KR101419133B1 - Apparatus for culturing oyster - Google Patents

Abstract

The present invention relates to an oyster culture, and more particularly, to an oyster culture system capable of efficiently culturing oysters of excellent quality. According to the present invention, there is provided a tow rope extending along a water surface above a water surface; A plurality of positive mesh connecting ropes extending downwardly from the tow rope at a plurality of points of the tow rope; And a plurality of securing members disposed alternately with the plurality of positive mesh connecting ropes along an extending direction of the tow rope, wherein each of the plurality of positive net connecting ropes is pulled by the plurality of engaging members, And the plurality of connecting ropes are lifted up on each of them.

Description

[0001] APPARATUS FOR CULTURING OYSTER [0002]

The present invention relates to an oyster culture, and more particularly, to an oyster culture system capable of efficiently culturing oysters of excellent quality.

Cave is a collective term for molluscs belonging to the Quercus mongolica, belonging to bivalve. Oysters have long been used for edible purposes. They are rich in flavor and aroma, rich in glycogen, which is the energy source of the body, and zinc, which is the active ingredient of sex hormones, and have recently become more popular for food. There is a trend.

Oysters that have been subjected to periodic exposure to water and experiencing extreme environments (strong sunshine in summer and cold winds in winter) are richer in nutrients, and taste and size are larger than other oysters. In order to make this aquaculture environment in the oyster style, conventionally, oyster aquaculture was installed in a large area where the tidal flats were large, and the oysters were submerged in the water during the high tide, and the oysters were exposed outside the surface of the water during the low tide. However, such a conventional method has a problem that it is difficult to install a structure for aquaculture on the bottom of the sea, and a structure is lost due to weakness in the bottom of the sea. There are many problems.

It is an object of the present invention to provide an oyster culturing apparatus capable of efficiently culturing oysters of excellent quality. Another object of the present invention is to provide an oyster cultivation apparatus having excellent workability. Another object of the present invention is to provide an oyster cultivation apparatus which does not require any additional power. Another object of the present invention is to provide an oyster culturing apparatus capable of culturing oysters of excellent quality out of local restrictions. It is still another object of the present invention to provide an oyster cultivation apparatus capable of efficiently using a limited form space.

According to an aspect of the present invention,

Tow ropes extending along the surface above water; A plurality of positive mesh connecting ropes extending downwardly from the tow rope at a plurality of points of the tow rope; And a plurality of securing members disposed alternately with the plurality of positive mesh connecting ropes along the extending direction of the tow rope, wherein each of the plurality of positive net connecting ropes is pulled by the plurality of engaging members, And the plurality of connecting ropes are lifted up on each of them.

The locking member may include a plurality of rings through which the tow rope passes, and may further include a fixing structure for fixing the plurality of rings.

The loop fastening structure may include a fixed rope extending along an extension direction of the traction rope and the plurality of rings being coupled and fixed in order.

The ring fixing structure may include a support for fixing the plurality of rings, respectively.

The oyster cultivation apparatus may further include a drive motor for towing the tow rope.

The tow ropes may be multiple.

Wherein the oysters further comprise a drive motor for rotating the tow drum on which the plurality of traction ropes are wound, at least one traction rope of the plurality of traction ropes being wound in an opposite direction to another traction rope and the tow drum .

In order to achieve the above object, according to another aspect of the present invention,

A tow rope fixed to extend along the direction of the algae above sea level; A plurality of positive mesh connecting ropes extending downwardly from the tow rope at a plurality of points of the tow rope; And a plurality of engaging members disposed alternately with the plurality of positive net connecting ropes along the extending direction of the traction ropes, wherein the moving bodies are movable by algae, and the moving bodies are moved by the algae, Wherein each of the positive rope connecting ropes is hooked on each of the plurality of engaging members so that the plurality of connecting ropes are raised.

The engaging member may have a rod shape extending in a direction perpendicular to the moving direction of the moving body.

The oyster culture apparatus may further include a guide structure for guiding movement of the moving body.

The guide structure may include guide ropes extending and fixed along the direction of the algae and two rings through which the guide ropes pass and which are coupled to the moving body.

The oyster cultivation apparatus may further include two stoppers each of which interacts with the two rings to define a moving section of the moving body.

The two stoppers may be provided with hooking grooves to which the hooks can be hooked.

The tow ropes may be multiple.

The positive net connecting ropes of at least one of the plurality of tow ropes may be arranged to engage in opposite directions to the positive net connecting ropes of the other traction ropes and the retaining members upon movement of the moving body.

According to another aspect of the present invention,

A plurality of stationary supports; A plurality of rotation supporting portions rotatably connected to the plurality of fixed supporting portions and the vertical positions of which are changed; A traction rope sequentially connected to each of the plurality of rotation supports; And a plurality of positive networks connected to the rotary support.

The positive net may be suspended and connected to the rotation support.

The positive net may be fixedly coupled to the rotary support.

According to another aspect of the present invention,

A positive network mount in which a positive network is installed so that the top and bottom of the network can be rotated so that the top and bottom of the network can be rotated; And a driving unit capable of bi-directional rotation by an algae, wherein the positive net mounting base is rotated by the rotation of the driving unit.

The positive network mount and the driving unit may be integrally formed.

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According to the present invention, all of the objects of the present invention described above can be achieved. Specifically, since the oysterous net is periodically exposed to the water surface, it is possible to efficiently produce high quality oysters regardless of the region. In addition, since the osmosis of the oysterous net is automatically controlled, the workability is excellent. Further, since the buoyancy of the oyster positive network can be performed by using algae, no additional power is required. In addition, it is possible to expose the oyster net in the water alternately on the water surface, so that the space utilization efficiency is excellent.

1 is a perspective view showing an oyster culturing apparatus according to a first embodiment of the present invention.
FIG. 2 is an enlarged perspective view of the tow rope and the positive net connecting rope shown in FIG. 1; FIG.
Figs. 3 and 4 are side views of the oyster cultivation apparatus shown in Fig. 1, each showing two operating states.
5 is a perspective view showing another example of the loop supporting structure in the oyster cultivation apparatus shown in Fig.
Fig. 6 is a plan view showing another example of the pulling portion in the oyster cultivation apparatus shown in Fig. 1. Fig.
7 is a side view of an oyster cultivation apparatus according to a second embodiment of the present invention.
8 is a perspective view of the oyster cultivation apparatus shown in Fig.
9 is an enlarged side view of the first stopper portion shown in Fig.
Figs. 10 and 11 are side views of an oyster cultivation apparatus according to a third embodiment of the present invention, each showing two operation states. Fig.
12 and 13 are side views of an oyster cultivation apparatus according to a fourth embodiment of the present invention, each showing two operation states.
Figs. 14 and 15 are side views of an oyster cultivation apparatus according to a fifth embodiment of the present invention, each showing two operation states. Fig.
16 is an enlarged cross-sectional view of the rotating shaft shown in Fig.

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

Fig. 1 shows an oyster cultivation apparatus according to a first embodiment of the present invention. Referring to FIG. 1, an oyster cultivation apparatus 100 includes a first positive network connecting unit 110, a second positive network connecting unit 120, and a towing unit 130. An oyster cultivation apparatus (100) is installed in a festive farm and cultivates oysters by periodically submerging a plurality of positive cells.

The first positive network connecting part 110 includes a first tow rope 111, a plurality of first positive net connecting ropes 112, a plurality of first positive net 113 and a first supporting part 116 Respectively.

The first traction rope 111 extends straight along the water surface above the water surface. In this embodiment, the direction of pulling by the pulling portion 130 in the first pull rope 111 is defined as a first pulling direction, and the opposite direction is defined as a first pulling pulling direction. A first elastic member 114 is connected to the first traction opposite end of the first traction rope 111. The first elastic member 114 exerts a force to pull the first traction rope 111 in the first traction opposite direction when the first traction rope 111 is pulled in the first traction direction. As the first elastic member 114, a tension spring or the like may be used. The first elastic member 114 facilitates initial operation when the plurality of first positive meshes 113 are lowered. It will be understood by those skilled in the art that the positive net 113 can be lowered by the weight of the positive net 113 without the first elastic member 111. [

A plurality of first positive net connecting ropes 112 are connected to a plurality of points of the first traction ropes 111 and extend downwardly from the first traction ropes 111. A plurality of first positive net connecting ropes 112 are connected to the first traction ropes 111 and are generally equally spaced and aligned in a row. It is preferable that the lengths of the plurality of first positive net connecting ropes 112 are the same.

The plurality of first positive networks 113 are each suspended on a plurality of first positive network connecting ropes 112. Each first positive network 113 is connected to the corresponding first positive network connecting rope 112 via a plurality of auxiliary connection ropes 115. A plurality of auxiliary connecting ropes 115 extend from the lower end of one first positive net connecting rope 112 and are coupled to respective corners of the first positive net 113. Thereby, the first positive network 113 maintains a balance. The plurality of first positive meshes 113 have a rectangular parallelepiped shape made of a mesh member and accommodate the oyster dust therein. The mesh size of the first positive net 113 can be appropriately adjusted according to the growth of the oyster shell. That is, the mesh size of the first positive net 113 can be appropriately selected within a range of 1 to 50 mm in diagonal length depending on the size of the oyster shell. The plurality of first positive nodes 113 are arranged in a line along the extending direction of the first tow ropes 111, and the distances to the water surface are almost the same.

The first support portion 116 includes a plurality of first fastening members 117 and a first fastening rope 118. The first support portion 116 supports the first pull rope 111 by using a plurality of first fastening members 117 and allows the plurality of first positive rods 113 to move in the vertical direction.

A plurality of first fastening members 117 are ring-shaped rings arranged in order along the first pull rope 111 and the first pull rope 111 passes through the first fastening member 117 in turn . The first bracing member 117 is provided corresponding to the plurality of first positive net connecting ropes 112. When the entire first positive net connecting rope 112 is extended downward, And is located adjacent to the rope 112 in the first traction direction. Accordingly, when the first pull rope 111 is pulled in the first pull direction, each first positive hook connecting rope 112 is caught by the corresponding first hooking member 117 so that the first positive rope 113 . In this embodiment, the first latching member 117 is described as being a ring-shaped ring, but a corresponding other means such as a pulley may be used instead.

The first fixed rope 118 is fixed at both ends to the bank 190. The first fixed rope 118 extends parallel to the extending direction of the first pull rope 111 and the first fixed rope 118 is fixed to the first fixed rope 118 by a string 118a, Is fixed to maintain the position.

The second positive network connecting part 120 includes a second tow rope 121, a plurality of second positive net connecting ropes 122, a plurality of second positive net 123 and a second supporting part 126 Respectively. The second positive network attachment unit 120 is disposed in parallel with the first positive network attachment unit 110.

The second traction rope 121 is elongated in parallel with the first traction rope 111 in a straight line along the water surface above the water surface. The second traction rope 121 is located at substantially the same height as the first traction rope 111. In this embodiment, the direction of pulling by the pulling part 130 in the second pulling rope 121 is defined as the second pulling direction, and the opposite direction is defined as the second pulling opposite direction.

A second elastic member 124 is connected to the second traction opposite end of the second traction rope 121. The second elastic member 124 exerts a force to pull the second traction rope 121 in the second traction opposite direction when the second traction rope 121 is pulled in the second traction direction. As the second elastic member 124, a tension spring or the like may be used. The second elastic member 124 facilitates initial operation when the plurality of second positive net 123 is lowered.

A plurality of second positive net connecting ropes 122 are connected to a plurality of points of the second traction rope 121 and extend downwardly from the second traction rope 121. The plurality of second positive net connecting ropes 122 are spaced substantially equidistantly along the second traction ropes 121.

The plurality of second positive networks 123 are each suspended on a plurality of second positive network connecting ropes 122. Each second positive network 123 is connected to the second positive network connecting rope 122 in the same manner as in the first positive network connecting part 110. The configuration of the second positive network 123 is the same as that of the first positive network 113.

The second support portion 126 includes a plurality of second fastening members 127 and a second fastening rope 128. A plurality of second latching members 127 have the same configuration and function as those of the first latching member 117 described above, and a detailed description thereof will be omitted. The second fixed rope 128 is fixed at both ends to the bank 190. The second fixed rope 128 extends parallel to the extending direction of the second pull rope 121 and is connected to the second fixed rope 128 in the same manner as in the first positive network connecting portion 110, (127) is fixed.

The tow unit 130 includes a main tow rope 131 connected to the first tow rope 111 and the second tow rope 121 and a long driving rope 131 connected to the first tow rope 111 and a drive motor 132 for towing the main tow rope 131 And a control unit 133 for controlling the drive motor 132. [ The main traction ropes 131 extend perpendicularly to the two traction ropes 111, 121, respectively. The two portions where the main traction rope 131 is connected to the two traction ropes 111, 121 are each supported by a support pulley 134. The driving motor 132 is a rotatable electric motor capable of bi-directional rotation and pulling or loosening of the main traction rope 131 along the direction of rotation. The control unit 133 controls the operation of the drive motor 132. The control unit 133 adjusts the number of turns of the plurality of positive networks 113 and 123 and the like.

Now, the operation of the first embodiment will be described in detail with reference to Figs. 3 and 4. Fig.

3, all of the plurality of first positive networks 113 of the first positive network connecting unit 110 are immersed in water. All of the first positive net connecting ropes 112 extend completely down from the first traction rope 111. Each of the plurality of first latching members 117 is adjacent to the corresponding first positive net connecting rope 112 in the vicinity of the first pulling direction. The driving motor 132 receives a control signal from the control unit 133 in FIG. 1 to pull the first traction rope 111 therefrom after a predetermined period of time in which the first positive network 113 is immersed in water do. As a result, the first pull rope 111 moves in the direction of the arrow and the first positive rope connecting rope 112 is caught by the corresponding first hooking member 117 and moves along the first pull rope 111, 1 positive net 113, as shown in FIG. The operation of the drive motor 132 is stopped when the first positive net 113 is raised to a predetermined height and exposed above the water surface. A state in which the first positive net 113 rises and is exposed above the water surface is shown in Fig. Referring to FIG. 4, the first positive net 113 is raised above the water surface by a height 'b' upward from the state shown in FIG. The first elastic member 114 is stretched by the moving distance of the first pull rope 111 so as to exert a force pulling the first pull rope 111 in the direction opposite to the first pull. After a predetermined period of time in which the first positive net 113 is exposed on the water surface, the drive motor 132 receives a control signal from the control unit 133 (Fig. 1) to operate to loosen the first traction rope 111 . So that the first pull rope 111 moves in the direction of the arrow, whereby the initial operation is facilitated by the first elastic member 114. As the first pull rope 111 is loosened, the plurality of first positive rods 111 are lowered to be submerged in water as shown in FIG. The second positive network connecting part 120 shown in FIG. 1 operates in the same manner as the first positive network connecting part 110 described with reference to FIGS. 3 and 4, .

Although the oyster cultivation apparatus 100 according to the first embodiment has been described as being installed in a festive farm, it will be understood by those skilled in the art that the apparatus can be installed in a water tank or in a cantilever.

Although the oysters cultivation apparatus 100 according to the first embodiment has been described as having two positive network infusion units, it will be understood by those skilled in the art that it can be configured to have three or more positive network infusion units.

Fig. 5 shows another example of the locking member fixing structure in the embodiment shown in Fig. Referring to FIG. 5, the retaining member fixing structure has two supports 218a and 218b for supporting each of the plurality of ring-shaped rings 117 as the retaining members. The two supports 218a and 218b are generally vertically extending legs, the lower end of which is fixed to the bottom of the farm and the upper end of which is coupled to the ring- The two supports 218a and 218b are formed so as to be further widened downward to stably support the ring-shaped ring 117. [

Fig. 6 shows another example of the pulling portion in the embodiment shown in Fig. Referring to FIG. 6, the traction unit 230 includes a traction drum 232 that is rotated by a driving motor (not shown). The first pulling rope 111 and the second pulling rope 121 are wound on the pulling drum 232 such that the pulling direction is opposite. One of the two traction ropes 111 and 121 is pulled and the other one is pulled out by one-way rotation of the pull drum 232 so that the first positive net (113 in FIG. 1) and the second positive net The positive network (213 in FIG. 1) alternates between rising and falling. Therefore, it becomes possible to efficiently utilize the limited form space.

7 and 8 show an oyster cultivation apparatus according to a second embodiment of the present invention. 7 and 8, the oyster culturing apparatus 200 includes a moving body 250, a moving body guide structure 260, a first positive network connecting unit 210, a second positive network connecting unit 220, .

The moving body 250 is a structure that can float in seawater and has an inner space formed therein and an upper portion and a lower portion opened. The moving body 250 includes a plurality of extension plates 251 that can move by the algae and face the algae to utilize the force of the algae to the utmost. A plurality of engaging members 252 are provided on the upper portion of the moving body 250. The engaging member 252 is an elongated rod shape extending in a direction perpendicular to the moving direction of the moving body 250 and extends substantially parallel to the water surface on the water surface. The plurality of latching members 252 are aligned along the moving direction of the moving body 250. The engaging member 252 located at one end of the plurality of engaging members 252 in the moving direction of the moving body 250 is provided with two guide rings 253 spaced apart from each other along the extending direction of the engaging member 252. As the moving body 250, a guardrail may be used.

The moving body guide structure 260 includes a first guide rope 261, a second guide rope 262, two first rings 261a and 261b and two second rings 262a and 262b . The first guide rope 261 extends parallel to the moving direction of the moving body 250 and is fixed to the bottom of the farm. The second guide rope 262 extends parallel to the first guide rope 261 and is fixed to the bottom of the farm. The two first rings 261a and 261b are ring-shaped and are coupled to the upper portion of the moving body 250 and are disposed along the extending direction of the first guide rope 261. The first guide ropes 261 pass through the first rings 261a and 261b in order. The two second rings 262a and 262b are ring-shaped and are coupled to the upper portion of the moving body 250 and disposed along the extending direction of the second guide rope 262. [ And the second guide ropes 262 pass through the two second rings 262a, 262b in order. The moving body guide rope 261 causes the moving body 250 to reciprocate along the direction of the algae.

The first guide rope 261 is provided with first and second stoppers 270 and 280 for limiting a moving section of the moving body 250. The first stopper 270 includes a wall portion 271 for preventing the movement of the first ring 261a and a concave portion 261a on which the first ring 261a is placed when the first ring 261a contacts the wall portion 271 272). The first ring 261a placed on the concave portion 272 can be separated from the concave portion 272 by a current that moves toward the center of the moving section. The second stopper 280 is fixed on the first guide rope 261 in the same configuration as the first stopper. Two stoppers (not shown) are installed in the second guide rope 262 in the same manner as in the first guide rope 261.

The first positive network connecting part 210 includes a first traction rope 211, a plurality of first positive net connecting ropes 212 and a plurality of first positive nettings 213.

The first pulling rope 211 extends along the moving direction of the moving body 250 so as to pass over the plurality of engaging members 252. One end of the first pulling rope 211 is fixed and the opposite end passes through a guide ring 253 provided on the engaging member 252. [ A plurality of first positive net connecting ropes 212 extend downwardly connected to a plurality of points of the first traction ropes 211. The plurality of first positive net connecting ropes 212 are spaced substantially equidistantly along the first traction ropes 211. When the first positive net connecting rope 212 is fully lowered, the plurality of positive net connecting ropes 212 are positioned adjacent to each other alternately with the guide ring 253. The plurality of first positive network connecting ropes 212 are each suspended and connected to a plurality of first positive networks 213.

The second positive network connecting part 220 is formed in parallel with the first positive network connecting part 210. Since the configuration of the second positive network connecting part 220 is the same as that of the first positive network connecting part 210, detailed description thereof will be omitted.

The operation of the above embodiment will now be described in detail with reference to FIG. In the state shown in Fig. 8, when the moving body 250 is moved in the arrow direction by the algae, the plurality of positive nets 213 are raised. When the positive net 213 is raised to a certain height and exposed to the water surface, the movement of the moving body 250 is restricted by the first stopper 270. In this state, when the direction of the algae is changed, the moving body 250 is moved in the opposite direction by the reversed algae, and the plurality of the positive nettings 213 are lowered. When the positive net 213 descends to a certain height and is immersed in water, the movement of the moving body 250 is restricted by the second stopper 280. The moving body 250 is periodically rotated in accordance with the change of the tide, and the plurality of positive nets 213 are periodically exposed to the water surface.

10 and 11 show an oyster culturing apparatus according to a third embodiment of the present invention. 10, the oyster cultivation apparatus 300 includes a plurality of stationary supports 310, a plurality of rotary supports 320, a pull rope 330, and a plurality of positive nets 340. The plurality of fixed supports 310 are generally aligned and fixed in a row at the bottom of the farm. Each of the plurality of rotary supports 320 is rotatably coupled to the fixed support 310 and extends obliquely upward from the fixed support 310. [ As the rotary support 320 rotates with respect to the fixed support 310, the vertical position of the end of the rotary support 320 is changed. The tow ropes 330 are sequentially connected to each of the plurality of rotary supports 320. The tow rope 330 may be connected to a driving device or the like. A plurality of positive nets (340) hang on the end of the rotation support part (320).

The operation of the third embodiment will now be described in detail with reference to Figs. 10 and 11. Fig. In FIG. 10, a plurality of positive networks 340 are all immersed in water. When the traction ropes 330 are pulled in this state, the ends of the rotatable supporters 320 are raised while the plurality of rotatable supporters 320 are rotated together with the fixed supporters 310, A plurality of suspended positive nets 340 are lifted above the water surface and exposed as shown in FIG. In the state shown in FIG. 11, when the traction ropes 330 are loosened and moved in the opposite direction, the plurality of positive nets 340 descend to be submerged in water as shown in FIG. 10 and 11, the rotation support portion 320 is inclined in the same direction in both the states, and the rotation support portion 320 shown in FIG. 10 is more inclined than the rotation support portion 320 shown in FIG. 11 It is tilted at a large angle.

12 and 13 show an oyster cultivation apparatus according to a fourth embodiment of the present invention. 12, the oyster cultivation apparatus 400 includes a plurality of fixed supports 410, a plurality of rotary supports 420, a pull rope 430, and a plurality of positive nets 440. 10 is substantially the same as that of the embodiment shown in FIG. 10, except that a plurality of positive meshes 440 are fixed to the upper ends of the plurality of rotation supporting portions 420, detailed description thereof will be omitted.

The operation of the fourth embodiment will now be described in detail with reference to Figs. 12 and 13. Fig. In FIG. 12, all of the plurality of positive networks 440 are immersed in water. When the traction rope 430 is pulled in this state, the ends of the rotation support portion 420 are raised while the plurality of rotation support portions 420 are rotated together with the fixed support portion 410, A plurality of fixed positive net 440 is raised above the water surface and exposed as shown in FIG. When the traction rope 430 is unfastened and moved in the opposite direction in the state shown in FIG. 13, the plurality of positive nets 440 descend and become submerged in water as shown in FIG. 12 and 13, the rotation support portion 420 is inclined in the same direction in both the states, and the rotation support portion 420 shown in FIG. 12 is more inclined than the rotation support portion 420 shown in FIG. 13 It is tilted at a large angle.

14 to 16 show an oyster culturing apparatus according to a fifth embodiment of the present invention. Referring to FIG. 14, the oyster cultivation apparatus 500 includes a body 510 and a plurality of benign net moving parts 520. The body 510 is a structure that can float in seawater, and has an inner space formed therein and an upper portion and a lower portion opened. The body 510 is fixed in position by means such as an anchor. As the body 510, a cassette can be used. The plurality of positive mesh moving parts 520 includes a shaft 521 and a rotation part 522 coupled to the shaft 521 so as to be rotatable about the axis. The shaft 521 is located above the sea surface and extends along the sea surface. The shaft 521 is provided with a locking protrusion 521a protruding upward radially outward. The rotating portion 522 includes a coupling portion 523 into which the shaft 521 is rotatably inserted and a positive net mounting base 524 and a driving portion 525 extending from the coupling portion 523 in the radial direction. The engaging portion 523 is provided with a through hole 523a through which the shaft 521 can pass. The first and second grooves 523b and 523c through which the latching protrusion 521a can be inserted are located in the through hole 523a along the circumferential direction. The two grooves 523b and 523c correspond to a state in which the positive net 530 is immersed in water and exposed to water. A positive net 530 is installed in the positive net mounting base 524. The driving unit 525 is located in the water and moves by the algae to rotate the rotating unit 522. The angle between the positive net mounting base 524 and the driving unit 525 is such that the positive net 530 provided on the positive net mounting base 524 is in a state of being submerged in water or exposed to water as the rotating unit 522 rotates As appropriate.

Now, the operation of the fifth embodiment will be described in detail with reference to FIGS. 14 to 16. FIG. Referring to FIG. 14, a plurality of positive nets 530 are exposed on the water surface. At this time, the latching protrusion 521a is inserted into the first groove 523b as shown in FIG. 16, so that the rotation of the rotation part 522 is restricted, thereby maintaining the state shown in FIG. In this state, when the algae flow in the direction of lowering the positive net 530 as shown by the arrow, the alveolus 522 is rotated by the algae, and the positive net 530 is lowered and immersed in the water. A state in which the positive net 530 is immersed in water is shown in Fig. At this time, the latching protrusion 521a is inserted into the second groove 523c so that the rotation of the rotation part 522 is restricted and the state shown in Fig. 15 is maintained. When the direction of the algae is changed in the state shown in FIG. 15, the rotation unit 522 is rotated so that the positive net 530 is exposed on the water surface as shown in FIG.

Although the present invention has been described with reference to the above embodiments, the present invention is not limited thereto. It is to be understood that the above-described embodiments may be modified or changed without departing from the spirit and scope of the present invention, and those skilled in the art will recognize that such modifications and changes are also within the scope of the present invention.

100: oyster cultivation apparatus 110: first positive network anchor section
111: first pulling portion 112: first positive net connecting rope
113: first positive network 116: support
117: first fastening member 118: first fastening rope
120: second positive network connecting part 130: pulling part
131: main traction rope 132: drive motor
133:

Claims (12)

A tow rope 111 extending along the water surface above the water surface;
A plurality of positive mesh connecting ropes (112) extending downwardly from said tow ropes (111) at a plurality of points of said traction ropes (111);
A plurality of locking members 117 arranged alternately with the plurality of positive net connecting ropes 112 along the extending direction of the tow ropes 111; And
And a drive motor (132) for towing the tow rope (111)
As the tow rope 111 is pulled, each of the plurality of positive net connecting ropes 112 is caught by each of the plurality of engaging members 117, so that the plurality of positive net connecting ropes 112 rises. Oyster cultivation equipment. The method according to claim 1,
The locking member 117 is a plurality of rings through which the tow rope 111 passes,
Further comprising a fixed rope (118) extending along an extension direction of the tow rope (111) and the plurality of rings being successively engaged and fixed. The method according to claim 1,
The locking member 117 is a plurality of rings through which the tow rope 111 passes,
And support rods (218a, 218b) for fixing the plurality of rings. The method according to claim 1,
There are a plurality of tow ropes 111 and 121,
Further comprising a traction drum (232) around which the plurality of traction ropes (111, 121) are wound and rotated by the drive motor (132)
Characterized in that at least one traction rope (111) of the plurality of traction ropes (111, 121) is wound in the opposite direction to the other traction rope (121) and the traction drum (232). A tow rope 211 fixed to extend along the algae direction on the sea surface;
A plurality of positive mesh connecting ropes 212 extending downwardly from the tow ropes 211 at a plurality of points of the tow ropes 211;
A moving body 250 having a plurality of engaging members 252 disposed alternately with the plurality of positive net connecting ropes 212 along the extending direction of the traction ropes 211 and capable of moving by algae; And
And a guide structure (260) for guiding movement of the moving body (250)
As the moving body 250 is moved by the current, each of the plurality of positive network connecting ropes 212 is caught by each of the plurality of the engaging members 252 and the plurality of positive network connecting ropes 212 are lifted up . The method of claim 5,
The guide structure 260 includes a guide rope 261 extending and fixed along the direction of the tide and two rings 261a and 261b through which the guide rope 261 passes and is coupled to the moving body 250 Wherein the oyster cultivation apparatus comprises: The method of claim 5,
Further comprising two stoppers (270, 280) respectively interacting with the two rings (261a, 261b) to define a moving section of the moving body (250)
Wherein the two stoppers (270, 280) are provided with hooking grooves (272) to which the hooks (261a, 261b) can be hooked. A plurality of stationary supports 310, 410;
A plurality of rotary supports 320 and 420 rotatably connected to the plurality of fixed supports 310 and 410, respectively, the vertical positions of which are changed;
Traction ropes (330, 430) sequentially connected to each of the plurality of rotation supports (320, 420); And
And a plurality of positive networks (340, 440) connected to the rotation supports (320, 420)
Wherein the positive net (340, 440) is connected to the rotation support part (320) by being suspended or connected to the rotation support part (420). A positive net mounting base 524 on which a positive net 530 is installed so that the top end of the net can be rotated so as to change its vertical position; And
And a driving unit 525 capable of bidirectional rotation by an alga,
Wherein the positive net mounting base (524) is rotated by the rotation of the driving unit (525), and the positive net mounting base (524) and the driving unit (525) are integrally formed. The method of claim 9,
Further comprising engaging structures (521a, 523b, 523c) for allowing said benign net mounting base (524) to stop rotating at two rotational positions. delete delete

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