KR101791856B1 - apparatus for farming shellfish - Google Patents

Abstract

The present invention provides a net for nurturing shellfish, which comprises: a plurality of culture plates having a bottom plate and a peripheral wall; and a net installed to collectively surround the peripheries of each culture plate, wherein the bottom plate of each culture plate is formed in a concave-convex structure in which a plurality of mountains and valleys are repeated, and each of the valleys is provided with a plurality of division raised spots which block corresponding valleys to provide a plurality of resting areas of each shellfish divided from each other, so that recycling is possible, manufacture is easily performed, and a phenomenon of the shellfish from moving to a certain place is prevented even if tilting occurs due to shaking by the influence of algae, thereby stabilizing the feeding activity.

Description

An apparatus for farming shellfish

The present invention relates to a shell-positive net, more specifically, it can be easily recycled and manufactured, and even if a tilt occurs due to the influence of algae, This is a new type of shellfish breeding network that can prevent feeding and stasis activities.

Generally, a shell-positive net is an instrument that can artificially cultivate shellfish. It is usually constructed by separating a plurality of flat plate-shaped plates made of wood in a net.

That is, a certain quantity of shellfish is supplied to each plate, and the shell-positive net is put into the sea so that the shellfish can be naturally cultivated.

However, in the case of the shell-positive net used in the conventional method, since the each aquaculture plate is merely a flat plate type, the seawater flow in the upper and lower parts can not be achieved and the mud is not discharged to the upper surface of the aquaculture plate, The problem of adversely affecting the growth was caused, and further, as each aquaculture plate was simply made into a flat plate, there was a problem that the shellfish stuck to a net located between each aquaculture plate and cut off.

In addition, when the shelf is tilted and tilted by the influence of algae, the shellfish piled up on each of the seating plates is piled up in a tilting direction, and the feeding operation can not be stably performed.

In addition, there is a problem in that the conventional shell-positive net is easily broken due to the backwater due to the influence of seawater as the various aquariums are made of wood.

Of course, in the case of the shellfish style apparatus disclosed in the recently proposed Laid-Open Patent Publication No. 10-2014-0004877, each plate is manufactured not from a flat wood but from a mesh, fixed to each outer frame, It is advantageous that the seawater flow in the upper and lower portions is smoothly carried out, and the high tone of the midge is not generated.

However, this technique has been problematic in that shells (for example, oysters) are cut off by eating the net because the whole plate is manufactured with a net, and the problem of leaning the shells due to tilting by birds is still solved There was a problem that was not able to do.

Further, the above-described technique has a problem in that it is difficult to manufacture a forming plate due to complicated operations such as forming a mesh into a supporting net by press-forming a mesh to form a forming plate, and then assembling the net into the outer frame made of a round bar.

On the other hand, in connection with the conventional shell-positive network, in addition to the above-mentioned patent publications, various utility models such as the Utility Model Bulletin 1987-0001641, the Utility Model Bulletin 1987-0001592, and the Public Utility Model Publication 20-1996-30028 have been provided .

In addition to the above-described general structure, there is also provided a multi-layered shellfish culture apparatus having a square box structure as disclosed in Japanese Patent Application No. 10-0424709, Registration Practical Utility Model No. 20-0195068, and Registration Practical Utility Model No. 20-0258786 However, it is difficult to accurately grasp the current state of the shellfish, and it is extremely difficult to perform operations such as the extraction of some shellfish directly at the culture site.

Japanese Patent Application Laid-Open No. 10-2014-0004877 Utility Model Public Affairs Office 1987-0001641 Utility Model Public Affairs Office 1987-0001592 Public Utility Model Publication No. 20-1996-30028 Registration No. 10-0424709 \ Registration Utility Model Bulletin No. 20-0195068 Registration Utility Model No. 20-0258786

SUMMARY OF THE INVENTION The present invention has been made in order to solve various problems of the prior art described above, and it is an object of the present invention to provide a method and apparatus for recycling, which can be easily manufactured and tilted by shaking due to the influence of algae And to provide a new type of poultry breeding network that can prevent feeding of shellfish to one place and to stabilize feeding activity.

In order to accomplish the above object, according to the present invention, there is provided a shell-positive net, comprising: a plurality of straps arranged in a vertically spaced relationship with a bottom plate and a cylinder having a circumferential wall; And a net installed to collectively surround the periphery of the diaphragm and the periphery of the diaphragm, wherein the bottom plate of each diaphragm is formed of a concave-convex structure in which a plurality of mountains and a valley are repeated And each of the plurality of compartments is provided with a plurality of partitioning jaws for intercepting the respective bones, thereby providing a plurality of seated areas of the shells separated from each other.

In this case, ventilation holes are respectively formed in the seating areas provided between the respective compartments of the respective bottoms of the bottom plate forming the cooking plate.

In addition, both side walls of each of the compartments are formed to be inclined so as to guide the flow of water or debris toward the position where the air holes are formed.

In addition, the peripheral wall of the culture dish is inclined so as to gradually extend toward the upper part, and the upper end of the peripheral wall is formed with a folded end bent in the horizontal direction, and the peripheral wall is provided with a plurality And the mesh network is connected through the through holes of the diaphragm plates to fix the positions of the diaphragm plates.

In addition, a boundary between the bottom plate and the peripheral wall of the culture plate is inclined toward the respective valleys.

As described above, according to the present invention, since the bottom plate has the concave-convex structure composed of the mountains and the valleys, it is possible to prevent the shells from flowing down in the direction in which the mountains and the valleys are repeated, Since the jaws are formed to block the flowing down of the shell along the corresponding bones, the shells can always remain in a fixed seating area irrespective of the tilting direction of the plate, such as the direction of the tide or the wave direction It is possible to prevent the problem that the shellfish can not be properly fed because they are bundled together.

Further, in the shell-positive net of the present invention, ventilation holes are formed at both ends of the seating area provided between the respective tabs of the respective bottoms of the bottom plate of the diaphragm, And the side walls of each of the compartments are inclined toward the side where the ventilation holes are formed, it is possible to smoothly discharge foreign substances such as mums accumulated in the respective dish plates through the ventilation holes, It can be prevented.

In addition, since the culture plate constituting the shell-positive net of the present invention is formed into a structure capable of injection molding, it is easy to manufacture and can be mass-produced.

Brief Description of Drawings Fig. 1 is a state diagram illustrating an installation state of a shell-positive net according to an embodiment of the present invention
FIG. 2 is a perspective view for explaining a plate in a shell-positive net according to an embodiment of the present invention. FIG.
Fig. 3 is a plan view for explaining a crockery in a shell-positive net according to an embodiment of the present invention. Fig.
4 is a side view for explaining a crockery in a shell-positive net according to an embodiment of the present invention;
5 is a sectional view taken along the line I-I in Fig. 3
6 is a plan view for explaining a crockery in a shell-positive net according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the shell-positive network of the present invention will be described with reference to FIGS. 1 to 6 attached hereto.

FIG. 2 is a perspective view for explaining a crockery in a shell-positive net according to an embodiment of the present invention. FIG. 2 is a perspective view 4 is a side view for explaining a corrugated board in a corrugated fiber net according to an embodiment of the present invention, and FIG. 5 is a cross- 3 is a sectional view taken along the line I-I in Fig.

As shown in these figures, the shell-positive net according to the embodiment of the present invention is largely composed of a plurality of aquaplanes 100 and a net 200, and in particular, each of the aquaplanes 100 is formed into a cylindrical shape having a low height So that it is possible to prevent the phenomenon in which the shells are tilted to one place even if the shaking due to the tide occurs, and to smoothly discharge the mud and flow the seawater.

This will be described in more detail below for each configuration.

First, the aquarium plate 100 is a structure for providing an area for shellfish culture.

The culture plate 100 is formed of a cylinder having a bottom plate 110 and a peripheral wall 120 and is configured to be vertically spaced apart from each other while being connected to each other by a mesh 200 while being provided in a plurality.

The diaphragm 100 according to the embodiment of the present invention is manufactured by injection molding synthetic resin such as plastic, thereby making it possible to mass-produce the diaphragm 100 and achieve the same shape.

The bottom plate 110 of each diaphragm 100 is formed in a concave and convex structure in which a plurality of mountains 111 and valleys 112 are repeated and a plurality of So as to provide a plurality of separate seating areas for the shells and to prevent the shells from being tilted to one place regardless of the tilting direction of each shelf plate 100. [

That is, the shellfish to be laid on the aquarium plate 100 is put into the seawater while being uniformly distributed over the entire area within the limited space provided by the aquarium plate 100, but due to the influences of algae or waves, If the repetitive tilting flows are repeated, the shellfish are gathered together on one side of the aquarium 100, so that they can not properly perform their feeding activities and have a great influence on the growth.

Thus, even if the tilting of the tine plate 100 due to algae occurs due to the structure of the concavities and convexities composed of the mountain 111 and the trough 112 and the structure of the tile 113 as described above, So that it is possible to prevent the problem of aggregating to a specific region of the substrate.

In addition, vent holes 114 are formed in both ends of the seating area provided between the respective compartments 113 among the respective valleys of the bottom plate 110 constituting the aquarium plate 100. That is, the follicles present in the aquaculture plate 100 can be smoothly discharged from the aquaculture plate 100 through the vent holes 114.

Particularly, it is shown that both side walls of the partitioning step 113 are inclined toward the valleys 112 of the bottom plate 110, and are formed so as to be gradually narrowed in the same shape as the respective valleys 112, Thereby allowing the water or the mud to collect as the air vent 114 is formed. At this time, the vent holes 114 are respectively formed at the portions where the compartments 113 and the valleys 112 are finally contacted with each other, so that the gathered ridge can be discharged straight without being accumulated in the valleys 112 , Which is shown in Figures 3 and 5 attached hereto.

The circumferential wall 120 forming the diaphragm 100 is formed so as to be inclined so as to gradually expand toward the upper side. That is, due to the inclined structure of the circumferential wall 120, shellfish such as oysters riding on the circumferential wall 120 or the net 200 between the respective cooking plates 100 are prevented from being eaten by the shellfish You can. Of course, since the circumferential wall 120 of the aqueduct 100 is formed to be inclined, it is possible to obtain an additional advantage that a plurality of the aquaplanes 100 can be stacked on each other. At this time, A bent end 122 bent outward in the horizontal direction is formed so as to prevent excessive insertion of the diaphragm 100 into other diaphragms when the diaphragm 100 is stacked. This is as shown in the attached FIG.

The boundary 130 between the bottom plate 110 and the circumferential wall 120 forming the forming plate 100 is inclined toward each of the valleys. This structure is intended to prevent a problem of accumulation of debris or foreign matter on the boundary portion 130 between the bottom plate 110 and the peripheral wall 120 in advance.

In addition, the circumferential wall 120 is formed with a plurality of through holes 121 for passing seawater inside and outside of the forming plate 100, respectively.

In addition, the circumferential wall 120 forming the diaphragm 100 may have a circular shape as shown in the drawings, but the present invention is not limited thereto. That is, the circumferential wall 120 may be formed into a polygon of various shapes such as a square, a pentagon, or a hexagon, if necessary.

Next, the net 200 is provided to prevent the loss of shellfish and fishes, which are put on the respective aquaculture plates 100 and are cultured.

The mesh 200 is formed to mesh the circumferential portions between the culture plates 100, and is formed by crossing the braids.

Particularly, the mesh 200 is configured to fix the position of each of the diaphragm 100 while passing through a part of the through holes 121 of the diaphragm 100. That is, a part of each of the through holes 121 is provided as a site for connection of the mesh 200, so that the entire circumference of the mesh 200 is uniformly wrapped around the entire circumference wall 120 of the stamper 100 , So that the diaphragm 100 can be stably installed.

At this time, it is preferable that the mesh 200 and the through-holes 121 of each dish 100 are connected to each other by using a separate rope.

In the following, the assembly and operation of the shell-positive net according to the embodiment of the present invention described above will be described in more detail.

After a single plate 100 is prepared, the lower end of the mesh 200 is wrapped around the circumferential wall 120 of the plate 100, and then the circumferential wall 120 of the plate 100, The lower end portion of the mesh 200 is connected to a part of the through-holes 121 formed in the upper surface of the mesh 200. At this time, the connection between the through hole 121 of the aquarium plate 100 and the mesh 200 is formed by bundling the through hole 121 and the mesh 200 with another rope.

When the above-mentioned process is completed, another preparing plate 100 is prepared and placed in a state of being spaced apart from the upper side of the forming plate 100 to which the net 200 is connected. The upper end portion of the mesh 200 is connected to a part of the through holes 121 formed in the wall 120 by separate ropes and connected to each other.

In this way, the connecting operation between the aqueduct 100 and the mesh 200 is repeated until the shell-positive net reaches a desired height or until the water supplied from the aquarium 100 reaches a desired quantity.

Of course, after arranging the plurality of style plates 100 so as to be vertically spaced apart, the circumference of each of the style plates 100 is collectively wrapped with a single net 200, A part of the through holes 121 formed in the circumferential wall 120 of the plate 100 may be connected with another rope so that the plate 100 and the net 200 are connected.

Then, shellfish and food (such as seaweed) are injected through the spaced-apart portions between the perimeter and the perimeter of each mesh 200, and then the separated portion is bundled with a separate rope so that the shellfish is lost , It is possible to prevent the entry of other fish. If the net 200 is configured to completely wind between the various plates 100, shellfish are provided to the plate 100 before the net 200 is wrapped around the plates 100 .

In addition, the above-described shell-positive net is put into seawater so that the shellfish can be cultured in an underwater environment.

On the other hand, as described above, the shell-positive net introduced into the seawater is continuously shaken due to the influence of the algae or the influence of the waves, and the shellfish laid on each aquarium plate 100 by the tilting due to the shaking is also removed 100 in a tilted direction.

However, since the bottom plate 110 of each aquarium plate 100 is composed of the concave-convex structure composed of the mountains 111 and the valleys 112, Since the plurality of compartments 113 are formed in the respective troughs 112 so as to block the flow of shellfish along the troughs 112, the direction of the tidal currents and the direction of the waves The shellfish can always remain in a fixed seating area regardless of the tilting direction of the cooking plate 100, so that the shellfish can perform smooth feeding without clumping.

A vent hole 114 is formed at both ends of the seating area provided between the respective tabs 113 of the respective troughs 112 of the bottom plate 110 constituting each tile plate 100, Particularly, considering that the boundary portion 130 between the bottom plate 110 and the peripheral wall 120 and both side walls of the partition walls 112 are inclined toward the side where the vent hole 114 is formed, So that debris or foreign matter accumulated on the plate 100 can be smoothly discharged through the vent hole 114, thereby preventing the growth of the shellfish from being deteriorated.

The structure for the seashells provided by the mountains 111 and the valleys 112 and the partition jaws 113 formed on the bottom plate 110 of the aquaculture plate 100 is shown in FIGS. (Rectangular or square) structure as shown in FIG. 6, the placement of the mountains 111, the valleys 112, and the partition jaws 113 formed on the bottom plate 110 may be different from that of the bottom plate 110 such that the seating area of the shell is hexagonal will be.

Of course, although not shown, the structure for the seam region of the shell may be formed to be pentagonal, octagonal, or even polygonal.

100. Deck 110. Deck
111. Mountain 112. Goal
113. Compartment chin 114. Vents
120. Perimeter wall 121,
122. Bending section 130. Boundary area
200. Network

Claims (5)

A plurality of staging plates (100) formed in a cylindrical shape having a bottom plate (110) and a peripheral wall (120) and spaced apart from each other;
And a net 200 installed to collectively surround the peripheries of the diaphragm 100 and the diaphragm 100,
The bottom plate 110 of each aquarium plate 100 is formed in a concave and convex structure in which a plurality of mountains 111 and a plurality of valleys 112 are repeated and a plurality of compartments 113 Are provided to provide a plurality of seated areas of each shell,
The circumferential wall 120 forming the diaphragm 100 is formed so as to be gradually inclined outwardly toward the upper side,
The side walls of each of the compartments 113 are inclined so as to guide the flow of water or debris toward the respective troughs 112 so that the shape of the troughs 112 As shown in FIG.
The boundary portion 130 between the bottom plate 110 and the peripheral wall 120 is inclined toward each of the troughs 112 so that water or mud can be gathered. Is formed in a narrowed structure,
Wherein a vent hole (114) is formed in a portion where each of the compartments (113) and the valleys (112) meet and a portion where the boundary portion (130) and the valleys (112) meet. delete delete The method according to claim 1,
The upper end of the peripheral wall 120 forming the forming plate 100 is formed with a bent end 122 bent in the horizontal direction,
The circumferential wall 120 is formed with a plurality of through holes 114 for passing seawater inside and outside the stagnant plate 100,
Wherein the mesh network (200) is configured to fix the positions of the aquaplanes (100) while being connected through a part of the through holes (114) of the aquaplanes (100). delete

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