KR20150041483A - Floating structure modules and method for constructing floating structure modules using the same - Google Patents

Abstract

The present invention relates to a floating structure module and a construction method using the same. According to the present invention, a concrete block body having a sheath tube embedded therein is manufactured in the ground, and the concrete block body is transferred to the water. Then, on the water site, a tendon force is applied to a steel wire so that the floating structure module can be constructed. Therefore, the performance of the floating structure module is increased with integration of the concrete block and construction costs can be reduced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a floating type enclosure module,

The present invention relates to a floating enclosure module and a construction method using the same. More particularly, the present invention relates to a floating enclosure module for constructing a concrete block in which a sheath pipe is buried on the ground and transporting it as water, connecting a concrete block by a steel wire and introducing a tension force, and a construction method using the same.

A floating structure is a generic term for structures that are built on a floating enclosure. A floating enclosure is a structure to be constructed beforehand to construct a floating structure and plays the same role as a foundation on land. Therefore, the floating enclosure has a great influence on the stability, construction, and construction cost of the floating structure.

Floating enclosures can be made as a single structure directly from the aquifer when the size of the floating structure is small at the time of construction. Generally, a method is used in which the enclosure is made on land and transported by water.

The method of manufacturing the enclosure of the floating structure is classified into a method of making a single enclosure and a method of assembling the unit member and combining unit members.

A single enclosure is one in which the member is made of one structure. Therefore, the size of the housing increases, and it becomes difficult to manufacture and manage the formwork, and there are many items to be taken into consideration when pouring concrete, which is economically disadvantageous because it is difficult to manage the construction. In addition, a single enclosure is heavy in weight and requires a large crane when lifting, which can take a long time to transport and cause additional economic losses.

There is a method of making an enclosure with a unit member and connecting them to form an integrated enclosure. If the housing is made of a unit member, the size of the member is small so that it can be easily manufactured and managed on the land, which can advantageously reduce the cost of production by molding, concrete pouring, and construction management. Also, since the unit member is light in weight, a large-sized crane is unnecessary, and water transportation can be facilitated, thereby reducing transportation cost. The unit-unit enclosure should be connected and assembled at the watercraft, and the enclosure should be constructed so that it can be integrated into a single enclosure. Bolts, steel rods and exposed cables are commonly used for connecting the unit members, but bolts and steel rods made by such methods are easily damaged by external load, exposed in a corrosive environment such as the oceans, The connection strength is reduced, and the tensile force of the exposed cable is lost, so that the module can not be connected so that the module is completely integrated.

Therefore, there is a demand for a floating type module housing which is able to secure the economical efficiency and the workability by integrating the floating housing with the water while transporting the floating housing in the land as a unit member.

A concrete block body in which a sheath pipe is buried is made onshore, and it is transported as a waterway to connect a concrete block with a steel wire, and a concrete block is integrated by introducing a tension force, thereby reducing the construction cost of the structure while increasing the performance of the structure And to provide a floating enclosure module.

In order to achieve the above object, a floating enclosure module according to the present invention includes a concrete block body having a hollow portion, a first sheath pipe, a second sheath pipe, a first steel wire and a second steel wire. The first sheath pipe is embedded in the upper side of each concrete block body, and at least one or more than one of the concrete block walls is disposed so as to penetrate the concrete block wall in one direction and expose both ends. The second sheath pipe is spaced downwardly from the first sheath pipe and buried in each concrete block body. At least one or more than one sheath pipe is disposed so that the concrete block body passes through in one direction and both end portions are exposed. The first steel wire penetrates the inside of each first sheath pipe and connects the concrete blocks to each other. The second steel wire penetrates the inside of each second sheath pipe to connect the concrete blocks to each other.

The floating enclosure module according to the embodiment of the present invention is provided with a shear resistance unit. The shear resistance portion is disposed on one side of each concrete block to which the sheath pipe is exposed, and may be protruded or formed in a groove to be engaged with a neighboring concrete block.

A floating enclosure module according to an embodiment of the present invention is provided with a filler. The filling material is filled in the hollow portion of each concrete block, and the filling material can be provided by EPS.

The second sheath tube of the floating enclosure module according to the embodiment of the present invention may be curvedly bent from one end to the other end.

The floating enclosure module according to the embodiment of the present invention may include a water resistance plate. The steel plate is disposed at the contact portion of each concrete block connected to the first steel wire and the second steel wire.

In the floating type enclosure module according to the embodiment of the present invention, grooves may be formed to fix the diaphragm to each concrete block to which the diaphragm contacts.

The floating enclosure module according to the embodiment of the present invention can fill the positions where the concrete blocks are connected to each other with the filling material.

The construction method using the floating enclosure module according to the embodiment of the present invention includes a step of providing a concrete block, a step of connecting a concrete block, a step of introducing a tension force, and a step of fixing a steel wire. The concrete block body includes a concrete block body having a hollow portion, a first sheath pipe embedded in the upper side of each concrete block body and penetrating each of the concrete block walls in one direction so as to expose both ends, A plurality of concrete blocks including a second sheath pipe spaced downward from the first sheath pipe and embedded in the respective concrete block bodies, the second sheath pipes passing through the respective concrete block bodies in one direction and having both ends exposed. In the concrete block connecting step, a first steel wire is inserted along the inside of the first sheath pipe, and a second steel wire is inserted along the inside of the second sheath pipe to continuously connect the concrete blocks. The tensional force introduction step is a step of introducing a tension force to the first and second strands connecting the concrete blocks. The step of fixing the steel wire is a step of fixing the tension introduced into the first steel wire and the second steel wire to both ends of the connected concrete block.

A construction method using a floating enclosure module according to an embodiment of the present invention includes a step of inserting a steel plate. The step of inserting the steel plate is a step of inserting a steel plate at a position where the concrete blocks are connected to each other by the first steel wire and the second steel wire.

A construction method using a floating enclosure module according to an embodiment of the present invention includes a void filling step. The pore filling step is a step of filling the pores of the contact portions of the respective concrete blocks after the tensional force introduction step.

The floating module module and the construction method using the module are used to transport the concrete block body embedded with the sheath pipe to the water line, connect the steel block to the steel line at the water field, and integrate the concrete block by introducing the tensional force, thereby enhancing the performance of the floating module. The construction cost can be reduced.

1 is a plan view of a floating enclosure module according to an embodiment of the present invention.
2 is a cross-sectional view taken along line II-II in Fig.
3 is a cross-sectional view taken along the line III-III in FIG.
FIG. 4 is a flowchart of a construction method using a floating enclosure module according to an embodiment of the present invention.
5 is a view illustrating a construction sequence using a floating enclosure module according to an embodiment of the present invention.
6 is a view showing a construction procedure of a concrete block according to an embodiment of the present invention.
7 is a construction plan view of a floating enclosure module according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some of the components in the drawings are exaggerated, omitted, or schematically illustrated.

FIG. 1 is a plan view of a floating enclosure module according to an embodiment of the present invention, FIG. 2 is a sectional view taken along line II-II in FIG. 1, and FIG. 3 is a sectional view taken along a line III- Sectional view.

As shown in FIGS. 1 to 3, the floating enclosure module according to the embodiment of the present invention includes a plurality of concrete blocks 1000 and a steel wire 1300.

The floating type housing module is a structure having a housing integrated with a concrete block 1000 as a unit member, and connects the concrete blocks 1000 by using a steel wire 1300.

The concrete block 1000 includes a concrete block body 1100 and a sheath pipe 1200 as a unit member of a floating enclosure module. A plurality of concrete blocks 1000 are connected to form a single structure, which may be arranged in a matrix as shown in FIG.

In this embodiment, the concrete block body 1100 is formed in a rectangular parallelepiped shape so that a plurality of concrete blocks can be easily connected and integrated. However, the concrete block body 1100 can be selected from various shapes that can be continuously connected and integrated .

The concrete block body 1100 can be hollowed to reduce weight and float in the water. The shape of the hollow portion is preferably a rectangular parallelepiped shape in order to reduce the weight, but the shape of the hollow portion may be changed depending on the arrangement of the sheath pipe 1200 and the steel wire 1300, and thus is not limited thereto.

The hollow portion may be filled with the filler material 1120 to increase buoyancy of the concrete block body 1100. The filling material 1120 is preferably foamed styrofoam or the like such as EPS capable of increasing the buoyancy of the concrete block body 1100. It is preferable that the filler material 1120 has a specific gravity smaller than that of water and can increase the buoyancy of the concrete block body 1100, The material is not limited thereto.

Since the concrete block 1000 is in contact with water and is exposed to harsh conditions such as the oceans, it is preferable that the surface of the concrete block body 1100 is coated with a waterproofing material. The waterproofing material may be silicone waterproofing, polyurea, or the like, which can exhibit resistance against salt, and may be selectively used according to the environment in which the concrete block 1000 is installed.

The shear resistance part 1110 is disposed on one side of each concrete block body 1100 where the sheath pipe 1200 is exposed. The shear resistance part 1110 is resistant to a vertical load coming from the upper part of the concrete block 1000 or a shearing force generated by a wave load transmitted from the water surface. The shear resistance part 1110 may be disposed at least one protruded or grooved to be engaged with the neighboring concrete block 1000 and may be protruded or grooved to have a maximum shear resistance surface. Also, the shear resistance of the shear resistance portion 1110 can be increased by increasing the shear frictional resistance by using studs, bolts, steel bars, reinforcing bars or the like in a direction parallel to the plane where the neighboring concrete blocks 1000 meet.

The water level plate 1130 may be provided at a contact portion of each concrete block body 1100 connected by a steel wire 1300. The water resistance plate 1130 prevents water from penetrating into the sheath pipe of the concrete block body 1100 and corrosion of the steel wire 1300. When the water resistance plate 1130 is formed of a rubber material, it is effective to tightly adhere to each concrete block body 1100 due to a tensile force to prevent water from penetrating into the sheath pipe 1200. However, Is not limited to this.

In this embodiment, the shape of the power plate 1130 is a quadrangle, but the power plate may be circular and polygonal, and its shape is not limited. The grooves 1140 may be formed so as to fix the diaphragm 1130 on the surface of the concrete block body 1100 that faces the diaphragm 1130. The watertight plate 1130 can be completely fixed by the groove 1140, thereby more effectively preventing water from penetrating. The gap generated by connecting each concrete block body 1100 with the filler material 1150 can be filled.

The filler material 1150 can bond the plurality of concrete block bodies 1100 to each other to perform integrated behavior and prevent water from penetrating into the interior. The filling material 1150 is preferably made of fine particles and a material that can effectively fill small gaps generated. The filling material 1150 is not limited to the material that can perform the integral behavior by connecting the concrete block body 1100 with cement mortar, non-shrinkage concrete or the like.

The sheath pipe 1200 is preferably made of a material that is not damaged by contact with the steel wire because the steel wire passes through the sheath pipe 1200. The sheath pipe 1200 includes a first sheath pipe 1210 through which the concrete block body 1100 is inserted through the concrete block body 1100 in one direction so as to be exposed at both ends thereof and is provided with at least one sheath pipe 1210, The concrete block bodies 1100 are separated in a downward direction and are embedded in the respective concrete block bodies 1100 so as to expose both ends thereof and are passed through the concrete block bodies 1100 in one direction and divided into at least one second sheath pipe 1220 do.

Two sheath pipes 1200 are placed on the upper side of the concrete block body 1100 and two lower pipes are placed on the lower side of the concrete block body 1100. However, Can be increased, and one each of them can be embedded at positions where the forces are balanced at the upper and lower portions of the concrete block body 1100.

The first sheath pipe 1210 may be disposed horizontally of the concrete block body 1100 in which the first sheath pipe 1210 is embedded. The second sheath pipe 1220 may be curved from one end to the other end of the concrete block body 1100 or embedded with a straight slope from one end to the other end of the concrete block body 1100. Although the sheath tube 1200 can be applied to the concrete block body 1100 in a curvilinear shape, a material such as plastic is preferable, but the present invention is not limited thereto.

When the second sheath pipe 1210 is bent or arranged so as to have a straight line inclination, the tensile force of the steel material 1300 that has passed through the second sheath pipe 1210 is transmitted from the upper portion of the concrete block body 1000 The shear force can be reduced by the vertical component of the tension force with respect to the load. As a result, the stress acting on the concrete block 1000 is reduced, and the wall thickness of the concrete block body 1100 can be reduced. Therefore, it is possible to increase the size of the hollow portion provided inside the concrete block body 1100, thereby reducing the weight of the concrete block body 1100 while reducing the construction cost, thereby reducing the weight of the concrete block body 1100, 1000) can be constructed.

The steel wire 1200 may be made of a PC steel wire having two or more steel wires twisted like a twisted pair and having increased strength, and a single steel material such as a PC steel bar may be used. Since the steel wire 1200 should pass through the inside of the sheath tube 1300, it is preferable that the steel wire 1200 has flexibility. However, the present invention is not limited thereto. The steel wire 1300 may pass through the sheath pipe 1200 embedded in each concrete block body 1100 and connect the concrete block bodies 1100 to each other. The first steel wire 1310 may pass through the first sheath pipe 1210 to connect neighboring concrete block bodies 1100 to each other. The second steel wire 1320 may pass through the second sheath pipe 1220 and connect neighboring concrete block bodies 1100 to each other.

In the present embodiment, two steel wires 1300 are provided at the upper and lower ends of the concrete block body wall 1100, respectively. However, each of the steel wires 1300 may be provided on the upper and lower sides of the concrete block body 1100, The installation position and the installation number of the steel wire 1300 can be increased depending on the size of the steel wire 1100. [

The steel wire 1300 may contact with the air inside the sheath tube 1200 and may be corroded to cause loss of tensile force. Accordingly, the corrosion inhibiting material such as lubricating oil and grease can be applied to the steel wire 1300, and the material is not limited to the material that can prevent corrosion. The tensioned steel wire 1300 is fixed to both ends of the concrete block 1000 to form a fixing hole 1330. A wedge type, a screw type, a nail type, a combination type, and the like, depending on the method of fixing the fixing port 1330, and the method for fixing the steel wire 1300 is not limited thereto.

Since the fixing port 1330 is a position where the tensile force of the steel wire 1300 is fixed, the stress is concentrated. Therefore, the fixing unit 1330 can increase the thickness of the concrete or reinforce the fixing around the fixing unit with the concrete reinforcing block, thereby dispersing the stress of the fixing unit. It is preferable to apply a waterproofing material to prevent corrosion due to corrosion of the steel material 1300 located at the fixing port 1330. [

A plurality of the concrete blocks 1000 are connected in a longitudinal direction in which the sheath pipes 1200 are embedded and a plurality of the concrete blocks 1000 are connected in the orthogonal direction in which the sheath pipe 1200 is embedded. As shown in FIG. 1, each concrete block 1000 may be connected by a steel wire to form one enclosure module. As shown in FIG. 2, the center of the concrete block body 1100 is formed to be symmetrical in the right and left directions. However, the concrete block 1000 is limited in the form that it can increase the resistance against external forces such as moment and shearing force. It does not.

FIG. 5 is a flow chart of a construction method using a floating enclosure module according to an embodiment of the present invention. FIG. 5 is a flow chart of a construction method using a floating enclosure module according to an embodiment of the present invention. As shown in FIGS. 4 and 5, a construction method using a floating enclosure module according to an embodiment of the present invention includes a concrete block preparing step S100, a concrete block connecting step S200, a torsional force introducing step S300, And a steel wire fixing step (S400).

The concrete block preparing step S100 includes a concrete block body 1100 having a hollow portion and a plurality of concrete block walls 1100 embedded in the upper side of each concrete block body 1100 and penetrating each of the concrete block walls 1100 in one direction, The first sheath pipe 1210 and the first sheath pipe 1210 are spaced downwardly from the first sheath pipe 1210 and are embedded in the respective concrete block bodies 1100. The first sheath pipe 1210 and the first sheath pipe 1210 are inserted into the concrete block body 1100 in one direction, And a plurality of concrete blocks 1100 including a second sheath pipe 1220 disposed over the second sheath pipe 1220.

As shown in FIGS. 1 and 2, in the present embodiment, the sheath pipe 1200 is illustrated as being penetratingly formed in the longitudinal direction (y-axis direction) of the rectangular parallelepiped concrete block body. However, (X-axis direction), and may be connected to the sheath pipe 1200 in a direction crossing the longitudinal direction.

In the concrete block connection step S200, the first steel wire 1310 is inserted along the inside of the first sheath pipe 1210, the second steel wire 1320 is inserted through the inside of the second sheath pipe 1220, Thereby continuously connecting the concrete blocks.

The tensional force introducing step 300 is a step of applying a tensile force to the concrete block 1000 connected in the concrete block connecting step S100. The introduction of the tensional force is preferably a step of applying tension to the steel wire 1300, but it is not limited thereto. And a void filling step occurring at the connection position of each concrete block 1000 after the tension introduction step S300. The pore filling can be further adhered by the steel wire fixing step (S400), which is the next step.

The step of fixing the steel wire (S400) is a step of fixing the steel wire introduced with the tension force to the concrete block body (1100) at both ends of the concrete block (1000). The concrete block body 1100 can be integrated through the steel wire fixing step S400. It is possible to prevent the loss of tensile force of the steel wire 1300 due to corrosion including the step of applying the waterproofing material to the fixing unit 1330 after the steel wire fixing step S300.

6 is a view showing a construction procedure of a concrete block according to an embodiment of the present invention. The construction procedure of the concrete block body 1100 is as follows: (a) a bottom mold and a reinforcement step, (b) a wall reinforcing steel and a sheath pipe, (c) a concrete pouring step, (d) And (f) placing the upper concrete.

The bottom mold and the reinforcement stage are steps of fabricating the lower mold 1160a and reinforcing the reinforcement. The step of inserting the wall reinforcement and the sheath tube is a step of installing the wall reinforcement vertically by connecting the bottom reinforcement and installing the side mold 1160b and installing the first sheath pipe 1210 and the second sheath pipe 1220. It is preferable that the second sheath tube 1220 is formed so that the curvature is formed in advance so that the curvature is formed. The concrete pouring step is a step of pouring concrete to integrate the floor, the wall and the sheath pipe 1200. It is preferable to observe the concrete pumping speed or to connect the sheath pipe 1200 and the reinforcing bars so that the position of the sheath pipe 1200 is not changed.

The filling material filling step is a step of filling the filling material 1120 to increase the buoyancy of the concrete block body 1100. The upper reinforcing step is a step of reinforcing the reinforcing bars to connect the wall and the upper portion. The upper concrete pouring step is a step of pouring concrete to close the concrete block body 1100. When concrete pouring is completed and curing of the concrete block body 1100 is completed, the durability performance can be increased by applying a waterproof material.

7 is a construction plan view of a floating enclosure module according to another embodiment of the present invention. The shape of the concrete block 1100 can be changed to construct a floating enclosure module. When the rectangular concrete block 1100a is connected and the square concrete block 1100b is positioned at the corner of the square, the area of the concrete block 1000 can be effectively arranged. The shape of the concrete block 1100 may vary in size and shape according to the plan of the floating enclosure module, but is not limited thereto.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative of the present invention in order to facilitate description of the present invention and to facilitate understanding of the present invention and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

1000: Concrete block 1100: Concrete block body
1110: Shearing resistance section 1120: Filler
1130: Index plate 1200: Sheath tube
1210: first sheath tube 1220: second sheath tube
1300: Steel wire 1310: First wire
1320: 2nd wire

Claims (12)

A concrete block body having a hollow portion;
A first sheath pipe embedded in the upper side of each of the concrete block bodies, the first sheath pipe passing through the respective concrete block walls in one direction and being exposed at both ends; And
A second sheath pipe spaced downwardly from the first sheath pipe and embedded in the respective concrete block bodies, the second sheath pipes passing through the respective concrete block bodies in one direction so as to expose both ends; A plurality of concrete blocks,
A first steel wire penetrating the inside of each of the first sheath pipes and connecting the concrete blocks to each other, and
And a second steel wire penetrating the inside of each of the second sheath pipes and connecting the concrete blocks to each other. The method according to claim 1,
And a shear resistance unit disposed on one side of each of the concrete blocks to which the sheath pipe is exposed and having a protrusion or a groove formed to be engaged with a neighboring concrete block. The method according to claim 1,
Wherein the hollow portion of each concrete block is filled with a filling material. The method of claim 3,
Wherein the filler is an EPS. The method according to claim 1,
Wherein the second sheath tube is curvedly embedded from one end to the other end. The method according to claim 1,
And a diaphragm disposed at a contact portion of each of the concrete blocks connected by the first steel wire and the second steel wire. The method of claim 6,
And a groove is formed in each of the concrete blocks to which the waterproof plate contacts, so that the waterproof plate is fixed. The method according to claim 1,
Wherein a position where the concrete blocks are connected to each other is filled with a filler. A first sheath pipe embedded in the upper side of each of the concrete block bodies and having at least one through hole penetrating the concrete block walls in one direction so as to expose both ends thereof; Providing a plurality of concrete blocks spaced downwardly and embedded in the respective concrete block bodies, the concrete blocks including a second sheath pipe penetrating through the concrete block bodies in one direction and having at least one end exposed;
A concrete block connecting step of inserting a first steel wire along the inside of the first sheath pipe and inserting a second steel wire along the inside of the second sheath pipe to continuously connect the concrete blocks;
A tensional force introduction step of introducing a tensional force to the first steel wire connecting the concrete block and the second steel wire;
And fixing a tension applied to the first steel wire and the second steel wire to both ends of the connected concrete block. The method of claim 9,
And inserting a diaphragm at a position where the concrete blocks are connected to each other by the first steel wire and the second steel wire. The method of claim 9,
And a void filling step of the contact portions of the concrete blocks after the step of introducing the tensions. The method of claim 9,
And applying a waterproofing material to the steel wire fixing unit fastened to fix the first rigid steel wire and the second steel wire after the steel wire fixing step.

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