KR20110138115A - Floating body - Google Patents

Abstract

PURPOSE: A floater is provided to easily change the installation positions of members in the extension direction of a restriction groove by connecting a buoyant member and a shock-absorbing member to a plurality of connecting members held in the restriction groove. CONSTITUTION: A floater comprises a base member(20), a connecting unit(30), and a buoyant member(40). The connecting unit comprises a profile member and a plurality of connecting members and is installed on the edge of the base member. The profile member comprises a sliding groove extended in the longitudinal direction. The connecting members are inserted and slid in the sliding groove. The buoyant member is installed in the connecting members and provides buoyancy.

Description

Floating Body

The present invention relates to a floating body, and more particularly to a floating body that can easily change the installation position of the buoyancy member and the buffer member relative to the base member.

In recent years, the use of suspended solids in the sea as an offshore structure is increasing.

These floating structures are used as offshore plants, water fishing or marine parks, and the size is also gradually increasing.

Floating structures are generally made of concrete, and the structure is a hollow rectangular parallelepiped structure, for the structural efficiency of the floating structure, partitions are usually installed at regular intervals in the inner space to form a plurality of hollows.

The partition wall does not completely divide the internal space, but may be installed as a plurality of pillars or discontinuous walls, and arranged according to a designer's intention.

In Korea Registered Room No. 20-0394559, 'floating floating structure' is disclosed.

The marine floating structure is composed of hexahedron filled with air, the side portion is provided with one or more upper and lower recessed grooves partially open to the outside vertically, and the vertical through-holes inward in the middle boundary of each upper and lower recessed grooves The upper and lower parts of the plurality of floats and the upper and lower portions which are inserted from the upper and lower portions so as not to be separated laterally to the two upper recessed grooves facing each other in a state where the sides of the floats to be connected are in close contact with each other. With an insert.

However, in the floating floating structure, the part providing buoyancy is integrally formed in the floating body, and since the floating body is also made by pouring concrete, it is difficult to change the part providing the buoyancy or install other additional structures as necessary. have.

The present invention has been made to improve the above problems, and an object thereof is to provide a floating body that can easily change the installation position of the buoyancy member and the buffer member for providing buoyancy with respect to the base member.

Floating body according to the present invention for achieving the above object is installed on the base member, the edge of the base member, a profile member having a sliding groove extending in the longitudinal direction, and a plurality of slidingly inserted into the sliding groove It is provided with a connection unit is provided with a connection member of the buoyancy member is provided on the connection member restrained by the sliding groove to provide buoyancy.

The connection member includes an insertion member inserted into the sliding groove, and a fixing member protruding from the insertion member so that the buoyancy member is installed on the insertion member inserted into the sliding groove.

The profile member may further include a departure prevention protrusion protruding to extend in the longitudinal direction on the inner wall surface of the sliding groove so as to prevent separation from the sliding groove by interfering with the insertion member inserted into the sliding groove. Do.

The sliding member is formed in each of the plurality of outer surfaces of the outer side surfaces formed side by side with respect to the longitudinal direction of the base member.

It is installed on the connection member that is constrained to the sliding groove formed on any one of the outer surfaces of the profile member except the side of the profile member on which the buoyancy member is installed to reduce the transmission of impact generated when the base member collides. It is preferable to further include a shock absorbing member.

In the floating body according to the present invention, since the buoyancy member and the buffer member are connected to the plurality of connection members constrained in the constrained groove, the members can be easily changed in the installation position according to the extending direction of the constrained groove, and other accessory structures are also connected. There is an advantage that can be easily installed in the base member through the member.

1 is a perspective view of a floating body according to the present invention,
2 is a partially separated perspective view of the floating body according to the present invention;
3 is a side cross-sectional view of a floating body according to the present invention,
Figure 4 is a front sectional view of the floating body according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in more detail the floating body according to the present invention.

1 to 4 show a float 10 according to the present invention.

Referring to the drawings, the floating body 10 is installed on the edge of the base member 20, the base member 20, the connection unit 30 and the connection unit 30 installed on the edge of the base member 20, The buoyancy member 40 installed on the base member 20 to provide buoyancy and the shock absorbing member 50 installed on the base member 20 by the connection unit 30 to reduce the transmission of the shock generated during the collision. ).

The base member 20 has a predetermined thickness and is formed in a plate shape extending a predetermined length. The base member 20 is preferably formed of a concrete material so that the initial shape can be firmly maintained by the external impact.

When placing concrete in the formwork to manufacture the base member 20, the mesh net 21 is embedded therein to reinforce the strength of the base member 20. In addition, it is preferable to install the profile member 31 before the concrete is cured so that the profile member 31 of the connection unit 30 to be described later on both sides of the base member 20 can be easily installed.

The connection unit 30 is installed at the edge of the base member 20, the profile member 31 formed with a sliding groove 33 extending in the longitudinal direction, and a plurality of slidingly inserted into the sliding groove 33 The connecting member 32 is provided.

The profile members 31 are respectively installed on both side surfaces of the base member 20, and extend in correspondence with the base member 20 in the longitudinal direction of the base member 20. The profile member 31 is provided with a filling space in which a portion of the concrete of the base member 20 is filled therein so that the fixing force to the base member 20 can be improved.

The profile member 31 has sliding grooves extending in the longitudinal direction on the upper surface, the lower surface and the side surface exposed to the outside, respectively.

At this time, the profile member 31 interferes with the insertion member 34 of the connecting member 32 to be described later inserted into the sliding groove 33 to prevent the departure from the sliding groove 33 to prevent the departure 36 ) Is further provided.

The profile member 31 is excellent in formability and is preferably formed of an aluminum material having a certain strength.

Meanwhile, in the example illustrated in the drawings, the profile member 31 has been described in which only the side surfaces of the base member 20 are installed. However, the profile member 31 is not limited to the illustrated example, but is also provided at both ends of the base member 20. Each may be installed.

The anti-separation protrusion 36 may be formed to protrude in the longitudinal direction, respectively, on inner wall surfaces of the sliding groove 33 which face each other.

The connecting member 32 may include an insertion member 34 inserted into the sliding groove 33 and a buoyancy member 40 and a shock absorbing member 50 installed in the insertion member 34 inserted into the sliding groove 33. It is provided with a fixing member 35 protruding to the insertion member 34 so as to.

The insertion member 34 is formed to have a size corresponding to the sliding groove 33 to be inserted into the sliding groove 33. Meanwhile, in the illustrated example, the insertion member 34 has been described as having a hexagonal cross section, but the insertion member 34 is not limited to the illustrated example, but may be formed in a circular, rectangular, and polygonal cross section.

The fixing member 35 has an outer diameter smaller than the mutual separation distance of the separation preventing projections 36 to prevent the insertion member 34 from being interfered by the separation preventing projections 36 when the insertion member 34 is inserted into the sliding groove 33. It is preferable to form.

The outer peripheral surface of the fixing member 35 is formed with a plurality of threads so that the buoyancy member 40 and the buffer member 50 can be easily coupled.

The connecting member 32 configured as mentioned above is inserted into the sliding grooves 33 formed in the profile member 31 so as to be slidable. Since the buoyancy member 40 and the buffer member 50 are fixed to the fixing member 35 of the connecting member 32 sliding along the sliding groove 33, the installation position of the buoyancy member 40 and the buffer member 50 is fixed. It can be easily changed along the sliding groove (33).

On the other hand, the buoyancy member 40 according to the present invention will be described in detail as follows.

The buoyancy member 40 is installed in the sliding groove 33 formed on the lower surface of the profile member 31 through the connecting member 32 to provide buoyancy to the base member 20. The buoyancy member 40 has a main body 41 and a flange member 42 provided above the main body 41.

The main body 41 is formed in a rectangular cross section, and preferably formed of a material such as styrofoam or urethane having a specific gravity smaller than water so as to easily provide buoyancy to the base member 20.

The main body 41 includes a plurality of first and second reinforcing protrusions 43 and 45 protruding from the outer surface of the main body 41 to prevent breakage by external forces such as waves. The first reinforcing protrusions 43 are formed to extend in the vertical direction and protrude a predetermined distance from the outer surface of the main body 41.

The plurality of first reinforcing protrusions 43 are formed at positions spaced apart from each other along the outer surface of the main body 41.

The second reinforcing protrusions 45 protrude from the upper surface of the main body 41 to extend in the longitudinal direction. The plurality of second reinforcing protrusions 45 are preferably formed at positions spaced apart from each other along the width direction of the main body 41.

On the other hand, although not shown in the drawings, unlike the present embodiment, the main body 41 may be formed of a synthetic resin material such as plastic, such as a plastic provided with an internal space filled with air to provide buoyancy.

The flange member 42 is formed to protrude laterally on the upper surface of the main body 41, the through hole is formed so that the fixing member 35 of the connecting member 32 can be inserted through.

The flange member 42 is formed in the main body 41 in the region except for the portion where the reinforcing protrusion 43 is formed so as to prevent the fixing member 35 from being interfered by the reinforcing protrusion 43 when the fixing member 35 is inserted through the through hole. It is preferable to be.

Meanwhile, in the illustrated example, the structure in which six flange members 42 are provided along the edge of the upper surface of the main body 41 has been described. It may be installed on the upper surface.

The buoyancy member 40 is installed in the connecting member 32 by fastening the nut 44 to the end of the fixing member 35 passing through the through hole of the flange member 42. As described above, the buoyancy member 40 configured as described above is installed in a plurality of positions spaced apart from each other in the longitudinal direction of the base member 20.

When changing the installation position of the buoyancy member 40, loosen the nut 44 fastened to the end of the fixing member 35 and then sliding the connecting member 32 along the sliding groove 33 of the profile member 31. Change the installation location. When the change of the installation position of the buoyancy member 40 is finished, the nut 44 is fastened to the end of the fixing member 35 to fix the installation position of the buoyancy member 40.

The buoyancy member 40 configured as mentioned above has an advantage that the installation position can be easily changed as necessary by the connecting member 32 slidably coupled along the sliding groove 33.

Hereinafter, the shock absorbing member 50 according to the present invention will be described in detail.

The buffer member 50 is slidably installed through the connecting member 32 in the restriction groove formed in the side surface of the profile member 31. The shock absorbing member 50 is preferably formed of a rubber material so as to reduce the transmission of the shock generated when the base member 20 collides.

The shock absorbing member 50 has a semicircular cross section and is formed to extend a predetermined length side by side in the longitudinal direction of the base member 20. The shock absorbing member 50 is preferably formed in the hollow 51 in the longitudinal direction in order to easily cushion the external impact.

In addition, the buffer member 50 is formed with a plurality of through-holes at positions spaced apart from each other along the longitudinal direction on the side so that the fixing member 35 of the connecting member 32 can be inserted.

The shock absorbing member 50 is installed in the connecting member 32 by fastening the nut 52 to the end of the fixing member 35 passing through the through hole of the shock absorbing member 50. A plurality of shock absorbing members 50 configured as mentioned above are respectively installed at positions spaced apart from each other in the longitudinal direction of the base member 20.

When changing the installation position of the buoyancy member 40, loosen the nut 52 fastened to the end of the fixing member 35 and then slide the buffer member 50 along the sliding groove 33 of the profile member 31 Change the installation location. When the change of the installation position of the shock absorbing member 50 is finished, the nut 52 is fastened to the end of the fixing member 35 to fix the installation position of the shock absorbing member 50.

On the other hand, although not shown in the drawings, a plurality of connecting members 32 are also provided in the sliding groove 33 formed on the upper surface of the profile member 31 to install the cleats and other additional units on the upper surface of the base member 20. Can be inserted.

Units installed on the upper surface of the base member 20 are fixed to the connecting member 32, so that the mounting member 32 is installed in the profile member 31 to be slidably along the sliding groove 33 by the connecting member 32, thereby easily installed. Can be changed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

10: floating body
20: base member
21: mesh net
30: connection unit
31: profile member
32: connecting member
33: sliding member
34: insertion member
35: fixing member
40: buoyancy member
41: main body
42: flange member
43: reinforcement protrusion
50: cushioning member

Claims (4)

A base member;
A connection unit installed at an edge of the base member, the profile member having a sliding groove extending in a longitudinal direction, and a connection unit provided with a plurality of connection members slidably inserted into the sliding groove;
And a buoyancy member installed on the connection members constrained by the sliding groove to provide buoyancy.
The method of claim 1,
The connecting member
An insertion member inserted into the sliding groove;
And a fixing member protruding from the insertion member so that the buoyancy member is installed in the insertion member inserted into the sliding groove.
The profile member further includes a departure prevention protrusion protruding to extend in the longitudinal direction on the inner wall surface of the sliding groove so as to interfere with the insertion member inserted into the sliding groove from being separated from the sliding groove. Float characterized by.
The method of claim 2,
The profile member is a floating body, characterized in that the sliding groove is formed in each of the plurality of outer surface of the outer surface formed side by side with respect to the longitudinal direction of the base member.
The method of claim 3,
It is installed on the connection member that is constrained to the sliding groove formed on any one of the outer surfaces of the profile member except the side of the profile member on which the buoyancy member is installed to reduce the transmission of impact generated when the base member collides. Floating member characterized in that it further comprises;

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