KR101247751B1 - A buoy and its manufacturing method for the ses-farming facility - Google Patents

Abstract

PURPOSE: A buoy for marine cage farming facility and a manufacturing method thereof are provided to allow reduction of manpower and to improve assembly efficiency. CONSTITUTION: A buoy for marine cage farming facility comprises a buoyant member which is made of styrofoam or foam, and a cover(30) which covers the outside of the buoyant member to prevent the buoyant member from being exposed to seawater. A pair of first penetration holes(36) are formed on both sides of the cover so that a connecting pipe can be inserted. A pair of second penetration holes(38) are formed on both sides of the first penetration hole so that the connecting pipe can be inserted.

Description

A cage and its manufacturing method for the sew-farming facility

The present invention relates to a cage for farming cages and a method of manufacturing the same, and more particularly for the installation of a connecting pipe for connecting the floats and scaffolds and a plurality of spheres used in cage cages to form a variety of objects in the offshore waters The penetrating holes are integrally formed, and the cage farming accessory and the manufacturing method thereof are used to facilitate the installation work of the cage farm facility and to reduce environmental pollution.

Through trade agreements between countries, many commodities are imported on a large scale without special tariffs or low tariffs, and there is a fierce competition between commodities and goods within the same sector.

Of course, in marine products, some fish species depend mostly on imports, but due to the three sides of the sea, the characteristics of eating habits and the difficulty of long-term distribution, For some fish species in circulation, they still have their own competitiveness.

In particular, the high value-added products for fish and shellfish that can be produced in aquaculture on the coast near the land provided high profits to the fishermen.

However, as the number of aquaculture farmers increases, in particular, as the number of aquaculture farms increases, there is a situation in which it is difficult to create high added value as the price difference varies according to the shipment and supply of aquaculture individuals.

Moreover, in the case of veteran abalone, which is mainly farmed on the coast of Korea, if the production time is constant and mass shipments occur at one time, the price drop is natural, and the fishermen who invested a lot of capital Receiving less than this, the situation has to come up with measures.

The present invention relates to a cage farm facility that requires a lot of economic burdens and hard labor that farmers are facing in the field of aquaculture, where competition is intensifying and profitability is gradually decreasing.

In particular, cage farm facilities must be installed at a specific time, depending on the season or seawater temperature at which the farmed animals are suitable, and farmers working in aquaculture in fishing villages, like farming seasons in rural areas, are required to complete all cage farm facilities in a short period of time. It should be prepared and installed at sea.

Therefore, in the process of preparing the cage farm facilities, a large number of workers are required, but the actual situation is lacking a lot of workers.

Looking at the structure of the cage farm facilities, the cages which display the range of the farm while supporting the nets and shelters floating below the sea level while floating on the sea, and the bottom of the cages at a certain depth under the cage frame It is made of a configuration that is provided with a net to be installed, the shelter in which the inhabited objects are installed and cultured inside the net, and a lower frame on which the shelter is fixed.

Most of these cage facilities are usually assembled on land and then moved offshore and installed on appropriate coasts.

One of the work that requires the most work among the cage farm facilities is the part that constitutes the cage frame, and the conventional cage frame prepares a plurality of floats so as to float on the sea surface, and fixes them at the bottom of the connecting pipe, respectively, On the upper surface of the connecting pipe where the two mouths are fixed, a scaffold is installed to provide a passage for the worker to work in the cage farm after the sea installation.

 In addition, since the mouth is formed of styrofoam, it is weak to external impact, easily broken during external shock, and has a disadvantage of shortening its durability life when exposed to sunlight. The outer circumference and the connecting pipe are integrally connected using a wire.

The process of assembling these caged farm facilities on land is very complicated, and the efficiency of the work is reduced, and the fishing boats wrapped in the wrapping paper after installation at sea are degraded by contact with the working fishing boat or prolonged exposure to the sun. Phenomena occur and are easily broken, and deterioration or tearing of the wrapping paper surrounding the mouth causes peeling and breakage of the styrofoam located therein.

Therefore, after using fish farm facilities for a certain period of time (typically 4 to 5 years), fishermen have to replace the styrofoam used as a float, and the economic cost of the new float is incurred.

In addition, the Schirofoam fragments and particles separated from the buoys installed in the sea floating along the sea water will not only cause the environmental pollution of the coast, but also act as a factor to damage the surrounding environment of the coast.

In addition, when meat is eaten Schirofoam particles floating on the sea surface, it does not discharge from the body acts as a cause of death.

In particular, the styrofoam particles floating in the sea water in the near sea are refracted or reflected by the sun's rays, thus acting as a factor that inhibits the growth of various marine plants inhabiting the sea surface. Due to the decrease in capacity, the seawater pollution of the coast is gradually increasing, and much effort has been made to prevent this.

An assembly structure of a cage according to an embodiment of such a conventional cage cage facility is briefly shown in FIG.

As can be seen in the conventional cage frame 10 shown in Figure 1, a plurality of sub-ball 5 is connected to the connection pipe or footrest member 9 through a separate fastening means (6, wire or connecting straps, etc.) Is installed, a plurality of scaffolding portion (8) is installed on the upper end of the connecting pipe or the footrest support member (9), the footrest part 8 is also a separate fastening means at a predetermined interval to the connection pipe or footrest support member (9) (7, fastening bolts, wires, etc.) is used to fix.

Therefore, since numerous fastening operations must be performed between the buckle 5 and the footrest part 8 and the footrest support member 9, it takes a lot of time and material costs to assemble one frame 10 into a rectangular structure. Of course, even after the conclusion of each configuration, the binding unit that was bound by the wave or waves of seawater gradually became loose over time or the binding force was broken, there was an inconvenience to perform the repair work from time to time.

In addition, the frame frame 10 is assembled in a rectangular shape having a certain standard, in which one side of the footrest support member and the other footrest support member is located at the top, the other side to cross each other at a portion (T) that cross at right angles. Since it must be located at the lower part, the stepped portion is formed at the intersection portion (T) of the scaffold support member, which is not only inconvenient to assemble, but also when the worker moves for work after installation on the sea surface, the accident falls over the stepped part of the corner. There was a risk of occurrence.

Therefore, in the assembly of cage farm facilities, the inventors can reduce the labor cost of workers by assembling the floats, connecting pipes and scaffolding, reduce the labor cost of workers, and reduce the economic cost of frequent replacement of the floats. The present invention was conceived by recognizing the necessity of developing a float to prevent marine pollution and to facilitate the growth of seabed plants.

Prior Art Document 1: Korea Utility Model Registration No. 20-0186723 (Registration Date: 2000.04.11) Prior Art Document 2: Korean Patent Publication No. 10-2004-20320 (published: 2004.03.09)

The present invention is to improve the shortcomings of the floats installed in the above-mentioned conventional cage cages, the present invention is to form a scaffold and a float integrally, as well as to form a through-hole for installing a connection pipe in the cage, the cage in the field The purpose is to provide a cage farming tool and a method of manufacturing the cage farming facility that greatly improves the labor saving of workers and the assembly work of cages by simplifying the assembly work of the farm.

In addition, the present invention is to provide a cage for farming cages and a method of manufacturing the same to prevent damage to the buoy after installation on the sea, and to prevent sea pollution and growth inhibition of the seabed plants due to breakage and separation of the buoyancy body. There is another purpose.

In addition, the present invention extends the endurance life of the floats to reduce the inconvenience caused by frequent replacement and economic expenditures required during replacement, to prevent the occurrence of safety accidents during the movement of the worker after sea installation And it is another object to provide a method of manufacturing thereof.

In order to achieve the above object, one embodiment of the cage cages according to the present invention is a buoyancy body of a certain size molded from styrofoam or foam foam; The buoyancy body is wrapped around the outside of the buoyancy body so as not to be exposed to sea water, the cover body formed with a pair of first through-holes in the front and rear direction so that the connecting pipe can be fitted to both sides of the upper and left sides.

In addition, a pair of second through holes penetrated in the front and rear directions may be further formed on both left and right sides of the lower end of the first through hole so that the connecting pipe may be fitted. It is made of a long rectangle, the upper surface is formed of a flat scaffolding portion and the bottom is a round shape, the scaffolding is characterized in that the anti-slip projections formed integrally.

In addition, another embodiment of the cage cage according to the invention is a buoyancy body of a certain size molded from styrofoam or foam foam; A pair of first through holes penetrated to the front and rear surfaces so that the connecting pipes can be fitted to the left and right sides of the upper and rear surfaces, and the connecting pipes are inserted into the front and rear surfaces so that the connecting pipes can be fitted to both the lower left and right sides where the first through holes are formed. A pair of second through-holes and a space for accommodating a portion of the buoyancy body are provided inside the lower end where the second through-hole is formed, and one side is provided with a buoyant body accommodating part each having an opening to be fitted to both sides of the buoyancy body. And a first cover and a second cover body made of plastic synthetic resin, which are in contact with the tip portion integrated by heat fusion and are not exposed to the seawater.

On the other hand, the manufacturing method of the cage farming accessories according to the present invention for achieving the above object comprises the steps of forming a buoyancy body in a rectangular shape with a length longer than the width; The upper surface is flat and the lower portion has a round shape, and has a rectangular shape with a length longer than the width, and the pair of first and second through holes are provided in the front and rear directions so that connecting pipes can be inserted up and down on both the left and right sides of the upper portion. At the same time, a flat upper surface formed to be used as a scaffolding portion is formed with a non-slip protrusion integrally, the buoyancy body accommodating a portion of the buoyancy body in which one side is opened in the lower end inside the first and second through holes are formed Molding first and second cover bodies of plastic synthetic resin to be additionally provided; Assembling the buoyancy body to the inner buoyancy body accommodating portion of the first and second cover bodies while the first and second cover bodies are positioned to both the left and right sides of the buoyancy body; Heat-sealing contact tip portions of the first and second cover bodies such that the first and second cover bodies are assembled to the outside of the buoyancy body so that the buoyancy bodies are not exposed to seawater while both tip portions are in contact with each other. Is done.

In the present invention described above, the scaffolding unit is integrally formed on the upper surface of the constituent frame of the cage farm, and through-holes penetrated to the front and rear surfaces of the upper portion of the cage are integrally formed so that a connection pipe connecting a plurality of the floats is formed between the respective spheres. Since it is assembled integrally through, it is possible not only to save a lot of labor at the time of assembling the ball and the frame assembly on the land, but also has a useful effect to further reduce the labor of the worker through the reduction of working time.

In addition, the float according to the present invention is coated with a plastic synthetic resin on the outer surface of the buoyancy body to prevent peeling or breakage of the styrofoam to prevent marine pollution as well as to prevent the growth of the seabed plants.

In addition, the ball according to the present invention is improved durability to solve the inconvenience of having to replace the ball every fixed period as in the conventional, and to reduce the economic cost of the replacement to improve the profitability of fishermen. .

In addition, when assembling the frame using the float according to the invention, the step is not generated in the height of the scaffolding portion of both sides by the vertical intersection of the connection pipe at the corner where the float or the connection pipe intersect, so that the worker's work at the cage farm To improve the convenience of movement and to prevent the occurrence of various safety accidents.

1 is an installation state of the corner portion of the frame according to a conventional embodiment,
Figure 2 is an external perspective view of the buoyancy body used in the float according to the invention,
3 is an external perspective view of a buoy according to an embodiment of the present invention in which a synthetic resin is integrally molded to the outside of the buoyancy body of FIG.
4 is an external perspective view of a float according to another embodiment of the present invention;
Figure 5 is an exploded perspective view of the floats of Figure 4,
Figure 6 is an installation state for one side corner portion when assembling the frame using the ball according to the invention,
7 is a cross-sectional view taken along the line AA of FIG. 6;
8 is a manufacturing process of the float according to the present invention.

Hereinafter, with reference to the accompanying drawings in the specification will be described in detail with respect to the float and the method for manufacturing the same.

2 and 3 is an external perspective view of the buoyancy body 20 used in the float according to the invention and the float 60 of one embodiment.

The buoy according to the present invention consists of a configuration including a buoyancy body 20 of a predetermined size molded into a styrofoam or foamable foam therein.

As shown in the figure, the buoyancy body 20 is formed in a shape in which the upper center portion protrudes more than the left and right upper surfaces, and the lower end portion is configured to have a round shape of a ∪ shape.

The lower end of the buoyancy body 20 is formed in the shape of a round shape in the shape of the cover to be described later to the shape of the shape of the bottom, when the bottom portion is made in the shape of the bottom when the wave or tidal current when installed on the sea surface This is to minimize the influence of the float.

In addition, the size is made of a rectangle formed with a length longer than the width of the longitudinal section, but there is no particular limitation on the size or shape.

The cover body 30 having a predetermined thickness is molded to prevent breakage due to an external impact to the outside of the buoyancy body 20 configured as described above, and to improve its durability.

As shown in FIG. 3, the cover body 30 is formed integrally with the buoyancy body 20 to form a film layer having a predetermined thickness, and the upper surface of the cover body 30 is maintained in a flat cross section, and the lower end thereof is It consists of a round shape of the X shape same as the shape of the said buoyancy body.

In particular, a pair of first through-holes 36 are formed at the upper and lower ends of the cover body 30 in the front and rear directions so that the connecting pipes can be fitted to the buckle 60, respectively. At the lower end of the first through hole 36, another pair of second through holes 38 having the same structure and size as the first through hole 36 are formed.

In addition, the top surface of the cover body 30 is assembled with a frame frame is provided with a flat scaffolding part 35 that can be stepped by the operator after installation on the sea, the scaffolding part 35 to prevent slipping Anti-slip projections 39 are further formed in the form of unevenness.

And, a plurality of net fixing holes (35a) is formed on the left and right edges of the scaffolding part 35 is installed so as to fix the upper end of the net installed on the seabed at the bottom of the cage frame when installed as a cage farm facility on the sea surface do.

In particular, the edge portion of the footrest portion 35 formed with the net fixing hole (35a) is more preferably configured to facilitate the fixing operation of the net is made of a size that partially protrudes outward than the body portion of the lower cover body (30). Do.

As described above, the buoy 60 according to an embodiment of the present invention in which a buoyancy body is included therein and the cover body 30 made of a plastic synthetic resin having a predetermined thickness to the outside of the buoyancy body is integrally formed is prevented from slipping on an upper surface thereof. The footrest part 35 having the protrusion 39 is integrally formed, and the first and second through holes 36 and 38 are formed integrally to fix the fitting 60 to the connection pipe. It is configured to improve the assembly convenience and shorten the working time, durability of the floats 60 and the like.

The first and second through-holes 36 and 38 formed in the sub-ball 60 are formed in two pairs of upper and lower sides at the same time, but in actual installation, connecting pipes are installed and assembled only in one of the upper and lower through-holes. Ribs 37 are formed in the other through hole where the pipe is not installed so that the user can see the ribs 37 formed in the through holes to determine the installation direction of the buckle 60 to assemble the frame.

That is, the reason why the two upper and lower pairs of through-holes are formed in one sub-ball 60 is that when assembling the cage frame in a rectangular structure, the connection pipes penetrate each sub-ball at the corner portions where one side direction and the other side cross at right angles. This is to prevent the stepped portion from being formed on the upper surface of the connection pipe due to the connection pipes intersected at right angles by maintaining the upper and lower steps.

That is, since the connecting pipe passing through the first through hole 36 is positioned at the upper end, and the connecting pipe passing through the second through hole 38 is positioned at the lower end thereof, it is encountered at the corner portion when assembling a frame structure having a rectangular structure. The connecting pipes cross up and down so that the scaffolding portion formed on the upper surface of the float maintains the same height.

On the other hand, Figure 4 shows a buckle 70 according to another embodiment of the present invention, the appearance is the same as the embodiment described above, but the buckle 60 according to the embodiment is a cover body surrounding the buoyancy body is a single On the contrary, the buoy 70 of FIG. 4 has two first and second cover bodies 32 and 34 divided into left and right sides from the outside of the buoyancy body having a predetermined shape and are fitted with the cover body. It is made of a structure in which the buoyancy body is integrally assembled, and the molding method of the buoy is somewhat different from the above-described embodiment.

As shown in FIG. 4, the scaffolding portion 35 having the anti-slip protrusion 39 is provided on the upper surface of the buoy 70, and the lower end portion has a round shape made of an X-shape having the same shape as the above-described buoyancy body. Have

In addition, a plurality of net fixing holes 35a are formed at left and right edges of the scaffolding part 35 to fix the upper end of the net installed under the cage after the cage is assembled.

In addition, a first through hole 36 and a second through hole 38 penetrated in the front-rear direction at the upper end of the front part 70 are formed in a structure formed up and down on both left and right sides.

5 is an exploded state of the buckle 70 according to another embodiment of the present invention.

As shown in FIG. 5, the buoy 70 includes a buoyancy body 20 having a predetermined shape therein, and the outside of the buoyancy body 20 to cover the buoyancy body 20. The first cover body 32 and the second cover body 34 separated in two are coupled to the first cover body 32 and the second cover body 34 so that the buoyancy body 20 is not exposed to seawater. ), The two cover bodies (32, 34), which were separated by forming a heat fusion portion 48 (see FIG. 4) by heat fusion, are integrally combined and molded.

The first cover body 32 and the second cover body 34 have a symmetrical structure and are simultaneously used as the first cover body 32 and the second cover body 34 in one mold.

The first cover body 32 and the second cover body 34 each have an inner width corresponding to one half of the entire width of the buoyancy body 20, that is, the buoyancy body 20. The buoyancy body having a portion 40 is formed, respectively, in order to fit the buoyancy body 20 to the buoyancy body receiving portion 40, the opening direction 42 is formed in the inner direction, the outer direction is closed state Is maintained.

Therefore, the buoyancy body receiving portion 40 formed in the inward direction of the first cover body 32 and the second cover body 34 is fitted to the both sides of the buoyancy body 20 half by one buoyancy body 20 It is made of a structure that can completely wrap.

In addition, reinforcing ribs 44 and 46 are formed on the inner wall of the buoyant body accommodating part 40 and the inner wall of the cover body 20 in which the first and second through holes 36 and 38 are formed. It is configured to improve the durability of the 30.

The material of the cover body 30 is made of plastic synthetic resin, it is particularly preferably composed of a PE material to be configured to have a shock resistance that is not easily damaged by a certain external impact.

6 is an enlarged view of a portion of the buckle 60, 70 according to the present invention having such a structure and structure assembled in a cage so as to be actually installed on the sea.

In particular, Figure 6 shows an excerpt of the configuration for the cross-section (E) showing the greatest feature when assembling the frame 50 using the floats (60, 70) according to the present invention.

The floats 60 and 70 according to the embodiment of the present invention described above include a buoyancy body 20 inside the cover body 30 made of plastic synthetic resin, and a plurality of floats on the upper end of the cover body 30. First and second through holes (36,38) and the scaffold (35) is formed integrally on the upper surface and the connecting pipes (55, 55 ') can be installed to connect the frame (50) When only the connecting pipes 55 and 55 'are inserted into the upper or first through holes 36 and 38 of the upper part of the molded parts 60 and 70, the accessory parts 60 and 70 and the connecting pipe 55 and the scaffolding part ( 20) assembly is completed at the same time, so the assembly process of the cage frame is very simple and can be completed in a short time.

In addition, as can be seen in Figure 6, the buoy 70 is installed in the right direction is assembled by fitting the connecting pipe 55 'to the upper end of the first through hole of the two upper and lower pairs of through holes, and is installed in the left direction When the connecting pipe 55 is inserted into the lower second side through hole 60, the left and right connecting pipes exposed to the outside of the buoys 60 and 70 at the intersections of the connecting pipes 55 do not face each other and can cross each other. .

Therefore, the scaffolding portions 35 formed on the upper surfaces of the plurality of floats 60 and 70 coupled to the connecting pipes 55 and 55 'on both the left and right sides are kept horizontal to each other, and the connecting pipes of the intersection portion E 55, 55 '), if a separate scaffold is installed, the scaffold of the footrest part 35 of the left side mouth 60 and the footrest part 35 and the crossing portion E of the right side mouth 70 are both in a horizontal state. It is maintained so that workers can move and work in cages on sea level.

On the other hand, Figure 7 shows a vertical cut section in a state in which the connecting pipe 55 is penetrated through the sub-ball 60 in FIG.

As shown in FIG. 7, the buoyancy body 20 is filled in the inner buoyancy body receiving portion 40 of the cover body 30, and the upper and lower left and right sides of the buoyancy body 20 of the cover body 30. The first and second through holes 36 and 38 formed at the upper end are respectively positioned.

Although the above described embodiments of the buoy 60 and 70 according to the present invention is filled or inserted into the foam resin foam having a styrofoam or equivalent properties therein, the interior of the cover 30 is separately When molded into a hollow hollow type that is not filled with the buoyancy body, the buoyancy body may have the same buoyancy as the buoys containing the buoyancy body, but if the buoyancy body is made of a hollow structure not included therein, the seawater flows into the inside of the cover body when it is damaged. Since it may be difficult to maintain the buoyancy state of the buoys, it would be desirable to mold the buoyancy body to be included in the interior of the cover body.

On the other hand, it will be described below the manufacturing process of the floats 60, 70 according to the embodiment of the present invention described above.

First, the buoy 60 according to an embodiment of the present invention is a buoyancy body forming step of molding a buoyancy body of a predetermined size formed of styrofoam or foamed resin foam.

Then, a plurality of through holes are formed at the top while forming a film layer with a predetermined thickness on the outer side of the molded buoyancy body, and a flat scaffold having an anti-slip protrusion is formed on the upper surface thereof, while the lower end is formed inside the mold such that a rounded shape of the bottom is formed. After the positioning of the buoyancy body is made of a cover body forming step of forming a coating layer of a predetermined thickness to the outside of the buoyancy body by injecting a raw material of plastic synthetic resin into the mold in which the buoyancy body is located.

In addition, the buoy 70 according to another embodiment of the present invention described above is a buoyancy body forming step (S1) of molding a buoyancy body of a predetermined size formed of styrofoam or foamed resin foam is performed as shown in FIG. .

A cover body forming step S2 for forming a cover body outside of the buoyancy body molded in the buoyancy body forming step S1 is performed.

The cover body forming step (S2) has a flat scaffold on the upper surface, the lower portion has a round shape of the lower end, and two pairs of through-holes are formed in the front-rear direction so that connecting pipes can be inserted up and down on both left and right sides of the upper end. The upper surface of the scaffolding portion is formed with a non-slip projection that prevents slipping and a net fixing hole is formed at both edge portions, and the buoyancy body accommodates a portion of the buoyancy body with one side open in the lower end where the through hole is formed. A pair of first and second cover bodies made of plastic synthetic resin is molded (S1) to form an additional portion.

After molding (S2) a pair of cover bodies separated from the buoyancy body forming step (S1), the first and second cover bodies are formed on the left and right sides of the buoyancy body, respectively. An assembling step (S3) of fitting the buoyancy body to the buoyancy body accommodating part formed inside the second cover body is performed.

As such, after the first and second cover bodies formed in the cover body forming step S2 are assembled (S3) to the outside of the buoyancy body formed in the buoyancy body forming step S1, the contact tip portions of both cover bodies are assembled. One cover is molded while the two cover body front ends which are separated through the heat fusion process S4 are integrally fused together.

5,20: buoyant body 6,7: fastening means
8,35: footrest 10,50: frame
30: cover body 32: first cover body
34: second cover body 35a: net fixing hole
36: first through hole 37: rib
38: second through hole 39: anti-slip projection
40: buoyant body receiving portion 42: opening
44,46: reinforcing rib 48: heat-sealed portion
55,55´: Connecting pipe 60,70: Spout

Claims (5)

delete In the cage culture buoy comprising a buoyancy body of a predetermined size molded from styrofoam or foam foam, and a cover body surrounding the outside of the buoyancy body so that the buoyancy body is not exposed to seawater,
A pair of first through holes penetrating the front and rear surfaces is formed on both the left and right sides of the upper and rear surfaces of the front and rear surfaces of the cover body, and the connection pipes are fitted on both the lower left and right sides of the first through hole. A cage for farm cages, characterized in that the second through-hole further penetrates the front and rear surfaces to be formed. Buoyancy bodies of any size molded into styrofoam or foamable foam;
A pair of first through holes penetrated to the front and rear surfaces so that the connecting pipes can be fitted to the left and right sides of the front and rear surfaces;
A pair of second through holes penetrated to the front and rear surfaces so that the connection pipes can be fitted to both left and right sides at the bottom of the first through hole;
A space for accommodating a portion of the buoyancy body is provided in the lower inner side where the second through-hole is formed, and a buoyant body accommodating part having one side is provided, and the front end portions contacted with each other after being fitted to the buoyancy body on both sides of the buoyancy body are opened. A cage for aquaculture farms, comprising: a first cover and a second cover body made of a plastic synthetic resin which is integrated by fusion to prevent the buoyancy body from being exposed to seawater. The method according to claim 2 or 3,
The cover body or the first and the second cover body is made of a rectangle having a length longer than the length of the width, the top surface is maintained while the flat state is formed with a scaffolding portion provided with a net fixing hole on both sides, the scaffolding The cage is a cage for farm cages, characterized in that the anti-slip projections are formed to prevent slipping. Forming a buoyancy body into a rectangle having a length of height relative to a length of width;
The upper surface has a flat scaffolding part, the lower part has a round shape, and has a rectangular shape with a length longer than the width, and two pairs of through-holes in the front and rear directions are simultaneously inserted so that connecting pipes can be inserted up and down on both left and right sides of the upper part. The upper surface of the scaffolding portion is formed with anti-slip projections and net fixing holes on both side edges, respectively, one side is opened in the lower end where the through hole is formed, and a buoyant body accommodating part capable of accommodating a part of the buoyancy body is provided and corresponds to a pair. Shaping the first and second cover bodies of plastic synthetic resin so configured;
Assembling the buoyancy body to the inner buoyancy body accommodating portion of the first and second cover bodies while the first and second cover bodies are positioned to both the left and right sides of the buoyancy body;
Heat-sealing contact tip portions of the first and second cover bodies such that the first and second cover bodies are assembled to the outside of the buoyancy body so that the buoyancy bodies are not exposed to seawater while both tip portions are in contact with each other. Method for producing a cage for cages, characterized in that made.

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