KR100796120B1 - Submersible cage facility for fish culture - Google Patents

Abstract

A submersible, sinking and floating net cage facility for culturing a fish in an open sea is provided to maintain a shape of a fish holding net constant at all times by installing upper and lower frames in upper and lower ends of the fish holding net, and to prevent the fish holding net from floating up and down by outer environmental factors by installing a weight material in the lower frame. A submersible, sinking and floating net cage facility for culturing a fish in an open sea includes: a fish holding net(10), having a space for holding a fish; an upper frame(20), having an inner space, and installed around an upper peripheral end of the fish holding net; a tube, arranged inside the inner space of the upper frame, and expanded or contracted by supplying or discharging an air so as to generate a buoyant force; and many through-holes, which are arranged in a peripheral surface of the upper frame, and through which a seawater is supplied to or discharged from the inner space of the upper frame according to an expansion or contraction motion of the tube.

Description

Submersible cage facility for fish culture

1 is a view showing the offshore edible cage farming apparatus according to the present invention.

Figure 2 is a view showing in detail the main configuration of the immersion cage farming apparatus shown in FIG.

3 is a view showing the internal structure of the etched cage farming apparatus shown in FIG.

4 is a view showing the internal structure of the upper frame shown in Figure 2 cut out.

5 is a view showing a state in which seawater flows into the inner space portion of the upper frame shown in FIG.

6 is a view illustrating the internal structure of the lower frame shown in FIG.

7 is a view showing the internal structure of the reinforcement frame shown in FIG.

<Description of the symbols for the main parts of the drawings>

10: cage net 20: upper frame

24: tube 28: through hole

30: lower frame 34: tube

38: heavy weight 40: network

42: reinforcement frame 50: chain

The present invention relates to a cage farming apparatus, and more particularly, a buoyancy means is built in the upper frame supporting the cage, so that the depth of the cage can be freely adjusted, and the shape of the cage is also adjusted. It relates to an offshore cage farming device for keeping it constant.

In general, cage farming is a net or a special facility in which a net is formed in a certain range from the inner surface of a sea or a dam, and a specific fish is farmed. In recent years, there is a tendency to advance into the open sea to worry about deterioration of water or to use the seawater itself.

Since the cage culture is freely passed through the mesh into and out of the cage, it is easy to exchange water, the oxygen can be supplied smoothly, and there is no need to remove or separate metabolic wastes in the cage. Even if fish are raised, the water quality in the cage does not deteriorate.

The conventional general configuration used in the cage form is a cage, the frame installed on the upper surface of the cage and the rope connecting the frame of the cage to the fixed structure and connected to the rope and the cage is floating on the water surface It comprises a plot to make.

However, the conventional cage farming device has a disadvantage in that the depth of the cage is not smoothly adjusted according to the type of fish since no floatation unit is provided except the buoyancy of the plot.

In addition, the cage network of the conventional cage farming device does not form a cylinder by its own weight during use, and forms a conical shape that gradually narrows toward the bottom thereof. This phenomenon narrows the space in the cage and makes fish In addition, when the flow rate is horizontally at sea, the bottom of the cage is biased to one side, causing a phenomenon in which the fly's activity space is further limited.

In addition, the conventional cage farming device does not have a heavy weight, so the cage can easily flow up and down under the influence of the waves, which can surprise the fish, and also cause the fish to be caught or wound in the flow process do.

In addition, the conventional cage farming system is exposed to the surface, and is affected by waves, and may be damaged by collision with passing ships. Also, the cage cage system with permeability is pervasive, but it is also resistant to climate change such as typhoon. There is a disadvantage.

In addition, there is a disadvantage that can be easily spread to other fish around the sea when it is installed in a limited place, causing pollution to the sea by the use of feed or antifouling agent, when the fish is sick.

On the other hand, recently imported products from abroad are expensive, difficult to install due to complex systems or steel structures, and costly, and also have both spaces compared to the size of the structure. The disadvantage is narrow.

Therefore, an object of the present invention for solving the problems as described above, by embedding a buoyancy means in the upper frame of the external sea erosion cage farming apparatus to freely adjust the depth of the cage according to the type of fish In providing.

Another technical problem to be achieved by the present invention is to provide an offshore etched cage culture apparatus capable of maintaining a constant shape of the cage by installing an upper frame and a lower frame at the top, bottom of the cage.

Another technical problem to be achieved by the present invention is to provide an external sea erosion cage farming device to prevent the cage net flows up and down due to waves or other external environmental factors by installing a weight on the lower frame.

Another technical problem to be achieved by the present invention is to provide an offshore edible cage farming apparatus that can be easily combined with small and large cages.

Another technical problem to be achieved by the present invention is to provide an external sea etched cage culture apparatus that can be implemented at a low cost and easy installation.

According to an aspect of the present invention, there is provided a cage structure including a cage formed with a space for trapping fish, and an upper frame installed along an upper circumference of the cage, wherein the space is formed inside the upper frame. It is formed, the space is installed in the expansion and contraction of the air in accordance with the supply and discharge operation of the tube is installed buoyancy, the inner surface of the upper frame in accordance with the contraction and expansion of the tube on the peripheral surface of the upper frame It is characterized in that a plurality of through holes for introducing and discharging sea water into the portion.

A lower frame is installed around the bottom of the cage, and the inner space of the lower frame is preferably configured by further installing a heavy object.

A partition network for partitioning the space of the cage network up and down is installed at the center of the cage, and a reinforcement frame is installed on the circumferential surface of the compartment network, and the inner space portion of the cage frame than the weight of the lower frame. It is desirable to install other weights with a small weight.

The upper frame, the lower frame and the reinforcement frame are configured to be connected by a chain, and one end of the connection strap is bound to the chain, and the other end of the connection strap is preferably configured to be bound to the cage network.

On the other hand, the caged net proposed in the present invention is generally used in a state submerged on the seabed, it can be configured to float the cage in the surface, if necessary, can adjust the buoyancy of the cage in this way It will be described that the technical gist of the present invention.

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

Attached Figure 1 is a view showing the offshore edible cage farming apparatus to be implemented in the present invention.

As shown, the offshore edible cage farming apparatus according to the present invention is manufactured in the form of a cylindrical body and has a cage net 10 having a space for trapping fish therein. The cage net 10 is provided with fixing means for fixing the cage net 10 to the position to be installed so as not to be floated by the waves.

The fixing means includes a structure 100 installed at the bottom of the sea water, an outer rope 110 connected to the structure respectively, and a connection rope connected to the outer rope 110 in a state connected to the cage 10. 120) is configured. At this time, the connection rope 120 is provided with a fastening band (buckle) (not shown) so that the attachment and detachment between the connection rope 120 and the outer rope 110 can be easily performed. The outer rope 110 is mounted with a plot 130 for generating a predetermined buoyancy.

2 and 3 are diagrams showing details of the cage net 10 constituting the offshore fringe cage farming device and the main components installed in the cage net 10.

As shown, upper and lower frames 20 and 30 are respectively installed at the upper circumference and the lower circumference of the cage net 10.

The upper frame 20 maintains the upper shape of the cage 10 in the state installed along the upper periphery of the cage 10, and also according to the buoyancy of the tube 24 installed therein 10 It will rise to the surface or sink below the surface to adjust the depth of the cage net 10 according to the type of fish.

4 and 5 are diagrams illustrating the durability of the upper frame 20. As shown, the upper frame 20 is formed in a cylindrical pipe form a space portion 22 therein, a tube 24 is installed in the space portion 22. An air supply and discharge port 26 is formed in the tube 24, and an end of the air supply and discharge port 26 passes through the upper frame 20 to be exposed to the outside and is a compressor as a driving source (not shown). Is configured with the connection.

The tube 24 expands to the pressure of the air supplied from the compressor through the air supply and discharge port 26 and generates buoyancy, and also contracts by discharging the air supplied through the air supply and discharge port 26. Buoyancy will be released. Through the expansion and contraction of the tube 24, the upper frame 20 can adjust the buoyancy, and thus the depth of the cage net 10 supported by the upper frame 20 can be adjusted according to the type of fish. Will be.

Meanwhile, in the present invention, the tube 24 is limited to being installed in the inner space 22 of the upper frame 20. However, if necessary, the tube 24 is exposed to the outside of the upper frame 20. I can install it in a state.

The circumferential surface of the upper frame 20 is formed in a state in which a plurality of through holes 28 maintain a predetermined interval. The through-holes 28 increases or decreases the weight of the upper frame 20 by introducing or discharging seawater into the inner space 22 of the upper frame 20 according to the contraction and expansion of the tube 24. Let's go. That is, when the tube 24 is contracted as shown in FIG. 4, the seawater is introduced into the space 24 of the upper frame 20 through the through hole 28, and in the process, the upper frame 20 is introduced. The weight is increased by the amount of sea water to sink the cage 10 below the surface of the water. In addition, when the tube 24 is expanded, the seawater introduced into the space 22 of the upper frame 20 is discharged to the outside through the through hole 28 at the expansion pressure of the tube 24, so that the upper frame 20 By reducing the weight of the cage net 10 will be able to rise to the surface.

On the other hand, the lower frame 30 is installed along the lower circumference of the cage net 10 and maintains the shape of the bottom of the cage net 10, and will be described later, but also using the weight 38 to lower the cage net 10 Pulling tightly to prevent the flow of the cage net (10).

6 is a cross-sectional view showing the internal structure of the lower frame 30 cut away. As shown, the lower frame 30 is provided with a space portion 32 in the form of a cylindrical pipe, the weight portion 38 is installed in the space portion 32.

The heavy material 38 is installed in the space portion 32 of the lower frame 30, to prevent the lower frame 30 from rising to the water surface or flowing up and down under the influence of waves. In addition, the weight of the weight 38, the lower frame 30 can always maintain the shape of the cage net 10 by pulling down the cage net 10 at all times.

Through the lower frame 30 of the above-described configuration, the cage net 10 does not flow upward and downward, as well as by pulling the cage net 10 downward at a predetermined pressure with a weight of the weight 36. In addition, it is possible to prevent the lower side of the cage 10 from being gathered in one direction or gathered in a conical form by other external stresses, so that the active space of the fish in the cage 10 can be kept constant at all times.

Meanwhile, the partition network 40 is further provided at the center of the above-described cage network 10 as shown in FIG. 3. The partition network 40 divides the internal space 10a of the cage network 10 up and down so that various types of fish can be farmed together in one cage network 10. That is, benthic fish species inhabiting the seabed such as flatfish or flounder are to be farmed in the lower space of the cage net 10 partitioned by the partition net 40, and other fish are caged net divided by the partition net 40 ( 10) Fish can be farmed in one place, depending on the depth of the water.

The reinforcement frame 42 is installed on the circumferential surface of the partition network 40. The reinforcement frame 42 prevents sagging of the partition network 40, and is also positioned between the upper and lower frames 20 and 30, and the cage net 10 connected to the upper and lower frames 20 and 30. ) Will reinforce the overall shape.

In the inner space 44 of the reinforcing frame 42, as shown in the accompanying Figure 7 is further provided with a separate weight 46, such as the lower frame 30 described above, the upper frame 20 and the reinforcing frame It is preferable to be able to pull down the cage net 10 located between the (42). At this time, the weight of the weight 46 installed in the reinforcing frame 42 is preferably configured to have a weight less than the weight 38 is installed in the lower frame (30).

On the other hand, the upper, lower frames (20, 30) and the reinforcement frame 42, a plurality of chains 50 are configured along the circumferential surface. The chain supports and secures the upper, lower frames 20 and 30 and the reinforcing frame 42 so that they are not separated by waves or other external stresses.

In the state in which one end of the connecting string 52 is bound to the chain 50, the other end of the connecting string 52 is configured to bind to the cage network 10. Through the chain 50 and the connecting string 52, the cage net 10 may be more firmly supported on the upper, lower frames 20 and 30 and the reinforcing frame 42 to maintain a circular shape.

Hereinafter, the operation of the offshore edible cage culture apparatus according to the present invention will be described.

First, when installing the offshore immersion cage farming apparatus of the present invention, the cage 10 is fixed to the outer rope 110 is fixed to the structure 100 by the connecting rope 120.

Next, when the caged net 10 is to be submerged in water, when the air supplied to the tube 24 of the upper frame 20 is discharged to the outside to constrict the tube 24, the sea water is applied to the upper frame 20. It is introduced into the inner space through the through-holes 28 are formed, at this time due to the weight of the incoming seawater cage 10 is settled down, located on the seabed to form fish.

On the other hand, when using the air in the tube 24 is installed in the upper frame 20 in order to injure the cage in the water in the use process, the upper end of the cage 10, the upper frame 20 is installed The surface of the lower surface of the cage 10 is submerged due to the weight of the weight 38 installed in the lower frame 30 with the water, and the weight of the lower frame 30 Due to the weight of the cage net 10 is pulled downwards to maintain the cage 10 in a circular shape.

As described above, the present invention achieves many effects as follows.

Firstly, the present invention enables to adjust the buoyancy through the tube installed inside the upper frame to have an effect of freely adjusting the depth of the cage according to the type of fish.

Secondly, the present invention provides an upper and lower frames to the upper and lower ends of the cage net so that the shape of the cage net is always kept constant, thereby effectively securing the active space of fish in the cage net.

Thirdly, the bottom of the cage is always pulled constantly by the weight of the heavy weight installed in the lower frame, which prevents the deformation of the cage or the flow of the cage up and down by waves or other environmental factors. It has an effect that can be done.

Claims (4)

In the cage farming apparatus comprising a cage net 10 is formed a space for trapping fish, and the upper frame 20 is installed along the upper periphery of the cage net 10, A space portion 22 is formed in the upper frame 20, and the space portion 22 is provided with a tube 24 which expands and contracts and generates buoyancy according to the supply and discharge of air; In the circumferential surface of the upper frame 20 is formed a plurality of through-holes 28 for introducing and discharging seawater into the inner space 22 of the upper frame 20 in accordance with the contraction and expansion of the tube 24 Offshore erosion cage farming apparatus, characterized in that. The method of claim 1, The lower frame 30 is installed around the lower end of the cage net 10, the internal space portion 32 of the lower frame 30, the offshore erosion cage, characterized in that the installation includes a heavy object 38 Aquaculture device. The method of claim 2, In the center of the cage 10 is divided into a partition network 40 for partitioning the space of the cage 10, up and down is installed; A reinforcement frame 42 is further installed on the circumferential surface of the partition network 40, and the inner space portion 44 of the reinforcement frame 42 has a smaller weight than the weight 38 of the lower frame 30. Offshore erosion cage device characterized in that the other heavy material 46 is installed. The method of claim 3, wherein The upper and lower frames 20 and 30 and the reinforcement frame 42 are connected to each other by a chain 50, and the one end of the connecting string 52 is bound to the chain 50, and the connecting string 52 of the The other end of the edible cage farming device, characterized in that to be bound to the cage (10).

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