KR101421260B1 - Fishing Net Structure for Tuna Culture - Google Patents

Abstract

The present invention relates to a structure of a fishing tuna fishing net, comprising a plurality of vertical skeleton ropes (10) for forming a skeleton of a fishing net to secure a depth of a fishing net; An upper tether 20 for connecting and fixing the uppermost ends of the plurality of longitudinal skeleton ropes in the lateral direction and determining the size of the fishing net by adjusting the number of longitudinal skeleton ropes installed; A lower tether 30 for connecting and fixing the lowermost ends of the plurality of longitudinal skeleton lines in the transverse direction and determining the floor size of the installed fishing net; A plurality of bottom crucifixes (40) connecting bottom surfaces of the lower towlines opposite to each other to a bottom surface to form a skeleton of the bottom of the fishing net; A rectangular bottom line 50 forming a net in a rectangular shape so as to prevent the fishing fish from detaching from the space between the vertical frame 10, the upper and lower tethers 20 and 30; As shown in FIG.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tuna fishing net structure,

The present invention relates to a structure of a square fishing net for cultivating tuna bluefin tuna and a tuna fish tuna, more specifically, to prevent a phenomenon in which a fishing net is tilted in a change of an intense tidal current, The present invention relates to a structure of a tuna cultured fish net and a method for producing the same.

Countries around the world are fighting hard to catch more tuna in the ocean.

As tuna resources are getting smaller and smaller, the international fisheries organizations are reducing their quota and fishing regulations are being tightened. Japan, Taiwan, and Korea, the world 's third biggest tuna catcher, also took an emergency.

 Recently, as countries around the world are making efforts to protect tuna resources and reducing fishing quotas, tuna farming is emerging as a high value added industry.

The leader of tuna culture is known as Japan, the world's largest tuna consumer. Japan began studying bluefin tuna since 1970. After that, European countries such as Norway, Sweden, and Ireland, the Mediterranean coastal countries, and the United States and Australia have started full-scale tuna culture in the 1972s.

It is estimated that about 40,000 tons of tuna are cultivated around the world, 20,000 tons of European countries such as the Mediterranean coast and Norway, 6,200 tons of Australia, 7,000 tons of Japan and 5,000 tons of Mexico. .

In Korea, aquaculture fish for cultivating bluefin tuna and migratory fish have mainly been imported from Japan. However, when the price of the fishing nets is high and repairs and repairs that occur during use are required, there is a problem that after-service is not provided promptly. This has resulted in a significant decline in the productivity of the aquaculture.

In addition, the conventional fishing nets are formed in the form of a rhombus. There is a problem that the fishing nets leaning to one side of the fishing nets are tilted due to the birds, and the phenomenon that the fishing nets are unfolded and unfolded as a whole is repeated and the fishing nets are lost or restored. This is caused by a phenomenon in which a conventional fishing net such as infinite despair or Lasse net can not actually be formed into a rectangular shape. The sickle net referred to here is in the form of a lozenge-shaped fishing net. That is, since the fishing net is in the shape of a rhombus, there is a phenomenon that the fishing net is attracted when it is swept by the bird.

In addition, if the bird catches on the entire fishing net by the bird, the communication of the bird is not smooth, and the incidence of the fish is high, and the mortality rate of the fish is very high, resulting in a great loss of economic loss and productivity.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a structure of a fishing net for fishing tuna, .

Another object of the present invention is to provide a tuna-type fishing boat which is made of a material in which fishing nets are not shrunk or broken so as to smooth the communication of algae, thereby reducing the incidence of fishes and reducing the mortality rate, And a method for manufacturing the same.

The structure of a tuna fishing net according to a preferred embodiment of the present invention includes a plurality of vertical skeleton ropes 10 for forming a skeleton of a fishing net to secure a depth of a fishing net; An upper tether 20 for connecting and fixing the uppermost ends of the plurality of longitudinal skeleton ropes in the lateral direction and determining the size of the fishing net by adjusting the number of longitudinal skeleton ropes installed; A lower tether 30 for connecting and fixing the lowermost ends of the plurality of longitudinal skeleton lines in the transverse direction and determining the floor size of the installed fishing net; A plurality of bottom crucifixes (40) connecting bottom surfaces of the lower towlines opposite to each other to a bottom surface to form a skeleton of the bottom of the fishing net; A rectangular bottom line 50 forming a net in a rectangular shape so as to prevent the fishing fish from detaching from the space between the vertical frame 10, the upper and lower tethers 20 and 30; As shown in FIG.

A handle bundle 22 extending from the upper tether 20 to allow the user to easily grip the tether 20; and a cage fixing tether 22 for fixing the cage to the cage by being fixed in the horizontal direction below the upper tether 20, An intermediate tether 70 for preventing torsion which is provided at an intermediate portion below the upper tether 20 and the cage fixing tether 60 to be fixed to the outer frame to prevent twisting, A cage bundle line 62 provided at an end of the torsion preventing intermediate tether 70 to be fixed to the cage and an outer tether line 72 installed at an end of the torsion preventing intermediate tether 70 to be fixed to the outer frame, .

It is preferable that the material of each of the above-mentioned tethers is made of polyethylene (PE), and the connecting portion is formed into a rectangular fishing net by welding.

Next, a method of manufacturing a fishing tuna fishing net according to an embodiment of the present invention includes a cutting step S10 of cutting a vertical skeleton rope 10 made of a polyester material according to a fishing net size; An intermediate tether welding step (S20) in which the upper tethers (20), the lower tethers (30), the cage fixing tethers (60), and the middle tethers (70) are welded and assembled to the vertical skeleton strings in the transverse direction; A net cutting step (S30) of cutting the net of the fishing net to the standard; (S40) of assembling the tent of the steps S10 and S20 to the net of the fishing net of S30 and assembling the net into the net desperation net; An antifouling treatment step (S50) of mixing the antifouling agent and the diluent for preventing contamination at a ratio of 1: 1 and applying the mixture to the outer surface of the tether and the fishing net; A sea surface immersion step (S60) of immersing the antifouling treated net in seawater for 20 to 30 minutes; And a drying step (S70) of taking out the net immersed in the sea surface after the antifouling treatment and drying it in the shade for 24 hours or more.

At this time, it is preferable that the seamless despot nets are configured to have a width of 15 [cm] and a width of 5 [mu] m so as to form a square.

It is preferable that the thinner is thinner.

According to the structure of the fishing tuna fishing net according to the preferred embodiment of the present invention, the structure of the fishing tuna fishing net which can prevent the netting of the fishing net by the elimination of the fish netting phenomenon even in strong algae, .

In addition, according to the structure of the fishing tuna fishing net according to the preferred embodiment of the present invention, since the fishing net is made of a material which is not shrunk or broken, it is possible to smoothly communicate the algae to lower the incidence rate of fishes, And to obtain the structure of a tuna farming fishing net to produce a sickle net in a square shape.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram showing a structure of a fishing net for a tuna culturing according to a preferred embodiment of the present invention;
Fig. 2 is an enlarged partial enlarged view of the structure of the bottom surface in the structure of the tuna fishing net shown in Fig. 1. Fig.
Fig. 3 is a front view showing the shape of a front surface to be cylindrical in the structure of the fishing net for tuna cultivation shown in Fig. 1,
FIG. 4 is a plan view for explaining the design structure of the front surface of the tuna fishing net shown in FIG. 1;
5 is a plan view for explaining the design structure of the bottom surface of the tuna fishing net shown in Fig. 1,
FIG. 6 is a detailed diagram illustrating a detailed structure of a tuna fishing net according to an embodiment of the present invention;
7 is a flowchart illustrating a method of manufacturing a tuna fishing net according to an embodiment of the present invention.

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

(Example)

FIG. 1 is a configuration diagram showing a structure of a fishing tuna fishing net according to a preferred embodiment of the present invention. FIG. 2 is an enlarged view of the structure of the bottom surface in the structure of the fishing tuna fishing net shown in FIG. Fig. 3 is a front view showing the shape of the front surface of the tuna cultivating fishing net shown in Fig. 1 in a cylindrical shape.

As shown in the drawings, the structure of a tuna fishing net according to a preferred embodiment of the present invention includes a plurality of vertical skeleton ropes 10 for forming a skeleton of a fishing net to secure a depth of a fishing net; An upper tether 20 for connecting and fixing the uppermost ends of the plurality of longitudinal skeleton ropes in the lateral direction and determining the size of the fishing net by adjusting the number of longitudinal skeleton ropes installed; A lower tether 30 for connecting and fixing the lowermost ends of the plurality of longitudinal skeleton lines in the transverse direction and determining the floor size of the installed fishing net; A plurality of bottom crucifixes (40) connecting bottom surfaces of the lower towlines opposite to each other to a bottom surface to form a skeleton of the bottom of the fishing net; A rectangular bottom line 50 forming a net in a rectangular shape so as to prevent the fishing fish from detaching from the space between the vertical frame 10, the upper and lower tethers 20 and 30; As shown in FIG.

The construction and operation and effect of the tuna fishing net according to the embodiment of the present invention constructed as above will be described below.

The vertical skeleton rope 10 is also called a sock for erecting a skeleton of a fishing nets, and determines the depth of the fishing nets by adjusting the length in the vertical direction. The material was polyethylene (P.E.). This polyethylene material has excellent durability against the salinity of sea water, and it can withstand severe algae due to its high strength. It is resistant to impact by cultured fishes and does not easily bite, thus ensuring a long life of fishing nets.

As shown in the figure, a plurality of the longitudinal skeleton ropes 10 are installed to form a fish net in a circular shape.

The upper tether 20 connects the upper ends of the plurality of longitudinal skeleton ropes in the lateral direction and fixes them, and determines the size of the fishing net by adjusting the number of vertical skeleton ropes installed. The upper space of the upper tether 20 may be opened to allow easy administration or removal of the fish, or a fish net like the bottom surface may be formed to be immersed in the sea surface.

At this time, the upper tether 20 is provided with a handle bundle 22 extending therefrom so as to be easily held by the user. In the present invention, the welding rope 22 is integrally provided on the upper tether 20 or the fishing net by welding.

Next, the lower tether 30 is connected to the lower ends of the plurality of vertical skeleton ropes 10 in the lateral direction, respectively, to determine the floor size of the installed fishing net. That is, it is the lower rim that forms the perimeter of the bottom surface.

Here, a cage fixing tether 60 for fixing the cage to the cage is fixed to the lower side of the upper tether 20 in the transverse direction.

In order to prevent twisting of the fishing nets due to migration (or shaking) by algae, movement or impact of fishes, etc., in the middle portion below the upper tether 20 and the cage fixing tether 60, The intermediate tether 70 for preventing torsion is provided.

A cage bundle line 62 for fixing the cage to the cage is provided at an end of the cage fixing tether 60. An outer tether line 72 for fixing the cage to the outer frame is provided at the end of the anti- .

Referring to FIG. 2, the structure of the tuna fishing net 100 according to the present invention will be described. The shape of the net formed on each line is a square. This provides a tension that can withstand the external pressure firmly as compared to a conventional fishing net having a rhombic shape. That is, regardless of the direction in which the algae are introduced, or when the fishes that are cultivated in the inside collide with each other, they function to support them so as not to collapse.

The inventor of the present invention has repeatedly conducted the experiment to confirm that no distortion occurs, thereby realizing the effect of preventing the fishing fish from being closed due to the fishing net not being frozen.

Next, referring to FIG. 3, the interval between the longitudinal frame ropes 10 is about 2 [m]. The upper tether 20 and the cage fixing tether 60, which are connected to each other in the transverse direction, are provided at an interval of 1 [m] above the vertical frame 10.

The gap between the cage fixing tether 60 and the anti-twist intermediate tether 70 is fixed at an interval of about 7.5 [m]. In addition, the interval between the anti-twist intermediate tent 70 and the lower tent 30 is fixed at an interval of about 7.5 [m].

Next, a description will be made of a manufacturing process of the tuna fishing net 100 according to the present invention with reference to FIGS. 4 and 5. FIG.

FIG. 4 is a plan view for explaining the design structure of the fishing tuna fishing net shown in FIG. 1, and FIG. 5 is a plan view for explaining a design structure of the bottom surface of the fishing tuna fishing net shown in FIG. 1 .

In FIG. 4, reference symbols A to J are used for description.

The diameter of the fishing tuna fishing net according to the embodiment of the present invention is 40 m, the total fishing net length is 125 m, and the height is 16 m.

A indicates the upper tent 20, and the material thereof is made of a polyester (PE) material and has a diameter of 18 mm (hereinafter, referred to as "ropes A" to "H" ). The upper tether A. 20 is attached to a handrail (not shown) at the upper end of the cage frame.

Reference numeral B denotes a cage fixing tether 60, which is attached to a 50 [mm] diameter body at the top of the cage frame.

The reference character C denotes an anti-torsional intermediate tether 70, which is attached to the anti-torsion frame located in the middle of the fishing net.

Reference symbol D denotes a lower tether 30 which is attached to the lower anti-tip frame located at the lower end of the fishing net.

And reference symbol E denotes a bundle cord for bundling and fixing to the hand rail at the upper end of the bar stool.

The symbol F is a bundle for bundling and fixing to a 50 [mm] body on the upper side of the barricot.

The code G is a bundle line for bundling and fixing to the middle border of a street girly.

The symbol H is a bundle line for bundling and fixing to the bottom edge of the bag lite.

Next, I is a polyester (P.E.) material with a diameter of 6 [mm] and is a moxibustion string installed between the rope and the fishing net.

J is made of polyester (P.E.) material and has a diameter of 18 [mm]. The length of the fishing net is 125m, and the length is 62.5m.

FIG. 5 is a view for explaining a process for fabricating the structure of a tuna fishing net according to an embodiment of the present invention with a rectangular net.

First, the width and the length are set to 40 [m], and the horizontal and vertical lines are set, and then four corners A 'are cut off.

Next, a rope transverse direction lead wire B 'having a diameter of 18 [mm] as a polyester (P.E.) material is installed in the transverse direction.

In addition, a rope longitudinal direction lead line C 'having a diameter of 18 [mm] as a material of polyester (PE) is provided so as to be perpendicular to the transverse lead line B' in the longitudinal direction.

Next, the skeleton line spacing is set to 2 [m], respectively.

Next, connect the ribs of the skeleton and the bottom tendons to support the floor. At this time, the interval between the length and the length is set to about 4 [m].

To summarize this, first, the body net is made into a flat surface, the both ends are made into a circular shape, and then the skeleton line and the bottom line are engaged with each other.

As described above, each connection portion is welded to form a seamless fishing net.

Next, referring to FIG. 6, the structure of a tuna fishing net according to an embodiment of the present invention will be described in detail.

6 is a detailed configuration diagram for explaining the detailed structure of a tuna fishing net according to an embodiment of the present invention.

As shown in the figure, the structure of the fishing tuna fishing net according to the present invention is composed of a seamless fishing net and consists of five polyester yarns.

At this time, the above-mentioned 150 ply is a pentagram having 362 denier, 150 strands, and 50 strands each consisting of 3 strands.

Here, the five hard water forms the node (a) with the same interval, the length (c) of one nose (b) is 75.75 [mm], and the color is black. Also, the distance between the node (a) and the node is the length of the half-angle (c) corresponding to 1/2 of the length of the one node (b).

Next, a method of manufacturing a tuna fishing net according to an embodiment of the present invention will be described in detail with reference to FIG.

A method for manufacturing a tuna fishing net according to an embodiment of the present invention includes a cutting step S10 for cutting a vertical skeleton string 10 made of a polyester material to match the standard of a fishing net as a tuna fishing net, An intermediate tether welding step (S20) in which the upper tethers (20), the lower tethers (30), the cage fixing tethers (60), and the middle tethers (70) are welded and assembled to the vertical skeleton strings in the transverse direction; A net cutting step (S30) of cutting the net of the fishing net to the standard; (S40) of assembling the tent of the steps S10 and S20 to the net of the fishing net of S30 and assembling the net into the net desperation net; An antifouling treatment step (S50) of mixing the antifouling agent and the diluent for preventing contamination at a ratio of 1: 1 and applying the mixture to the outer surface of the tether and the fishing net; A sea surface immersion step (S60) of immersing the antifouling treated net in seawater for 20 to 30 minutes; And a drying step (S70) of taking out the net immersed in the sea surface after the antifouling treatment and drying it in the shade for 24 hours or more.

The cutting step S10 is a step of cutting the 18 [mm] original string made of polyester (P.E.) to match the size of the fishing net with the vertical skeleton string 10. Of course, the polyester material can be changed to another material that is resistant to salt and has good strength.

In the intermediate tether welding step S20, the upper tether 20, the lower tether 30, the cage fixing tether 60, and the intermediate tether 70 are welded to the vertical frame 10 in a transverse direction And assembling. This intermediate tether is also called a tether.

The net cutting step (S30) is a step of cutting the mesh of the fishing net according to the standard.

The seamless despair assembling step S40 is a step of assembling the tether of the steps S10 and S20 to the net of the fishing net of S30 and assembling it into the desperate despot. The present inventor welded and connected the entire fishing net with a desperate desperation by performing electric welding.

The antifouling treatment step (S50) is a step of mixing the antifouling agent and antifouling agent for preventing contamination on the main line or the tether in a ratio of 1: 1 and applying the antifouling agent to the outer surface of the tether and the fishing net. In the present invention, Bowmuo Silicone Antifouling Agent # 1500 manufactured by Basel Chemical Co., Ltd. was used and mixed with a diluent to form a thin antifouling film on the raw line. At this time, thinner was used as thinner.

The sea surface immersion step (S60) is a step of immersing the antifouling treated net in seawater for 20 to 30 minutes. By doing so, it is possible to perform a test that can perform and withstand the actual ocean conditions.

Next, the drying step (S70) is a step of taking out the net immersed in the sea surface after the antifouling treatment and drying it in the shade for 24 hours or more. Once it is immersed in sea water, it is taken out and sufficiently dried to complete the product.

The tuna fishing net produced in this way is folded and transported and installed in a cage farm at the beach.

The structure of the tuna fishing net according to the embodiment of the present invention can be manufactured by the above-described structure.

While the invention has been described by way of example and in terms of the foregoing description, various modifications and additions may be made within the spirit and scope of the present invention. Therefore, it is to be understood that these modifications are within the technical scope of the present invention.

10: Vertical skeleton line
20: upper tether
22: Hand strap
30: Lower tether
40: bottom crisscross
50: Square bottom line
60: Tether for fixing the cage
62: cage string
70: Intermediate Tether
72: External tape bundle
100: Tuna fishing nets

Claims (6)

delete delete The upper end of a plurality of vertical skeleton ropes 10 for securing the depth of a fishing net by connecting the upper ends of the longitudinal skeleton ropes 10 in the lateral direction to form the skeleton of the fishing net, (20); A cage fixing bracket 60 fixed to the cage at a lower side of the upper tether 20 in the transverse direction to fix the cage to the cage and a cage bundle 62 installed at the end of the cage fixing cage 60 and fixed to the cage A lower tether 30 for connecting and fixing the lowermost ends of the plurality of longitudinal skeleton ropes in the transverse direction and determining the floor size of the installed fishing net; A plurality of bottom crucifixes (40) connecting bottom surfaces of the lower towlines opposite to each other to a bottom surface to form a skeleton of the bottom of the fishing net; A tether 50 having a square bottom line 50 formed in a rectangular shape so as not to allow fish for aquaculture to escape from the space between the vertical frame 10 and the upper tether 20 and the lower tether 30, A method for manufacturing a fishing net,
Wherein the material of each of the tethers is made of polyethylene (PE), and the connecting portion constitutes a rectangular fishing net which is integrally connected by welding,
An antifouling treatment step (S50) of mixing the antifouling agent and the diluent for preventing contamination of each of the tethers at a ratio of 1: 1 and applying the antifouling agent to the outer surface of the tether and the fishing net;
A sea surface immersion step (S60) of immersing the antifouling treated fish net in seawater for 20 to 30 minutes; And
And a drying step (S70) of taking out the fishing net immersed in the sea surface after the antifouling treatment and drying it in the shade for 24 hours or more. delete delete The method of claim 3,
In the antifouling treatment step (S50) of mixing the antifouling agent and the diluent for preventing the contamination at a ratio of 1: 1 and applying the antifouling agent to the outer surface of the tether and the fishing net,
Wherein the thinner is thinner.

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