KR20150048539A - Assemblable apparatus for bouyancy - Google Patents

Abstract

The present invention relates to an assembly-type buoyancy body. More specifically, a buoyancy body is produced to float on the surface of water such as the lake or sea and to be used for cage culture and the like. Connection holes are formed in both ends of a buoyancy material having a particular length, and another buoyancy material can be fitted and coupled through the connection holes. A coupling structure is simplified compared to an existing one, thereby improving production efficiency and and reinforcing floating stability and durability even when a water surface situation is rough. The buoyancy body of the present invention comprises: a buoyancy material having a particular length; and connection holes coupled with both length direction ends of the buoyancy material. The connection holes are coupled to be symmetrical to other connection holes, and a supporting buoyancy material can be coupled with the connection holes and other connection holes.

Description

Assemblable apparatus for bouyancy < RTI ID = 0.0 >

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a prefabricated buoyant body, and more particularly, to a prefabricated buoyant body which is capable of floating on a water surface such as a lake or the sea and forming a buoyant body used for cage culture, The connecting structure is formed and the other buoyant material can be fastened through the connecting hole so as to further simplify the fastening structure compared with the prior art so that the efficiency of the manufacturing operation is further improved and, So that the durability is further improved.

Prior to describing the background of the present invention, among the various fields in which the present invention is used, cages used for fish farming will be described as an example.

In general, caged fish is used to float several buoyant objects on the surface of the water and connect the net to the lower side of the water so that certain fish can be confined within the net. Thus, in recent years, And the tendency to worsen is often progressing far into the offshore area.

A typical facility used in the above-mentioned cage culture is a structure in which a small-diameter pipe or the like is screwed in a longitudinally and horizontally fixed form and a buoyant sphere is installed at regular intervals therebetween. That is, the net is connected to a certain depth below the water surface.

The conventional structure as described above will be described in more detail. In the conventional structure, a small diameter pipe having little buoyancy is used, and the structure is structured such that it is connected by screw tightness in the vertical and horizontal directions. In addition, And the structure is floated on the water surface, so that when the wave is severely generated, it is not suspended on the surface continuously, and often sinks down to the surface of the water or is damaged by wave shaking.

In order to prevent the above-described problems, a technique has been developed in which the large-diameter pipe itself is provided with a buoyancy function by using a large-diameter pipe instead of the existing small-diameter pipe.

However, since the above-described technology has an integral structure in which a large-diameter pipe is vertically and horizontally connected and a plurality of parts are screwed together, it is difficult to manually tighten the screws in the course of work, There is a problem that the working efficiency is very low due to the fastening structure.

In addition, the fastening structure of a conventional structure requiring complicated screwing of longitudinally and horizontally as described above has a low flexibility and high rigidity, so that there is a problem that the risk of breakage due to continuous waves is very high.

Korean Public Practice No. 1999-5930 'Cage farm (released on February 18, 1999)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

In order to form the buoyant member by fastening the buoyant member longitudinally and laterally, the buoyant member can be fastened with another buoyant member using a connecting port, and the connecting port can be fastened in a symmetrical shape to each other, thereby simplifying the fastening structure The present invention has been made in view of the above problems, and it is an object of the present invention to provide a prefabricated buoyant body which can be assembled easily.

In addition, when the buoyant material, the buoyant material, the buoyant material, and the connecting port are fastened together, the buoyancy compensating portion is formed on the outer side of the buoyant body by forming a watertight diaphragm portion at the connection portion thereof, The present invention also provides a buoyant buoyant body which is capable of flexibly responding to swinging caused by the buoyancy of the buoyant buoyant body.

In order to accomplish the above object, the present invention is described as follows.

First, the assembled buoyant body according to the present invention comprises: a buoyant material formed to a predetermined length; A connecting hole which is fastened to both longitudinal ends of the buoyant material; Wherein the connecting port is symmetrically coupled with the connecting port of another buoyant material so that the supporting buoyant material can be cross-connected with a connecting port of the connecting port and another buoyant material.

Here, the connector may include: a coupling plate portion formed in a shape corresponding to an outer surface of the supporting buoyant member; A fastening piece formed on upper and lower sides of the fastening plate portion; A fusion splice formed on the opposite side of the splicing plate and fastened to an end of the buoyancy material; A watertight diaphragm formed inside the fused joint portion; And a control unit.

The connection port and the other connection port are characterized in that the respective coupling plate portions are opposed to each other and the fastening pieces formed on the upper and lower sides are opposed to each other so as to be symmetrically fastened by the fastening means so that the supporting buoyant material is interposed therebetween .

In addition, the other buoyant members to be connected to the connecting port of the buoyant member are connected to each other by the sealing fusion at every predetermined length, and are connected together with the watertight diaphragm portion.

In addition, a buoyancy complementary part including a buoyancy complementary material having a predetermined length is formed outside the buoyancy body including the buoyancy material and the connection port, and the buoyancy complementary part includes a buoyancy complementary part in a direction crossing the connecting port, Is formed by being fastened with a fitting.

In addition, the foot plate is fastened to the buoyancy member, wherein the foot plate has: a support body part that is fastened to the outer side surface of the buoyancy member at regular intervals; A plate portion formed horizontally above the support fastening portion; And a control unit.

The present invention having the above-described configuration can be expected to have the following technical and economic effects.

In order to form a buoyant body by connecting a buoyancy material having a predetermined length longitudinally and laterally, a connecting member is fastened to both ends of the buoyant member, and the connecting member is fastened symmetrically with another connecting member, It is possible to form a lattice-shaped buoyant body having a relatively simple structure as compared with the prior art.

In addition, unlike the conventional method of tightening the buoyancy material and the buoyancy material and fastening the buoyancy material and the connecting port, the buoyancy material can be formed integrally through fusion bonding, thereby maximizing the flexibility of the buoyancy material So that it is not easily damaged even in the case of severe waves.

In addition, the connector is formed to be symmetrically fastened to the other connector with respect to each other, so that the connector can be easily attached to the outer surface of the supporting buoyant member. Thus, the work time and manpower required to make the assembled buoyant body can be reduced, The working efficiency is further improved.

In addition, when the watertight diaphragm is formed inside the fusion splice portion of the connector and the watertight diaphragm portion for support is formed at the connection portion when the buoyant material having a predetermined length is connected in the longitudinal direction, even if the buoyancy function is lost, Due to the watertight segregation part, the rest of the components can float on the water surface, thereby further improving the stability and durability of the buoyant body.

In addition, the buoyancy compensating portion is formed on the outside of the buoyant body, so that the buoyant body can be continuously and stably floated to the surface of the buoyant body even when the waves are shaken, thereby further improving the durability and stability of the buoyant body.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
Fig. 2 is a view showing the basic fastening degree of the buoyant body according to the present invention
3 is an enlarged view of a portion A in Fig. 2
Fig. 4 is a longitudinal cross-sectional view of the connector according to the present invention
Figure 5 is a cross-sectional view of the fastening of the connector according to the invention
Fig. 6 is a graph showing the overall tightening degree of the buoyant body according to the present invention
7 is a cross-sectional view of the buoyancy compensating portion according to the present invention,
Fig. 8 is a plan view showing the entire floor plate of the buoyant body according to the present invention
8 is a detailed view of a foot part of a buoyant body according to the present invention
9 and 10 are side views of a foot plate of a buoyant body according to the present invention
11 is a cross-sectional view of the foot of the buoyant body according to the present invention

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, the buoyant body (100) according to the present invention comprises: a buoyant material (10) formed with a predetermined length; (20) fastened to both longitudinal ends of the buoyant material (10); The coupling 20 is symmetrically coupled with the coupling 20a of the other buoyancy material 10a so that the supporting buoyancy material 11 can be cross-coupled with the coupling 20 and the coupling hole 20a. As shown in FIG.

Here, the buoyant material 10 is formed to have a predetermined length, is hollow and has a cylindrical shape in cross section, and the buoyant material 10 is preferably made of plastic, The buoyant member 11 is also formed in the same shape.

When the both end portions of the buoyancy material 10 having such a configuration are sealed, the air inside the buoyancy material 10 is sealed, so that the buoyancy material 10 can also have a buoyancy function capable of floating on the water surface.

The connecting member 20 is fastened to both ends of the buoyant member 10 having the above-described structure. Both ends of the buoyant member 10 can be sealed through the fastening of the connecting member 20, ), And the buoyant member (11) can be fastened with the support buoyant member (11).

6, a supporting buoyant material 11 is formed to be long in the longitudinal direction, and a connecting hole 20 is formed at both ends of the buoyant material 11, and the supporting buoyant material 11 is inserted into the connecting hole 20 Is a buoyancy material (10).

Hereinafter, a structure for fastening the buoyant member 10 and the buoyant buoyant member 11 through the connecting hole 20 will be described in more detail.

First, the connector 20 includes a coupling plate 21 formed in a shape corresponding to the outer surface of the supporting buoyant member 11; A fastening piece 22 vertically formed on the upper and lower sides of the fastening plate portion 21; A fused joint portion 23 formed on the opposite side of the binding plate portion 21 and fastened to an end portion of the buoyant material 10; A watertight diaphragm 24 formed inside the fused joint portion 23; .

The connection port 20 formed as described above is symmetrical with the connection port 20a fastened to the end portion of another buoyant material 10a so that the fastening plate portions 21 and 21a of the connection ports 20 and 20a So that the supporting buoyant member 11 can be tightly inserted and clamped between the symmetrically fastened coupling plates 21 and 21a.

At this time, the fastening pieces 22 and 22a which are brought into confrontation with each other are structured to be fastened by the fastening means 25 through the fastening holes 26 formed through the fastening pieces 22 and 22a have.

Since the coupling plate 21 is formed to be parallel to the end surface of the buoyant member 10 and curved to correspond to the outer surface of the buoyant member 10, the coupling plate 21 of the coupling hole 20, (11) are fastened in a direction crossing horizontally with respect to the buoyant member (10).

The connecting port 20a of another buoyant material 10a which is symmetrically fastened to the connecting port 20 is also fastened to the end of another buoyant material 10a in the same manner as the fastening form of the buoyant material 10 and the connecting port 20 Therefore, if the fastening structure as described above is repeatedly formed in the longitudinal direction of the buoyancy material 10, the fastening structure as described above can be formed at regular intervals.

In addition, the same fastening structure may be formed at regular intervals in the horizontal crossing direction with respect to the longitudinal direction of the buoyant member 10, so that the support buoyant member 10 fastened to the connecting hole 20 of the buoyant member 10 Another coupling 20 can be attached to the flange 11 at regular intervals and when the coupling structure is repeatedly formed in the longitudinal direction of the buoyancy material 10 and the horizontal crossing direction thereof as described above, ) Can be formed.

Here, the supporting buoyant member 11, which is fitted in the connecting hole 20 of the buoyant member 10 and formed in a horizontal crossing direction, is formed to have a predetermined length. When a longer length is to be formed, It is preferable that the buoyancy material 11 is integrally formed by connecting the ends of the buoyancy material 11 by fusing them together.

At this time, when the ends of the supporting buoyant members 11 are connected to each other by the fit welding, it is preferable that the watertight diaphragm portions 12 for support are also formed and connected so that the rest of the buoyant members 11 are suspended on the water surface in a stable manner Do.

At this time, it is preferable that the support watertight diaphragm portion 12 is formed in a plate-like shape having an area corresponding to the end face of the buoyant material 11, and is sandwiched between the end portions and fused together.

The watertight diaphragm 12 for support is formed in a plate-like shape, and an insertion fitting (not shown) is formed by protruding on both front and rear surfaces of the support waterproof diaphragm 12 so that the waterproof diaphragm 12 can be fastened and fused It is also possible to do.

The fusion splicing between the fusion splicing portion 23 of the connector 20 and the fusion splicing portion 23 of the splicing receptacle 20 is also applied to the fusion splicing between the end portion of the buoyancy material 10 and the fusion splicing portion 23 of the splicing receptacle 20. More specifically, The end faces of the buoyant member 10 are fused to each other to form a single body. In this case, the end face of the fused joint portion 23 should be formed to have the same size as the end face of the buoyant member 10.

The flexibility of the buoyant body 100 can be further improved by forming the support buoyant member 11 in the longitudinal direction or tightening the buoyant member 10 and the connection port 20 through the grease fusion as described above So that it is possible to flexibly cope with the shaking of severe waves, so that it is not easily broken.

The connecting structure of the buoyancy material 10 according to the present invention is such that the connecting hole 20 is fastened to both ends of the buoyant material 10 having a predetermined length and the other buoyant material 11 is fastened through the connecting hole 20 Therefore, compared with the conventional fastening structure in which screws are screwed in a complicated manner in the vertical and horizontal directions, the fastening structure can be further simplified because of the simplified fastening structure.

Meanwhile, the buoyancy compensating part 30 formed on the outside of the buoyant body 100 according to the present invention formed as described above allows the buoyant body 100 to float on the water surface in a stable manner at all times Do.

6, the buoyancy compensating portion 30 is provided at both side ends of the supporting buoyant material 11 which is horizontally cross-coupled to the buoyancy material 10 so that the overall buoyancy force of the buoyant body 100 So that it can be strengthened.

More specifically, the buoyancy compensating part 30 includes a buoyancy compensating material 31 having a predetermined length. The buoyancy compensating part 31 has a length And are fitted into fittings 20b which are fastened to both ends of the buoyancy material 11 in a direction intersecting the horizontal direction.

That is, the structure of the basic buoyant body 100 according to the present invention is formed by fastening the supporting buoyant material 11 in the horizontal crossing direction to the end of the buoyant material 10 through the connecting hole 20, The buoyancy compensating portion 30 formed on the outer side of the buoyant body 100 can be formed on the same principle by forming the connecting hole 20b at both side ends of the buoyant material 11 and fastening the buoyant complementary material 31 thereto. It is.

Meanwhile, it is preferable that the both ends of the buoyancy comple- ment 31 and the end portions of the supporting buoyant material 11 at the corresponding positions are connected to each other by the elbow-type connecting port 32. [

One end of the elbow type connecting port 32 is connected to the end of the buoyancy filling member 31 and the other end of the elbow type connecting port 32 is connected to the side end of the supporting buoyant member 11 at the corresponding position To be connected.

It is preferable that the elbow type connecting port 32 is formed in a curved shape at an angle of 90 degrees with a predetermined length having the same cross section as the buoyancy compliant material 31 and the supporting buoyant material 11.

The buoyancy force of the buoyant body 100 according to the present invention is further strengthened by forming the buoyancy compensating portion 30 on the outer side of the buoyant body 100. As a result, Will not sink below the surface of the water and will be able to float on the surface continuously and steadily.

The buoyancy material 10, the supporting buoyant material 11, the connecting hole 20, the buoyancy filling material 31 and the elbow type connecting hole 32 are made of plastic so that they can be easily manufactured and fastened. It is preferable that the plastic is formed of polyethylene (PE) having high flexibility as a thermoplastic resin.

Accordingly, not only the above-mentioned structures can be easily welded together but also can be more flexibly coped with the shaking of severe waves owing to the structure formed integrally with the welded joints.

In addition, it is also possible to fasten the foot plate 200 to the upper side of the buoyant body 100 constructed as described above, as shown in FIG.

The foot plate 200 includes a plate portion 210 horizontally installed on the upper side of the buoyancy material and a support body portion 220 fastened to the outer surface of the buoyancy material 30, To be able to know.

At this time, the support body 200 has a pair of mutually symmetrical structures, and the inner side is formed in a shape corresponding to the outer side surface of the buoyancy member 10, and is attached to the outer side surface of the buoyancy member 10 And a plate portion 210 is horizontally mounted on the upper side of the support body 200. [

In addition, other specific configurations other than the configuration of the footrest 200 are generally known, and a detailed description thereof will be omitted.

While the present invention has been particularly shown and described with reference to embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments.

10, 10a: buoyant material 11: buoyant material for support
12: watertight diaphragm for support 20, 20a, 20b:
21, 21a: Binding plate portion 22, 22a:
23: fusion splicing portion 24: watertight diaphragm
25: fastening means 26: fastening hole
30: Buoyancy supplement part 31: Buoyancy supplement part
32: elbow type connector 100: buoyant body
200: foot plate 210: plate portion
220: support fitting

Claims (6)

A buoyant material (10) formed with a predetermined length; (20) fastened to both longitudinal ends of the buoyant material (10); The coupling 20 is symmetrically coupled with the coupling 20a of the other buoyancy material 10a so that the supporting buoyancy material 11 can be cross-coupled with the coupling 20 and the coupling hole 20a. Wherein the first and second baffle members are made of a synthetic resin.
The method according to claim 1,
The connector (20)
A coupling plate portion 21 formed in a shape corresponding to the outer surface of the supporting buoyant member 11; Fastening pieces 22 formed on the upper and lower sides of the binding plate portion 21; A fused joint portion 23 formed on the opposite side of the binding plate portion 21 and fastened to an end portion of the buoyant material 10; A watertight diaphragm 24 formed inside the fused joint portion 23; Wherein the buoyant body comprises:
3. The method of claim 2,
The connecting port 20a and the other connecting port 20a are formed such that the binding plate portions 21 and 21a are opposed to each other and the fastening pieces 22 and 22a formed on the upper and lower sides thereof face each other and are symmetrically So that the supporting buoyant member (11) is inserted and fastened therebetween.
The method according to claim 1,
Wherein the supporting buoyant member (11) fastened to the connecting port (20) of the buoyant member (10) is connected to the watertight diaphragm part (12) for support at a predetermined length and is connected together with the sealing fusion.
The method of claim 3,
The buoyancy compensating unit 30 includes a buoyancy compensating member 31 having a predetermined length at the outside of the buoyancy body 100 including the buoyancy member 10 and the connecting port 20. The buoyancy compensating unit 30, Is formed by fitting a buoyancy compliant material (31) in a direction transverse to a connecting port (20b) to be fastened to both side ends of the buoyancy material (10).
The method according to claim 1,
The foot plate 200 is fastened to the buoyant member 10, and the foot plate 200 includes a support body 220 which is fastened to the outer surface of the buoyant member 10 at regular intervals; A plate portion 210 formed horizontally above the support body 220; Wherein the buoyant body comprises:

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