KR102682080B1 - Concrete structure jointing apparatus and pc slab construction method using the same - Google Patents

Abstract

By bonding the connecting sides (A) of the concrete structure including the PC slab together and integrating them, it is possible to resist loads acting in all three axes, making it more stable and constructable, making it an economical concrete. This relates to a structure joining device and a PC slab construction method using the same. The concrete structure joining device has two side connection flanges (141) fixed to both buried plates pre-installed so that the upper surface is exposed on the bottom of the connection groove, and between the fixed two side connection flanges. A semicircular connection plate that connects the concrete structures to each other by allowing the semicircular body portion to pass through both connection sides (A); and an elastic means including a spring fixedly installed between both lower ends inside the semicircular body of the semicircular connection plate to pass through both connection sides (A).

Description

Concrete structure joint device and PC slab construction method using the same {CONCRETE STRUCTURE JOINTING APPARATUS AND PC SLAB CONSTRUCTION METHOD USING THE SAME}

The present invention relates to a concrete structure joining device. More specifically, in joining the connecting sides (A) of the concrete structure including the PC slab together to integrate them, it is possible to resist loads acting in all three axes, ensuring more stability and constructability. This relates to an economical concrete structure joining device and a PC slab construction method using the same.

Figure 1a is an example of the behavior of a conventional PC slab (solid precast floor slab).

In other words, according to Figure 1a, when a horizontal load acts on a building, the floor slab (horizontal element) of the building receives in-plane bending and resists the transmitted horizontal load by transferring it to the wall or column (vertical element) supporting the floor slab. .

In this way, if the floor slab (horizontal element) to which the horizontal load acts is high in rigidity (strong diaphragm), the horizontal displacement occurs the same as that of a wall or column (vertical element), and if the rigidity is not high (weak diaphragm), the horizontal displacement occurs the same as that of a wall or column (vertical element). Displacements occur differently for each wall or column (vertical element), resulting in horizontal displacement similar to the horizontal deflection of a beam.

At this time, as shown in Figure 1a, in the case of PC slabs (solid precast floor slabs) subjected to horizontal loads (wind load, earthquake load), if they are not joined to each other, they behave like a simple beam and are compressed into the PC slab. It is known that excessive tensile stress occurs.

This PC slab can be integrated by pouring topping concrete on the adjacent PC slab so that the placed floor plate reinforcement is buried, as in the half PC slab construction method, so that the PC slab can be joined to each other. However, in this case, when the topping concrete hardens, There is a limitation in that subsequent processes cannot proceed until this point.

Accordingly, the full precast construction method is used, which does not use topping concrete but connects PC slabs using various joining means such as connecting reinforcing bars and bonding hardware. In this case, securing the integrity of the PC slab is very important. I do it.

Accordingly, when using connecting reinforcing bars as a means of joining the PC slab, the connecting sides (A) of the PC slab are placed in contact with each other so that the hoop or hook reinforcing bars are exposed on the connecting side (A) of the PC slab.

A method of joining PC slabs is introduced by filling the space on the connection side (A) with concrete or mortar so that the exposed hoop or hook rebars overlap and are buried.

However, in the case of this method of using connecting reinforcing bars, there is a limitation that it is difficult to effectively resist deformation due to horizontal shear in the longitudinal direction of the PC slab, opening due to tension in the width direction, and vertical shear and deflection due to vertical load. There was,

Looking at the joining means of conventional PC slabs, they are as follows.

Figures 1b and 1c are examples of using joint hardware as a means of joining PC slabs.

That is, in the case of the bonded steel material shown in FIG. 1b, synthetic grooves 21 are formed on both PC slabs 20, respectively,

The steel plate 22 and the anchor bar 23 are formed integrally on the bottom of the composite groove 21,

The joint plate 24 is connected with a fastening nut 25 to both anchor bars 23 of the synthetic grooves 21 spaced apart from each other, which is ultimately connected to the joint plate 24 using a fastener such as a fastening nut. It can be said to be a method of joining both PC slabs (20).

In addition, in the case of the jointed steel material shown in Figure 1c, the connection side (A) of both PC slabs (30) has a bent connection plate in the space (S) formed by the lower flanges (31) in contact with each other. (32) to be reclaimed,

A method in which the exposed inclined flange (33) is exposed at the exposed end of the bent connecting plate (32) by extending into the space provided by the connection side (A), and the V-shaped connecting plate (34) is welded to the exposed inclined flange (33). It can be seen that this is a method of joining both PC slabs (30).

However, recently, construction sites are avoiding on-site welding to prepare for risks such as fire, so the use of jointed hardware that requires welding is restricted.

When a PC slab is installed on a PC beam/girder, differences in adjacent PC slabs may occur, but in the case of existing welding methods or methods using rebar, there is a problem in that these differences cannot be overcome on their own.

Figure 1d shows an example of a conventional shear connector 40.

That is, as a shear connector 40 that is joined to the steel 41 and embedded in concrete for a complete composite action between steel and concrete in a steel concrete composite structure or composite structure,

It can be seen that both flanges 42 have a shear connector function that perforates a plurality of holes 44 in the semicircular steel plate 43 formed on the side and allows the steel material 41 to be joined and concrete (not shown) to be synthesized with each other. there is.

Accordingly, it can be seen that the shear connector 40 embedded in concrete can allow concrete to be filled inside through the hole 42, but this shear connector 40 is used for joining the PC slab installed on the beam/girder. The use of joint hardware has not been introduced for its function.

Republic of Korea Patent No. 10-2304567 (Title of invention: Pie-shaped precast slab construction method using lateral connection means, Publication date: June 29, 2021) Republic of Korea Patent No. 10-1272601 (Title of invention: PC joint structure of rooftop sculpture, Publication date: June 10, 2013) Republic of Korea Publication Patent No. 10-2006-0042725 (Title of invention: Concrete confining shear connector, Publication date: May 15, 2006)

Accordingly, the present invention ensures constructability and economic efficiency by allowing precast concrete structures (hereinafter referred to as concrete structures), which are PC slabs (solid precast floor slabs), to be simply joined together in the field using fasteners rather than welding methods. The technical problem to be solved is to provide a concrete structure joining device and a PC slab construction method using the same.

In addition, the present invention is structurally superior by being able to resist loads acting in all three axes on the connection side (A, connection area) of the concrete structure, and provides elasticity to prevent steps and openings on the connection side of the concrete structure. This is a technical problem that can be overcome by providing an efficient concrete structure joining device and a PC slab construction method using the same.

In addition, the present invention aims to provide a concrete structure joining device that can be installed more securely by forming a through slot in the concrete structure joining device so that the filler can be filled into the through slot, and a PC slab construction method using the same. It is a technical task to do.

The concrete structure joining device of the present invention to achieve the above problem,

In a concrete structure joining device for joining and integrating PC slab concrete structures, both side connecting flanges are fixed to both buried plates pre-installed so that the upper surface is exposed on the concrete structure, and a semicircular body portion between the fixed two side connecting flanges is provided. A semicircular connection plate connecting the concrete structures to each other via both connection sides (A); and an elastic means including a spring fixedly installed between both lower ends on the inside of the semicircular body of the semicircular connection plate to pass through both connection sides (A),
The connection flanges on both sides of the semicircular connection plate are fixed to each embedded plate formed on each PC slab by fastening bolts to restrain both ends of the integrated semicircular body, thereby deforming (Y-axis direction) and width due to horizontal shear. It is designed to resist opening due to tension (in the fastening nut), and the elastic means serves to restore deformation and movement due to the load acting on the semicircular connecting plate to its original state, and the elastic means is used to restore the original state to the vertical load caused by the vertical load during the PC slab installation process. In terms of shear and vertical deflection (Z-axis direction), multiple springs are installed to have the function of restoring the steps that occur during the PC slab installation process or preventing the gap between PC slabs from opening due to vertical load by restoring them to their original positions. Using , both ends of the spring are installed in advance between the lower ends of both sides inside the semicircular body.

The PC slab construction method using the concrete structure joining device of the present invention to achieve the above task is,

(a) manufacturing the PC slab so that the fastening hole of the buried plate is exposed on the bottom of the connection groove of the PC slab; and (b) bringing the PC slab to the site and horizontally connecting and installing it on a wall or pillar (vertical element) using a concrete structure joining device including a semicircular connecting plate with integrated elastic means on the connecting side (A). It includes a step; wherein the semicircular connection plate has both connection flanges fixed to both embedded plates pre-installed so that the upper surface is exposed on the bottom of the connection groove, and the semicircular body between the fixed connection flanges on both sides passes through both connection sides (A). The concrete structures are connected to each other, and the elastic means is configured to include a spring that is fixedly installed between both lower ends inside the semicircular body of the semicircular connection plate to pass through both connection sides (A),
The connection flanges on both sides of the semicircular connection plate are fixed to each embedded plate formed on each PC slab by fastening bolts to restrain both ends of the integrated semicircular body, thereby deforming (Y-axis direction) and width due to horizontal shear. It is designed to resist opening due to tension (in the fastening nut), and the elastic means serves to restore deformation and movement due to the load acting on the semicircular connecting plate to its original state, and the elastic means is used to restore the original state to the vertical load caused by the vertical load during the PC slab installation process. In terms of shear and vertical deflection (Z-axis direction), multiple springs are installed to have the function of restoring steps that occur during the PC slab installation process or preventing the gap between PC slabs from opening due to vertical load by restoring them to their original positions. Using , both ends of the spring are installed in advance between the lower ends of both sides inside the semicircular body.

According to the concrete structure joining device of the present invention, the embedded fastening nut is manufactured in advance to be exposed to the concrete structure, and the concrete structure joining device is installed by fastening the semicircular connection plate to the embedded fastening nut at the site, so the on-site welding process is performed. It is possible to provide a concrete structure joining device that can prevent risks such as fire and a PC slab construction method using the same.

In addition, according to the concrete structure joining device of the present invention, an elastic means including a spring is included in the inner lower part of the semicircular connecting plate fastened to the embedded fastening nut, so that the concrete is formed by the action of load through the semicircular connecting plate on which the elastic means is formed. Opening of the connection side (A) of the structure. It is possible to more effectively control loads acting in three axes, such as steps and horizontal displacements, and provide a concrete structure joining device that can sufficiently secure constructability and economic feasibility and a PC slab construction method using the same.

In addition, according to the concrete structure joining device of the present invention, a through slot is formed in the semicircular connection plate, and the filler is finished through the through slot, thereby reliably securing the integrity of the concrete structure, and the same. It becomes possible to provide a PC slab construction method using this method.

Figure 1a is an example of the behavior of a conventional PC slab (solid precast floor slab),
Figures 1b and 1c are examples of using joint hardware as a means of joining PC slabs;
Figure 1d is an example of a conventional shear connector,
2A and 2B are an exemplary configuration and a combined perspective view of the concrete structure joining device of the present invention;
Figure 2c is an illustration of the operation of the concrete structure joining device of the present invention;
Figures 3a and 3b show an example of a PC slab construction method using the concrete structure joining device of the present invention.

Below, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts unrelated to the description are omitted, and similar parts are given similar reference numerals throughout the specification.

Throughout the specification, when a part is said to “include” a certain element, this means that it may further include other elements rather than excluding other elements, unless specifically stated to the contrary.

[Concrete structure joining device (100) of the present invention]

Figures 2a and 2b show an exemplary configuration and a combined perspective view of the concrete structure joining device 100 of the present invention, and Figure 2c shows an operating example of the concrete structure joining device 100 of the present invention.

Referring to FIG. 2C, the concrete structure joining device 100 is a device that connects adjacent concrete structures 200 to each other using joining hardware. The concrete structure 200 is a PC slab 210, a solid precast floor. slab) as a standard.

This PC slab (210) is manufactured in a factory, manufactured in the form of a horizontal plate of a certain size, brought to the site, and installed on the connection side (A) on a wall or pillar (vertical element). A concrete structure joining device (100) They are joined together and then integrated using .

Accordingly, the concrete structure joining device 100 includes embedded anchoring rebar 110, embedded fastening nut 120, embedded plate 130, semicircular connecting plate 140, and elastic means 150, as shown in FIGS. 2A and 2B. , fastening bolts 160, and filler 170. Referring to Figure 2c, it is installed in the connection grooves 220 formed on both connection sides (A) of the PC slab 210 to form a PC slab ( 210) are joined and finally integrated.

First, the embedded anchorage rebar 110 is installed on the PC slab 210 by setting the position of the embedded fastening nut 120, which is installed in the lower part of the connection groove 220 of the PC slab 210, as shown in FIGS. 2A and 2B. It plays a supporting role to enable stable fixed installation of the embedded fastening nut 120 at the bottom of the connection groove.

According to FIGS. 2A and 2B, these embedded anchorage reinforcing bars 110 can be installed in advance inside the formwork (not shown) for the PC slab 210 using those formed horizontally in a V shape, and both wings 111 ) It can be seen that the embedded fastening nut 120 can be used in advance in such a way that it is fixed inside the connection part 112 between the two by welding, etc.,

Referring to Figure 2b, it is installed to be buried in the lower part of the connection groove 220 formed on both connection sides (A) of the PC slab 210.

Next, the embedded fastening nut 120 is installed to be embedded in the lower part of the connection groove 220 formed on both connection sides (A) of the PC slab 210 together with the embedded anchoring rebar 110, as shown in FIGS. 2A and 2B. As a nut, the fastening bolt 160 is inserted and fastened to the embedded fastening nut 120 so that the semicircular connection plate 140 can be fixedly installed on the upper surface of the embedded plate 130 by the fastening bolt 160.

Referring to FIG. 2b, this embedded fastening nut 120 can be used by setting at least one hexagonal nut that has been previously fixed to the embedded anchoring rebar 110 by welding, etc., set up and down,

It is set vertically and the screw portion of the fastening bolt 160 is lowered and fastened internally, so that the semicircular connection plate 140 is fixedly installed on the upper surface of the embedded plate 130, and at least You can install more than one.

Next, the buried plate 130 is pre-installed so that its upper surface is exposed on the bottom of the connecting groove 220 of the PC slab 210, as shown in FIGS. 2A and 2B, and a semicircular connecting plate 140 is attached to the upper surface with a fastening bolt ( 160) It is a horizontal plate that serves to ensure fixed installation.

For this purpose, referring to Figure 2a, the embedded plate 130 is formed with a fastening hole 131 that is in contact with and communicates with the embedded fastening nut 120 at the bottom of the connecting groove 220, corresponding to the bottom of the connecting groove 220. It can be seen that a horizontal plate in the form of a rectangular plate can be used.

Next, as shown in FIGS. 2A and 2B, the semicircular connection plate 140 is connected to both side connection flanges 141 on both buried plates 130 that are pre-installed so that the upper surface is exposed to the bottom of the connection groove 220 of the PC slab 210. It is fixed by the fastening bolt 160, and the semicircular body portion 142 between the fixed two side connection flanges 141 passes through both connection sides A, connecting both PC slabs 210 to each other,

As shown in Figure 2c, deformation due to horizontal shear (Y-axis direction) occurring on the connection side (A) of the PC slab 210 due to an external force applied, opening due to tension in the width direction (X-axis direction), and vertical load It effectively resists all loads acting in three axes (X, Y, Z), such as vertical shear and vertical deflection (Z-axis direction).

Referring to FIG. 2A, this semicircular connection plate 140 is formed so that both connection flanges 141 in the form of horizontal plates extend from both ends of the semicircular body 142 passing between both connection sides A, It can be seen that a through slot 143 is formed in the semicircular body 142.

Accordingly, referring to FIGS. 2A and 2C, the semicircular body portion 142 is restrained by the connecting flanges 141 on both sides, so that it can efficiently resist vertical shear and vertical deflection (Z-axis direction) due to vertical load. This allows it to play a role in resisting the level difference caused by vertical deflection during the installation process of both PC slabs 210.

In addition, it plays a role in resisting deformation due to horizontal shear (Y-axis direction) and opening due to tension in the width direction (X-axis direction).

Referring to FIGS. 2A and 2B, the two-side connection flange 141 is a semicircular body portion ( 142) by restraining both ends to effectively resist deformation due to horizontal shear (Y-axis direction), opening due to tension in the width direction (X-axis direction), and vertical shear and vertical sagging (Z-axis direction) due to vertical load. A fastening hole 144 having an oval shape is formed so that the fastening bolt 160 can pass through it and be fastened to the embedded fastening nut 120 via the fastening hole 131 of the embedded plate 130. I do it.

Referring to FIGS. 2A, 2B, and 2C, the through slot 143 is a groove-shaped slit extending to both sides of the semicircular body portion 142, and the filler 170 is connected to the semicircular connection plate 140 through this through slot. ) It can be seen that it plays a role in smoothly filling the lower part of the.

Next, the elastic means 150 is a spring fixedly installed between both lower ends inside the semicircular body 142 of the semicircular connection plate 140 to pass through both connection sides A, as shown in FIGS. 2A and 2B. Including, it serves to restore deformation and movement due to the load acting on the semicircular connection plate 140 to its original state.

These elastic means 150 are deformed by horizontal shear occurring on the connection side (A) of the PC slab 210 (Y-axis direction), opened by tension in the width direction (X-axis direction), and vertically caused by vertical load. During deformation and movement due to shear and vertical deflection (Z-axis direction),

In particular, in terms of vertical shear and vertical deflection (Z-axis direction) due to vertical load during the installation process of the PC slab (210), the steps that occur during the installation process of the PC slab (210) must be restored, or the PC slab (210) may be damaged by the vertical load. 210) It has the function of preventing gap opening by restoring it to its original position.

Using a plurality of springs as the elastic means 150, both ends of the spring can be installed in advance between the lower ends of both sides inside the semicircular body 142.

Next, as shown in FIGS. 2A and 2B, the fastening bolt 160 is damaged by horizontal shear that occurs on the connection side (A) of the PC slab 210 due to vertical load, horizontal load, etc. during the installation process of the PC slab 210. The semicircular connection plate 140, which has been deformed and moved by deformation (Y-axis direction), opening due to tension in the width direction (X-axis direction), and vertical shear and vertical deflection (Z-axis direction) due to vertical load, is buried plate ( 130) again serves as a fixed setting.

For example, when an upper and lower step occurs between the PC slabs 210, the semicircular connecting plate 140 is temporarily fastened to the embedded plate 130 by tightening the fastening bolt 160. Due to its own elasticity and the spring action of the elastic means 150, the sagging PC slab 210 is brought up again to overcome the step.

Referring to FIG. 2A, the fastening bolt 160 is composed of a bolt portion 162 extending downward from a bolt head 161 that may further include a washer, and the bolt portion 162 is connected to the semicircular connection plate 140. The semicircular connection plate 140 is finally fastened into the embedded fastening nut 120, which is formed of hexagonal nuts stacked up and down, through the fastening holes 144 formed in the connection flanges 141 on both sides. It is pressed and fixed to the plate 130.

As we have seen, in this pressing and fixing process, the self-elasticity of the semicircular connecting plate 140 and the spring action of the elastic means 150 allow the sagging PC slab 210 to rise again to overcome the step. .

Next, referring to FIGS. 2B and 2C, the filler 170 is filled and connected to the connection groove 220 at the bottom of the semicircular connection plate 140 through the through slot 143 formed in the semicircular connection plate 140. It serves as a finishing material to ensure that both PC slabs 210 are integrated with each other on the side (A).

As a result, during the installation of both PC slabs (210), the deformation and movement due to the load acting on the semicircular connection plate (140) on the connection side (A) can be restored to their original state, so that both connected PC slabs (210) can be restored to their original state. 210) can be finally integrated.

Figure 2c shows an example of the operation of the concrete structure joining device 100 of the present invention, and the action of the concrete structure joining device 100 in the connection groove 220 can be observed before filling with the filler 170. .

First, the external force acting on the concrete structure joining device 100 at the connection side (A) of both PC slabs 210 can be decomposed into the X, Y, and Z axes (3 axes directions).

First, the There is,

Next, the Y-axis direction can be said to be a horizontal direction extending along the connection side (A) at a right angle to the

Next, the Z-axis direction can be said to be a vertical direction extending at right angles to the X and Y axes, and can be said to be the direction of vertical shear and vertical deflection of the PC slab 210 due to vertical load.

Accordingly, in the process of installing both PC slabs 210 adjacent to each other (pre-tightening of fastening bolts), the tension of both PC slabs 210 causes expansion in the direction (X-axis direction) due to the construction load.

If deformation or movement of both PC slabs 210 occurs, such deformation or movement can be resisted by the self-elasticity of the semicircular connection plate 140, and the elastic means 150 can add restoring force to this resistance. , By final fastening of the fastening bolts 160, the final semicircular connection plate 140 can be fixed and set again to the embedded plate 130.

Next, in the process of installing both PC slabs 210 adjacent to each other (pre-tightening of fastening bolts), deformation (Y-axis direction) due to horizontal shear of both PC slabs 210 due to construction load,

When deformation or movement of both PC slabs 210 occurs, such deformation and movement can be resisted by the self-elasticity of the semicircular connection plate 140, and the elastic means 150 can add restoring force to this resistance. And, by final fastening of the fastening bolts 160, the final semicircular connection plate 140 can be fixed and set again to the embedded plate 130.

Next, in the process of installing both PC slabs 210 adjacent to each other (pre-tightening of fastening bolts), the vertical shear and vertical deflection (Z-axis direction) of the PC slab 210 due to the construction load, which is a vertical load,

When deformation or movement of both PC slabs 210 occurs, such deformation and movement can be more effectively resisted by the restoring action of the elastic means 150 under the self-elasticity of the semicircular connection plate 140, and in particular, the elastic means The spring action of (150) causes the sagging PC slab (210) to rise again, thereby overcoming the step.

[PC slab (210) construction method using the concrete structure joining device (100) of the present invention]

Figures 3a and 3b are illustrations of a PC slab 210 construction method using the concrete structure joining device 100 of the present invention.

The concrete structure joining device 100 of the present invention is used to join and integrate the connection sides (A) of the PC slab 210 among the concrete structures 200.

At this time, when the concrete structure joining device 100 manufactures the PC slab 210, the PC slab 210 has embedded anchoring rebar 110, embedded fastening nut 120, and embedded plate 130 embedded in the connection groove 220. It is formed in advance as much as possible, so that the upper surface of the buried plate 130 is exposed in the connecting groove 220, the semicircular connecting plate 140 is prepared by integrating the elastic means 150 in advance, and the fastening bolt 160 is installed at the site. When the setting of the PC slab 210 is completed by pre-fastening, the filler 170 is finally completed in the connection groove 220 through the through slot 143 of the semicircular connection plate 140.

Accordingly, as shown in Figure 3a, the PC slab 210 is manufactured so that the embedded anchorage rebar 110, embedded fastening nut 120, and embedded plate 130 are embedded.

This PC slab 210 is manufactured in advance at a factory using molds, etc.

At this time, the form is manufactured so that the connecting groove 220 is formed while arranging the necessary reinforcing bars, etc. inside the form,

An embedded anchoring rebar 110 that can set the position of the embedded fastening nut 120 embedded in the lower part of the connection groove 220 of the PC slab 210 is set inside the form,

In addition, the buried plate 130 is set inside the form so that its upper surface is exposed to the bottom of the connection groove 220 of the PC slab 210 so that it communicates with the embedded fastening nut 120 exposed on the bottom of the connection groove 220.

At this time, it can be seen that the embedded plate 130 has a fastening hole 131 formed in communication with the embedded fastening nut 120 exposed on the bottom of the connecting groove 220,

Concrete is poured and cured into the formwork so that the fastening hole 131 of the buried plate 130 is exposed on the bottom of the connection groove 220 of the PC slab 210.

Next, as shown in Figure 3b, the PC slab 210 manufactured to embed the embedded anchoring rebar 110, embedded fastening nut 120, and embedded plate 130 is brought into the site and placed on the wall or pillar (vertical element). On the connection side (A), the elastic means 150 is connected and installed horizontally using an integrated semicircular connection plate 140.

The PC slab (210), which is manufactured to embed the embedded anchoring rebar (110), embedded fastening nut (120), and embedded plate (130), is manufactured in large numbers, brought to the site, lifted with a crane, etc., and used as a wall or pillar (vertical element). It is installed so that the connection side (A) is in contact with the top, and the connection groove 220 is in communication.

In this installation process, a construction load is generated, and there are cases where the level difference of the PC slab 210 does not match due to clearance and construction errors. That is, deformation due to horizontal shear (Y-axis direction), opening due to tension in the width direction (X-axis direction), and vertical shear and vertical sagging (Z-axis direction) due to vertical load may occur.

Accordingly, the semicircular connecting plate 140, in which the elastic means 150 is integrated, is temporarily fastened to each buried plate 130 exposed in the connecting groove 220 of both PC slabs 210 using the fastening bolt 160. , so that the generated deformation, opening, sagging, etc. are primarily absorbed,

By tightening the final fastening bolt 160, the semicircular connection plate 140 is finally fixed and installed on the embedded plate 130, and both PC slabs 210 are joined at the connection side (A).

For example, when an upper and lower step occurs between the PC slabs 210, the semicircular connecting plate 140 is temporarily fastened to the embedded plate 130 by tightening the fastening bolt 160. Due to its own elasticity and the spring action of the elastic means 150, the sagging PC slab 210 is brought up again.

Accordingly, the filler 170 is filled into the connection groove 220 at the bottom of the semicircular connection plate 140 through the through slot 143 formed in the semicircular connection plate 140, and connects both PC slabs 210 on the connection side (A). become integrated with each other.

Therefore, in the case of the present invention, it is possible to connect and integrate the PC slab (210, solid precast floor slab) using the semicircular connection plate 140 using the fastening bolt 160, which is a high-strength bolt, so that it can be connected and integrated in the field. The constructability and economic feasibility are very excellent.

It is possible to resist external forces acting in all three axes by using a semicircular connecting plate 140 equipped with an elastic means 150 including a spring, which is simple but has a very excellent structural effect.

Since the PC slab (210, solid precast floor slab) is used compared to the conventional half-slab PC slab, the construction type is simplified, making rapid construction of the concrete structure 200 possible.

It is natural that this concrete structure joining device 100 can be used in addition to the PC slab 210 for precast walls, connections between precast beams and PC slabs, and connections between PC slabs and columns.

The description of the present invention described above is for illustrative purposes, and those skilled in the art will understand that the present invention can be easily modified into other specific forms without changing the technical idea or essential features of the present invention. will be. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. For example, each component described as single may be implemented in a distributed manner, and similarly, components described as distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. do.

100: Concrete structure joining device
110: Embedded anchorage rebar
111: both wings 112: connection part
120: Embedded fastening nut
130: buried plate 131: fastening hole
140: semicircular connection plate
141: Connecting flange on both sides 142: Semicircular body
143: Through slot 144: Fastening hole
150: Elastic means (including spring)
160: fastening bolt
161: bolt head 162: bolt portion
170: Filler
200: Concrete structure 210: PC slab
220: Connection groove A: Connection side

Claims (13)

In the concrete structure joining device 100 for joining and integrating the concrete structures 200, which are PC slabs 210, with each other,
Both side connecting flanges 141 are fixed to both buried plates 130 that are pre-installed so that the upper surface is exposed to the concrete structure 200, and the semicircular body portion 142 between the fixed two side connecting flanges 141 is connected to both connection sides. A semicircular connection plate 140 connecting the concrete structures 200 to each other via (A); and
It includes an elastic means 150 including a spring that is fixedly installed between both lower ends of the semicircular body 142 of the semicircular connection plate 140 via both connection sides A,
The connection flanges 141 on both sides of the semicircular connection plate 140 are fixed to each embedded plate 130 formed on each of the PC slabs 210 by fastening bolts 160 and integrated into the semicircular body portion 142. ) by restraining both ends to resist deformation due to horizontal shear (Y-axis direction), opening due to tension in the width direction (X-axis direction), and vertical shear and vertical sagging (Z-axis direction) due to vertical load. A fastening hole 144 is formed so that the fastening bolt 160 penetrates and can be fastened to the embedded fastening nut 120 via the embedded plate 130, and the elastic means 150 is connected in a semicircular shape. It serves to restore deformation and movement due to the load acting on the plate 140 to its original state, and is responsible for vertical shear and vertical deflection (Z-axis direction) due to the vertical load during the installation process of the PC slab 210. In order to have the function of restoring the level difference that occurs during the installation of the PC slab (210) or preventing the gap between the PC slabs (210) from opening due to a vertical load, a plurality of springs are used to restore the spring amount. A concrete structure joining device that uses a plurality of ends to be pre-installed between both lower ends inside the semicircular body 142. According to paragraph 1,
The concrete structure 200 is a PC slab 210 with a connecting groove 220 formed, and a semicircular connecting plate 140 is formed on the bottom of the connecting groove 220,
The buried plate 130 is,
It is pre-installed so that the upper surface is exposed on the bottom of the connecting groove 220 of the PC slab 210, and includes a horizontal plate that allows the semicircular connecting plate 140 to be fixed and installed on the upper surface by the fastening bolt 160, and the connecting groove ( 220) A concrete structure joining device that forms a fastening hole 131 that contacts and communicates with the lower embedded fastening nut 120. According to paragraph 2,
The embedded fastening nut 120,
It includes a nut installed to be embedded in the lower part of the connection groove 220 formed on both connection sides (A) of the PC slab 210 along with the embedded anchorage rebar 110,
A concrete structure joining device in which the fastening bolts 160 are inserted and fastened to the embedded fastening nuts 120 so that the semicircular connecting plate 140 can be fixedly installed on the upper surface of the buried plate 130 by the fastening bolts 160. According to paragraph 3,
The buried anchorage rebar 110 is,
It is installed to be embedded in the lower part of the connecting groove 220 formed on both connection sides (A), and the position of the embedded fastening nut 120, which is installed embedded in the lower part of the connecting groove 220 of the PC slab 210, is set. It is supported to enable stable fixed installation of the embedded fastening nut 120 at the lower part of the connection groove of (210), and is formed horizontally in a V shape, and is provided with an embedded fastening nut ( 120) A concrete structure joining device including one manufactured to be fixed in advance. delete According to paragraph 2,
The semicircular body portion 142 of the semicircular connection plate 140 is,
It is restrained by the connecting flanges (141) on both sides, making it possible to resist vertical shear and vertical deflection (Z-axis direction) due to vertical load, and the step due to vertical deflection during the installation process of both PC slabs (210). A concrete structure joining device that plays a role in resisting deformation due to horizontal shear (Y-axis direction) and opening due to tension in the width direction (X-axis direction). According to clause 6,
A concrete structure joining device that is a groove-shaped slit extending to both sides of the semicircular body 142 and allows filler 170 to be filled into the lower part of the semicircular connection plate 140 through the through slot. delete According to paragraph 2,
The fastening bolt 160 is,
A nut composed of a bolt part 162 extending downward from the bolt head 161, and the bolt part 162 penetrates the fastening hole 144 formed in the connection flange 141 on both sides of the semicircular connection plate 140. It is finally fastened inside the embedded fastening nut 120 formed by pressing and fixing the semicircular connection plate 140 to the embedded plate 130,
In the compression fixing process, the self-elasticity of the semicircular connection plate 140 and the spring action of the elastic means 150 bring the sagging PC slab 210 upward again to overcome the level difference. A concrete structure joining device . (a) manufacturing the PC slab 210 so that the fastening hole 131 of the embedded plate 130 is exposed on the bottom of the connection groove 220 of the PC slab 210; and
(b) A concrete structure joining device including a semicircular connection plate 140 with elastic means 150 integrated at the connection side (A) by bringing the PC slab 210 to the site and placing it on a wall or pillar (vertical element). It includes the step of connecting and installing horizontally using (100),
The semicircular connection plate 140 has both connection flanges 141 fixed to both embedded plates 130 pre-installed so that the upper surface is exposed on the bottom of the connection groove 220, and the semicircular body between the fixed connection flanges 141 on both sides. The concrete structure 200 is connected to each other by allowing the part 142 to pass through both connection sides (A),
The elastic means 150 includes a spring that is fixedly installed between both lower ends inside the semicircular body 142 of the semicircular connection plate 140 to pass through both connection sides A, and the semicircular connection plate 140 ), the connecting flanges 141 on both sides are fixed to each embedded plate 130 formed on each of the PC slabs 210 by fastening bolts 160 and restrain both ends of the integrated semicircular body portion 142. This allows it to resist deformation due to horizontal shear (Y-axis direction), opening due to tension in the width direction (X-axis direction), and vertical shear and vertical deflection due to vertical load (Z-axis direction). The fastening hole ( 144) is formed so that the fastening bolt 160 penetrates and can be fastened to the embedded fastening nut 120 via the embedded plate 130, and the elastic means 150 acts on the semicircular connecting plate 140. It serves to restore deformation and movement due to the load to its original state, and in the vertical shear and vertical deflection (Z-axis direction) due to the vertical load during the installation process of the PC slab (210), the PC slab (210) In order to have the function of restoring the steps that occur during the installation process or preventing the gap between the PC slabs (210) from opening due to the vertical load, a plurality of springs are used to replace both ends of the spring with a semicircular body ( 142) PC slab construction method using a concrete structure joining device that uses multiple pre-installed units between the bottom of both sides on the inside. According to clause 10,
In step (a), the PC slab 210 is
Manufacturing the form so that the connecting groove 220 of the PC slab 210 is formed,
An embedded anchoring rebar 110 that can set the position of the embedded fastening nut 120 embedded in the lower part of the connection groove 220 of the PC slab 210 is set inside the form,
Set inside the form so that the top surface is exposed to the bottom of the connection groove 220 of the PC slab 210 so that the embedded plate 130 communicates with the embedded fastening nut 120 exposed on the bottom of the connection groove 220,
A PC slab construction method using a concrete structure joining device that is manufactured by pouring and curing concrete into the formwork. According to clause 10,
In step (b),
The semicircular connecting plate 140, in which the elastic means 150 is integrated, is temporarily fastened to each buried plate 130 exposed in the connecting groove 220 of both PC slabs 210 using fastening bolts 160, The generated deformation, opening, and sagging are primarily absorbed, and the semicircular connection plate 140 is finally fixed to the buried plate 130 by tightening the fastening bolts 160 to connect both PC slabs 210 to the connection side ( A) PC slab construction method using a concrete structure joining device to be joined in A). According to clause 10,
The PC slab 210 in step (b) includes a solid precast floor slab, and the filler 170 is inserted into the semicircular connection plate 140 through the through slot 143 formed in the semicircular connection plate 140. A PC slab construction method using a concrete structure joining device that fills the lower connection groove 220 and integrates both PC slabs 210 on the connection side (A).