 extends through the communication port 130 to the girder placing portion 132. Therefore, when later poured by concrete, the joining effect is raised by the column reinforcing bars 124.

The arcuate slab 116 is inserted into the slab reinforcement (118, 120) to reinforce the tensile force. Among them, the slab reinforcement 120 disposed on the upper side is exposed to the outside, and is connected by the slab reinforcement 120 and the connecting reinforcement 122 of the other arched slab 116. Accordingly, the stress of the arcuate slab 116 may be transmitted along the slab reinforcement 120 and the connecting reinforcement 122. The connecting reinforcement 122 is disposed above the inner girder 112. The connection method of the connecting reinforcement 122 and the slab reinforcement 120 can be simply used welding, forming a separate thread on the end of the connecting reinforcement 122 and the slab reinforcement 120 to form a separate coupler It is also possible to use.

By the above configuration, the hollow 105 of the PC inner pillar 102, the girder placing portion 132 of the inner girder 112, and the pouring place 119 of the arcuate slab 116 When the concrete is poured into the space to be formed, as shown in Figure 4, to the one reinforcement portion 150 reinforced by the column reinforcement 124, the connecting reinforcement 122, the slab reinforcement 120 Are bonded.

In addition, the outer girder 114 is in contact with the upper portion of the outer column 104 and formed in the longitudinal direction elongated, the girder placing portion 113 is formed on the upper side of the junction portion 117 to have a space therein And an outer slab seat 115 formed at one side of the girder placing part 113 to be in contact with and supported by an end of the arcuate slab 116.

Unlike the inner girder 112, the outer girder 114 is not integrally coupled to the outer pillar 104 and concrete, but is fixed by the coupling pin 140 on the upper end of the transverse side wall 106. Therefore, the integral placing part 150 formed in the outer girder 114 is formed in a space between the girder placing part 113 of the outer girder 114 and the placing place 119 of the arcuate slab 116. .

The lateral side wall 106 or the longitudinal side wall 108 is an L-shaped support part fixed to the bottom slab 110 and PC panels 136 and 144 spaced apart from each other by fixing bolts 138 and 146 with respect to the L-shaped support part. And wall pouring parts 134 and 142 formed by injecting concrete into a space formed between the PC panels 136 and 144 and the L-shaped support part.

The wall placing parts 134 and 142 may improve the waterproof property of the slab structure 100 by placing the PC panels 136 and 144 in place of the formwork.

The lateral side wall 106 and the longitudinal side wall 108 is substantially the same structure, the lateral side wall 106 is the outer girder 114 is disposed on top, the longitudinal side wall 106 is the arcuate slab ( It is formed convexly upward as shown in FIG. 1 to fill the arch space formed by 116.

In addition, as shown in Figure 9, it is possible to be configured to replace the role of the pillar itself without the outer pillar between the transverse wall 406 and the longitudinal wall 408. In this case, there is no need to configure the outer column separately, which reduces the number of processes and can also expand the internal space, making it economical.

The slab structure 100 according to the first embodiment of the present invention is basically configured as described above. Hereinafter, the construction method of the slab spheres 100 will be described.

First, the bottom slab 110 is installed together with the L-shaped support portion, the PC inner pillar 102, and the outer pillar 104. Then, in order to form the lateral side wall 106 and the longitudinal side wall 108, the PC panels 136, 144 at intervals of the installation by the fixing bolts (138, 140) to the outside of the L-shaped support portion, the interval The concrete is poured into the space created and cured.

Next, the inner girder 112 is disposed on the PC inner pillar 102, and the outer girder 114 is disposed on the outer pillar 104. Thereafter, the arcuate slab 116 is arranged between the inner girder 112 and the inner girder 112 or between the inner girder 112 and the outer girder 114. In addition, the slab reinforcement 120 protruding from the arcuate slab 116 is connected to the adjacent slab reinforcement 120 and the connecting reinforcement 122.

Then, the concrete is supplied to the upper side of the inner girder 112, the pouring place 119 of the arcuate slab 116, the girder placing portion 132 of the inner girder 112, and the PC inner pillar ( The hollow 105 of 102 is integrally coupled. In addition, by supplying concrete to the upper side of the outer girder 114, the pouring place 119 of the arcuate slab 116 and the girder placing portion 132 of the outer girder 114 is integrally coupled. Finally, the concrete is fed into the upper side of the longitudinal wall 108 and cured so as to close the free space generated between the upper side of the longitudinal wall 108 and the arcuate slab 116.

7 shows a rainwater storage tank 200 according to the second embodiment of the present invention, the rainwater storage tank 200 has the same structure as the slab structure 100, the outside to have a feature as a rainwater storage tank It includes a rainwater induction portion 252 and the filter plate 254 from which rainwater flows from.

The rainwater induction part 252 may be configured in the form of a duct, and thus a detailed description thereof will be omitted.

The filtration plate 254 divides the internal space, and the rainwater supplied to the space between the filtration plate 254 and the rainwater induction part 252 is slowly filtered through the filtration plate 254 over time, and thus, primary. Perform regular cleansing functions. As the filtration plate 254, a known zeolite may be used.

In addition, adapters 256 and 258 may be installed on both sides of the filtering plate 254 to install the filtering plate 254 on the PC inner pillar 202 and the PC outer pillar 204.

8 shows the rainwater storage tank 300 according to the third embodiment of the present invention, the rainwater storage tank 200 has the same structure as the slab structure 100, and the rainwater storage tank 200 of the second embodiment Otherwise, the filter box 354 instead of the filter plate is connected to the rainwater induction part 252 and disposed in the space of the rainwater storage tank 300. Rainwater storage tank 300 of the third embodiment is characterized in that the workability is advantageous compared to the rainwater storage tank 200 of the second embodiment.

The filter box 354 may be manufactured using a zeolite, and the front surface of the filter box 354 is closed except for a portion communicating with the rainwater induction part 252. Therefore, the rainwater supplied by the rainwater induction part 252 is primarily filtered by the filter box 354 and then supplied to the internal space of the rainwater storage tank 300.

As described above, it has been described with reference to the preferred embodiment of the present invention, but those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the present invention described in the claims below I can understand that you can.

100,400: slab structure 102,202,302,402: PC inner column
103: girdling
104,204,304,404: Outer column 105: Hollow
106,206,306,406: transverse walls 108,208,308,408: longitudinal walls
110,210,310,410: Floor slab 112,212,312,412: Interior girder
113,132: Girder placing section 114,214,314,414: External girder
115: outer slab seat 126: inner slab seat
116,216,316,416: arched slabs
117,128: junction 118,120: girder reinforcement
119: pouring place 122: connecting rod
124: column reinforcement 130: communication hole
134,142: Wall casting part 136,144: PC panel
138,146: Fixing bolt 140,148: Coupling pin
150: integrated plate 200,300: rainwater storage tank
252, 352: rainwater induction part 254: filtration plate
256,258: Adapter 354: Filter box

Claims (10)

Floor slabs that form the floor;
A plurality of outer columns disposed at edges of the floor slab;
A plurality of PC inner pillars disposed inside the bottom slab;
A longitudinally long inner girder disposed on the upper portion of the PC inner pillar;
An outer girder arranged in parallel with the inner girder and extending in a longitudinal direction on an upper side of the outer column;
An arcuate slab disposed between the inner girder and the outer girder or between the inner girder and the inner girder adjacent to each other;
A longitudinal wall disposed in parallel with the inner girder between the outer columns;
A transverse wall disposed at right angles to the inner girder between the outer columns; And
And an integral casting portion in which the PC inner pillar and the inner girder and the end of the arcuate slab or the outer pillar and the outer girder and the end of the arcuate slab are integrally combined with concrete.
The inner girder includes a junction formed in contact with the upper portion of the PC inner pillar in the longitudinal direction;
A communication port formed at the junction and communicating with the hollow of the PC inner pillar;
A girder placing portion formed on an upper side of the junction portion and having a space communicating with the communication hole; And
Slab structure using an integrated girder for an arc-shaped slab, characterized in that formed on both sides of the girder placing portion and including an inner slab seat in contact with and supported by the end of the arcuate slab.
Floor slabs that form the floor;
A plurality of PC inner pillars disposed inside the bottom slab;
A longitudinally long inner girder disposed on the upper portion of the PC inner pillar;
A vertical wall disposed at an edge of the floor slab in parallel with the inner girder;
A transverse wall disposed at an edge of the floor slab in a direction perpendicular to the inner girder;
An outer girder disposed parallel to the inner girder and extending in a longitudinal direction on an upper portion of the lateral wall;
An arcuate slab disposed between the inner girder and the outer girder or between the inner girder and the inner girder adjacent to each other;
And an integral casting portion in which the PC inner pillar and the inner girder and the end of the arcuate slab, or the outer girder and the end of the arcuate slab are integrally combined with concrete,
The inner girder includes a junction formed in contact with the upper portion of the PC inner pillar in the longitudinal direction;
A communication port formed at the junction and communicating with the hollow of the PC inner pillar;
A girder placing portion formed on an upper side of the junction portion and having a space communicating with the communication hole; And
Slab structure using an integrated girder for an arc-shaped slab, characterized in that formed on both sides of the girder placing portion and including an inner slab seat in contact with and supported by the end of the arcuate slab.
delete According to claim 1 or 2, wherein the outer girder,
Long junction formed in the longitudinal direction;
A girder placing portion having a space therein formed above the junction portion; And
The slab structure using an integrated girder for an arcuate slab, characterized in that it comprises an outer slab seat formed on one side of the girder placing portion in contact with the end of the arcuate slab.
The slab structure according to claim 1 or 2, wherein the column reinforcing bar installed in the hollow of the PC inner pillar extends through the communication port to the girder placing section.
The slab structure according to claim 1 or 2, wherein the slab bars exposed at the ends of adjacent arcuate slabs are connected to each other by connecting bars at an upper side of the inner girder.
According to claim 1 or 2, wherein the horizontal wall or the vertical wall is an L-shaped support portion fixed to the bottom slab, PC panels arranged at intervals with a fixed bolt relative to the L-shaped support portion, and the PC panel Slab structure using an integral girder for an arc-shaped slab, characterized in that it comprises a wall cast portion to form the concrete cast in the space formed between the L-shaped support.
In the rainwater storage tank using the slab structure of claim 1,
Rainwater storage tank, characterized in that it comprises a rainwater induction portion installed on the horizontal wall or the vertical wall.
9. The rainwater storage tank according to claim 8, wherein a filtration plate for dividing the space inside the slab structure is arranged to primarily filter rainwater supplied from the rainwater induction part.
The rainwater storage tank according to claim 8, further comprising a filter box connected to the rainwater induction part and disposed in an inner space of the slab structure.

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