KR101346671B1 - The pin connection structure using the spacer in the junction of pc beam and vertical member - Google Patents

Abstract

The present invention relates to a pin joint structure between a PC beam and a vertical member using a spacer to improve constructability and economic efficiency as a steel frame usage decreases by using a PC beam and a PC column instead of using a rigid joint method for filling a joint between a beam and a vertical member with concrete in a building in which a core wall bears the entire horizontal load; and as a PC beam and a vertical member (PC column and core wall) are joined to each other by a pin at a distance using a spacer without being filled with concrete.

Description

The pin connection structure using the spacer in the junction of PC beam and Vertical member}

In the present invention, the core wall is completely filled with the horizontal load, and is unnecessarily filled in the joints of the beams and the vertical members so that the rigid joints are removed. Joint between beam and vertical member (PC column, core wall) is spaced without filling with spacer and behaves as a pin connection, so the connection between PC beam and vertical member using spacer with improved construction and economy It relates to a pin junction structure.

1 illustrates a construction process of a general building to which a core wall is applied, and a construction process of a building to which the present invention is applied.

As shown in Figure 1, the core wall is applied to the building is the core core wall (CW) is pre-constructed, followed by the pillar and beam construction, the slab is filled with the slab concrete 300 to join the column and beam construction together do.

In the building to which the core wall is applied, the core wall CW bears vertical loads and all horizontal loads. Thus, there is no need to bear the horizontal load of the column and beam.

In addition, the building to which the core wall is applied is mainly constructed of columns and beams in steel frame, and in the case of the steel frame, there is a problem in that construction cost is higher than that of reinforced concrete buildings due to an increase in raw material prices.

Therefore, the use of PC beams and PC pillars reduces the amount of steel, and the connection between the PC beams and the vertical members (PC pillars, core walls) is not filled with concrete due to the spacers and therefore acts as a pin connection. There is an urgent need to study the joint-free structure of PC beams and vertical members with reduced size and improved construction and economy.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-mentioned problems of the related art. The purpose is as follows.

First, the use of PC beams and PC columns composed of steel brackets at both ends reduces the amount of use and weight of steel, thereby providing a pin joint structure of the joints of the PC beams and vertical members using spacers with improved economic efficiency and constructability.

Secondly, the space between the PC beam and the vertical member (PC column, core wall) is separated by the spacer and behaves as a pin connection without space. It is intended to provide a joint pin joint structure of a vertical member.

In order to solve the above technical problem, the present invention provides a building in which a core wall (CW) is constructed that bears a vertical load and a horizontal load.

PC pillar 100 is installed vertically; An m bed plate 500 including a plate 520 integrally installed on an outer surface of the PC pillar 100 and a bracket 580 installed on the plate 520 using a stud bolt SB; The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the lower portion of the lower body concrete 260, including the main root, the lower end steel frame 220 is coupled to the bracket 580; And, Slab concrete 300 is poured onto the PC beam 200; configured to include,

The core wall (CW) bears all the horizontal loads acting on the building and the PC pillar 100 bears only the vertical loads,

The spacer 600 is installed between the end of the lower concrete 260 and the PC pillar 100, and the lower concrete between the lower concrete 260 and the PC pillar 100 when the slab concrete 300 is placed. Since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600,

Combined portion of the PC pillar 100 and the PC beam 200 is not filled with the slab concrete 300 by the spacer 600, the PC using a spacer characterized in that the pin joint (pin joint) It provides a joint pin joint structure of the beam and the vertical member.

According to the present invention, the following effects are expected.

First, by using the PC beam and PC pillar composed of steel brackets only at both ends, to reduce the amount of use and weight of the steel frame to provide a pin joint structure of the junction portion of the PC beam and the vertical member using spacers with improved economic efficiency and workability.

Secondly, the space between the PC beam and the vertical member (PC column, core wall) is separated by the spacer and behaves as a pin connection without space. It provides a junction pin joint structure of the vertical member.

1 illustrates a construction process of a general building to which a core wall is applied, and a construction process of a building to which the present invention is applied.
Figure 2 shows the site to which the present invention is applied.
Figure 3 shows the m bed plate used in the embodiment of the junction portion pin joint structure of the PCB and the vertical member using the spacer of the present invention.
4 to 6 show the construction process of the embodiment of the junction pin joint structure of the PCB and the vertical member using the spacer of the present invention.
Figure 7 illustrates a PC pillar including a pillar connector used in another embodiment of the junction pin joint structure of the PCB and the vertical member using the spacer of the present invention.
8 to 10 illustrate a process of constructing another embodiment of the junction pin bonding structure of the PCB and the vertical member using the spacer of the present invention using the pillar connector of FIG. 7.
11 and 12 illustrate the assembly process of the PC column including the other column connector used in the present invention.
Figures 13 and 14 illustrate the assembly process of the PC column including another column connector used in the present invention.
15 and 16 illustrate a process of applying the present invention to a core wall instead of a PC column.
17 to 20 are yet another embodiment of the present invention.

Figure 2 shows the site to which the present invention is applied.

Specifically, the A portion of the red dotted line is the portion where the embodiment in which the PC pillar 100 is used as the vertical member is installed, and the B portion of the blue dotted line is the portion in which the embodiment in which the core wall CW is used as the vertical member.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 shows the m bed plate used in the embodiment of the pin joint structure of the junction portion of the PC and the vertical member using the spacer of the present invention, Figures 4 to 6 are perpendicular to the PC beam using the spacer of the present invention. The construction process of the embodiment of the junction pin junction structure of the member is shown.

3 to 6 is an embodiment of the pin joint structure of the junction portion of the PC beam and the vertical member using the spacer of the present invention in a building in which a core wall (CW) that bears vertical load and horizontal load is constructed.

PC pillar 100 is installed vertically; An m bed plate 500 including a plate 520 integrally installed on an outer surface of the PC pillar 100 and a bracket 580 installed on the plate 520 using a stud bolt SB; The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the lower portion of the lower body concrete 260, including the main root, the lower end steel frame 220 is coupled to the bracket 580; And, Slab concrete 300 is poured onto the PC beam 200; configured to include,

The core wall (CW) bears all the horizontal loads acting on the building and the PC pillar 100 bears only the vertical loads,

The spacer 600 is installed between the end of the lower concrete 260 and the PC pillar 100, and the lower concrete between the lower concrete 260 and the PC pillar 100 when the slab concrete 300 is placed. Since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600,

The coupling portion of the PC pillar 100 and the PC beam 200 is characterized in that the slab concrete 300 is not filled by the spacer 600 is pin-joined (pin joint).

The PC beam 200 of the present invention, as shown in Figure 4, the upper end 240 is installed on the upper and lower ends of the lower end steel frame 220 and the lower end steel frame 220 is installed horizontally, respectively And a lower portion of the lower portion and the lower portion of the lower portion of the steel frame 220 is exposed and the lower portion of the lower portion of the concrete, including the lower portion of the lower portion. In some cases, a stud bolt may be installed on the upper end steel frame 220 in order to increase the coupling force with the slab concrete 300.

Styrofoam or wood chips can be easily used as the spacing member 600, but the slab concrete 300 can be temporarily held until the slab concrete 300 is hardened without changing its position when placed. Any material can be used, and it is not necessary to remove it after forming the gap.

Figure 7 illustrates a PC pillar including a column connector used in another embodiment of the junction portion pin joint structure of the PC beam and the vertical member using the spacer of the present invention, Figures 8 to 10 using the spacer of the present invention Another embodiment of the junction pin bonding structure of the PC beam and the vertical member is shown the process of construction using the column connector of FIG.

Another embodiment of the junction pin bonding structure of the PC beam and the vertical member using the spacer of the present invention shown in Figures 7 to 10 is in a building in which the core wall (CW) to bear the vertical load and the horizontal load is constructed,

PC pillar 100 vertically extended using a plurality of pillar connector 400 including the pillar bracket 480; The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the bottom portion concrete 260 is pour cured including the main root and the bottom end steel frame 220 is coupled to the pillar bracket 480; And, Slab concrete 300 is poured onto the PC beam 200; configured to include,

The core wall (CW) bears all the horizontal loads acting on the building and the PC pillar 100 bears only the vertical loads,

The pillar connector 400 is installed between the upper plate 420 and the lower plate 440 and the upper plate 420 and the lower plate 440 which are installed in parallel in the same shape as shown in FIG. It comprises a plate connecting steel 460 and the pillar bracket 480 is installed on the plate connecting steel 460,

The slab concrete 300 is filled between the upper plate 420 and the lower plate 440, but the spacer 600 is installed between the end portion of the lower concrete 260 and the PC pillar 100. When the slab concrete 300 is poured, since the slab concrete 300 is not poured between the bottom portion concrete 260 and the PC pillar 100 by the thickness of the spacer 600,

The coupling portion of the PC pillar 100 and the PC beam 200 is characterized in that the slab concrete 300 is not filled by the spacer 600 is pin-joined (pin joint).

In some cases, a stud bolt may be installed at an upper portion of the upper plate 420 and a lower portion of the lower plate 440 to increase coupling force with the pillar concrete.

When using two L-shaped angles as the pillar bracket 480, the two ends of the L-shaped angles are installed to face each other with a gap having a gap corresponding to the thickness of the lower end steel frame 220, and the lower end is formed by the gap. The web of steel frame 220 is inserted,

In order to extend the length of the pillar bracket 480, the length of the extension steel plate or the extension plate is combined with a separate extension steel plate or extension plate between the two L-shaped angles, and the proximal end steel frame ( 220) Fasten the coupling plate on both sides by abutting the ends of the web.

11 and 12 show the assembly process of the PC column including the other column connector used in the present invention, Figures 13 and 14 illustrate the assembly process of the PC column including another column connector used in the present invention 11 to 14, the pillar connector 400` portion constitutes a so-called concrete filled tube (CFT).

11 and 12 of the present invention is that the CFT column connector 400` is configured in place of the above-described column connector 400,

The CFT pillar connector 400 ′ includes an upper plate 420 ′ and a lower plate 440 ′ installed in parallel with each other; A plurality of column reinforcing bars 490 installed between the upper plate 420 'and the lower plate 440'; A tube iron plate 470 which wraps the upper plate 420` and the lower plate 440` to the upper and lower ends, respectively; A pillar bracket 480 'attached to an outer surface of the tube iron plate 470; And a filling concrete 450 filled in the tube iron plate 470.

At this time, the spacer 600 is installed between the end portion of the lower concrete 260 and the tube iron plate 470, and the lower concrete 260 and the PC pillar 100 when the slab concrete 300 is placed. Since the slab concrete 300 is not poured as much as the thickness of the spacer 600, it has a play,

The coupling portion of the PC pillar 100 and the PC beam 200 is characterized in that the slab concrete 300 is not filled by the spacer 600 is pin-joined (pin joint).

The upper plate 420 ′ and the lower plate 440 ′ may be configured in a circular shape as shown in FIGS. 13 and 14 or a square shape as shown in FIGS. 11 and 12, according to field conditions and design needs.

15 and 16 illustrate a process of applying the present invention to a core wall instead of a PC column.

15 and 16 is a core wall (CW) is configured in place of the PC pillar 100,

An m bed plate 500 including a plate 520 integrally installed on an outer surface of the core wall CW using a stud bolt SB and a bracket 580 installed on the plate 520; The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the lower portion of the lower body concrete 260, including the main root, the lower end steel frame 220 is coupled to the bracket 580; And, Slab concrete 300 is poured onto the PC beam 200; configured to include,

The spacer 600 is installed between the end of the lower concrete 260 and the core wall CW, and the lower concrete 260 and the core wall CW are disposed between the lower concrete 260 and the core wall CW. Since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600,

The coupling portion of the PC pillar 100 and the core wall CW is not filled by the spacer 600, and thus is pin-joined.

The present invention is to design the joint between the vertical member and the PC beam by the pin joint, focusing on the function of the PC beam that resists only the vertical load, not the horizontal load because the core wall (CW) receives all the horizontal load In addition, it is possible to design economically without waste of materials, and it is economical because steel usage is drastically reduced compared to steel structure with construction speed such as RC structure or steel structure.

And because the upper and lower reinforcement of the PC beam is not connected to the inside of the column, the construction is simple, and the air is saved.The slab concrete 300 is provided by the spacer at the joint to prevent it from being poured, The slab concrete 300 can be poured.

Particularly, after the slab concrete 300 is placed before the spacing member 600 is inserted, the joint formwork is installed together with the slab formwork at the lower portion of the junction between the PC beam 200 and the PC pillar 100 or the core wall (CW). Alternatively, after the junction die is installed, when the spacer 600 is mounted on the junction die and the slab concrete 300 is poured, the joint and the slab may be constructed together.

17 to 20 are yet another embodiment of the present invention.

Specifically, in the embodiment of FIG. 17, in the embodiment of FIGS. 4 to 6,

The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the PC pillar 100, the spacer 600 is removed after being used as a temporary formwork when placing the slab concrete 300 ,

Between the bottom concrete 260 and the PC pillar 100, since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600 used as a temporary formwork, the PC pillar 100 and Coupling portions of the PC beam 200 is characterized in that the pin joint is formed by forming a non-filling portion (BB) is not filled with the slab concrete (300).

Specifically, the embodiment of Figure 18 is in the embodiment of Figures 7 to 10,

The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the PC pillar 100, the spacer 600 is removed after being used as a temporary formwork when placing the slab concrete 300 ,

Between the bottom concrete 260 and the PC pillar 100, since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600 used as a temporary formwork, the PC pillar 100 and Coupling portions of the PC beam 200 is characterized in that the pin joint is formed by forming a non-filling portion (BB) is not filled with the slab concrete (300).

Specifically, in the embodiment of Figures 11 to 14,

The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the tube iron plate 470 so that the spacer 600 is removed after being used as a temporary formwork when placing the slab concrete 300 ,

Between the bottom concrete 260 and the tube iron plate 470, since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600 used as a temporary formwork, the PC pillar 100 and Coupling portions of the PC beam 200 is characterized in that the pin joint is formed by forming a non-filling portion (BB) is not filled with the slab concrete (300).

Specifically, in the embodiment of FIG. 20, in the embodiment of FIGS. 15 to 16,

The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the core wall (CW), the spacer 600 is removed after being used as a temporary formwork when pouring the slab concrete 300 ,

Since the slab concrete 300 has a play between the bottom portion concrete 260 and the core wall (CW) as the thickness of the spacer 600 used as a temporary formwork, the slab concrete 300 is not placed, and the core wall (CW) and Coupling portions of the PC beam 200 is characterized in that the pin joint is formed by forming a non-filling portion (BB) is not filled with the slab concrete (300).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention.

It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

BB: no filling
CW: core wall
SB: Stud Bolt
100: PC pillar
200: PC Report
220: Bodanbu Steel
240: upper root
260: Boha Concrete
300: slab concrete
400: column connector
400`: CFT pillar connector
420, 420`: upper plate
440, 440`: lower plate
450: Filled concrete
460: plate connection steel
470: tube iron plate
480, 480`: Pillar bracket
500: embedded plate
520: plate
580: bracket
600: spacer

Claims (9)

In buildings where core walls (CW) are constructed that bear vertical and horizontal loads,
PC pillar 100 is installed vertically;
An m bed plate 500 including a plate 520 integrally installed on an outer surface of the PC pillar 100 and a bracket 580 installed on the plate 520 using a stud bolt SB;
The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the lower portion of the lower body concrete 260, including the main root, the lower end steel frame 220 is coupled to the bracket 580; And
Slab concrete 300 is poured onto the PC beam 200;
, ≪ / RTI >
The core wall (CW) bears all the horizontal loads acting on the building and the PC pillar 100 bears only the vertical loads,
The spacer 600 is installed between the end of the lower concrete 260 and the PC pillar 100, and the lower concrete between the lower concrete 260 and the PC pillar 100 when the slab concrete 300 is placed. Since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600,
Combined portion of the PC pillar 100 and the PC beam 200 is not filled with the slab concrete 300 by the spacer 600, the PC using a spacer characterized in that the pin joint (pin joint) Pin joint structure of beam and vertical member.
In buildings where core walls (CW) are constructed that bear vertical and horizontal loads,
PC pillar 100 vertically extended using a plurality of pillar connector 400 including the pillar bracket 480;
The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the bottom portion concrete 260 is pour cured including the main root and the bottom end steel frame 220 is coupled to the pillar bracket 480; And
Slab concrete 300 is poured onto the PC beam 200;
, ≪ / RTI >
The core wall (CW) bears all the horizontal loads acting on the building and the PC pillar 100 bears only the vertical loads,
The pillar connector 400 is the upper plate 420 and the lower plate 440 and the plate connection steel 460 is installed between the upper plate 420 and the lower plate 440 in parallel with the same shape and It is configured to include the pillar bracket 480 is installed on the plate connecting steel 460,
The slab concrete 300 is filled between the upper plate 420 and the lower plate 440, but the spacer 600 is installed between the end of the lower concrete 260 and the PC pillar 100, When the slab concrete 300 is poured, since the slab concrete 300 is not poured between the bottom portion concrete 260 and the PC pillar 100 by the thickness of the spacer 600,
Combined portion of the PC pillar 100 and the PC beam 200 is not filled with the slab concrete 300 by the spacer 600, the PC using a spacer characterized in that the pin joint (pin joint) Pin joint structure of beam and vertical member.
3. The method of claim 2,
An upper plate 420 ′ and a lower plate 440 ′ installed up and down in parallel;
A plurality of column reinforcing bars 490 installed between the upper plate 420 'and the lower plate 440';
A tube iron plate 470 which wraps the upper plate 420` and the lower plate 440` to the upper and lower ends, respectively;
A pillar bracket 480 'attached to an outer surface of the tube iron plate 470; And
Filled concrete 450 is filled in the tube iron plate 470;
CFT pillar connector 400` configured to include is configured in place of the pillar connector 400,
The spacer 600 is installed between the end portion of the lower concrete 260 and the tube iron plate 470, and is disposed between the lower concrete 260 and the PC pillar 100 when the slab concrete 300 is placed. Since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600,
Combined portion of the PC pillar 100 and the PC beam 200 is not filled with the slab concrete 300 by the spacer 600, the PC using a spacer characterized in that the pin joint (pin joint) Pin joint structure of beam and vertical member.
4. The method of claim 3,
The upper plate 420 ′ and the lower plate 440 ′ have a circular or rectangular shape, and a junction pin bonding structure of a PCB and a vertical member using spacers.
In claim 1,
Instead of the PC pillar 100, the core wall (CW) is configured,
An m bed plate 500 including a plate 520 integrally installed on an outer surface of the core wall CW using a stud bolt SB and a bracket 580 installed on the plate 520;
The upper end 240 and the lower main root and the lower end of the upper end 240 and the lower end of the upper end of the lower end steel frame 220 are respectively installed horizontally and the lower end of the lower end steel frame 220 PC beam 200 is configured to include the lower portion of the lower body concrete 260, including the main root, the lower end steel frame 220 is coupled to the bracket 580; And
Slab concrete 300 is poured onto the PC beam 200;
, ≪ / RTI >
The spacer 600 is installed between the end of the lower concrete 260 and the core wall CW, and the lower concrete 260 and the core wall CW are disposed between the lower concrete 260 and the core wall CW. Since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600,
Coupling portion of the PC pillar 100 and the core wall (CW) is not filled by the spacer 600 is pin-joined (pin joint) of the PCB and the vertical member joint pin using the spacer Junction structure.
In claim 1,
The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the PC pillar 100, the spacer 600 is removed after being used as a temporary formwork when placing the slab concrete 300 ,
Between the bottom concrete 260 and the PC pillar 100, since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600 used as a temporary formwork, the PC pillar 100 and The joining portion of the PC beam 200 is a pin joint structure of the PC beam and the vertical member using the spacer member, characterized in that the slab concrete 300 is not filled with the pin joint (pin joint).
3. The method of claim 2,
The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the PC pillar 100, the spacer 600 is removed after being used as a temporary formwork when placing the slab concrete 300 ,
Between the bottom concrete 260 and the PC pillar 100, since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600 used as a temporary formwork, the PC pillar 100 and The joining portion of the PC beam 200 is a pin joint structure of the PC beam and the vertical member using the spacer member, characterized in that the slab concrete 300 is not filled with the pin joint (pin joint).
4. The method according to claim 3 or 4,
The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the tube iron plate 470 so that the spacer 600 is removed after being used as a temporary formwork when placing the slab concrete 300 ,
Between the bottom concrete 260 and the tube iron plate 470, since the slab concrete 300 has a play without pouring as much as the thickness of the spacer 600 used as a temporary formwork, the PC pillar 100 and The joining portion of the PC beam 200 is a pin joint structure of the PC beam and the vertical member using the spacer member, characterized in that the slab concrete 300 is not filled with the pin joint (pin joint).
The method of claim 5,
The thickness of the spacer 600 is the gap width between the bottom concrete 260 and the core wall (CW), the spacer 600 is removed after being used as a temporary formwork when pouring the slab concrete 300 ,
Since the slab concrete 300 has a play between the bottom portion concrete 260 and the core wall (CW) as the thickness of the spacer 600 used as a temporary formwork, the slab concrete 300 is not placed, and the core wall (CW) and The joining portion of the PC beam 200 is a pin joint structure of the PC beam and the vertical member using the spacer member, characterized in that the slab concrete 300 is not filled with the pin joint (pin joint).

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