KR101090306B1 - Pc slab-wall connection structure and construction method thereof - Google Patents

Abstract

The present invention includes a lower PC wall (100) formed so that the upper end of the lower cast iron 110 embedded therein protrudes upward; A pair of PC slabs 200 whose ends are placed on both edges of the upper surface of the lower PC wall 100; An upper PC reinforcement 310 embedded therein and an upper PC wall 300 installed on an upper portion of the pair of PC slabs 200; A main reinforcing bar connecting member 400 embedded in the upper PC wall 300 so that the upper end is coupled to the lower end of the upper main reinforcing bar 310 and the lower end is coupled to the upper end of the lower main reinforcing bar 110; By presenting a PC wall-slab coupling structure comprising; a topping concrete 210 placed in the space between the upper and upper PC walls 300 and the lower PC wall 100 of the pair of PC slabs 200, By taking the bonded structure, it is possible to precisely construct while securing structural stability, to shorten the construction time, to secure excellent workability while using topping concrete with low construction time, and to reduce the thickness of the PC wall. .

Pre-Cast, Wall, Slab

Description

PC wall-slab connection structure and construction method {PC SLAB-WALL CONNECTION STRUCTURE AND CONSTRUCTION METHOD THEREOF}

TECHNICAL FIELD The present invention relates to the field of construction, and in particular, to a coupling structure of a PC wall and a PC slab.

The construction method of building structure by assembling PC (Pre-Cast) member has advantages such as fast and simple construction and high quality reliability because it uses PC member by factory production.

Figure 1 shows the structure of a conventional PC wall-slab coupling structure (pin junction structure).

Ends of the pair of slabs 20 are respectively placed on the upper edge of the lower wall 10, and the upper wall 30 is installed on the upper side thereof, and then finished by pouring the leveling concrete 21.

The ends of the main reinforcing bars 11 of the lower wall 10, the main reinforcing bars 31 of the upper wall 30, and the tensile bars 22 and 23 of the slab 20 are machined and joined in a circular shape, and a pin 40 in the center thereof. ) Is inserted.

However, such a conventional structure has been pointed out as a problem in the following points.

First, since it is basically a pin joint structure rather than a steel joint structure, the lower wall 10 and the upper wall 30 can be bent around the pin 40, bar structural stability is weak.

Second, because the joint structure of the rebar is complicated, it is difficult to precise construction, the construction time is long.

Third, the leveling concrete should be used that has almost no slump, which is because the construction year is low, workability is further reduced when applied to the joint structure of the reinforcing bar as in the prior art.

Fourth, the pin 40 installed in the center portion of the reinforcing bar structure is structurally meaningless.

Fifth, the thickness of the lower wall 10 and the upper wall 30 excessively increases.

In order to achieve the above-mentioned reinforcing bar structure, the rebars should be bent 360 degrees between the slabs 20 on both sides. Since the bend radius of D16 or D19 is more than 3db, a space of at least 13-15 cm is required for the commonly used D16. Required.

At this time, adding 5cm to the spacing of both slabs on the wall, the wall width is 25cm.

Therefore, even in the case of a building having a sufficient wall thickness of 12-15cm in the low-rise wall structure, 25cm thick wall is used to apply the above-mentioned reinforcing bar structure, PC quantity is increased about twice.

In addition, SD400 rebar, which is commonly used as a main reinforcing material in Korea, causes a decrease in strength when bent at 360 degrees, requires a 4db radius, and is difficult to work with.

The present invention has been derived to solve the above problems, take the steel joint structure to ensure structural stability while ensuring structural stability, can shorten the construction time, excellent work while using topping concrete with low construction years The purpose of the present invention is to propose a PC wall-slab coupling structure and a construction method thereof, which can secure the characteristics and reduce the thickness of the PC wall.

The present invention, in order to achieve the object described above, the lower PC wall 100 is formed so that the upper end of the lower cast iron reinforcement 110 is embedded therein; A pair of PC slabs 200 whose ends are placed on both edges of the upper surface of the lower PC wall 100; An upper PC reinforcement 310 embedded therein and an upper PC wall 300 installed on an upper portion of the pair of PC slabs 200; A main reinforcing bar connecting member 400 embedded in the upper PC wall 300 such that an upper end is coupled to a lower end of the upper main reinforcing bar 310 and a lower end is coupled to an upper end of the lower main reinforcing bar 110; Presenting a PC wall-slab coupling structure comprising; a topping concrete 210 placed in the upper portion of the pair of PC slab 200 and the space between the upper PC wall 300 and the lower PC wall 100. .

It is preferable that the tensile reinforcing bars 220 are installed on the upper surface of the pair of PC slabs 200, and the reinforcing bars 220 are embedded in the topping concrete 210.

A plurality of protrusions 320 are formed on the bottom of the upper PC wall 300, and the plurality of protrusions 320 are mounted on the upper surface of the pair of PC slabs 200. It is preferable that the tensile reinforcing bar 220 is installed through the free space formed between).

Among the plurality of protrusions 320, the protrusions 321 formed at both ends of the upper PC wall 300 may be formed to be spaced inwardly from both ends.

Preferably, the pair of PC slabs 200 are embedded with a second tensile bar 230 so that their ends are exposed, and the ends of the second tensile bars 230 are coupled to each other.

It is preferable that the ends of the second tensile bar 230 are welded to each other.

Mortar injection pipe 410 is formed below the main reinforcing bar connecting member 400, mortar discharge pipe 420 is formed above the main reinforcing bar connecting member 400, the main reinforcing bar connecting member 400 is the mortar injection Preferably embedded in the upper PC wall 300 to expose the trim of the tube 410 and the mortar discharge tube 420.

Mortar injection pipe 410 of the cast iron connecting member 400 is preferably installed to be embedded in the topping concrete (210).

The present invention provides a method for constructing the PC wall-slab coupling structure, comprising: placing end portions of the pair of PC slabs 200 on both side edges of the upper surface of the lower PC wall 100; Reinforcing the reinforcing bar 220 on top of the pair of PC slabs 200; Pouring the topping concrete 210 primarily to an area between the pair of PC slabs 200 and to the height of the reinforcing bars 220; Placing the upper PC wall (300) on top of the pair of PC slabs (200) such that an upper end of the lower cast iron (110) is coupled to a lower portion of the cast steel connecting member (400); Presenting the construction method of the PC wall-slab coupling structure, including; the second step of placing the topping concrete 210 so that the bottom of the upper PC wall 300 is embedded.

The present invention provides a method for constructing the PC wall-slab coupling structure, comprising: placing end portions of the pair of PC slabs 200 on both side edges of the upper surface of the lower PC wall 100; Welding the ends of the second tensile bars 230 of the pair of PC slabs 200 to each other; Reinforcing the reinforcing bar 220 on top of the pair of PC slabs 200; Pouring the topping concrete 210 primarily to an area between the pair of PC slabs 200 and to the height of the reinforcing bars 220; Placing the upper PC wall (300) on top of the pair of PC slabs (200) such that an upper end of the lower cast iron (110) is coupled to a lower portion of the cast iron connecting member (400); Presenting the construction method of the PC wall-slab coupling structure, including; the second step of placing the topping concrete 210 so that the bottom of the upper PC wall 300 is embedded.

The present invention provides a method for constructing the PC wall-slab coupling structure, comprising: placing end portions of the pair of PC slabs 200 on both side edges of the upper surface of the lower PC wall 100; Reinforcing the reinforcing bar 220 on top of the pair of PC slabs 200; Pouring the topping concrete 210 primarily to an area between the pair of PC slabs 200 and to the height of the reinforcing bars 220; Placing the upper PC wall (300) on top of the pair of PC slabs (200) such that an upper end of the lower cast iron (110) is coupled to a lower portion of the cast iron connecting member (400); Injecting mortar through the mortar injection tube 410 of the cast iron connecting member 400 until mortar is discharged through the mortar discharge pipe 420; Presenting the construction method of the PC wall-slab coupling structure, including; the second step of placing the topping concrete 210 so that the bottom of the upper PC wall 300 is embedded.

The present invention takes the steel joint structure, while ensuring structural stability while ensuring structural stability, can shorten the construction time, while ensuring excellent workability using topping concrete with low construction years, and the thickness of the PC wall To reduce it.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figures 2 to 5, the PC wall-slab coupling structure according to the present invention basically includes a lower PC wall 100 formed so that the upper end of the lower main reinforcement 110 embedded therein protrudes upward; A pair of PC slabs 200 whose ends are placed on both edges of the upper surface of the lower PC wall 100; An upper PC reinforcement 310 embedded therein and an upper PC wall 300 installed on an upper portion of the pair of PC slabs 200; A main reinforcing bar connecting member 400 embedded in the upper PC wall 300 so that the upper end is coupled to the lower end of the upper main reinforcing bar 310 and the lower end is coupled to the upper end of the lower main reinforcing bar 110; And topping concrete 210 placed in the space between the upper and upper PC walls 300 and the lower PC walls 100 of the pair of PC slabs 200.

That is, the main reinforcing bar 110 of the lower PC wall 100 and the main reinforcing bar 310 of the upper PC wall 300 is taken by a separate connecting member 400, which is to achieve the following effects do.

First, since it takes a steel joint structure instead of the conventional pin joint structure, there is no fear of occurrence of bending can ensure structural stability.

Second, since the connection structure of the reinforcing bar is simplified by the connecting member 400, precise construction is possible, and the construction time is shortened.

Third, since the connection structure of the reinforcing bar is simple, excellent workability can be secured even when using topping concrete with little slump.

Fourth, it is possible to achieve a stable structure by omitting a structurally meaningless configuration, such as the pin 40 is installed in the center of the conventional structure of reinforcing bar.

Fifth, since the bending structure of the reinforcing bar is not adopted in the joint structure of the rebar as in the prior art, the thickness of the lower wall 10 and the upper wall 30 can be reduced.

As shown in FIGS. 2 and 3, the continuous structure of the pair of PC slabs 200 is installed on the upper surface of the pair of PC slabs 200 so that the reinforcing bars 220 are continuous, and the tensile bars 220 are topping. It can be obtained by taking the structure embedded in the concrete 210.

In order to facilitate the installation work of the upper PC wall 300 in a state where the reinforcing bars 220 are continuously installed on the upper surface of the pair of PC slabs 200 as described above, a plurality of the lower side of the upper PC wall 300 is lowered. The protrusion 320 is formed, the plurality of protrusions 320 are placed on the upper surface of the pair of PC slab 200, the tensile reinforcing bars 220 are disposed through the free space formed between the plurality of protrusions 320 It is desirable to.

Since the protrusion 320 only needs to have a free space for the arrangement of the tensile reinforcing bars 220 as described above, a structure in which a plurality is formed at appropriate ends at both ends and the center of the upper PC wall 300 is sufficient. .

However, as shown in FIG. 12, in the case where four walls meet each other, to make it easier to secure a working space for coupling of reinforcing bars and installing reinforcing bars in the lower part of the upper PC wall 300. In order to achieve this, the protrusions 321 formed at both ends of the upper PC wall 300 among the plurality of protrusions 320 are preferably formed to be spaced inwardly from both ends.

In general, a sufficient strength can be obtained even by the structure in which the tensile reinforcing bars 220 are installed. However, in order to obtain a high-strength structure as in the case of the seismic design, the pair of PC slabs 200 have a second tension such that their ends are exposed. Reinforcing bars 230 may be embedded, and the ends of the second tensile bars 230 may have a structure in which they are coupled to each other (FIG. 3).

End portions of the second tensile bar 230 is preferably welded to each other.

The main reinforcing bar connecting member 400 is a structure that combines the lower main reinforcing bar 110 and the upper main reinforcing bar 310, and plays the most important role for the formation of steel joints, the interior of the main reinforcing bars (110,310) It is necessary to make the connection of) more secure.

To this end, the mortar injection pipe 410 is formed on the lower portion of the cast steel connecting member 400, the mortar discharge pipe 420 is formed on the upper portion of the cast steel connecting member 400, the cast iron connecting member 400 is a mortar injection pipe 410 and the mortar discharge pipe 420 has a structure embedded in the upper PC wall 300 to expose the trim, through the injection pipe 410 and the discharge pipe 420 mortar inside the connecting member 400 It is preferable to be filled.

Here, the mortar injection pipe 410 of the cast iron connecting member 400 is more preferably installed for the filling to be embedded in the topping concrete 210.

Hereinafter, the construction method of the PC wall-slab coupling structure according to the present invention will be described.

The ends of the pair of PC slabs 200 are placed on both edges of the upper surface of the lower PC wall 100, respectively (Figs. 6 and 7).

When a high-strength structure is required, such as an earthquake-proof design, the ends of the second tensile bars 230 of the pair of PC slabs 200 are joined to each other by welding (FIG. 8).

The reinforcing bar 220 is placed on the upper part of the pair of PC slabs 200, and the topping concrete 210 is poured first up to the area between the pair of PC slabs 200 and the height of the reinforcing bar 220. (Figures 9, 10, 11).

The upper PC wall 300 is placed on the upper part of the pair of PC slabs 200 so that the upper end of the lower cast iron 110 is coupled to the lower part of the cast iron connecting member 400 (FIGS. 12 and 13).

At this time, the tension reinforcing bars 220 are arranged in the area between the lower protrusions 320 of the upper PC wall 300 (Fig. 5).

Until mortar is discharged through the mortar discharge pipe 420, mortar is injected through the mortar injection pipe 410 of the cast iron connecting member 400.

Secondly, the topping concrete 210 is poured so that the lower end of the upper PC wall 300 is embedded, and the compacting operation is performed by vibrator or the like (FIGS. 14 and 15).

Since the above has been described only with respect to some of the preferred embodiments that can be implemented by the present invention, the scope of the present invention, as is well known, should not be construed as limited to the above embodiments, the present invention described above It will be said that both the technical idea and the technical idea which together with the base are included in the scope of the present invention.

1 is a cross-sectional view of a conventional PC wall-slab coupling structure.

2 to 5 show an embodiment of a PC wall-slab coupling structure according to the present invention,

2 is a cross-sectional view of the first embodiment.

3 is a sectional view of a second embodiment;

4 is a perspective view of an upper PC wall.

5 is a perspective view of the main part of the upper PC wall and the reinforcing bar;

6 to 15 is a process chart for explaining the construction method of the PC wall-slab coupling structure according to the present invention.

DESCRIPTION OF REFERENCE NUMERALS

100: lower PC wall 110: lower cast bar

200: PC slab 210: topping concrete

220: tensile bar 230: second tensile bar

300: upper PC wall 310: upper cast bar

320: protrusion 400: cast iron connecting member

410: mortar injection pipe 420: mortar discharge pipe

Claims (11)

A lower PC wall 100 formed so that an upper end of the lower cast iron 110 embedded therein protrudes upward; A pair of PC slabs 200 whose ends are placed on both edges of the upper surface of the lower PC wall 100; An upper PC reinforcement 310 embedded therein and an upper PC wall 300 installed on an upper portion of the pair of PC slabs 200; A main reinforcing bar connecting member 400 embedded in the upper PC wall 300 such that an upper end is coupled to a lower end of the upper main reinforcing bar 310 and a lower end is coupled to an upper end of the lower main reinforcing bar 110; And topping concrete (210) placed in an upper portion of the pair of PC slabs (200) and a space between the upper PC wall (300) and the lower PC wall (100). On the upper surface of the pair of PC slab 200 is installed so that the tensile reinforcing bars 220 are continuous, the tensile reinforcing bars 220 are embedded in the topping concrete 210, A plurality of protrusions 320 are formed on the bottom of the upper PC wall 300, and the plurality of protrusions 320 are mounted on the upper surface of the pair of PC slabs 200. The tension reinforcing bar 220 is installed through the free space formed between), PC wall-slab coupling structure, characterized in that the protrusions 321 formed at both ends of the upper PC wall 300 of the plurality of protrusions 320 are spaced inwardly from both ends. delete delete delete The method of claim 1, The pair of PC slab 200 is buried in the lower portion of the reinforcing bar 220 so as to expose the end of each of the reinforcing bars 230, the ends of the second tensile bar 230 is coupled to each other PC wall-slab joint structure. The method of claim 5, End portions of the second reinforcing bar 230 is welded to each other, characterized in that the PC wall-slab coupling structure. The method according to any one of claims 1, 5 and 6, Mortar injection pipe 410 is formed below the main reinforcing bar connecting member 400, mortar discharge pipe 420 is formed above the main reinforcing bar connecting member 400, the main reinforcing bar connecting member 400 is the mortar injection PC wall-slab coupling structure, characterized in that the buried in the upper PC wall 300 so as to expose the trim of the pipe (410) and mortar discharge pipe (420). The method of claim 7, wherein Mortar injection pipe 410 of the reinforcing bar connecting member 400 is PC wall-slab coupling structure, characterized in that installed to be embedded in the topping concrete (210). A method of constructing a PC wall-slab joint structure of claim 1, Placing ends of the pair of PC slabs 200 on both side edges of the upper PC wall 100; Reinforcing the reinforcing bar 220 on top of the pair of PC slabs 200; Pouring the topping concrete 210 primarily to an area between the pair of PC slabs 200 and to the height of the reinforcing bars 220; Placing the upper PC wall (300) on top of the pair of PC slabs (200) such that an upper end of the lower cast iron (110) is coupled to a lower portion of the cast iron connecting member (400); Pouring the topping concrete 210 secondly so that the bottom of the upper PC wall 300 is embedded; Construction method of a PC wall-slab coupling structure comprising a. A method of constructing a PC wall-slab joint structure of claim 6, Placing ends of the pair of PC slabs 200 on both side edges of the upper PC wall 100; Welding the ends of the second tensile bars 230 of the pair of PC slabs 200 to each other; Reinforcing the reinforcing bar 220 on top of the pair of PC slabs 200; Pouring the topping concrete 210 primarily to an area between the pair of PC slabs 200 and to the height of the reinforcing bars 220; Placing the upper PC wall (300) on top of the pair of PC slabs (200) such that an upper end of the lower cast iron (110) is coupled to a lower portion of the cast iron connecting member (400); Pouring the topping concrete 210 secondly so that the bottom of the upper PC wall 300 is embedded; Construction method of a PC wall-slab coupling structure comprising a. A method of constructing a PC wall-slab joint structure of claim 7, Placing ends of the pair of PC slabs 200 on both side edges of the upper PC wall 100; Reinforcing the reinforcing bar 220 on top of the pair of PC slabs 200; Pouring the topping concrete 210 primarily to an area between the pair of PC slabs 200 and to the height of the reinforcing bars 220; Placing the upper PC wall (300) on top of the pair of PC slabs (200) such that an upper end of the lower cast iron (110) is coupled to a lower portion of the cast iron connecting member (400); Injecting mortar through the mortar injection tube 410 of the cast iron connecting member 400 until mortar is discharged through the mortar discharge pipe 420; Pouring the topping concrete 210 secondly so that the bottom of the upper PC wall 300 is embedded; Construction method of a PC wall-slab coupling structure comprising a.

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