KR102585366B1 - Casing typed shear connecting apparatus, concrete marine buoyancy structure connection method and concrete marine buoyancy structure using the same - Google Patents

Abstract

Disclosed is a casing-type shear connection device that can effectively resist separation and shear forces in the laminate connection of concrete buoyancy bodies, while ensuring constructability and enabling rapid transportation and construction, a method of connecting concrete buoyancy bodies using the same, and a concrete buoyancy body, The casing type shear connection device includes a casing connector disposed so that the internal space (S) communicates with each other upward and downward on the upper and lower joint surfaces (E) of the concrete buoyancy bodies stacked upward and downward; And a shearing insert connector that is inserted downwardly from above the internal space (S) so as to penetrate the upper and lower joint surfaces (E) and resists the shear force and separation force acting on the upper and lower joint surfaces (E). do.

Description

Casing type shear connection device, method of connecting concrete buoyancy body using the same, and concrete buoyancy body

The present invention relates to a casing type shear connection device, a method of connecting a concrete buoyancy body using the same, and a concrete buoyancy body. More specifically, a casing-type shear connection device that can effectively resist separation force and shear force in the laminate connection of exterior panels (precast members) of a concrete buoyancy body while ensuring constructability, enabling rapid transportation and construction, and concrete using this device. It relates to buoyancy body connection methods and concrete buoyancy bodies.

Figure 1a shows an example of a conventional concrete buoyancy body (floating body).

The concrete buoyancy body (floating body) refers to a structure that can float on the water by buoyancy, such as a pontoon. In particular, the outer peripheral surface (outside) is covered with concrete (10) to effectively resist waves and currents. ), but it can be seen that a buoyancy body 20 is formed inside the concrete covering layer to secure buoyancy.

At this time, the concrete cover 10 may be formed by pouring concrete into a form (not shown) installed spaced apart from the outer peripheral surface of a plurality of assembled buoyancy bodies 20 and integrating them.

Referring to FIG. 1B, the concrete covering 10 may use a precast method in which concrete panels are integrated into each other.

Figure 1b shows an example of installing an external panel of a conventional concrete buoyancy body (floating body).

In other words, the buoyancy body of a concrete buoyancy body (floating body) is usually manufactured in the form of a box with an empty interior, and various materials and materials can be used.

EPS and PE buoyancy bodies can be used, but it can be seen that buoyancy bodies manufactured including a steel frame can also be used as long as buoyancy is secured and adjustable.

Accordingly, according to Figure 1b, it can be seen that it can be installed by forming a fastening hole in the buoyancy body 30 made of a steel frame and fastening the exterior panel 40 to the fastening hole.

This exterior panel 40 must take into account the convenience of manufacturing, non-corrosiveness, ease of assembly and installation, etc., but must also be able to effectively resist waves. It can also be seen that precast concrete panels can be used considering economic efficiency. .

Figures 1c and 1d show examples of connection parts of a conventional concrete buoyancy body (floating body).

The concrete buoyancy body (floating body, 50) is manufactured to a certain size in consideration of manufacturing and construction. When constructing it to float on the sea, each concrete buoyancy body (floating body) is constructed by connecting to each other. It can be seen that the connection part of the concrete buoyant body (floating body) is inevitably formed.

Accordingly, looking at the connection portion of the concrete buoyancy body (floating body, 50) in Figure 1c, the connecting reinforcing bars 51 are pulled out from adjacent concrete buoyancy bodies (floating bodies) and coupler to each other at the notch portion (blockout portion, 52). connected by (53),

It can be seen that the connecting portion of the concrete buoyant body (floating body) can be grouted (54).

In addition, according to FIG. 1D, looking at the connection portion of the concrete buoyancy body (floating body, 50), the connecting blocks and connecting rods 55, which are drawn out from adjacent concrete buoyancy bodies (floating bodies), are connected to each other at the notch portion (blockout portion, 52). 56), and it can be seen that the connecting portions of the concrete buoyancy body (floating body) can be made to resist shear force with each other by the grouting finish 54 and the shear key 57.

Figures 1e and 1f are examples of connection parts of a conventional precast structure constructed on the ground.

According to Figure 1e, a connecting device capable of resisting separation force and shear force is introduced when constructing a precast structure such as a precast culvert by connecting it upward and downward.

Accordingly, the connection device is an internal space ( 17) is exposed, and the connecting steel material 25 is inserted into the inner space 17 of both connecting fittings 18 in the inner space 17, while the approximately central portion of the connecting steel material 25 is connected to the connecting surface 12a. It can be seen that it is intended to pass through ,12b).

Accordingly, the connecting steel material 25 resists the shear stress occurring on the connecting surfaces 12a and 12b, and the separating force is closed by a grouting material (not shown) while inserted into both connecting metal fittings 18, so that the connecting steel material 25 It can be seen that both ends of (25) are provided with flange-type anchoring means for resistance.

However, in most cases, the internal space 17 is formed only to the extent that the connecting steel 25 can be inserted in order to reduce the amount of finishing of the grouting material, so there is a limit when sufficient connection performance must be secured, and the connecting steel 25 ) is not directly connected to the fixed reinforcing bars (21, 22) embedded in the connection surfaces (12a, 12b) of the upper precast structure (10a) and the lower precast structure (10b), so there is also a limit to securing connection performance. do.

In addition, since the connecting steel material 25 is horizontally inserted into the connection surfaces 12a and 12b of the upper precast structure 10a and the lower precast structure 10b, it is separate from the upper precast structure 10a lifting process. It is inevitable that this will be done, so it can be seen that there are limits to securing constructability and workability.

According to Figure 1f, when constructing a vertical wall such as a soundproof wall, the precast vertical wall 71 is manufactured within a liftable range, and in the process of constructing the precast vertical wall 71 by vertically stacking, the precast vertical wall (71) is It can be seen that vertical connecting steel members 72 are installed on the upper and lower joint surfaces (E) of 71).

That is, insertion holes into which the top and bottom of the vertical connection steel 722 can be inserted are formed on both connection surfaces of the precast vertical wall 71, respectively, and insertion holes are formed on the upper surface of the lower precast vertical wall 71. Insert the lower end of the vertical connecting steel material 72 so that the upper end is exposed to the upper side,

The upper end of the vertical connecting steel material 72 is inserted into the insertion hole formed on the bottom of the upper precast subic wall 71, and the lower end is inserted into the insertion hole formed on the upper surface of the lower precast vertical wall 71, and the insertion hole is It is also finished with grouting material.

Accordingly, it can be seen that the lower precast vertical wall 71 is capable of resisting shear force and separation force.

However, the vertical connecting steel material 72 can secure the connection performance of the lower precast vertical wall 71), the upper precast vertical wall 71, and the grouting material of the insertion hole, but it is necessary to use the grid-type steel frame 73. Therefore, although it is possible to secure connection performance, there are limits to its application.

Japanese Patent No. 3793852 (Title of invention: Inter-block joining method of concrete structure using precast concrete blocks, Publication date: November 10, 1998) Republic of Korea Patent No. 10-1419188 (Title of invention: Concrete floating pontoon assembly, Publication date: July 14, 2014) Republic of Korea Patent No. 10-2368919 (Title of invention: Sea connection device and construction method for concrete floating structures, Publication date: January 11, 2018) Republic of Korea Patent No. 10-2319792 (Title of invention: Two-way precast panel structure and structure using the same, Publication date: September 17, 2021) Republic of Korea Patent No. 10-2368919 (Title of invention: Marine floating sofa using concrete pontoon with adjustable buoyancy, Publication date: March 2, 2022) Republic of Korea Patent No. 10-1252708 (Title of invention: Direct construction method of offshore floating structure with underwater space, Publication date: March 2, 2022) Republic of Korea Patent No. 10-1252709 (Title of invention: Marine floating structure with buoyancy reflection and construction method thereof, Publication date: November 2, 2012) Republic of Korea Patent No. 10-1318111 (Title of invention: Wave force-reducing multi-row pile hybrid offshore wind power support structure and construction method thereof, Publication date: October 15, 2013) Republic of Korea Patent No. 10-1459649 (Title of invention: Double floating structure for installation of offshore support structure and method of constructing offshore support structure using the same, Publication date: November 12, 2014) Republic of Korea Patent No. 10-1665979 (Title of invention: Offshore wind power support structure using sea concrete base and construction method thereof, Publication date: October 13, 2016) Republic of Korea Patent No. 10-1932432 (Title of invention: Jacket structure construction method with jacket leg can, Publication date: September 5, 2018) Republic of Korea Patent No. 10-1997165 (Title of invention: Floating platform with sea cucumber floating body and construction method thereof, Publication date: June 19, 2019) Republic of Korea Patent No. 10-2205960 (Title of invention: Tower connection structure of foundation structure for partial repowering of wind turbine and construction method thereof, Publication date: January 21, 2021) Republic of Korea Patent No. 10-2266480 (Title of invention: Monopile capable of drawing using tension material and its construction method, Publication date: May 4, 2021)

Republic of Korea KICT2018-146 (Name: Buoyancy and counting system development plan for offshore solar power generation, Publication date: December 2018) Korea Photovoltaic Society of Korea Technology status and equivalent review by field (Name: Floating solar power generation system technology development and market trends, Publication date: December 2015)

Accordingly, the present invention is to construct the exterior panels (A, precast members) of a concrete buoyancy body by stacking them vertically, by directly structurally connecting the exterior panels (A), which are simply stacked, in the process of inserting them vertically downward. The technical challenge is to provide a casing-type shear connection device that can secure constructability and workability while ensuring the same connection performance.

In addition, the present invention aims to solve the technical problem of providing a concrete buoyancy body manufactured by vertically stacking the exterior panels (A) of the concrete buoyancy body using the casing type shear connection device and a method of manufacturing the concrete buoyancy body.

In addition, the present invention aims to provide a concrete buoyancy body and a method of manufacturing a concrete buoyancy body that can simply connect and move the concrete buoyancy body on which the exterior panel (A) of the concrete buoyancy body is installed using the casing type shear connection device. It is a technical task to do.

The casing type shear connection device of the present invention to achieve the above problem,

A casing connector disposed on the upper and lower joint surfaces (E) of the exterior panels (A, precast members) stacked upward and downward so that the internal space (S) communicates with each other upward and downward; And a shearing insert connector including a reinforcing bar assembly that is inserted downwardly from above the internal space (S) so as to penetrate the upper and lower joint surfaces (E) and resists the shear force and separation force acting on the upper and lower joint surfaces (E). Contains ;,
The casing connector is a vertical steel pipe that ensures integrity with the exterior panel (A) by having casing connecting reinforcing bars arranged horizontally up and down on the outer circumferential surface so as to be located on the upper and lower joint surfaces of the exterior panel (A). It includes, wherein the casing connecting rebar is formed so that the other side of the rebar is formed in a hook shape at one end extending inside the exterior panel (A) and extends inward through the casing connecting material, and the other side of the casing connecting rebar is formed inside the exterior panel (A). The position is fixed by being directly connected to an internal connecting reinforcing bar including a horizontally arranged band reinforcing bar in the space (S), and the internal connecting reinforcing bar includes a horizontally arranged circular band reinforcing bar, and is connected to the internal space (by the casing connecting reinforcing bar). S) are arranged to be spaced apart from the inner side of the casing connector at the top and bottom so that the casing connector rebar does not interfere with the filling when the shear filler is filled.

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In addition, the concrete buoyancy body using the casing-type shear connection device of the present invention to achieve the above problem is set to contact both the upper and lower concrete buoyancy bodies and the lower concrete buoyancy bodies stacked upward and downward, and communicates upward and downward. A connection flange with an internal space (S) formed; A casing connecting material disposed on the upper and lower joining surfaces (E) of the connecting flange so that the internal space (S) communicates with each other upward and downward; And a shear insertion connector including a reinforcing bar assembly that is lowered and inserted from the top plate of the upper concrete buoyancy body into the casing connector, wherein the casing connector is located on the top of the exterior panel (A) formed on the connection flange. , Located on the lower joint surface, the outer peripheral surface includes a vertical steel pipe that ensures unity with the exterior panel (A) by arranging the casing connecting reinforcing bars horizontally up and down, and the casing connecting reinforcing bars are connected to the exterior panel. (A) The other side of the reinforcing bar, which has one end extending inward in the form of a hook, is formed to extend inward through the casing connecting material, and the other side of the casing connecting reinforcing bar is a band reinforcing bar arranged horizontally in the internal space (S). It is directly connected to and fixed in position to the internal connecting reinforcing bar, and the internal connecting reinforcing bar includes circular band reinforcing bars arranged horizontally, and is connected upward and downward to the internal space (S) by the casing connecting reinforcing bar from the inner surface of the casing connecting material. They are arranged to be spaced apart so that the casing connecting bars do not interfere with the filling when the shear filler is filled.

The method of connecting a concrete buoyancy body using the casing-type shear connection device of the present invention to achieve the above problem is (a) connected to the upper and lower joint surfaces (E) of the exterior panels (A, precast members) stacked top and bottom. Installing a casing connector so that the internal space (S) communicates top and bottom; and (b) a reinforcing bar assembly that is inserted downwardly from above the internal space (S) so as to penetrate the upper and lower joint surfaces (E) and directly resists the shear force and separation force acting on the upper and lower joint surfaces (E). Including the step of installing a shear insert connector,
The casing connecting material in step (a) is positioned on the upper and lower joint surfaces (E) of the exterior panel (A), so that the casing connecting reinforcing bars are arranged horizontally up and down on the outer circumferential surface to ensure unity with the exterior panel (A). It includes a vertical steel pipe to secure the casing connecting reinforcing bar, and the other side of the reinforcing bar is formed in a hook shape at one end extending inside the exterior panel (A) so that it extends inside through the casing connecting material. , the other side of the casing connecting reinforcing bar is directly connected to the internal connecting reinforcing bar including a horizontally arranged band reinforcing bar in the internal space (S) to fix the position, and the internal connecting reinforcing bar includes a horizontally arranged circular band reinforcing bar, The casing connecting reinforcing bars are arranged to be spaced apart from the inner surface of the casing connecting material at the top and bottom in the internal space (S), so that the casing connecting reinforcing bars do not interfere with the tight filling when the shear filler is filled.

In the casing-type shear connection device according to the present invention, for example, the internal space (S) of the casing-type member embedded in the bottom of another exterior panel (A) is connected to the upper surface of the exterior panel (A) of a concrete buoyancy body and is in contact with each other. It is installed so that the internal penetrating reinforcing bar extends from the inside of the exterior panel (A) in the communicating internal space (S) so that it is exposed and integrated with the strip reinforcing bar, and the reinforcing bar network is inserted and connected to the strip reinforcing bar. By finishing with a filler, the reinforcing bar network can resist shear force by penetrating and passing through the upper and lower joint surfaces (E) of the exterior panel (A).

In addition, the reinforcing bar network of the casing-type shear connection device according to the present invention extends at the top and bottom of the inner space of the casing member installed to contact each other at the upper and lower joint surfaces (E), and is finished with a filler material to form a casing-type member. become integrated with each other and can effectively resist the separation force of the exterior panel (A).

In addition, the reinforcing bar network of the casing-type shear connection device according to the present invention is lifted and installed in a casing-type member that communicates with each other, and can be connected to and installed in the band reinforcement installed in the internal space (S) of the casing-type member by a holder at the top. The installation process is simple, making it possible to quickly construct a concrete buoyancy body with the exterior panel (A) installed.

In addition, the casing type shear connection device according to the present invention can be applied to the exterior panel of a concrete buoyancy body (floating body) to quickly manufacture and transport the concrete buoyancy body, making it a more economical casing type shear connection device. It is possible to provide a concrete buoyancy body and a method for manufacturing a concrete buoyancy body.

In addition, the casing type shear connection device according to the present invention can be directly applied to the connection flange and opening of a concrete buoyancy body (floating body), enabling quick connection and transportation of the concrete buoyancy body, making it a more economical casing type. It becomes possible to provide a shear connection device, a concrete buoyancy body using the same, and a method for manufacturing a concrete buoyancy body.

Figure 1a is an illustration of a conventional concrete buoyancy body (floating body);
Figure 1b is an example of the installation of an external panel of a conventional concrete buoyancy body (floating body);
Figures 1C and 1D are illustrations of connection parts of a conventional concrete buoyancy body (floating body);
Figures 1e and 1f are examples of connection parts of precast structures conventionally constructed on the ground;
2A and 2B are illustrations and usage diagrams of the casing type shear connection device of the present invention;
Figures 3a, 3b and 3c are illustrations of a method of connecting an exterior panel (A) using the casing type shear connection device of the present invention;
Figures 4a, 4b, and 4c show examples of concrete buoyancy bodies using the casing-type shear connection 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 that are not related 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.

[Casing type shear connection device (100) of the present invention]

2A and 2B are illustrations and usage diagrams of the casing type shear connection device 100 of the present invention.

The casing-type shear connection device 100 is, for example, applied to the upper and lower joint surfaces (E) of the exterior panels (A, precast members) of the concrete buoyancy bodies (200a, 200b), using conventional simple couplers, tendons, etc. It can be said that this is to overcome the limitation of using a connecting means that requires excessive work due to the large area of the upper and lower joining surfaces (E).

In addition, the casing-type shear connection device 100 can be naturally installed in the process of lifting and stacking the exterior panel (A), ensuring constructability and workability while also ensuring sufficient connection performance at the upper and lower joint surfaces (E). so that you can do it.

Accordingly, the casing type shear connector 100 is formed to include a casing connector 110, an insert connector 120 for shear, and a filler 130 for shear, as shown in FIGS. 2A and 2B.

First, as shown in FIGS. 2A and 2B, the K-shaped connecting member 110 is formed to communicate upward and downward at the upper and lower joint surfaces (E) of the exterior panels (A) stacked upward and downward, so that the upper and lower The shear insertion connector 120, which is inserted downwardly through the lower joint surface E, serves as a type of formwork installed to be buried by the shear filler 130.

Accordingly, referring to FIGS. 2A and 2B, the casing connector 110 has an internal space to secure space for installation so that the shear insert connector 120 penetrates the upper and lower joint surfaces (E) of the exterior panel (A). It can be seen that a vertical steel pipe with (S) is used.

Accordingly, it can be seen that the internal space (S) is arranged to communicate with each other upward and downward on the upper and lower joint surfaces (E) of the exterior panels (A), which are stacked upward and downward.

At this time, when manufacturing the exterior panel (A), the casing connector 110 is placed in advance inside the formwork (not shown) of the exterior panel (A), and is set by pouring concrete and embedding it in both internal spaces (S ) is installed in a way that determines the position of the casing connector 110 in advance so that it can communicate.

In addition, casing connecting reinforcing bars 111 are arranged horizontally up and down on the outer peripheral surface of the casing connector 110 so as to be positioned and fixed on the upper and lower joint surfaces E of the exterior panel A. It can be seen that this is being done to ensure integrity.

The casing connecting reinforcing bar 111 is formed so that one end extending inside the exterior panel A is formed in a hook shape, and the other side extends inward through the casing connecting material 110,

It can be seen that the other side of the casing connecting reinforcing bar 111 is directly connected to the internal connecting reinforcing bar 112 including a strip reinforcing bar arranged horizontally in the internal space (S) to fix the position.

At this time, it can be seen that the internal connecting reinforcing bar 112 uses, for example, a circular band reinforcing bar, so that a plurality of other sides of the casing connecting reinforcing bar 111 are connected along the outer peripheral surface of the internal connecting reinforcing bar 112, which is a circular band reinforcing bar.

Accordingly, it can be seen that the internal connecting reinforcing bar 112, which is the circular band reinforcing bar, is fixedly set inside the casing connecting material 110 by the casing connecting reinforcing bar 111.

As a result, it can be seen that the casing connector 110 is connected to and embedded in the internal reinforcing bars of the exterior panel (A) so that it can be integrated, as shown in FIGS. 2A and 2B.

The internal connecting reinforcing bar 112 is arranged to be spaced apart from the inner surface of the casing connecting material 110 up and down in the internal space (S) by the casing connecting reinforcing bar 111. Referring to Figure 3c, the shear filler 130 It can be seen that the casing connecting reinforcing bar 111 does not interfere with tight filling when being filled.

In addition, according to FIG. 2a, it can be seen that the casing connector 110 can use a vertical steel pipe with the same diameter at the top and bottom, or can use a tapered cone-shaped steel pipe whose diameter becomes narrower toward the bottom according to FIG. 2b.

In this way, when using a tapered cone-shaped steel pipe whose diameter narrows downward, the exterior panels (A) arranged at the top and bottom become more effective in resisting the separation force, such as a wedge action, against the separation force that tries to separate the exterior panels (A) from each other.

According to Figure 2b, the casing connector 110, which is a cone-shaped steel pipe, is set symmetrically up and down based on the upper and lower joint surfaces (E), so that the wedge action occurs more effectively up and down the upper and lower joint surfaces (E). You can see that it is being done.

In addition, the upper and lower inner spaces (S) are communicated so that when the shear filler 130 is filled in the inner space (S), the shear filler 130 does not leak into the lower inner space (S). A finishing plate in the form of a horizontal plate may be further formed in advance.

Next, the insert connector 120 for shear penetrates the upper and lower joint surfaces (E) of the exterior panel, as shown in FIGS. 2A and 2B, to the shear force and separation force acting on the upper and lower joint surfaces (E). It plays a role of direct resistance, and connects with the internal connecting reinforcing bar 112, which is a circular band reinforcing bar constituting the casing connecting material 110, to bear the shear force and separation force transmitted with the K-shaped connecting material 110. I do it.

This shear insertion connector 120 includes a reinforcing bar assembly that is inserted from top to bottom into the communicating internal space (S) of the casing connector 110.

That is, according to FIGS. 2A and 2B, it can be seen that the insert connector 120 for shear can be formed of a cylindrical reinforcing bar assembly. For example, a plurality of horizontal reinforcing bars 121 are formed spaced apart, and the horizontal reinforcing bars 121 ) so that the vertical reinforcing bars 122 that restrain the top and bottom are formed as one piece,

On the upper surface, it can be seen that the mounting reinforcing bar 123, which descends and is caught by the internal connecting reinforcing bar 112, extends to the outside of the horizontal reinforcing bar.

Accordingly, the insert connector 120 for shearing is manufactured as a cylindrical reinforcing bar assembly, and the operation of mounting it by the mounting rebar 123 by the internal connecting rebar 112 inside the casing connector 110 involves lifting the insert connector 120 for shearing. It can be seen that it can be installed simply by lowering it, showing that the installation work can be done very simply and quickly.

Accordingly, since the shearing insert connector 120 penetrates the upper and lower joint surfaces E, it directly resists the shear force of the exterior panel A that occurs on the upper and lower joint surfaces E,

This shear force is generated by the insertion connector 120 for shear being connected to the internal connecting reinforcing bar 112 of the casing connector 110, and as it is embedded and integrated by the shear filler 130, the shear force is generated along with the casing connector 110. You can see that it can be resisted.

In addition, the insert connector 120 for shearing penetrates the upper and lower joint surfaces (E) of the exterior panel (A), and the upper and lower portions of the exterior panel (A) are buried in the shearing filler 130 and cured. It is also possible to directly resist the separation force occurring on the joint surface (E).

Next, the shear filler 130 is set in the communicated internal space (S) using concrete filled in the communicated internal space (S) of the casing connector 110, as shown in FIGS. 2A and 2B. The casing connecting reinforcing bar 111, the internal connecting reinforcing bar 112, and the shear insertion connecting member 120 are embedded and serve to integrate with each other.

When this shear filler 130 is finally cured, it is formed to penetrate the upper and lower joint surfaces (E), so it also serves to additionally resist shear force with its own rigidity. It can be seen that this shear filler 130 can be filled from top to bottom, making rapid filling work possible.

[Exterior panel (A) connection method using the casing type shear connection device (100) of the present invention]

Figures 3a, 3b, and 3c show examples of a method of connecting an exterior panel (A) using the casing-type shear connection device 100 of the present invention.

As described above, the casing-type shear connection device 100 is formed of the casing connection material 110 and the insertion connection material 120 for shearing, and the shearing filler ( 130) is used to connect the exterior panels (A) arranged above and below to each other.

Accordingly, as shown in FIG. 3A, the casing connector 110 of the casing-type shear connector 100 is installed in advance on the exterior panel A to be stacked top and bottom.

The casing-type shear connection device 100 first forms the casing connector 110 on the exterior panel (A), and the exterior panel (A) can be a slab of a concrete buoyancy body, an exterior wall, etc.

At this time, the casing connector 110 is embedded in the upper and lower joint surfaces (E) of the exterior panel (A) so that the internal space (S) is exposed, and it can be seen that this casing connector 110 uses a vertical steel pipe. can,

It can be seen that the casing connecting reinforcing bars 111 are integrally fixed inside the exterior panel (A), and the internal connecting reinforcing bars 112 are set horizontally and spaced apart in the inner space (S) of the casing connecting material 110. You can.

In addition, it can be seen that the internal space (S) of the casing connector 110 is exposed by being opened up and down.

Next, as shown in FIG. 3b, the casing connector 110 of the casing type shear connector 100 is installed in advance and the exterior panel A with the interior space S exposed is stacked up and down to form the interior space S. It is set to communicate upward and downward, and the insert connector 120 for shearing is inserted into the internal space S communicating up and down and set to be mounted on the casing connector 110.

The exterior panel (A), where the casing connector 110 of the casing type shear connector 100 is installed and the internal space S is exposed, is set up and down, and for connection, the internal space of the casing connector 110 ( You can see that the initial setting is so that S) communicates upward and downward,

This is approached by first setting the exterior panel (A) at the bottom, then lifting and stacking the exterior panel (A) at the top.

Referring to FIG. 3b, the insert connector 120 for shear penetrates the upper and lower joint surfaces (E) of the exterior panel (A) and directly resists the shear force acting on the upper and lower joint surfaces (E). It serves to bear the shear force transmitted with the K-shaped connecting material 110 by connecting it with the internal connecting reinforcing bar 112, which is a circular band reinforcing bar constituting the casing connecting material 110,

On the upper surface, the mounting reinforcing bar 123, which descends and hangs on the internal connecting reinforcing bar 112, is formed to extend outside the horizontal reinforcing bar, so it can be installed simply by lifting and lowering the shearing insert connector 120. It can be seen that the installation work is done very simply and quickly.

Next, as shown in FIG. 3C, a casing-type shearing connection device 100 is installed in advance, and the inner space (S) is filled with the shearing filler 130 to close the inner space (S).

The shear filler 130 uses concrete filled in the communicating internal space (S) of the casing connector 110, and the casing connecting reinforcing bar 111 and internal connecting reinforcing bar set in the communicating internal space (S). (112), it can be seen that the shear insert connector 120 can play a role in being embedded and integrated with each other,

When this shear filler 130 is finally cured, it is formed to penetrate the upper and lower joint surfaces (E), so it also serves to additionally resist shear force with its own rigidity. It can be seen that this shear filler 130 can be filled from top to bottom, enabling rapid filling.

[Concrete buoyancy body (200) using the casing type shear connection device (100) of the present invention]

Figures 4a, 4b, and 4c show an example of a concrete buoyancy body 200 using the casing type shear connection device 100 of the present invention.

Referring to FIG. 4C, the concrete buoyancy body 200 using the casing type shear connection device 100 of the present invention is manufactured so that the lower part is submerged underwater and the upper part is exposed above water due to buoyancy in the water,

Figure 4a specifically shows that the lower plate 240 and the upper plate 250, as exterior panels of the concrete buoyancy bodies 200a and 200b, can be laminated and connected using the casing-type shear connection device 100 up and down. ,

Figure 4b shows that the connection flange 260 of the concrete buoyancy body 200 can be stacked and connected upward and downward using the casing type shear connection device 100,

Figure 4c shows an example of underwater transportation in which the concrete buoyancy bodies 200 of Figure 4b are connected and transported.

First, Figure 4a shows that the concrete buoyancy body 200 using the casing-type shear connection device 100 of the present invention is used to install the exterior panels (A) by stacking them up and down, and is formed at the corner of the buoyancy body 210. It was shown that, using the opening 220, the lower plate 240 and the upper plate 250 of the concrete buoyancy bodies 200a and 200b can be laminated and connected upward and downward using the casing type shear connection device 100. .

That is, according to Figure 4a, the concrete buoyancy body 200 uses an exterior panel (A), and it can be seen that the buoyancy body 210 is accommodated inside, and the upper plate (A) is used as the exterior panel (A), which is a slab. It can be seen that it includes 250) and a lower plate 240.

At this time, it can be seen that the edges and edges of the buoyancy body 210 are formed with openings 220, and these openings 220 are formed to penetrate the concrete buoyancy body 200 upward and downward.

Accordingly, it can be seen that the casing type shear connection device 100 of the present invention is formed on the upper and lower plates 240 and 250 of the concrete buoyancy body 200, respectively, and is used for construction by stacking the concrete buoyancy body 200. .

That is, according to Figure 4a, the upper concrete buoyancy body 200a and the lower concrete buoyancy body 200b are stacked up and down,

The casing connector 110 of the casing-type shear connection device 100 is connected upward and downward to the lower plate 240 of the upper concrete buoyancy body 200a and the upper plate 250 of the lower concrete buoyancy body 200b, respectively. It can be seen that the space (S) is also connected to each other,

After passing through the upper and lower exterior panels (A) of the upper concrete buoyancy body (200a) and the lower concrete buoyancy body (200b) and tensioning the upper surface of the upper concrete buoyancy body (200a) and the bottom surface of the lower concrete buoyancy body (200b), , so that the upper and lower sides are pressurized and connected using the anchored tendon material 230,

Constituting the casing connector 110 of the casing-type shear connection device 100 formed and connected to the lower plate 240 of the upper concrete buoyancy body 200a and the upper plate 250 of the lower concrete buoyancy body 200b, respectively. The shear insertion connector 120, which is connected to the internal connecting reinforcement 112, which is a circular band reinforcement, to bear the shear force transmitted with the K-shaped connector 110, is inserted into the upper plate 250 of the upper concrete buoyancy body 200a. ) and the opening 220 formed in the lower plate 240 of the lower concrete buoyancy body 200b is set by lifting and then lowering installation,

The opening 220 of the upper plate 250 of the upper concrete buoyancy body 200a is filled with shear filler 130, and the inside of the opening 220 and the casing connector 110 penetrating the buoyancy body 210 is formed. The casing-type shear connection device 100 of the present invention is formed on the upper and lower plates of the concrete buoyancy body 200 by final filling and finishing with shear filler 130, so that the concrete buoyancy body 200 can be used for upper and lower stacking. You can see that it is possible.

Next, Figure 4b shows that the concrete buoyancy body 200 using the casing type shear connection device 100 of the present invention is used to install the exterior panels (A) by stacking them up and down, and further shows the exterior of the concrete buoyancy body 200. A separate connection flange 260 is formed on the panel (A),

It was shown that the concrete buoyancy body 200 can be stacked up and down by installing the casing type shear connection device 100 of the present invention on the connection flange 260.

That is, according to Figure 4b, the concrete buoyancy body 200 also uses an exterior panel (A), and it can be seen that the buoyancy body 210 is accommodated inside, and compared to Figure 4a, the exterior panel (A) It can be seen that more horizontally protruding connection flanges 260 are installed at the upper and lower corners of .

By using the connection flange 260, it can be seen that the concrete buoyancy body 200 horizontally connected by the connection flange 260 can be transported together in water, as shown in Figure 4c,

It can be seen that the exterior panel (A) can be connected top and bottom to each other by installing the casing type shear connection device 100 of the present invention on the connection flange 260.

That is, according to Figure 4b, the upper concrete buoyancy body 200a and the lower concrete buoyancy body 200b are stacked up and down, and the connection flange formed on the upper concrete buoyancy body 200a and the lower concrete buoyancy body 200b ( 260) are also set to touch top and bottom,

It can be seen that the casing connectors 110 of the casing-type shear connection device 100 are connected upward and downward to the connection flange 260, which is set to contact upward and downward, so that the internal space S is also in communication with each other,

A cone-shaped casing connector is used as the casing connector 110,

After passing through the upper and lower exterior panels (A) of the upper concrete buoyancy body (200a) and the lower concrete buoyancy body (200b) and tensioning the upper surface of the upper concrete buoyancy body (200a) and the bottom surface of the lower concrete buoyancy body (200b), , The upper and lower sides are pressurized and connected using the anchored tendon material 230,

A circular shape constituting the cone-type casing connector 110 of the casing-type shear connection device 100 connected to the connection flange 260 installed to contact the upper and lower concrete buoyancy bodies 200a and the lower concrete buoyancy bodies 200b. The upper concrete buoyancy body (200a) and the lower concrete buoyancy body (200a) are shear insertion connectors (120) that are connected to the internal connecting reinforcing bars (112), which are band reinforcing bars, to bear the shear force transmitted with the K-type connector (110). It is set by lifting and then lowering it into the internal space (S) formed in the connection flange 260 of 200b),

The casing of the present invention is made by final filling and finishing the internal space (S) of the connection flange 260 formed to contact the top and bottom of the upper concrete buoyancy body 200a and the lower concrete buoyancy body 200b with shear filler 130. It can be seen that the type shear connection device 100 can also be used for the connection flange 260 installed to contact the top and bottom of the concrete buoyancy body 200.

According to Figure 4c, it can be seen that the concrete buoyancy body 200 on which the connection flange 260 is formed can be used as a connection means on the water.

That is, each concrete buoyancy body 200 is formed so that the connection flange 260 is in contact with the top and bottom on the upper and lower sides, and the casing type shear connection device of the present invention formed on the connection flange 260 ( It can be seen that it can be horizontally connected using 100), connected to two concrete buoyancy bodies 200, floated on the water, and transported together.

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 unitary 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: Casing type shear connection device
110: Casing connector
111: Casing connecting rebar 112: Internal connecting rebar
120: Insert connector for shearing
121: Horizontal rebar 122: Vertical rebar
123: Mounting rebar 130: Shear filler
200,200a,200b: Concrete buoyancy body
210: buoyancy body 220: opening
230: tension material 240: lower plate
250: upper plate 260: connection flange
A: Exterior panel E: Top and bottom joint surfaces
S: internal space

Claims (20)

delete A connection flange 260 that is set to contact the upper and lower concrete buoyancy bodies 200a and the lower concrete buoyancy bodies 200b stacked upwards and downwards, forming an internal space S communicating upwards and downwards; A casing connecting member 110 disposed on the upper and lower joining surfaces E of the connecting flange 260 so that the internal space S communicates with each other upward and downward; And a shear insertion connector 120 including a reinforcing bar assembly that is lowered and inserted from the upper plate of the upper concrete buoyancy body 200a into the casing connector 110, wherein the casing connector 110 includes, Casing connection reinforcement bars (111) are arranged horizontally up and down on the outer circumferential surface to be located on the upper and lower joint surfaces of the exterior panel (A) formed on the connection flange (260) to ensure integrity with the exterior panel (A). It includes a vertical steel pipe that allows the casing connecting reinforcing bar 111 to form a hook shape at one end extending inside the exterior panel (A), and the other side of the reinforcing bar penetrates the casing connecting material 110 to the inside. It is formed to extend, but the other side of the casing connecting reinforcing bar 111 is directly connected to and fixed in position to the internal connecting reinforcing bar 112 including a band reinforcing bar disposed horizontally in the internal space (S), and the internal connecting reinforcing bar 112 It includes circular band reinforcing bars arranged horizontally, and is arranged to be spaced apart from the inner surface of the casing connecting material 110 up and down in the internal space (S) by the casing connecting reinforcing bar 111, forming a shear filler 130. A concrete buoyancy body using a casing-type shear connection device that prevents the casing connection rebar (111) from interfering with the filling when it is filled. A casing connector 110 disposed on the upper and lower joint surfaces (E) of the exterior panels (A, precast members) stacked upward and downward so that the internal space (S) communicates with each other upward and downward; And a shearing insert connector including a reinforcing bar assembly that is inserted downwardly from above the internal space (S) so as to penetrate the upper and lower joint surfaces (E) and resists the shear force and separation force acting on the upper and lower joint surfaces (E). (120); and the casing connecting material 110 has casing connecting reinforcing bars 111 arranged horizontally up and down on the outer circumferential surface so as to be located on the upper and lower joint surfaces of the exterior panel (A), thereby forming the exterior panel ( It includes a vertical steel pipe to ensure unity with A), and the casing connecting reinforcing bar 111 has one end extending inside the exterior panel (A) formed in a hook shape, and the other side of the reinforcing bar is formed as a casing connecting material. It is formed to extend inward through (110), and the other side of the casing connecting reinforcing bar 111 is directly connected to the internal connecting reinforcing bar 112 including a band reinforcing bar disposed horizontally in the internal space (S) and is fixed in position. , the internal connecting reinforcing bar 112 includes circular band reinforcing bars arranged horizontally, and is arranged to be spaced apart from the inner surface of the casing connecting material 110 upward and downward in the internal space (S) by the casing connecting reinforcing bar 111. A casing-type shear connection device that prevents the casing connection rebar 111 from interfering with the filling when the shear filler 130 is filled. According to paragraph 3,
The inner space (S) connected to the upper and lower joint surfaces (E) of the exterior panel (A) is filled so that the shear insert connector 120 is embedded in the upper and lower joint surfaces together with the casing connector 110. (E) A casing-type shear connection device further formed with a shear filler 130 that resists both the shear force and the separation force acting on it. According to paragraph 4,
The shear filler 130 is,
It contains concrete filled in the connected internal space (S) of the casing connector 110, and is cured and formed to penetrate the upper and lower joint surfaces (E), so that it also serves to resist shear force and separation force, and the connected interior A casing-type front end connection device that allows the space (S) to be filled from top to bottom. delete According to paragraph 3,
The casing connector 110 is,
A casing-type shear connection device formed of a vertical steel pipe or a cone-shaped steel pipe to resist the shear force and separation force generated on the upper and lower joint surfaces (E) of the exterior panel (A) by the shear filler (130). delete delete According to paragraph 3,
The insert connector 120 for shearing is,
A plurality of horizontal reinforcing bars 121 are formed to be spaced apart, and vertical reinforcing bars 122 that restrain the horizontal reinforcing bars 121 upward and downward are formed as one piece, and are formed so as to hang downwardly on the internal connecting reinforcing bars 112 on the upper surface. A casing-type shear connection device including a reinforcing bar assembly formed of mounting reinforcing bars (123) extending to the outside of the horizontal reinforcing bars. According to clause 10,
The shearing insert connector 120 is,
A casing that is connected to the internal connecting reinforcing bar 112 of the casing connecting material 110 and is embedded and integrated by the shear filler 130 so that it can resist shear and separation forces together with the casing connecting material 110. Type shear connection device. (a) installing a casing connector 110 on the upper and lower joint surfaces (E) of the exterior panels (A, precast members) stacked upward and downward so that the internal space (S) communicates with each other upward and downward; and (b) a reinforcing bar assembly that is inserted downwardly from above the internal space (S) so as to penetrate the upper and lower joint surfaces (E) and directly resists the shear force and separation force acting on the upper and lower joint surfaces (E). Includes; installing the insert connector 120 for shearing,
The casing connection material 110 in step (a) is located on the upper and lower joint surfaces (E) of the exterior panel (A), so that the casing connection reinforcing bars 111 are arranged horizontally up and down on the outer circumferential surface to form an exterior panel ( It includes a vertical steel pipe to ensure unity with A), and the casing connecting reinforcing bar 111 has one end extending inside the exterior panel (A) formed in a hook shape, and the other side of the reinforcing bar is formed as a casing connecting material. It is formed to extend inward through (110), and the other side of the casing connecting reinforcing bar 111 is directly connected to the internal connecting reinforcing bar 112 including a band reinforcing bar arranged horizontally in the internal space (S) so that its position is fixed. In addition, the internal connecting reinforcing bar 112 includes circular band reinforcing bars arranged horizontally, and is arranged to be spaced apart from the inner surface of the casing connecting material 110 upward and downward in the internal space (S) by the casing connecting reinforcing bar 111. A method of connecting a concrete buoyancy body using a casing-type shear connection device that prevents the casing connection rebar 111 from interfering with tight filling when the shear filler 130 is filled. According to clause 12,
After step (b), the casing connector 110 is connected to the upper and lower joint surfaces (E) of the exterior panel (A) to resist the shear force and separation force acting on the upper and lower joint surfaces (E). A method of connecting a concrete buoyant body using a casing-type shear connection device further comprising the step (c) of filling the shear filler 130 so that the shear insert connector 120 is embedded in the internal space (S). According to clause 13,
The shear filler 130 includes concrete filled in the communicating internal space (S) of the casing connector 110, and is cured and formed to penetrate the upper and lower joint surfaces (E) to resist shear force and separation force. A method of connecting a concrete buoyant body using a casing-type shear connection device that plays the role of filling the connected internal space (S) from top to bottom. According to clause 13,
The exterior panel (A) of step (a) is,
As an exterior panel of a concrete buoyancy body, a casing type shear connection device used to connect the top and bottom of the exterior panel using the casing connector 110 and the insertion connector 120 for shearing of the casing type shear connection device 100. Concrete buoyancy connection method using . delete delete According to clause 13,
The insert connector 120 for shearing in step (b) is,
A plurality of horizontal reinforcing bars 121 are formed to be spaced apart, and vertical reinforcing bars 122 that restrain the horizontal reinforcing bars 121 upward and downward are formed as one piece, and are formed so as to hang downwardly on the internal connecting reinforcing bars 112 on the upper surface. A method of connecting a concrete buoyant body using a casing-type shear connection device including a reinforcing bar assembly formed of mounting reinforcing bars (123) extending to the outside of the horizontal reinforcing bars. According to clause 18,
A shearing filler ( 130) A method of connecting a concrete buoyancy body using a casing-type shear connection device further formed. According to clause 13,
The exterior panel (A) in step (a) further includes a connection flange 260, and the connection flange 260 is a connection flange 260 overlapped above and below the concrete buoyancy body 200 set to the left and right. A method of connecting concrete buoyancy bodies using a casing-type shear connection device that allows concrete buoyancy bodies (200) set to the left and right to be connected to each other.