KR101219539B1 - Feed-floating system for fish-raising farm using nano-micro bubble - Google Patents

Abstract

PURPOSE: A fodder floating system is provided to prevent water pollution inside a floating fish cage, and to reduce the waste of management costs. CONSTITUTION: A fodder floating system for a floating fish cage using nano-microbubbles comprises an oxygen dissolving water supplier(200) formed on one side of an upper plate; a first supply line(210) where the oxygen dissolving water which is supplied from the oxygen dissolving water supplier flows in; a second supply line(220) where the oxygen dissolving water which is supplied from the first supply line flows in; and a spraying device(230) installed at the second supply line which sprays the 10-30nm nano-microbubbles to be attachable to the fodder.

Description

Feed-floating system for Fish-raising farm using Nano-micro bubble

The present invention relates to a feed cage system for cage farms using nano-micro bubbles, and more particularly, by spraying nano-micro bubbles to feed sprayed cage cages consisting of circular or polyhedrons to delay the sedimentation rate of the feed, Cages using nano-micro bubbles aimed at improving feed efficiency by reducing feed loss and preventing coastal pollution, and improving the growth of aquaculture live fish by providing high concentration of oxygen water with high dissolved oxygen. It relates to aquaculture feed flotation system.

In general, when feeding fish for livestock in cages, they could not evenly distribute the feed in the farms because of direct feeding of people's hands. In addition, waste was excessive due to loss of feed, and financial problems due to overburden of labor cost occurred.

In order to solve the above problems, as described in Korean Patent Office Registration No. 20-0297876 (application date 2002.9.12) has been developed a "feeding device of the cage farm" to evenly spread the feed in every corner. By using the above feeding device, the loss of feed due to the direct sprinkling of food by humans can be reduced, and the feed can be sprayed in every corner, so that the growth state of aquaculture live fish is also relatively good. In addition, due to the operation of the automation system by the timer has been solved financial problems due to the overburden of labor costs.

Nevertheless, even if the feed is evenly spread, if the feed settles at the surface faster than the live fish eats, the surface of the water as shown in FIG. Laminated to In addition, live fish eat well the foods that settle in the water, but feeds that are stacked on the bottom of the water do not eat well. There was a problem that the water quality is contaminated, and people cannot provide high quality live fish.

Registered Korean Patent Office No. 20-0297876 (Application date 2002.9.12) "Feeding device for cage farm"

The present invention has been proposed to solve the above problems, the nano-micro bubble spraying device is installed on the bottom of the cage bottom net net spraying and nano-micro bubble is attached to the feed sprayed in cage cages cause buoyancy effect By delaying the sedimentation rate and by allowing the feed to float on the surface for a long time, by ensuring a long time for contact with aquaculture live fish, it is possible to eat feeds without aquaculture live fish without loss, improving the growth rate, water pollution and financial It is an object of the present invention to provide a feed system for cage farms using nano-micro bubbles that can solve problems such as phosphorus consumption.

The present invention for achieving the above object is a grid-shaped upper plate, a mesh-shaped side net extending to a certain depth in water from the edge of the upper plate, and a mesh-shaped for closing the lower portion of the side net As a feed system for cage farms consisting of a lower net,

An oxygen dissolved water supply device formed on one side of the upper plate, a first supply line extending into the water along one edge of the side net and into which the oxygen dissolved water supplied from the oxygen dissolved water supply device flows, and the lower net The sedimentation rate of the feed fed to the cage farm using the second supply line and the oxygen dissolved water introduced into the second supply line and located in the bottom and supplied from the first supply line Solution to solve the problem is to include a feed device installed in the second supply line for ejecting the nano-micro bubbles of 10-30nm size attachable to the feed to the upper portion of the lower net to slow down It is done.

Feed cage farm feed system using the nano-micro bubbles of the present invention, wherein the second supply line is composed of at least one pipe branched from the first feed line cage farm feed using nano-micro bubbles The flotation system is used as a solution to the problem.

In addition, the injector is a cage feed system for cage cages using nano-micro bubbles, characterized in that consisting of at least one nozzle as a means of solving the problem.

The injection device is a cage feed farm system for cage cages using nano-micro bubbles, characterized in that installed in the center of the lower net as a means of solving the problem.

As described above, according to the feed support system using the nano-micro bubble of the present invention,

Oxygen dissolved water generated from the oxygen dissolved water supply device formed on one side of the cage farm is moved to the second supply line through the first supply line and sprayed in the vertical upward direction from the bottom through an injector installed on the bottom of the lower net, The nano-micro bubbles rise in the form of bubble clusters in the water, attached to the feed settled on the surface of the water and buoyancy effect to delay the settling speed of the settled feed can be secured for a long time.

As a result of experiments for the purpose of the present invention, when the nano-micro bubble sprayed from the lower net of cage farms, the settling speed of the feed is about 0.03m / s, it was confirmed that the settling speed is delayed more than about 60% compared to the conventional.

As a result, the financial waste is solved by minimizing the loss of feed sprayed to the farm, and there is an advantage to increase the feeding efficiency.

In addition, the amount of feed is deposited on the bottom of the water is significantly reduced to improve the water cleanliness compared to the prior art can provide a high quality live fish, and since the live fish ingest the feed that is supported by the nano-micro bubbles digestion Well, by increasing the amount of dissolved oxygen in aquaculture farms to supply high concentration (15 ~ 40ppm) of oxygen water, the growth rate of aquaculture live fish is significantly increased compared to the prior art.

In addition, by supplying nano-micro bubbles, it is possible to see the dissolved oxygen supply and sterilization and antimicrobial effects required for fish farming, and to create benefits from various substitutions and structural changes of the present invention.

1 is a view showing a problem according to an embodiment of the prior art.
Figure 2 is a state diagram using the feed buoyancy system for cage farms using nano-micro bubbles according to an embodiment of the present invention.
3 is a view to help understand the feed support method according to an embodiment of the present invention.

Hereinafter will be described in detail with reference to the accompanying drawings with respect to the feed cage system for cage farms using the present invention nano-micro bubbles.

For reference, the terms used in the present invention are intended to describe one embodiment and are not intended to limit the present invention. Also, the present invention is not limited to the embodiments described herein and may be embodied in other forms. It is.

Figure 2 is a state diagram using the feed support system using a nano-micro bubble according to an embodiment of the present invention, although not shown in the figure feed cage system for cage farm using nano-micro bubbles of the present invention The power supply unit for operating this should be basically premised and the description thereof will be omitted.

As shown in FIG. 2, the cage farm feed feeding system using the nano-micro bubbles of the present invention includes a grid-shaped upper plate 241 and a mesh extending to a certain depth in water from the edge of the upper plate 241 ( In a cage farm consisting of a mesh-type side net 243 and a mesh-type bottom net 245 for closing the bottom of the side net 243, the oxygen-dissolved water supply device 200 and the first supply It may be configured to include a line 210 and the second supply line 220 and the injection device 230.

Here, the oxygen-dissolved water supply device 200 is formed in the shape of a circular or polyhedron, for example, cages or floats attached to the bottom surface buoyancy body (float, float) in a large moxibustion, etc. designed to float on the water surface It can be formed and installed on one side of the upper plate 241, the raw water suction unit that can continue to supply water with a power supply capable of supplying power, a compressor for applying pressure to the water, the oxygen dissolved water in the first supply line 210 Can be controlled by controlling the positive pressure valve to control the sending by the high pressure to the second supply line 220, UV sterilizer and ozone generator, chlorine dioxide generator and the aforementioned devices It may include a prior art or additionally modified devices, such as a control panel, and other than the core device is not described in detail It is assumed that the assumption is made in principle.

In addition, the oxygen dissolved water generated in the oxygen dissolved water supply device 200 may be configured to be connected to the first supply line 210 and the second supply line 220 to move to the injection device (230).

In this case, the first supply line 210 and the second supply line 220 may be made in a streamline type due to the combination of a straight line and a curve to facilitate deformation even if the pipe is installed in any part irrespective of the form of the cage cage 240. In addition, the oxygen dissolved water moving to the second supply line 220 through the first supply line 210 when installed on the bottom of the lower net 245 is preferably configured so that physical and chemical modifications are not applied.

In addition, the oxygen dissolved water moves to the second supply line 220 via the first supply line 210, wherein the first supply line 210 is submerged along one edge of the side net 243. Is extended to the oxygen dissolved water supplied from the oxygen dissolved water supply device 200, the second supply line 220 is located on the bottom surface of the cage bottom net 245 and the first supply line 210 The oxygen dissolved water flowing from the inflow) may be introduced to be formed to the center of any edge of the lower net 245.

The end of the first supply line 210 may be coupled to the branch pipe 215 formed of a "T" or "+".

The second supply line 220 is coupled to the branch pipe 215 formed in a portion of "T" or "+" in part to fit the structure of the cage farm 240, the lower net 245 in the form of a combination of straight and curved It is formed to be long on the bottom of the, and to the upper end of the second supply line 220 is provided with a spray pipe 225 protruding at any predetermined intervals so that the injection device 230 can be screwed together. Can be.

The branch pipe 215 described above allows the oxygen dissolved water that is moved from the first supply line 210 to be divided into one or more branches, and the second supply line 220 that is bound to the branch pipe 215. Oxygen dissolved water is characterized in that the movable through).

The injection device 230 is coupled to the injection pipe 225 formed on the upper part of the second supply line 220 by a screw tightening method, and the oxygen dissolved water delivered through the second supply line 220 is placed on the surface of the water 10. Spraying to the nano-micro bubble 250 of the ~ 30 nm size, but can be configured to be configured to control the direction according to the user's needs, but in the present invention will be described in the fixed installation in the vertical upward direction to explain the effect.

The nano-micro bubble (250) generated by the above-described process is a technology that is useful in various fields, such as the environment, health, industry, agriculture, fisheries, food washing, beauty and medical, as well as fish farms, increasing dissolved oxygen and There is a feature to keep it.

In addition, 10 to 30 nanometer (nm) sized pores smaller than pores generate numerous bubbles, and impurities of human body and living organisms are easily removed by oxygen dissolved water, and it also acts as a bactericidal effect of various bacteria present in the skin. .
The reason for generating bubbles of 10 to 30 nm in the present invention is that bubbles of this size are easily attached to the periphery of the feed and, as a result, can slow down the settling speed of the feed.

Referring to the present invention configured as described in detail as follows.

As shown in FIG. 2, the feed cage system for cage farms using nano-micro bubbles of the present invention is formed by installing an oxygen-dissolved water supply device 200 on one side of the cage farm top plate 241 and receiving power through a power supply unit. It is desirable to drive.

The oxygen-dissolved water supply device 200 is to control all the system from the control panel, inlet the compressed air into the intake water by using a compressor and oxygen and nitrogen gas inflow from the oxygen and nitrogen tank by DO Dissolved Oxygen Dissolves the dissolved oxygen in the first supply line 210 at a pressure regulated through a constant pressure valve.

At this time, the discharged oxygen dissolved water is to move through the first supply line 210, is connected to the water along one edge of the cage farm side net 243, any corner of the cage bottom net 245 After moving to the second supply line 220 through the branch pipe 215 is installed in the corner center can be moved to each.

Here, the second supply line 220 is installed on the bottom of the lower net 245, it is effective to be divided into two to three large as shown in FIG. The portion of the oxygen dissolved water that is being moved to the second supply line 220 farthest from the branch pipe 215 has a low water pressure, and thus its strength is weakened when the nano-micro bubble 250 is sprayed to be difficult to exert effect. As a result of the experiment, there was almost no difference in pressure when the oxygen-dissolved water was injected from the injector 230 due to the strength and speed of moving the first supply line 210 or the second supply line 220. It was confirmed.

In addition, the experiment result that the injection device 230 is disposed on the bottom surface of the cage bottom net 245 to spray the nano-micro bubble 250 to maximize the effect of the feed cage system for cage cages using nano-micro bubbles It was confirmed that it can be made.

The injector 230 may be adjusted in number or arrangement according to the size of the cage farm 240, but when the width and length of the injector 230 is approximately 6m x 6m in size so that one or two injectors 230 are disposed. It is effective.

Here, the direction of the injection device 230 can be adjusted in various directions, but the effect is maximized when fixed in the vertical upward direction.

As shown in FIG. 3, the nano-micro bubbles 250 are sprayed through the injector 230. When the nano-micro bubbles 250 are sprayed, the nano-micro bubbles 250 form a bubble cluster 310 and rise to the feed 110. Close contact.

At this time, the feed 110 is buoyant effect is obtained by the bubble cluster 310 formed on the upper portion of the injector 230 located on the bottom of the lower net 245 is in close contact with the feed 110, thereby the feed 110 May slow down the sedimentation rate.

As a result of experiments performed by the present inventors, the sedimentation speed of the feed 110 was reduced to 0.03 m / s, and the results confirmed that the sedimentation speed was improved by about 60% or more.

On the other hand, when the nano-micro bubbles 250 are distributed to the second supply line 220 from the branch pipe 215 disposed at the center of any corner of the lower net 245, the furthest from the branch pipe 215 Arranged injector 230 was concerned that the effect of the pressure of the nano-micro bubble 250 is lowered because the injection is concerned, but the experimental result is only a very small difference, did not differ enough to affect the gist of the present invention Confirmed.

As another example, the present inventors have arranged the injection device 230 in the center of the rectangular shape of 6m × 6m of the lower net 240 presented, but modified in the form of "W" or "O" shape, etc. Even if the effect will not be significantly different from the object of the present invention. Therefore, regardless of the type when installing the second supply line 220 in the lower net 245, the bubble cluster 310 is raised to maximize the buoyancy effect on the feed 110 is the object of the present invention Can be.

As described above, by constructing a feed cage system for cage farms using nano-micro bubbles, delaying the settling speed of the feed 110 evenly spread on the cage farm 240 and contacting the farmed live fish and feed 110 By extending the time to minimize the loss of the feed 110 is sprayed by the feed spreader 300, there is an advantage that can increase the feeding efficiency to prevent excessive consumption of the feed (110).

In addition, if the feed 110 is stacked on the bottom because it is not ingested the feed 100 is stacked due to the habit of the live fish, it is possible to minimize the contamination of the coastal environment due to this, and the dissolved oxygen high nano-micro By ingesting the feed 110 together with the bubble 250, there is an advantage that the digestion of cultured live fish is promoted and the growth rate is significantly faster than the prior art.

In addition, the breathing or physiological activity of the farming live fish is smooth and there is an effect that can minimize the disease.

As described above, one embodiment of the cage culture feed support system using the nano-micro bubble of the present invention, but those skilled in the art without departing from the spirit of the invention described in the claims Within the scope of the present invention, various modifications and changes of the present invention may be made by adding, changing, deleting or adding components, which will also be included within the scope of the present invention.

100: stacked feed 110: feed
200: oxygen dissolved water supply device 210: first supply line
215: branch pipe 220: second supply line
225 injection pipe 230 injection device
240: cage farm 241: top plate
243: side net 245: bottom net
250: nano-micro bubble 300: feed spreader
310: bubble cluster

Claims (4)

As a feed system for cage farms consisting of a grid top plate, a mesh side net extending from the edge of the top plate to a certain depth in the water, and a mesh bottom net for closing the bottom of the side net. ,
An oxygen dissolved water supply device formed on one side of the upper plate;
A first supply line extending into the water along one edge of the side net and into which the oxygen dissolved water supplied from the oxygen dissolved water supply device flows;
A second supply line located at a bottom of the lower net and into which the oxygen dissolved water supplied from the first supply line flows;
Using the oxygen dissolved water introduced into the second supply line to eject the 10 ~ 30nm size nano-micro bubbles attached to the feed to the upper portion of the lower net in order to slow down the sedimentation rate of the feed fed to the cage farm Feeding system for cage farms using nano-micro bubbles characterized in that it comprises a spray device installed in the second supply line. The method of claim 1,
The second supply line is a feed system for cage farms using nano-micro bubbles, characterized in that consisting of at least one pipe branching from the first supply line. The method of claim 1,
The injector is a feed system for cage farms using nano-micro bubbles, characterized in that consisting of at least one nozzle. 3. The method according to claim 1 or 2,
Wherein the injection device is cage feed farming system for cages using nano-micro bubbles, characterized in that installed in the center of the lower net.

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