KR102420387B1 - Floating type artificial fish reef - Google Patents

Abstract

The present invention includes a tube comprising a floating body, a tube body connected to the floating body, a plurality of pin-holes formed in the tube body, and a chelating composition injected into the tube body, the chelating composition comprising: It relates to a floating artificial reef comprising a humic material selected from the group consisting of humic acid, fulvic acid, ulmic acid, and combinations thereof, shellfish and organic feed. Metal salts contained in shell fossils, various mineral components dissolved in seawater, and amino acid components and minerals obtained when organic feed corrodes are converted into chelate forms by humic substances so that marine organisms can consume them, and prevent the de-whitening of seawater. can In addition, by adopting a humic acid having a pore structure, it is possible to absorb odor components such as ammonia in seawater. Using the artificial reef according to the present invention, it is possible to prevent sea desertification by naturally forming a food chain in the surrounding marine ecosystem.

Description

Floating artificial reef {FLOATING TYPE ARTIFICIAL FISH REEF}

The present invention relates to an artificial reef, and more particularly, to a floating artificial reef that can solve the environmental pollution problem of a marine ecosystem and can increase fishing by inducing spawning and growth of marine organisms.

Artificial reefs are intended to increase the production of mass-produced organisms by inducing the growth of marine organisms. According to the 「Artificial reef facility project implementation and management regulations」 of the Ministry of Agriculture, Food and Rural Affairs of the Republic of Korea, artificial reef refers to various structures installed to artificially create spawning and habitats of aquatic organisms, sea ranches, sea forests, and marine forests in the water. do. In addition, artificial reefs are classified into reefs for fish or reefs for shellfish and algae depending on the type of marine life inhabiting the surrounding area. Fish reefs refer to artificial reefs installed for spawning, growth and fishing of fish, and shellfish/algae reefs are used for breeding, growing and collecting shellfish, attaching and inhabiting seaweeds, or artificially transplanting seaweed seeds. artificial reefs to be installed.

In general, artificial reefs are manufactured in the form of blocks artificially protruding from the seabed of the coast. Conventional block-type artificial reefs are manufactured using cement, gravel, sand, etc. as main materials, and their useful life is only 2-3 years on average, which is very short. In addition, there are not many voids between the cement, gravel, and sand, so it takes at least 6 months for the spores of seaweed to attach. In the case of using a conventional artificial reef, the growth of seaweed is slow and the density of the colony of seaweed is low. Therefore, there is a limit to greatly increasing the production of various marine organisms. In addition, artificial reefs are installed in the water, causing a problem in that the marine ecosystem is disturbed, such as causing water pollution.

Republic of Korea Patent No. 10-1995633

An object of the present invention is to provide a floating artificial reef that can promote the growth of marine organisms and induce proliferation, including humic substances.

Another object of the present invention is to provide a floating artificial reef that can prevent contamination of seawater, chelate various minerals in seawater, and prevent bleaching of the marine ecosystem.

The present invention is a floating body; and a tube comprising a tube body connected to the floating body, a plurality of pin-holes formed in the tube body, and a chelating composition injected into the tube body, wherein the chelating composition is humic acid, fulvic acid, It provides a floating artificial reef including a humic material selected from the group consisting of ulmic acid and combinations thereof, fossilized fossils (Fossil Shell, hereinafter, English notation in parentheses is omitted) and organic feed.

As an example, the humic material is a humic material extracted from carbonaceous powder using a solvent in a vacuum pressure tank at a temperature of 200 to 260 ° C and a pressure of 200 to 600 kgf / ㎠, and after opening the pressure tank, It can be obtained by cooling at a temperature of -20 ~ -30 ℃.

The pin-holes may be formed in the tube with an interval of 3-20 cm, and the pin-holes may have a size of 0.1-2 mm.

For example, the organic feed may be obtained by roasting food waste composed of leftover food, slaughter residues, food by-products, and a combination thereof.

Illustratively, it may further include a first fixture connecting the float and the tube body, and a bundle connected to the first fixture.

In another embodiment, the floating body includes a first floating body connected to the tube and a second floating body positioned adjacent to the second floating body, connected to the second floating body and connected to the shellfish, sea urchin and seaweed It may further include a fixture to which at least one marine creature selected from among is attached.

In another embodiment, the tube further comprises a plurality of first fixtures connected to the floating body, a second fixture connecting the first fixtures, and a plurality of meshes connected to the second fixtures, may be disposed within the mesh.

In another embodiment, a tube body connected to the second fixture, a plurality of pin-holes formed in the tube body, and a second tube comprising the chelating composition injected into the tube body. can

In another embodiment, the floating body includes floating means of the cage farm, and further includes a mesh connected to the floating means or scaffold constituting the cage farm, and the tube may be disposed inside the mesh. .

For example, it further includes a shelter for aquaculture connected to the net, the tube may be connected to the shelter for aquaculture.

The present invention proposes a floating artificial reef including a tube in which a chelating composition including a humic material, a fossil and an organic feed is injected and filled in a tube body having a fine pin-hole. Metal salts contained in shell fossils, minerals contained in organic feed, amino acids produced by decomposition of proteins, etc. form chelated complexes with humic substances, and are discharged to the outside through pinholes. Marine organisms that ingest the chelating complex can multiply naturally, and can induce the growth and proliferation of marine organisms while forming a food chain.

In addition, the mineral component included in the seawater introduced into the tube body may also react with the humic material to be transformed into a chelated complex compound. In particular, substances causing odors such as ammonia and hydrogen sulfide contained in the discharge of marine organisms may react with the humic material or be trapped in the porous humic material. It is possible to prevent whitening of seawater or the ocean caused by minerals, etc. contained in seawater, and to minimize odor.

1 is a view schematically showing the construction form of a floating artificial reef according to a first exemplary embodiment of the present invention.
Figure 2 is a perspective view schematically showing the shape of the tube constituting the floating artificial reef according to the present invention.
3 is a view schematically showing a construction form of a floating artificial reef according to a second exemplary embodiment of the present invention.
4 is a view schematically showing the construction form of a floating artificial reef according to a third exemplary embodiment of the present invention.
5 is a view schematically showing the construction form of a floating artificial reef according to a fourth exemplary embodiment of the present invention.
6 is a view schematically showing a cage farm in which a floating artificial reef according to an exemplary embodiment of the present invention is constructed.
7 is a view schematically showing the construction form of a floating artificial reef according to a fifth exemplary embodiment of the present invention.
8 is a view schematically showing a construction form of a floating artificial reef according to a sixth exemplary embodiment of the present invention.
9 is a view schematically showing a state in which a tubular artificial reef is mounted between shelters for aquaculture according to a sixth exemplary embodiment of the present invention.
9A is an electron microscope image of humic acid prepared according to an exemplary embodiment of the present invention.
Figure 9b is an electron microscope image divided into a layer form for EDS analysis of the humic acid prepared according to an exemplary embodiment of the present invention.
10 is a graph showing the results of EDS analysis for humic acid prepared according to an exemplary embodiment of the present invention.

Hereinafter, the present invention will be described with reference to the accompanying drawings, if necessary.

1 is a view schematically showing the construction form of a floating artificial reef according to a first exemplary embodiment of the present invention. 2 is a perspective view schematically showing the configuration of the tube 110 into which the chelate composition is injected according to the present invention. As shown in FIG. 1 , the floating artificial reef 100 according to the first embodiment of the present invention has a floating body 150 , a fixed body 160 connected to the floating body 150 , and the fixed body 160 . Includes a tube 110 connected to, and optionally includes a bundle (bunch, 170) independently connected to the tube 110 to the fixture (160). When using terms such as connection, coupling, etc. in this specification, it includes a case where two components are directly connected, as well as a case where another component is interposed between these two components.

The floating body 150 may be a buoy capable of floating on the sea level, and the fixing body 160 may be a fixing rope. For example, the floating body 150 is connected to one end of the fixed body 160 through the first connecting means 152 . On the other hand, the tube 110 into which the chelating composition containing the humic material, shell fossils, and organic feed is filled and injected is connected to the fixture 160 through the second connecting means 162 . On the other hand, the bundle 170 made of fibers may be connected to the middle height of the fixture 160 through the third connecting means (172). In addition, the anchor 180 is connected to the bottom of the floating body 150 through the fourth connecting means 182, and the floating body 150 and the floating body 150 are due to the anchor 180 fixed to the sea bottom. It is possible to prevent the tube 110 and the bundle 170 connected independently to each other from deviate from the original position even at a strong flow rate. In one exemplary embodiment, the first to fourth connecting means 152 , 162 , 172 , 182 may be a clamp, a fastener, or a connecting string, but is not limited thereto.

2, the tube 110 connected to the fixture 160 is a tube body 120 made of a vinyl or plastic material, a closing member 130 blocking both ends of the tube body, and the tube body 120. It includes a plurality of pin-holes 140 formed at predetermined intervals. As an example, the tube body 120 may have a rectangular or elongated cylindrical shape, and may be formed of a vinyl or plastic material such as polyvinyl chloride (PVC), polyolefin such as polyethylene or polypropylene, or polyurethane, but is limited thereto. doesn't happen

A plurality of pin-holes 140 are formed in the tube body 120 at predetermined intervals. For example, the diameter of the pin-hole 140 may have a size of 0.1-2 mm, and may be formed in multiple numbers with an interval of approximately 3-20 cm in the tube body 120 . On the other hand, both ends of the tube body 120 may be formed with a closing member 130 capable of completely isolating the inside and the outside of the tube body 120 by heat sealing, an adhesive, a binding string, or the like.

Before closing both ends of the tube body 120 , a chelating composition including a humic material, a fossilized stone (Fossil Shell) and an organic feed may be injected and filled in the tube body 120 . For example, the chelating composition may include 20-30 parts by weight of a humic material, 20-30 parts by weight of shell fossil, and 50-60 parts by weight of an organic feed. If necessary, the chelating composition is compressed and molded into a cylinder having a size of 20-100 mm in length × 20-100 mm in width × 10-30 mm in height or 20-100 mm in diameter × 20-100 mm in length to form a tube body ( 120) can be injected or filled inside. The term parts by weight means the relative weight ratio between ingredients to be formulated, unless otherwise stated.

In an exemplary embodiment, the humic material constituting the chelating composition may be selected from the group consisting of humic acid, fulvic acid, ulmic acid, and combinations thereof. The humus constituting the chelating composition is, for example, from a carbonaceous material such as humus, peat moss, peat and/or leonardite or a wood material such as lignin. can be obtained, but is not limited thereto. In an exemplary embodiment, the humic material may be extracted from bituminous coal or lignin.

Peat is a carbonaceous material that is biochemically carbonized by the deposition of incompletely decomposed materials near the surface of aquatic plants such as swamps or marshlands, mosses, and plant organisms such as grasses in wetlands. Peat contains more than 90% organic matter and is a porous carbonaceous material having a porosity of approximately 60-85%. In swamps or swamps with excess moisture, the activity of microorganisms that decompose organisms is inhibited, and the carbonaceous material is in a state in which the organism is not completely decomposed, so it is yellowish brown or dark brown. Peat has excellent moisture absorption, absorption and odor absorption properties, has a low content of inorganic components, and is relatively light, so it can be easily handled.

Peat is a carbonaceous material that has been degenerated by biochemical carbonization due to the thick deposition of the fluid of flowering plants or trees in the basin. It is formed when lignin and cellulose, the main components of plant matter, are decomposed at the surface. After the peat layer is formed in the swamp, the soil is deposited on the top of the peat, and the moisture is removed by earth pressure and geothermal heat, and the natural vegetable polymers condense and the cellulose disappears. It is partially oxidized.

These carbonaceous substances contain a humic substance that is modified by decomposition and polymerization of soil organic matter by microorganisms, in other words, an organic substance called humus substance. In general, soil organic matter is decomposed by microorganisms in the tissues of animals and plants, and immature organic matter in the immature process, polysaccharide, protein, lipid, amino acid, etc. and a humic material that is an organic material in which the non-humic material is further changed to become a brown-black organic colloid.

The humic material is a polymer compound in which a condensed ring is formed as soil organic matter is decomposed, condensed, polymerized, and oxidized for a long period of time, and is an organic colloidal organic material having a size of approximately 1-100 nm. Humic materials derived from carbonaceous materials such as briquettes are catabolized such as color, degree of polymerization, molecular weight, number of functional groups such as carboxyl group (-COOH) and hydroxyl group (-OH), number of carbon and oxygen, substitution degree, water solubility, etc. It can be divided into humin (humic acid, humin), humic acid, fulvic acid, and ulmic acid according to the biological characteristics. The humic material constituting the chelating composition according to the present invention may be selected from the group consisting of humic acid, fulvic acid, ulmic acid, and combinations thereof.

Humic acids, such as humic acid, fulvic acid, and ulmic acid, can be classified according to the polymerization structure, ring and chain shape, etc., and have an average size of approximately 5-50 nm, and the three-dimensional structure and size are determined during the humicization process . These humic substances contain organic ligands, which combine with metal salts or amino acids produced from shell fossil powder and organic feed, which will be described later, to convert them into a chelated state.

Humic substances such as humic acid, fulvic acid, and ulmic acid have a macromolecular structure with a low functional group in the center and low polarity, such as fatty acids and aromatic compounds having a benzene ring such as lignin. It is a free ligand having both a fat-soluble functional group and a water-soluble functional group such as an alcoholic hydroxyl group (ROH) and a carboxyl group (RCOOH) formed under the influence of amino acids and sugar compounds, which are highly polar and water-soluble natural polymers. Since organic ligands have very good cation exchange properties, chelate complexes can be formed by cation exchange reactions with various cationic materials around them.

For example, humic acid is almost insoluble in water, but is a high molecular compound that is soluble in alkali agents such as potassium hydroxide (KOH) and sodium hydroxide (NaOH). Since it is usually brown-black brown in color and contains a large number of functional groups in the molecule, various trace elements are easily combined, so that the oxidized portion is negatively charged. Humic acid is a complex aromatic macromolecule in which amino acids, amino sugars, peptides, and aliphatic compounds are intricately bonded between the aromatic rings. have.

Fulvic acid is a highly soluble compound that dissolves in water regardless of acidity, and has a yellow or orange color. Fulvic acid has aromatic and aliphatic structures, both of which are extensively substituted with oxygen-containing functional groups. Fulvic acid has a large number of oxygen compared to humic acid, but a small number of carbon as a corrosive component, and contains a large amount of functional groups, particularly carboxyl groups, hydroxyl groups and ketone groups (C=O).

In one example, the humic material used in accordance with the present invention is negatively charged. Accordingly, minerals having a positive charge, included in the fossil fuel powder and organic feed, are combined with the humic material. Minerals combined with humic substances can be easily ingested by marine organisms including algae and plankton, and can induce them to gather around these marine organisms.

For example, humic acid, one of the humic substances, promotes the growth of marine organisms, activates the source microorganisms, increases nutrient availability and absorption, and in particular, nitrate nitrogen (NO ₃ ^- N) to improve the utilization rate. Humic acid helps the growth of marine life by accumulating trace elements and organic matter necessary for marine life including algae.

Fulvic acid has a stronger acidity than humic acid and has high hydrophilicity, so it can dissolve minerals that humic acid cannot dissolve. In addition to dissolving minerals, fulvic acid can help the growth of marine organisms by acting as a nutrient medium.

That is, the humic substance contained in the chelating composition according to the present invention is extracted in a chelate form that is good for marine organisms to absorb nutrients such as minerals and amino acids by utilizing humic substances such as humic acid, fulvic acid, and ulmic acid, which are organic ligands. can In particular, the humic material, a free ligand in the form of a complex that forms a coordination bond with amino acids contained in shell fossil powder and organic feed, functions as an important inorganic electrolyte component in marine animals. Organic ligands derived from humic substances can improve the efficiency when ingesting shell fossil powder and organic feed by stabilizing the microflora inside fish, shellfish, and zooplankton, and have antibacterial and anti-viral activity.

As mentioned above, the humic material may be prepared from a carbonaceous material such as brown coal. First, the carbonaceous material is pulverized. In order to prepare a humic material having an organic ligand, the briquette is fed to a pulverizing device to an appropriate size, for example, an average particle size of 0.5 mm or less, for example 0.01-0.5 mm, preferably is pulverized to a size of 0.05-0.5 mm. At this time, by supplying wind or hot air from the lower part of the crushing device, only the bituminous coal in the form of dust and the bituminous coal fraction having an appropriate size are classified. When the size of the carbonaceous particles, such as brown coal, is less than the above-mentioned range, the humic material having the organic ligand can be easily extracted, but the processing cost of the carbonaceous particles may increase. In addition, when the size of carbonaceous particles such as briquettes exceeds the above-mentioned range, the reaction time for extracting the humic material having an organic ligand may be long.

The pulverized briquettes are fed to the reactor to extract free ligands. For example, the reactor may be a compartmentalized or ladle-type extraction reactor and may be processed into a humic material in such a reactor. Among the humic substances contained in the carbonaceous material, since humin is not soluble in water regardless of acidity, the humic material composed of humic acid, fulvic acid, ulmic acid and a combination thereof through the above-described extraction process has an organic ligand form. can be extracted.

In the case of extracting humic substances such as humic acid, fulvic acid and ulmic acid having an organic ligand from the pulverized carbonaceous material, special treatment may not be required when extracting the fulvic acid, but an extraction solvent in a neutral state, for example, water It is necessary to change the pH of the reactant to alkaline in order to extract humic acid, which is not readily soluble in . The alkalizing agent used is not particularly limited, and may be selected from the group consisting of calcium oxide (quick lime, CaO), calcium hydroxide (slaked lime, CaOH), sodium hydroxide (NaOH), potassium hydroxide, and combinations thereof. For example, the pH of the reactant may be adjusted to about 8-12, preferably 8-10 by adding an alkalizing agent, and the alkalizing agent may be used at a concentration of about 5-30% (w/v) in the solvent.

If necessary, the reactor is stirred using a stirring means such as a magnetic bar, and the reactants are stirred at a temperature of 50° C. or higher, for example 80-100° C., and at atmospheric pressure or higher, for example 1-2 atm, for 12 hours or more, preferably is reacted for 24-72 hours. Accordingly, the humic material contained in the pulverized carbonaceous material swells, and the humic material having the organic ligand is extracted while being dissolved in the solvent. Through this process, not only humic substances that are well soluble in water, the extraction solvent, but also polymers, which are humic substances that are difficult to dissolve in water, are hydrolyzed into small molecules of humic acid, fulvic acid, and ulmic acid.

In an alternative embodiment, when extracting a humic material such as humic acid, fulvic acid, or ulmic acid from a carbonaceous material, gypsum (CaSO _4· nH ₂ O) may be added to the reactor together with or independently of the alkalizing agent. can Solvent and gypsum have better solubility in water used as an extraction solvent than metal salts or metal ions contained in shell fossil powder or organic feed, which will be described later, or amino acids generated by corrosion of organic feed. Therefore, the organic ligand contained in the humic material such as humic acid, fulvic acid, and ulmic acid extracted through the above-described process and gypsum react to form a calcium chelate complex. In this process, the sulfuric acid liberated from the gypsum reacts with a metal salt or metal ion contained in the fossil stone, for example, calcium carbonate, and is converted into calcium sulfate to prevent the pH of the chelate composition from lowering. Calcium sulfate converted in this process may react again with the organic ligand of the humic material, which did not react with the humic material in the fossilized powder or corroded organic feed.

However, when the amount of gypsum, that is, calcium sulfate, is too large, the chelate composition becomes acidic, so it may be difficult for marine organisms to ingest the chelate composition according to the present invention. Therefore, it may be preferable to add gypsum in a proportion of 5-10 parts by weight based on the humic material.

Through the above-described process, a humic material having a low molecular weight or in the form of an organic ligand that is well soluble in water may be extracted. For example, humic acid contains a large number of anions, and when the pH is increased by adding an alkalinizing agent, the agglomerated structure collapses and expands into a colloidal state by repulsing each anionic molecule. Since it changes, it is possible to extract humic acid in the form of an organic ligand.

On the other hand, fulvic acid is well soluble in water, but can be easily soluble in water at pH in acidic conditions. In order to extract fulvic acid, an acidifying agent, which may be, for example, an inorganic strong acid such as nitric acid or hydrochloric acid, or an organic acid such as lactic acid, acetic acid, fumaric acid, formic acid, propionic acid, malic acid, or citric acid, may be added to the solvent. For example, by adding an acidifying agent, the pH of the reactant may be adjusted to about 3-5, but is not limited thereto.

At this time, the humic material derived from the carbonaceous material may be classified into humic acid, fulvic acid, ulmic acid, etc. according to color, polymerization degree, molecular weight, number of functional groups, substitution degree, water solubility, and the like. If necessary, the humic material extracted through the solvent extraction method can be selected according to specific gravity and separated into humic acid, fulvic acid, and ulmic acid.

In an alternative embodiment, the humic material, such as humic acid, may be obtained from carbonaceous materials such as humus containing natural lignin-based materials, peat, peat, and lignite, for example, lignite. For example, humic acid extracted from lignin generated from brown coal or natural swamps has very little carbon content, but a relatively glue component exists. When a humic material extracted from brown coal or lignin is burned, it does not catch fire, but it produces a lot of smoke and is not broken and has many crumbs. Using these characteristics, it is possible to obtain a humic material in which pore structures are formed in various directions when treated under high temperature and high pressure conditions and quenched.

Specifically, the humic material extracted and separated through the above-described solvent extraction method and specific gravity screening method is placed in a pressure tank having high heat of 200-260° C. and high pressure of 200-600 kgf/cm 2 , and the pressure tank is instantaneously in a vacuum state. When the door is opened, the humic material is sprayed and crushed into a powder form. At this time, when rapidly cooled (-30°C to -20°C), a large number of pores of a honey comb type having many pores are formed in the humic material. If this process is repeated several times (for example, 2-10 times), a humic material in which pores in various directions (for example, 6 directions) are formed is obtained. In this case, components such as ammonia, which are included in the excrement of marine organisms and cause a bad odor, may react with the humic material or be trapped in the pores inside the humic material.

The chelate composition also includes shell fossil powder. Shellfish, etc. secrete a protein-bound metal, such as calcium, from the epidermal cells of the mantle covering the mollusc toward the shell. The secreted metal component dissolves in seawater for a long period of time and binds to carbon dioxide to combine with calcium carbonate and calcium phosphate. And materials that exist as crystals in the form of inorganic metal salts such as magnesium carbonate are shell fossils. For example, shell fossils can be obtained from the uplift of seashell tombs deposited on the sea floor in the process of changing the sea to land tens of millions of years ago by volcanoes and tectonic movements.

These metal salts contained in shell fossils are separated into metal ions and anions in seawater, and the metal ions form chelated complexes with humic substances. The metal mineral component transformed into a chelated complex can be easily ingested by marine organisms. According to one exemplary form, the shell fossil may be injected into the tube body 120 in the form of powder. In this case, shell fossil powder pulverized to a size of about 0.1-0.5 mm may be used. For example, the shell fossil powder may have a size of 0.1-0.3 mm by separating it into 40 mesh. In another alternative embodiment, the shell fossil may be injected into the tube body 120 in a mass. In this case, the shell fossil may have a size of approximately 0.1-0.5 cm. When the shell fossil powder or mass in the above-mentioned range is used, the metal component can be efficiently extracted.

The chelating composition also includes an organic feed. In an exemplary embodiment, the organic feed may be obtained by processing food waste such as leftovers, slaughter residues, and food by-products. Since such components can be recycled, the tubular artificial reef according to the present invention can contribute to minimizing environmental pollution caused by food waste that is difficult to treat. For example, organic feed can be prepared by removing leftovers, slaughter residues and/or food by-products (by-products from milk mills, confectionery mills and food processing plants that use soy/wheat/rice flour, etc.) at approximately 40-75°C. It can be obtained by ripening for 30 days or more, for example, 90-120 days, and processing.

The organic feed includes a liquid component and a solid component, and the content of the liquid component may be, for example, 10 to 20% by weight. Solid components include organic components such as proteins, polysaccharides, and fats contained in food waste, as well as macro elements such as sodium, calcium, magnesium, phosphorus, potassium, chlorine, and trace elements that are metal components. Some components, such as amino acids, monosaccharides, oligosaccharides, fatty acids, etc. hydrolyzed by organic components during the fermentation process, may be included. The organic feed may include a solid organic feed or a liquid organic feed. In this case, the content of the liquid component may vary depending on the type of food waste that is the raw material of the organic feed, the content of the liquid component, and the fermentation process. For example, the content of the liquid component in the liquid organic feed may be 10-60% by weight, but is not limited thereto.

Accordingly, the organic feed injected into the tube body 120 together with the above-described humic material is further corroded by the humic material to include a large number of monomer components such as amino acids and mineral components. The amino acid and the mineral component react with the humic material to form a chelated complex, and are discharged to the outside through the pin-hole 140, and the chelated complex can be ingested by marine organisms.

In addition, sodium and potassium, as well as nutrients such as nitrate, phosphate, and silicate, and gases such as oxygen, nitrogen and carbon dioxide are dissolved in seawater. Therefore, when the mineral component contained in seawater flows into the tube body 120 through the pin-hole 140, it reacts with the humic material to form a chelating complex, and the formed chelating complex is the pin-hole 140. It can be ingested by marine organisms as it leaks out through the

That is, according to the present invention, when a chelating composition in which a humic material having an organic ligand, a fossil having a metal salt, and an organic feed are injected into the tube body 120, the metal salt included in the shell fossil and amino acids included in the organic feed And the mineral component reacts with the organic ligand contained in the humic material to form a chelating complex, and the formed chelating complex flows out through the pin-hole 140 to be ingested by marine organisms, and the growth and reproduction of marine organisms can induce

Components such as sodium and potassium included in the seawater introduced into the tube body 110 also react with the organic ligand of the humic material to form a chelating complex, and may flow out of the tube body 120 . By chelating the mineral components contained in seawater, it is possible to prevent and minimize the whitening phenomenon caused by these mineral components. In addition, since the humic material includes a porous structure formed in a plurality of directions, it is possible to minimize marine pollution by collecting components such as ammonia that cause odor in excrement of marine organisms. In addition, oxygen contained in the pores formed in the molecular structure of the humic material may be supplied to marine organisms.

In addition, the seawater pressure increases with the depth of the seawater, and there is an advantage in that the chelation reaction is promoted between the humic material having an organic ligand and the metal salt in the fossil and/or the amino acid or mineral component in the organic feed at the elevated pressure. can In addition, among the metal salts contained in the shell fossil, calcium carbonate is poorly soluble in water. However, since carbon dioxide contained in seawater can be converted into carbonic acid, calcium carbonate is relatively easily dissolved, and calcium carbonate can easily combine with an organic ligand of a humic material to form a chelated complex.

In an alternative embodiment, the floating artificial reef 100 may further include a bundle 170 independently connected to the fixed body 160 . Bunch 170 may be manufactured using synthetic components such as vinyl or plastic, but since these materials are not decomposed, there is a risk of disturbing the marine ecosystem. Therefore, the bunch 170 may be manufactured using an eco-friendly material that is a natural fiber such as coconut palm fiber, which is decomposed after a certain period of time.

Bunch 170 is made of hard and impervious fibers, and can serve as a hiding place for plankton and the like. In an exemplary embodiment, the bundle 170 may be connected in a form suspended at an intermediate position of the fixture 160 . To this end, the fixture 160 and the bundle 170 may be connected through a third connecting means 172 such as a clamp, a fastener, or a string for fixing. Accordingly, the chelating complex that flows out through the pin-hole 140 formed in the tube body 120 is due to the bundle 170 disposed near the tube 110, and the floating artificial reef 100 is constructed. It can be prevented or minimized from going out of bounds.

In another exemplary embodiment, the bunch 170 may be filled with fillers including the humic material described above, shell fossils, and optionally organic feed. In this case, the filler punches the central portion of the bundle 170 with a diameter of 2-40 mm to form a groove in the center of the bundle 170, fills the inside with a humic material and shellfish, and attaches it to the tube body 120 . it might be In this case, the humic material filled in the bundle 170 may contain 30-40 parts by weight, and the shell fossil may include 60-70 parts by weight. Accordingly, calcium, amino acids and various mineral components of organic feed, and mineral components in seawater generated from the shell fossil are leaked from the inside of the bundle 170 to the outside, and spores such as algae and plankton living around the bundle 170 are fed. becomes Accordingly, a food chain is naturally formed around the tube body 110 and the bunch 170 to induce the growth of marine organisms. The number of bundles 170 disposed adjacent to the tube body 110 is not particularly limited.

In this case, the chelated complex that flows out of the tube 110 through the pin-hole 140 of the tube body 120 is attached to the surface of the bundle 170 . The spores of seaweed may be attached to the bundle 170 made of fibers, and the phytoplankton and zooplankton living around the bundle 170 ingest the chelated complex attached to the surface of the bundle 170 . Subsequently, these plankton are ingested by rotifers, and then a food chain ingested by marine organisms such as freshly hatched fry, scallops, sea squirts, oysters, sea cucumbers, and abalone is naturally formed in the floating artificial reef 100 . do. Accordingly, it is possible to induce the growth and proliferation of various marine organisms, and it is possible to prevent the marine ecosystem from becoming deserted while forming a natural pasture for marine life.

In another exemplary embodiment, the chelating composition injected and filled in the tube body 110 may further include a binder capable of binding these components in addition to the above-described humic material, pyrite, and organic feed. As the binder, a natural binder obtained from starch or seaweed may be used. At this time, the binder may be added in a proportion of about 1-5 parts by weight in the chelating composition.

3 is a view schematically showing a construction form of a floating artificial reef according to a second exemplary embodiment of the present invention. As shown in Figure 3, the floating artificial reef 200 according to the second embodiment of the present invention is a first tube (210a) connected to the first floating body (250a), the first floating body (250a) and spaced apart A second tube (210b) connected to the second floating body (250b) and a fixing body (250c) connected to the third floating body (250c) positioned between the first floating body (250a) and the second floating body (250b) 260). The fixture 260 may be a fixing rope, and the first to third fixtures 250a, 250b, and 250c may each be a buoy.

The first tube 210 and the second tube 220 are respectively injected and filled with a humic material, fossil fuel, organic feed and optionally a binder therein, and the first and second tube bodies 220a made of vinyl or plastic material; 220b) and first and second pin-holes 240a and 240b formed in plurality in the first and second tube bodies 220a and 220b at predetermined intervals. Although not shown, both ends of the first and second tube bodies 220a and 220b may be closed by a closing member 130 (refer to FIG. 2 ).

The upper end of the first tube 210a is connected to the first floating body 250a through the first connecting means 252a, and the lower end of the first tube 210a is a first anchor through the second connecting means 282a. (280a) is connected. The upper end of the second tube 210b is connected to the second floating body 250b through the third connecting means 252b, and the lower end of the second tube 210b is a second anchor through the fourth connecting means 282b. (280b). The upper end of the fixed body 260 is connected to the third floating body 250c through the fifth connecting means 252c, and the lower end of the fixed body 260 is connected to the third anchor 280c through the sixth connecting means 282c. ) is connected to The first to sixth connecting means 252a, 282a, 252b, 282b, 252c, and 282c may be clamps, fasteners, or fastening strings, respectively. In this case, a sea creature 270 such as scallops and oysters and/or sea squirts may be attached to the fixture 260 positioned between the first and second tubes 210a and 210b.

When the chelated complex formed by the reaction of the humic material charged in the first and second tubes 210a and 210b with the fossil fuel and organic feed flows out of the first and second tubes 210a and 210b, the first and Marine organisms attached to the fixture 260 installed between the second tubes 210a and 210b can ingest it. Accordingly, in the floating artificial reef 200, these marine organisms can induce the reproduction of these marine organisms while growing while consuming sufficient nutrients.

4 is a view schematically showing the construction form of a floating artificial reef according to a third exemplary embodiment of the present invention. As shown in Figure 4, the floating artificial reef 300 according to the third embodiment of the present invention is a first fixed body (360a, 360b) respectively connected to the first and second floating body (350a, 350b), A plurality of vertical meshes 390a, each of which is coupled to the second fixing body 362 and the second fixing body 362, in which the tube 310 is disposed, respectively, to the first fixing body 360a and 360b; 390b, 390c).

The upper ends of the first fixing bodies 360a and 360b are respectively connected to the first and second floating bodies 350a and 350b through first connecting means 352a and 352b, and The lower ends are respectively connected to the first and second anchors 380a and 380b fixed to the sea floor through the second connecting means 382a and 382b. The second fixture 362 may be coupled to the first fixtures 360a and 360b disposed to be spaced apart from each other. Each of the first fixtures 360a and 360b and the second fixture 362 may be a fixing tether.

A plurality of vertical meshes 390a, 390b, and 390c may be coupled to the second fixture 362 . A plurality of vertical meshes (390a, 390b, 390c) are the upper meshes 392a, 394a, 396a, the upper meshes 392a, 394a, and 396a respectively connected to the central meshes 392b, 394b, 396b, and the central mesh 392c , 394c, 396c). The upper ends of each of the upper meshes 392a, 394b, and 396a are connected to the second fixing body 362 through the first fastening means 364a, 366a, 366c. The upper meshes 392a, 392b, 392c and the central meshes 392b, 394b, 396b are connected through the second fastening means 364b, 366b, and 368b, and the central meshes 392b, 394b, 396b are the third fastening means. (364c, 366c, 368c). The first fastening means (364a, 366a, 366c), the second fastening means (364b, 366b, 368b) and the third fastening means (364c, 366c, 368c) may be fixed ropes that are respectively bound to the meshes constituting the mesh. .

Although the figure shows that the number of vertical meshes 390a, 390b, and 390c is three, the number of vertical meshes that can be connected to the second fixture 362 is not limited thereto, and 2-20 pieces, for example 2-10 vertical meshes may be connected to the second fixture 362 . In addition, although the number of meshes constituting each of the vertical meshes 390a, 390b, and 390c is also illustrated as being three, the number of meshes constituting each of the vertical meshes 390a, 390b, 390c is 2-10 days. can

In this case, shellfish (not shown) such as scallops may be inhabited in each of the meshes 392a, 392b, 392c, 394a, 394b, 394c, 396a, 396b, and 396c. According to the present embodiment, one or more tubes 310 are disposed inside each of the meshes 392a, 392b, 392c, 394a, 394b, 394c, 396a, 396b, 396c. The tube 310 is made of a vinyl or plastic material, and a chelating composition containing a humic material, fossilized stone, organic feed, and optionally a binder is injected and filled therein. It includes pin-holes 340 formed at intervals.

In this embodiment, when nutrients such as metals, minerals, and amino acids converted into a chelated complex state inside the tube body 320 flow out of the tube body 320 through the pin-hole 340, the tube ( 310) Shellfish that live nearby can grow by consuming these nutrients. In addition, odor components such as ammonia emitted by shellfish may react with the humic material to be chelated or may be trapped by pores inside the humic material.

5 is a view schematically showing the construction form of a floating artificial reef according to a fourth exemplary embodiment of the present invention. As shown in Figure 5, the floating artificial reef 400 according to the fourth embodiment of the present invention is a first fixed body (460a, 460b) respectively connected to the first and second floating body (450a, 450b), A plurality of vertical nets each having a second fixing body 462 coupled to the first fixing body 460a and 460b, respectively coupled to the second fixing body 462, in which a first tube 410a is disposed ( 490a, 490b) and a second tube 410b connectable to the second fixture 462 via the third fixture 460.

The upper ends of the first fixtures 460a and 460b are respectively connected to the first and second floats 450a and 450b through first connecting means 452a and 452b, and The lower ends are respectively connected to the first and second anchors 480a and 480b fixed to the sea floor through the second connecting means 482a and 482b. The second fixture 462 may be coupled to the first fixtures 460a and 460b that are spaced apart from each other. On the other hand, the upper end of the third fixing body 460 is connected to the second fixing body 462 through the first connecting means 452, and the lower end of the third fixing body 460 is connected to the third through the third connecting means. It may be connected to the anchor 480 . In addition, the second tube 420b may be connected to the third fixture 460 through the second connecting means 464 . In this case, the first fixing body (460a, 460b) and the second fixing body 362 may each be a fixing rope, and the first to third connecting means 452 and 464 may be a clamp, a fastener, or a fixing string, respectively. .

A plurality of vertical meshes 490a and 490b may be coupled to the second fixture 462 . A plurality of vertical meshes (490a, 490b) are upper meshes (492a, 494a) connected to the first fastening means (464a, 466a), the second fastening means (464b, 466b) through the upper meshes (492b, 494b). The central meshes 492b and 494b are connected, and the lower meshes 492c and 494c are connected to the central meshes 492b and 494b through the third fastening means 464c and 466c. The number of vertical meshes connected to the second fixture 462 and the number of meshes forming each vertical mesh may be changed. The first fastening means (464a, 466a), the second fastening means (464b, 466b) and the third fastening means (464c, 466c) may be fixed ropes that are respectively bound to the meshes constituting the mesh.

As in the third embodiment, shellfish (not shown) such as scallops can inhabit inside each of the meshes 492a, 492b, 492c, 494a, 494b, 494c, and one or more first tubes ( 410a) is placed.

The first tube 410a disposed inside the mesh and the second tube 410b connected to the third fixture 460 each have a chelating composition comprising a humic material, fossil fuel, organic feed and optionally a binder therein. The first and second tube bodies 420a and 420b to be injected and filled, and a plurality of first and second pin-holes 440a and 440b formed at predetermined intervals in the first and second tube bodies 420a and 420b. ) is included. The chelated complex synthesized inside the first tube 410a may be food for shellfish, etc. living in the first tube 410a, and odor components such as ammonia emitted by the shellfish etc. can The chelating complex synthesized inside the second tube 420b can be food such as plankton that inhabits near the second tube 410b, and forms a sequential food chain to induce the reproduction and proliferation of marine organisms. can

6 is a view schematically showing a cage farm in which a floating artificial reef according to an exemplary embodiment of the present invention is constructed. 7 is a view schematically showing the construction form of a floating artificial reef according to a fifth exemplary embodiment of the present invention.

6 and 7, the floating artificial reef 500 according to the fifth embodiment of the present invention includes one cell 510 constituting the cage farm. As an example, the cage farm cell 510 includes a scaffold 540 fixed through a first connecting means 532 on a grid-shaped pipe 520 in which a floating body 530 is formed at the lower portion, and the second It is connected to the floating body 530 or the footrest 540 through the connecting means 562, and includes a mesh 560 in which the tube 610 is disposed. If the tube 610 can be arranged inside the mesh 560, the structure and shape of the cage farm cell 510 can be changed.

As an example, the floating body 530 may be a floating pipe or a float, and a plurality of protrusions may be formed on the footrest 540 to prevent sliding. The first connecting means 532 and the second connecting means 562 may be clamps, fasteners, and fastening strings, respectively, but is not limited thereto. In another alternative embodiment, the float 530 may be one or more buoys 660 positioned inside the cage farm cell 510 . In this case, the tube body 620 may be connected to the buoy 660 through a fixing body 670 such as a fixing rope. The tube 610 may be connected to one end of the fixture 670 through a connecting means 672 such as, for example, a connecting clip 672 . Depending on the type of fish to be cultured, the position and height of the tube 610 may be adjusted by adjusting the length of the fixture 670 . Although not shown, marine organisms such as fish inhabit the inside of the net 560 . . On the other hand, the tube 610 disposed inside the mesh 560 is made of a vinyl or plastic material, and a chelating composition including a humic material, fossilized stone, organic feed, and optionally a binder is injected and filled in the tube body. 620 and a plurality of pin-holes 640 formed at predetermined intervals in the tube body 620 .

When the chelate complex formed by the reaction of the humic material, shell fossil, and organic feed inside the tube body 620 flows out of the tube body 620 in the form of a nutrient, marine organisms such as fish living inside the mesh 560 are ingested. Thus, it is possible to prevent the marine ecosystem from becoming desertified by inducing the growth and reproduction of these marine organisms. In addition, since the mineral component in seawater reacts with the organic ligand constituting the humic material and is transformed into a chelated complex, the problem of de-whitening of seawater can be solved. In addition, humic substances capture odor components such as ammonia emitted by marine organisms such as fish, thereby solving marine pollution caused by these odor components.

8 is a view schematically showing a construction form of a floating artificial reef according to a sixth exemplary embodiment of the present invention. 9 is a view schematically showing a state in which a tubular artificial reef is mounted between shelters for aquaculture according to a sixth exemplary embodiment of the present invention.

8 and 9, the floating artificial reef 600 according to the sixth embodiment of the present invention includes one cell 510 constituting the cage farm. As an example, the cage farm cell 610 includes a scaffold 540 fixed through a first connecting means 532 on a grid-shaped pipe 520 in which a floating body 530 is formed at the lower portion, and the second A net ( 560). If the shell 580 and tube 610 for aquaculture in which shellfish such as abalone can be inhabited can be disposed inside the net 560, the structure and shape of the cage farm cell 510 can be changed.

A shelter 580 for aquaculture in which shellfish such as abalone inhabits is disposed inside the mesh 560 , and a tube 610 is connected to the shelter 580 for aquaculture between the shelters 580 for aquaculture. Referring to FIG. 9 , the shelter 580 for aquaculture extends long and includes a shelter body 582 that may be made of a plastic material, a first through portion 584 formed at an end of the shelter body 582 , and a shelter body 582 . ) and includes a plurality of second through-portions 586 formed at a predetermined interval on the upper surface. A space in which shellfish such as abalone can inhabit is provided in the shelter body 582 .

The plurality of shelter bodies 582 are respectively connected through a fixing frame 590 penetrating a groove (not shown) formed on the side surface of the shelter body 582 . In addition, the fixing frame 590 having the outermost bent shape is connected to the mesh 560 through the third connecting means 564, respectively.

Meanwhile, a tube 610 is disposed between the shelter bodies 582 . The tube 610 is made of a vinyl or plastic material, and a chelating composition containing a humic material, fossil fuel, organic feed, and optionally a binder is injected and filled therein with the tube body 620 and the tube body 620 . It includes a plurality of pin-holes 640 formed at predetermined intervals. The tube body 620 is connected to the adjacent shelter body 582 through a fourth connecting means 650 . In this case, the third connecting means 564 and the fourth connecting means 650 may be clamps, fasteners, and fixing strings.

When the chelate complex formed by the reaction of the humic material, shell fossil and organic feed inside the tube body 620 flows out of the tube body 620 in the form of a nutrient, nutrition through the first and second penetration parts 582 and 584 The material flows into the shelter body 582. The shellfish living inside the shelter body 582 can induce the growth and reproduction of shellfish while ingesting nutrients, thereby preventing the marine ecosystem from becoming desertified. can In addition, since the mineral component in seawater reacts with the organic ligand constituting the humic material and is transformed into a chelated complex, the problem of whitening of seawater can be solved. In addition, humic substances capture odor components such as ammonia emitted by shellfish, thereby solving marine pollution caused by these odor components.

Hereinafter, the present invention will be described with reference to exemplary embodiments, but the present invention is not limited to the technical ideas described in the examples.

Example 1: Humic acid extraction and preparation

Bitumen powder pulverized to a size of 0.05-0.5 mm is put in a reactor, water and 5-30% (w/v) of an alkalizing agent are added, and then reacted under stirring at 80-120° C. and atmospheric pressure for 24 hours. The humic material was extracted. The extracted humic material was separated according to the specific gravity separation method to separate humic acid and fulvic acid. The separated humic acid and fulvic acid are placed in a pressure tank with high heat of 200-260°C and high pressure of 200-600 kgf/cm 2 It was quenched at -30℃~-20℃. This process was repeated several times to extract and prepare humic acid and fulvic acid. Among the extracted humic substances, the moisture content was 5-10 wt%, the humic acid content was 66-34 wt%, and the fulvic acid content was 7 wt%.

The molecular structure of the humic acid prepared in the present embodiment was analyzed by an external agency. Figure 10a is an electron microscope image of the humic acid powder, Figure 10b is an electron microscope image for EDS analysis of the humic acid powder, Figure 11 is a graph showing the EDS analysis results of the humic acid powder. Meanwhile, Table 1 below shows the EDS analysis results for the humic acid powder.

EDS analysis of humic acid powder element line Apparent Concentration k ratio weight% atom% standard label O K 14.39 0.04842 61.68 74.91 SiO ₂ Al K 1.58 0.01134 9.82 7.07 Al ₂ O ₃ Si K 3.55 0.02811 23.06 15.96 SiO ₂ Ca K 0.23 0.00201 1.25 0.60 Wollastoite Fe K 0.64 0.00649 4.19 1.46 Fe

As can be seen from these results, the pores of the humic acid powder form a phase formed in 6 directions. That is, in the molecular structure of the humic acid powder, voids were present before, after, left and right, and above and below each unit powder. In particular, 61.6% of oxygen, a component of humic acid, is present in the pores, so it is expected that the specific gravity is light and the gas to be deodorized can be quickly absorbed. That is, by using humic acid powder, odor components such as ammonia and hydrogen sulfide contained in the excrement of marine organisms were captured and chelated in the pores, and it was confirmed that the odor components could be decomposed and deodorized quickly.

Example 2: Evaluation of ripening ability of humic acid powder

(1) Assessing pig house sludge infertility

The moisture content was adjusted to 50-60% by mixing the solid material (water content about 70-90%) from dewatered pig pig sludge and organic feed (water content about 13%) obtained by corroding and processing food waste in a 1:1 ratio. The humic acid powder containing the decomposing enzyme was mixed with 10-30% by weight to deodorize, and the pig sludge was completely aged at 40-70°C for 20-60 days. As a result of evaluating the degree of maturation of the aged pig house sludge to an external institution, it was confirmed that it was fully aged.

(2) Deodorization and purification ability evaluation

10-30 parts by weight of the humic acid powder extracted in Example 1 and 10-30 parts by weight of shell fossil powder compared to the leachate were administered to the septic tank leachate, and the deodorization and purification ability was evaluated. Four septic tanks were filled with 20-30 parts by weight of leachate and deodorized by stirring slowly, and humic acid powder and shell fossil powder were filled in a ratio of about 1:1 in a filtration tank connected to the last septic tank and filtered. The analysis results are shown in Table 2. It was confirmed that the humic acid powder and the shell fossil powder reacted and the metal component contained in the shell fossil was chelated, and the content of harmful ingredients was low, so that it could be used as feed or fertilizer for living things to be ingested.

Leachate purification ability evaluation Analysis item (unit) standard result specification content Nitrogen total (%) Total amount of each ingredient 0.11 Total amount of phosphoric acid (%) 0.3% or more, each component 0.005 Total amount of potassium (%) guarantee the content 0.10 harmful ingredients Arsenic (mg/kg) 5 or less - Cadmium (mg/kg) 0.5 or less - Mercury (mg/kg) 0.2 or less - Lead (mg/kg) 15 or less 0.05 Chromium (mg/kg) 30 or less 0.04 Copper (mg/kg) 50 or less - Zinc (mg/kg) 130 or less - Nickel (mg/kg) 5 or less - E. coli O157:H7 - - Salmonella - - other standards salt(%) 0.3 or less 0.07 Moisture content (%) 95 or more 99.68

Example 3: Analysis of feed effect of chelating composition

Water is added to the solid chelating composition and solid feed obtained by fermenting and fermenting the chelating composition consisting of 50 to 60% by weight of organic feed obtained by erosion and processing of food, 10 to 30% by weight of humic acid powder, and 10 to 30% by weight of shell fossil powder. The applicability of the liquid chelating composition mixed and compressed in a 1:1 weight ratio as a feed was evaluated. Table 3 shows the results of analyzing the contents of calcium and amino acids after the solid chelating composition was corroded, and Table 4 shows the results of analyzing the contents of calcium and amino acids after the liquid chelating composition was corroded. It was confirmed that mineral components and amino acids react with humic substances to be chelated while ripening, and exist in a form that can be ingested and absorbed by marine organisms.

Analysis of mineral and amino acid content after corrosion of solid phase chelating composition Ingredients (units) Analysis Ca (%) 5.59 Total Amino Acids (%) 2.04 ASP 0.18 THR 0.1 SER 0.12 GLU 0.35 GLY 0.19 ALA 0.15 VAL 0.11 ILE 0.06 LEU 0.16 TYR 0.04 PHE 0.16 LYS 0.07 HIS 0.04 ARG 0.07 PRO 0.07 CYS 0.08 MET 0.09

Analysis of mineral and amino acid content after corrosion of liquid chelating composition Ingredients (units) Analysis Ca (%) 0.65 Total Amino Acids (%) 0.89 ASP 0.09 THR 0.05 SER 0.07 GLU 0.19 GLY 0.06 ALA 0.06 VAL 0.04 ILE 0.03 LEU 0.07 TYR 0 PHE 0.1 LYS 0.03 HIS 0.03 ARG 0.03 PRO 0 CYS 0.03 MET 0.01

In the above, the present invention has been described based on exemplary embodiments and examples of the present invention, but the present invention is not limited to the technical ideas described in the following examples. Those skilled in the art to which the present invention pertains will be able to easily conceive of various modifications and changes based on the above-described embodiments and examples. However, it is apparent from the appended claims that such modifications and variations fall within the scope of the present invention.

100, 200, 300, 400, 500, 600: floating artificial reef
110, 210a, 210b, 310, 410a, 410b, 610: tube
120, 220a, 220b, 320, 420a, 420b, 620: tube body
130: closing member
140, 240a, 240b, 340, 440a, 440b, 640: pin-hole
150, 250a, 250b, 250c, 350a, 350b, 530, 660: floating body
152, 162, 172, 252a, 252b, 252c, 352a, 352b, 452, 452a, 452b, 552, 562, 564, 650, 662: connecting means
160, 260, 360a, 360b, 362, 460a, 460b, 462, 670: fixed body
270: marine life
364a, 364b, 364c, 366a, 366b, 366c, 368a, 368b, 368c, 464a, 464b, 464b, 466a, 466b, 466c: binding means
390a, 390b, 390c, 490a, 490b: vertical mesh
392a, 394a, 396a, 492a, 494a: upper mesh
392b, 394b, 396b, 492b, 494b: central mesh
392c, 394c, 396c, 492c, 494c: lower mesh
160, 260, 360, 360a, 360b, 362: fixed body
180, 280a, 280b, 280c, 380a, 380b, 480a, 480b: anchor
510: cage farm shell
520: pipe
540: scaffold
560: net
580: shelter

Claims (10)

floating body; and
A tube body connected to the floating body, a plurality of pin-holes formed in the tube body, and a tube containing a chelating composition injected into the tube body,
The chelating composition comprises a humic material selected from the group consisting of humic acid, fulvic acid, ulmic acid, and combinations thereof, shell fossils and organic feed,
The humic material is a humic material extracted from the carbonaceous powder using a solvent in a vacuum pressure tank at a temperature of 200 ~ 260 ℃ and a pressure of 200 ~ 600 kgf / ㎠, after opening the pressure tank, -20 ~ Floating artificial reef, characterized in that obtained by cooling at a temperature of -30 ℃.
delete The floating artificial reef according to claim 1, wherein the pin-holes are formed at intervals of 3-20 cm in the tube, and the pin-holes have a size of 0.1-2 mm.
[Claim 2] The floating artificial reef according to claim 1, wherein the organic feed is obtained by hanging food waste composed of leftover food, slaughter residues, food by-products, and combinations thereof.
The floating artificial reef according to claim 1, further comprising a first fixed body connecting the floating body and the tube body and a bunch connected to the first fixed body.
The method according to claim 1, wherein the floating body includes a first floating body connected to the tube and a second floating body positioned adjacent to the first floating body, and connected to the second floating body, including shellfish, sea urchin and sea urchin; Floating artificial reef further comprising a fixture to which at least one marine creature selected from among the sea is attached.
floating body; and
A tube body connected to the floating body, a plurality of pin-holes formed in the tube body, and a tube containing a chelating composition injected into the tube body,
The chelating composition comprises a humic material selected from the group consisting of humic acid, fulvic acid, ulmic acid, and combinations thereof, shell fossils and organic feed,
A plurality of first fixtures connected to the floating body, a second fixture connecting the first fixtures, and a plurality of meshes connected to the second fixtures, wherein the tube is disposed in the meshes floating artificial reef.
8. The method of claim 7, further comprising a tube body connected to the second fixture, a plurality of pin-holes formed in the tube body, and a second tube containing the chelating composition injected into the tube body. floating artificial reef.
floating body; and
A tube body connected to the floating body, a plurality of pin-holes formed in the tube body, and a tube containing a chelating composition injected into the tube body,
The chelating composition comprises a humic material selected from the group consisting of humic acid, fulvic acid, ulmic acid, and combinations thereof, shell fossils and organic feed,
The floating body includes a floating means of the cage farm, and further includes a mesh connected to the floating means or scaffold constituting the cage farm, and the tube is a floating artificial reef that is disposed inside the mesh.
The floating artificial reef according to claim 9, further comprising a shelter for aquaculture connected to the net, wherein the tube is connected to the shelter for aquaculture.

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