JP2004201557A - Rearing apparatus for underwater organism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rearing apparatus for underwater organisms, which solves problems that water purification in a fish-breeding pond is deteriorated and proliferation of nitrifying bacteria is controlled and an environment suitable for fish rearing is not produced. <P>SOLUTION: The rearing apparatus for underwater organisms has constitution that rearing water is flown in the fish-breeding pond 31 of pisciculture facilities 30 by the drive of a circulation pump 36 to rear fishes in the fish-breeding pond 31. In the rearing apparatus, a magnetism apparatus A for fractionating cluster in the rearing water flowing at a fixed velocity by magnetic force is laid in a flowing pipe conduit for the rearing water, the rearing water is passed in two kinds of non-metal inside and outside tubes 24B and 24A to make an environment suitable for rearing fishes in the fish-breeding pond 31. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention provides a method for breeding aquatic organisms in a breeding water area in a breeding water area in a breeding facility such as a fish farm, a live fish breeding facility, a goldfish breeding facility, and an ornamental aquarium facility such as an aquarium. The present invention relates to a breeding device for underwater organisms.
[0002]
[Prior art]
The principle of circulating filtration ponds in breeding facilities such as fish breeding facilities, live fish breeding facilities, ornamental underwater creature facilities, and goldfish breeding facilities is based on the principle that wastewater from the breeding ponds is first led to a sedimentation tank to remove solid organic matter, and then filtered. The dissolved organic matter is oxidized and decomposed by aerobic bacteria through a tank, and then injected again into a breeding pond to breed fish.
[0003]
In a circulation filtration pond, phytoplankton in pond water cannot be used for water purification or oxygen supplementation. Therefore, most of the treatment of organic substances is performed in a filtration tank or a precipitation tank, and replenishment of oxygen is performed by aeration using mechanical force or a head.
[0004]
Therefore, in the circulation filtration pond, the ammonia in the water generated during the mineralization process of nitrogen-containing organic matter contained in the dung and remaining food of the breeding fish, and excreted directly from catfish and kidneys (urine) is collected in the filtration tank. In the process of passing through the filter medium, nitrifying bacteria grown on the surface of the filter medium are oxidatively decomposed into nitrite and then nitrate. Nitrifying bacteria require molecular oxygen to grow and express their activity.
[0005]
Therefore, when passing through the filtration tank, if the dissolved oxygen in the filtered water is scarce, the growth and activity of nitrifying bacteria are inhibited, and the oxidation reaction of ammonia nitrogen does not progress, resulting in accumulation in the water as it is. Become. The organic matter decomposition activity of the bacterial group in the filter bed is almost constant at any depth irrespective of the depth of the filter bed, but the activity of the nitrification reaction is highest in the surface layer of the filter bed.
[0006]
From the above, it is important to increase the amount of dissolved oxygen by aerating the filtered water (breeding water) well before passing through the filter bed. To achieve the purification effect with the same amount of filter material, It is said that reducing the depth and increasing the surface area are effective.
[0007]
In addition, in the ornamental aquarium which is a closed system water area, various germs easily grow. Germs are one of the causes of fish diseases and must be removed in order to maintain fish health and maintain an ornamental effect.
[0008]
On the other hand, it is known that magnetic processing can be used for improvement in a wide range of fields such as liquid reforming. The reason is that in the flow of liquid, a so-called Lorentz force is generated by applying a magnetic field at right angles, and this Lorentz force breaks down liquid molecules, acts on charged particles, and separates liquid molecules from charged particles. Therefore, since the structure of the arrangement and distribution of various atoms in the liquid changes and the properties of the liquid change, the density, surface tension, viscosity, dielectric constant, electrolyte dissolution rate, etc. increase, Alternatively, various effects such as an increase in electric conductivity, gas solubility, and the like are caused to activate the liquid.
[0009]
Magnetically treated water or liquids mainly composed of water, or magnetic water, which is an organic liquid containing these liquids, is used for water, red water for pipes, measures against red rust and scale, sludge control, promotion of plant growth in agriculture and horticulture. It is known that it can be used in a wide range of fields, such as preserving the freshness of food in food production, promoting aquaculture of fish and shellfish, and improving fuel efficiency by reforming fuel oil.
[0010]
A conventional magnetic processing apparatus that forms and applies a simple magnetic field to a flow of a liquid to be processed including charged particles such as various positive and negative ions and charged fine particles is disclosed in FIG. 9 and FIG. There are techniques.
[0011]
The disclosed technology has first and second divided bodies 50A and 50B, and the first divided body 50A includes a case 51 made of a synthetic resin. A semicircular groove 52 is formed, and a permanent magnet 53 is fixed to the bottom of the case 51.
[0012]
The second divided body 50B includes a case 54 made of a synthetic resin, and a semicircular groove 55 is formed in opposing surfaces of the case 54, and a permanent groove is formed in the bottom of the case 54. A magnet 56 is fixed.
[0013]
Then, the first divided body 50A and the second divided body 50B are sandwiched by a metal tube 60 through which water to be treated flows (the first and second divided bodies 50A and the grooves 52B of the 50B). , 55 are inserted into the circular hole formed by the pipe 55).
[0014]
Further, the present applicant has previously proposed in Japanese Patent Application No. 10-149225 a harmful substance treatment device for exhaust gas which forms and applies a magnetic field perpendicular to the flow of liquid fuel containing molecules of mineral components, Further, in Japanese Patent Application No. 2000-6684, harmful substances such as carbon monoxide (CO), hydrocarbons (HC) and nitrogen oxides (NOX), and black smoke in exhaust gas emitted from automobiles and the like are reduced. A device for treating harmful substances in exhaust gas has been proposed. In Japanese Patent Application No. 2001-183394, carbon monoxide (CO), hydrocarbon (HC), sulfur oxide (SOx) and We have proposed an emission control system by activating liquid fuel to reduce harmful substances such as nitrogen oxides (NOx) and black smoke.
[0015]
[Problems to be solved by the invention]
The above-described conventional magnetic processing apparatus has a state in which a metal pipe body 60 through which water is to be treated is sandwiched (the first and second divided bodies 50A and 50B have circular holes formed by grooves 52 and 55). The pipe 60 is inserted into the magnetic processing apparatus itself, and the magnetic processing apparatus itself does not have a connection pipe. In addition, there is no magnetic processing holding case and no magnetic induction closed circuit is formed, and it is merely a configuration in which the permanent magnets 53 and 58 face each other.
[0016]
Further, the above-mentioned conventional magnetic processing apparatus uses a connection pipe for flowing the liquid fuel in order to expose the flow of the liquid fuel to a magnetic field. As a result of diligent research, the applicant of the present invention has decided to use two inner and outer pipes made of non-ferrous metal made of a non-magnetic substance having a high ionization tendency or a substance having a low ionization tendency as this connection pipe. As a result, the reforming of liquid fuel was found, and the liquid molecules were further subdivided.
[0017]
Then, the fragmentation of the liquid molecules in the conventional magnetic processing apparatus, the breeding water is allowed to flow into the breeding water area of the breeding facility, and the underwater creature breeding apparatus is designed to breed the underwater creatures in this breeding water area. It has been found that the application can make the breeding facility an environment suitable for breeding underwater organisms.
[0018]
An object of the present invention is to provide a breeding apparatus for aquatic organisms capable of subdividing clusters of the breeding water flowing at a predetermined flow rate by magnetic force to make the breeding water area an environment suitable for breeding of aquatic organisms. It is in.
[0019]
[Means for Solving the Problems]
In order to achieve the above object, the underwater breeding apparatus according to the present invention is configured to raise water for breeding in a breeding water area of a breeding facility by driving a water pump to breed the aquatic organisms in the breeding water area. A breeding apparatus for underwater creatures, wherein a magnetic processing device is provided in a breeding water flow pipe to subdivide clusters of breeding water flowing at a predetermined flow rate by magnetic force, and the inside of the breeding water area is provided with an underwater creature. The environment is suitable for breeding.
[0020]
With this configuration, in the breeding apparatus for aquatic organisms, by applying magnetic force to the breeding water by the magnetic treatment device, the cluster of the breeding water flowing at this predetermined flow rate is subdivided by the magnetic force, and the phytoplankton in the breeding water area is crushed. Can promote water purification, and can also promote the oxidation reaction of ammonia nitrogen by growing nitrifying bacteria and expressing its activity, and also suppress the growth of various bacteria by ionizing the breeding water. The breeding water area can be made an environment suitable for breeding underwater organisms.
[0021]
Further, in the underwater breeding apparatus according to the present invention, in the underwater breeding apparatus according to the above-described present invention, the magnetic processing device is configured to hold one anisotropic magnetic body of a square cube and one magnet made of a magnetic body. One of the magnetic processing bodies housed in the case and the other anisotropic magnetic body of the angular cube are housed in the other magnet holding case made of a magnetic material, and the other magnet holding case is provided with the one magnet holding case. And a magnetic treatment body connected to one of the magnetic treatment bodies by magnetic attraction so as to form a magnetic induction double pole closed circuit at the joint, and breeding water is provided at the joint between the one and the other magnet holding cases. Sandwiching a connecting pipe made of a non-magnetic material that flows, magnetically attracts each other at the joint, and makes one and the other magnet holding case a part of a magnetic induction double-pole closed circuit, and one anisotropic magnetic body. With the other anisotropic magnetic body It is intended to apply the magnetic field to breeding water to form a right angle field to the flow of rearing water in between the magnetic poles.
[0022]
With this configuration, a flow rate of, for example, 1.2 m to 1.6 m per second is given to the breeding water, so that a metal element (calcium) contained in the breeding water in a trace amount is provided in a conduit (connecting pipe) through which the breeding water flows. Static electricity (for example, 0.06 mA at 1.2 m / s, 0.08 mA at 1.6 m / s) is generated on a charged body (charged particles) such as sodium, magnesium, potassium, aluminum, iron, and titanium; A potential difference is generated between the outer tube and the inner tube in the connecting tube to make the ionic bond unstable, and between the magnetic poles of one anisotropic magnetic body and the other anisotropic magnetic body. For example, an electromotive force is generated by applying magnetism of a magnetic field of 4000 gauss to 8000 gauss to the connecting pipe, and the charged body can be ionized by reacting with the + ions of the material of the connecting pipe.
[0023]
In this way, the breeding water can be subdivided into clusters of the breeding water by magnetic force, flow and potential difference to promote water purification by phytoplankton in the breeding water area, and also to grow nitrifying bacteria and increase their activity. To promote the oxidation reaction of ammonia nitrogen and suppress the propagation of various bacteria by ionizing the breeding water, thereby making the breeding water area an environment suitable for breeding underwater organisms.
[0024]
Also, in the underwater breeding apparatus according to the present invention, in the underwater breeding apparatus according to the above-described present invention, the connecting pipe is formed of a non-ferrous metal outer pipe, and the outer pipe is housed inside the outer pipe. A flow path extending from the inlet side to the outlet side of the connecting pipe is formed between the outer pipe and the inner pipe made of a different non-ferrous metal. There is a difference (potential difference) between the potential (H = 0 V reference standard potential) of each of the two types of non-ferrous metals between the tube and the tube.
[0025]
Further, in the underwater breeding device according to the present invention, in the underwater breeding device according to the above-described present invention, the outer tubular body has a monopolar potential of a positive potential, a monovalent and a divalent or trivalent physicochemical. The inner tube is made of a non-ferrous metal tube having a physicochemical property of a negative potential with a monopolar potential of minus.
[0026]
Further, in the underwater breeding apparatus according to the present invention, in the underwater breeding apparatus according to the present invention, when the two types of non-ferrous metals are gold (Au) and titanium (Ti), platinum (Pt) and platinum (Pt) are used. One of the cases of titanium (Ti).
[0027]
With this configuration, a difference (potential difference) between the potentials (H = 0 V reference standard potential) of each of the two types of non-ferrous metals can be reliably generated. For this reason, the ionic bond of breeding water can be made more unstable.
[0028]
The breeding apparatus for aquatic organisms according to the present invention is the breeding apparatus for aquatic organisms according to the present invention described above, further comprising a breeding water circulation system having the water pump for circulating the breeding water in the breeding water area. A zeolite filter is disposed in a water circulation system, and the breeding water that has passed through the magnetic treatment device is filtered by the zeolite filter and circulated to the breeding water area by driving the water pump.
[0029]
By such a configuration, in addition to the function of subdividing the breeding water clusters by magnetic force, flow, and potential difference, the cation exchange function of zeolite can be added, and the adsorption function can be added, and phytoplankton in the breeding water area can be added. Water purification can be promoted, and nitrifying bacteria proliferate and express their activity to promote the oxidation reaction of ammonia nitrogen, and also suppress the growth of various bacteria by ionizing breeding water, The breeding water area can be made an environment suitable for breeding underwater organisms.
[0030]
Further, the underwater breeding apparatus according to the present invention is the underwater breeding apparatus according to the above-described present invention, wherein the breeding facility is a fish breeding facility, a live fish breeding facility, a goldfish breeding facility, an ornamental aquarium facility such as an aquarium, or the like. It is.
[0031]
With such a configuration, in a breeding facility such as a fish breeding facility, a live fish breeding facility, a goldfish breeding facility, and an ornamental aquarium facility such as an aquarium, the magnetic processing device applies magnetic force to the breeding water, so that the water flows at the predetermined flow rate. The breeding water clusters can be subdivided by magnetic force to promote water purification by phytoplankton in the breeding waters. Also, nitrifying bacteria can proliferate and express their activity to oxidize ammonia nitrogen. In addition, the propagation of various bacteria can be suppressed by ionizing the breeding water, and the breeding water area can be made an environment suitable for breeding underwater organisms.
[0032]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0033]
FIG. 1 is a configuration explanatory view of an underwater breeding apparatus according to the present invention, FIG. 2 is a perspective view of a magnetic processing apparatus, FIG. 3 is a side view of the magnetic processing apparatus, and FIG. 4 is along the line XX in FIG. It is sectional drawing.
[0034]
The magnetic processing apparatus A has a magnetic processing main body A-1 as shown in FIGS. 2 to 6, and the magnetic processing main body A-1 has one magnetic processing body 1 and the other magnetic processing body 2 And a connection pipe 24.
[0035]
One magnetic processing body 1 and the other magnetic processing body 2 have the same configuration. The one magnetic processing body 1 has a magnet holding case 3 which is one box-shaped magnet holding case made of a soft iron material. The magnet holding case 3 has a bottom surface 3A and a left and right surface 3B. 3C and front and rear portions 3D and 3E. Further, semicircular grooves 6 are formed at the edges of the front and rear surfaces 3D and 3E. On the inner surface of the bottom portion 3A of the magnet holding case 3, a quadrangular prism-shaped permanent magnet 7, which is one anisotropic magnetic body of a square cube, is fixed. A filler 8 made of a synthetic resin, for example, an epoxy resin, which is a magnetic material, is filled, and a permanent magnet 7 is exposed at the center of the filler 8. In this case, the corners of the magnet holding case 3 are rounded at a bending angle of 56 degrees or more to prevent magnetic leakage.
[0036]
The other magnetic processing body 2 has the same configuration as the one magnetic processing body 1, but is given a different symbol for convenience of explanation. That is, the other magnetic processing body 2 has a magnet holding case 3-1 which is the other box-shaped magnet holding case made of a soft iron material, and the magnet holding case 3-1 has a bottom surface portion 3A-1. And left and right surfaces 3B-1, 3C-1 and front and rear surfaces 3D-1, 3E-1. Further, semicircular grooves 6-1 are formed at the edges of the front and rear surfaces 3D-1 and 3E-1. On the inner surface of the bottom surface 3A-1 of the magnet holding case 3-1 is fixed a quadrangular prism-shaped permanent magnet 7-1 which is the other anisotropic magnetic body of the rectangular cube. A non-magnetic filler 8-1 made of a synthetic resin, for example, an epoxy resin is filled in 3-1. A permanent magnet 7-1 is exposed at the center of the non-magnetic filler 8-1.
[0037]
The magnetic processing main body A-1 connects the one magnetic processing body 1 and the other magnetic processing body 2 to each other with a connection pipe 24 made of a non-magnetic substance through which a liquid to be processed flows. Be composed.
[0038]
The connection pipe 24 includes an outer pipe 24A and an inner pipe 24B as an inner container. The outer tube 24A is made of a non-ferrous metal made of a substance having a high ionization tendency or a substance having a low ionization tendency.
[0039]
Gold (Au), platinum (Pt), or the like is applicable as the substance having a low ionization tendency. A tube made of gold (Au) or platinum (Pt) can be used. In particular, gold (Au) can be used. ) Indicates that the monopolar potential has monovalent, divalent, or trivalent physicochemical properties, so that gold tubes made of gold (Au) are respectively provided on the outer tube 24A. Used. Joint portions 9 are provided on both sides of the outer tube 24A.
[0040]
As the inner tube 24B, a non-ferrous metal tube having a physicochemical property such that titanium (Ti), tungsten (W) or the like has a monopolar negative potential is used.
[0041]
Then, in a state where the inner tube 24B is concentrically accommodated in the outer tube 24A, the opposing portions are crushed at the center of the outer tube 24A, and the inner tube 24B is crushed by these crushed portions 30. The inner tube 24B is concentrically housed and fixed in the outer tube 24A by being sandwiched. In this case, an outer flow path 31 is formed between the inner and outer pipes 24B and 24A except for the crushed portion 30, and an inner flow path 32 is formed in the inner pipe 24B. It is formed.
[0042]
As shown in FIG. 4, one magnetic processing body 1 and the other magnetic processing body 2 are fitted together at joints (edges) 3a, 3a-1 of the magnet holding cases 3, 3-1. Further, the connection pipe 24 penetrates a circular hole which is a pipe sandwiching portion formed by the semicircular grooves 6 and 6-1, and the permanent magnet 7 of one magnetic processing body 1 and the other magnetic processing body 2 Of the permanent magnet 7 is an S pole, and the opposite end 7a-1 of the permanent magnet 7-1 is an N pole. .
[0043]
In this case, the magnet holding cases 3, 3-1 constitute a continuous frame, and this frame forms a part of a so-called magnetic circuit. That is, the magnetic flux density is high (4000 gauss to 8000) from the facing end (S pole) 7a of the permanent magnet 7 of the one magnetic processing body 1 to the facing end (N pole) 7a-1 of the permanent magnet 7-1. A magnetic field (Gauss) is formed, and the two lines of magnetic force F penetrate the connecting pipe 24, pass through the frame 10, and are converged on the permanent magnet 7 to form a magnetic circuit (inductive magnetic double pole closed circuit).
[0044]
In the case of this magnetic circuit, since the corners of the magnet holding cases 3 and 3-1 are rounded at a bending angle of 56 degrees or more, the magnetic efficiency is improved by eliminating magnetic leakage and forming a closed circuit. I have.
[0045]
The lines of magnetic force F generated in the magnetic circuit penetrate through the connecting pipe 24 and flow through the connecting pipe 24 as a fluid to be processed (a fluid to be processed including various positive and negative ions and charged fine and charged particles). A magnetic field perpendicular to the flow is formed and applied.
[0046]
Therefore, when a magnetic field is applied at right angles to the flow of the fluid to be treated including various positive and negative ions and charged fine charged particles, so-called Lorentzka is generated, and the fluid molecules and the charged particles move relative to each other. In addition, collisions occur, and the structure such as the arrangement and distribution of various atoms in the fluid to be processed changes, and the properties of the fluid change, resulting in density, surface tension, viscosity, dielectric constant, and electrolyte dissolution rate. Or various effects such as an increase in electric conductivity, gas solubility, and the like.
[0047]
As shown in FIG. 1, a fish cultivation facility 30 as a breeding facility for underwater creatures includes a fish ponds (breeding tank) 31 such as a fry pond, a training pond, a parent fish pond, and a stock ponds as a breeding water area, and the fish ponds 31. And a breeding water circulation system 35 for circulating breeding water (fresh water or seawater). The fishpond 31 is circular, and the bottom 32 is formed in the lowest conical shape at the center. A drain 33 is provided at the center of the bottom 32. A zeolite filter 42 is provided on the inner peripheral portion of the peripheral wall 31a of the fishpond 31. The zeolite filter 42 is constituted by, for example, filling a cage 43 with a large number of zeolites (zeolites) 44. A water injection pipe 41 is disposed above the peripheral wall 31 a of the fishpond 31, and the water injection port 34 of the water injection pipe 41 is located immediately above the zeolite filter 42.
[0048]
Zeolite is a hydrated silicate of aluminum containing alkali metals such as sodium, potassium and calcium, and alkaline earth metals. It is supplemented with positively charged alkali metal and alkaline earth metal.This type of cation can move relatively freely in voids and pores, so it comes into contact with solutions containing different cations. Then exchange with each other. This is the reason why zeolite can be used as a cation exchange agent, and is generally represented by the value of base substitution capacity (CEC).
[0049]
In addition, zeolite has much more water of crystallization than other minerals, and this water of crystallization is not released at once when heated, but is almost continuously dehydrated. Since the structure becomes porous without being destroyed, the voids and pores passing through vertically and horizontally have a structure like a sponge, and adsorb moisture and various gases. Therefore, the dehydrated zeolite becomes an adsorbent.
[0050]
Many pores and pores existing in the zeolite are not so coarse, and the diameters of the pores and pores are 3 to 6 angstroms (1 angstrom is one hundred millionth of a centimeter) and are generally fixed depending on the type. Depending on the size of the voids and pores, molecules can be sieved and used as an adsorbent or a separating agent.
[0051]
The breeding water circulation system 35 has a circulation pump 36, which is a water pump, and a filter 37. The suction side 36b of the circulation pump 36 is connected to the outlet side 37b of the filter 37 via a pipe 38. The inlet side 37a of the filter 37 is connected to the drain 33 of the fishpond 31 via a pipe 39. The discharge side 36 a of the circulation pump 36 is connected to a water injection pipe 41 via a pipe 40.
[0052]
The pipes 38, 39, and 40 constitute a part of a circulation pipe as a flow pipe, and the magnetic processing apparatus A is disposed in the pipe 40. The arrangement of the magnetic processing apparatus A in the pipe 40 is performed by connecting the magnetic processing apparatus A to the pipe 40 using the joint 9 of the connection pipe 24 of the magnetic processing apparatus A.
[0053]
Therefore, the breeding water filtered by the filter 37 by the driving of the circulation pump 36 falls from the water injection pipe 41 to the zeolite filter 42 via the pipe 40. In this case,
The breeding water passes through the magnetic treatment device A. The breeding water dropped on the zeolite filter 42 is further filtered by the zeolite 44 and then injected into the fishpond 31. The breeding water in the fishpond 31 enters the filter 37 from the drain port 33 via the pipe 40, is filtered by the filter 37, is sucked into the suction side of the circulation pump 36, and is circulated.
[0054]
When the breeding water passes through the magnetic processing apparatus A, the breeding water having charged particles as the fluid to be processed passes at a constant flow rate at a right angle at a magnetic field of 4000 to 8000 Gauss. For this reason, the breeding water clusters are fragmented, and the charged particles having higher conductivity are ionized. In particular, ionizable metal elements such as potassium, calcium, and magnesium undergo repetitive motion when permeated by a magnetic field, and these ionizable metal elements are released from the binding substance to produce anions and cations, that is, magnetic decomposition. Then, as described above, the properties of the breeding water change, and various effects such as an increase in density, surface tension, viscosity, dielectric constant, dissolution rate of the electrolyte, or an increase in electric conductivity, gas solubility, etc. Occurs.
[0055]
By applying a flow rate of 1.2 m to 1.6 m per second to the breeding water, metal elements (calcium, sodium, magnesium, potassium, aluminum, etc.) contained in the breeding water in a trace amount are formed in the connecting pipe 24 through which the breeding water flows. Static electricity (0.06 mA at a flow rate of 1.2 m / s, 0.08 mA at a flow rate of 1.6 m / s) is generated on a charged body (charged particle) such as iron, titanium, or a mineral component.
[0056]
In addition, the outer tube 24A is a non-ferrous metal having a monopolar potential of gold (Au) having a positive potential of monovalent, divalent or trivalent physicochemical properties (the monopolar potential of gold Au is 1.7). The inner tube 24B is formed of a non-ferrous metal tube having a physicochemical property such as titanium Ti or the like having a negative monopolar potential (monopolar potential of titanium Ti is -1.75). Therefore, a potential difference is generated between the outer tube 24A and the inner tube 24B. This potential difference makes the ionic bond unstable.
[0057]
Then, a magnetic field of 4000 gauss to 8000 gauss is generated between the magnetic poles NS of the permanent magnet 7 as one anisotropic magnetic body and the permanent magnet 7-1 as the other anisotropic magnetic body. An electromotive force is generated by applying the magnetism of the magnetic field to the connection pipe 24, and the charged body reacts with + ions of the material of the connection pipe 26 to be ionized (− ionized).
[0058]
For these reasons, the breeding water can be changed in properties by its own flow rate and application of magnetic force to promote water purification by the phytoplankton in the fishpond 31 and to grow nitrifying bacteria. Then, by expressing its activity, the oxidation reaction of ammonia nitrogen is promoted, and the breeding of various bacteria is suppressed by ionizing the breeding water, so that the inside of the fishpond 31 becomes an environment suitable for breeding fish. it can.
[0059]
In addition, the cation exchange function and the adsorption function of zeolite can be added to the breeding water in addition to the function of subdividing the breeding water cluster by magnetic force, flow, and potential difference, and the water quality of the phytoplankton in the fishpond 31 can be increased. Purification can be promoted, and nitrifying bacteria can be proliferated and express their activity to promote the oxidation reaction of ammonia nitrogen, and the breeding of various bacteria can be suppressed by ionizing breeding water. The environment in the pond 31 suitable for breeding fish can be provided.
[0060]
In addition, since the corners of the magnet holding cases 3 and 3-1 are rounded at a bending angle of 56 degrees or more, there is no leakage of magnetic field lines to the outside, and the magnetic treatment of breeding water is smoothly performed. Therefore, it is possible to suppress adverse effects on other control devices due to leakage of the magnetic field lines.
[0061]
In addition, not only when the combination of the outer tube 24A and the inner tube 24B is the above-described gold (Au) and titanium (Ti), but also when the combination is platinum (Pt) and titanium (Ti). A potential difference occurs between the outer tube 24A and the inner tube 24B, and this potential difference destabilizes ionic bonds.
[0062]
In the above-described embodiment, the magnetic processing device A is arranged on the discharge-side pipe 40. However, as shown by the phantom line in FIG. 1, the magnetic processing apparatus A is arranged on the suction-side pipe. You may.
[0063]
The underwater breeding apparatus according to the present invention can also be used in a breeding facility 50 having a breeding tank for breeding underwater creatures such as goldfish, other fish, crustaceans, and mollusks.
[0064]
As shown in FIG. 7, the breeding facility 50 includes a breeding tank 51 as a breeding water area, and a breeding water circulation system 52 that circulates water in the breeding tank 51. The rearing tank 51 includes a box-shaped tank body 51A made of glass and transparent acrylic resin, and a lid body 51B is attached to the tank body 51A.
[0065]
The breeding water circulation system 52 has a circulation pump 53 and a filter (for example, a zeolite filter) 54, and the circulation pump 53 and the filter 54 are held on the lid 52 side. That is, the circulating pump 53 is held by the lid 51B at its drive motor 54 and is mostly a rotary pump that is submerged in water.
[0066]
Further, a filter housing chamber 55 is provided in the lid 51B, and a water supply port 56 is provided in the lid 51B constituting the bottom of the filter housing chamber 55. The filter 57 is housed in the filter housing chamber 55. The shower pipe 58 is disposed above the filter 57.
[0067]
The suction side pipe 53b of the circulation pump 53 is installed in the water, and the discharge side pipe 53a of the circulation pump 53 passes through the lid 51B and is led out of the tank body 51A, and is connected to the shower pipe 58. I have.
[0068]
The discharge-side pipe 53a, the shower pipe 58, and the suction-side pipe 53b constitute a part of a circulation pipe as a flow pipe, and the magnetic processing device A is disposed in the discharge-side pipe 53a. I have. The magnetic processing apparatus A is arranged in the pipe 40 by connecting the magnetic processing apparatus A to the discharge side pipe 53a using the joint 9 of the connection pipe 24 of the magnetic processing apparatus A.
[0069]
Therefore, similarly to the case where the magnetic processing apparatus A is disposed in the fish farm 30 described above, the magnetic lines of force F generated in the magnetic circuit of the magnetic processing apparatus A penetrate the connecting pipe 24, and the inner and outer flow paths 32 in the connecting pipe 24, A magnetic field that is perpendicular to the flow of the breeding water flowing as a treatment target flowing through 31 is formed and applied.
[0070]
Therefore, by applying magnetism (lines of magnetic force F) at right angles to the flow of water containing the molecules of the mineral components, a so-called Lorentz force is generated, and the molecules of the mineral components can be ionized and subdivided. That is, the mineral components of the breeding water are magnetically reacted to subdivide the clusters and ionize them.
[0071]
By giving a flow rate of 1.2 m to 1.6 m per second to the breeding water, a metal element (calcium, sodium, magnesium, potassium) contained in a trace amount in the mineral component as the breeding water in the connecting pipe 24 through which the breeding water flows. Static electricity (0.06 mA at a flow rate of 1.2 m / s, 0.08 mA at a flow rate of 1.6 m / s) is generated on a charged body (charged particles) such as aluminum, iron, and titanium.
[0072]
In addition, the outer tube 24A is a non-ferrous metal having a monopolar potential of gold (Au) having a positive potential of monovalent, divalent or trivalent physicochemical properties (the monopolar potential of gold Au is 1.7). The inner tube 24B is formed of a non-ferrous metal tube having a physicochemical property such as titanium Ti or the like having a negative monopolar potential (monopolar potential of titanium Ti is -1.75). Therefore, a potential difference is generated between the outer tube 24A and the inner tube 24B. This potential difference makes the ionic bond of the mineral component of the breeding water unstable.
[0073]
Then, a magnetic field of 4000 gauss to 8000 gauss is generated between the magnetic poles NS of the permanent magnet 7 as one anisotropic magnetic body and the permanent magnet 7-1 as the other anisotropic magnetic body. An electromotive force is generated by applying the magnetism of the magnetic field to the connection pipe 24, and the charged body is made to react with + ions of the material of the connection pipe 26 to be ionized (-ionized).
[0074]
For this reason, the breeding water can be changed in properties by its own flow rate and application of a magnetic force to promote water purification by the phytoplankton in the breeding tank 51, and also to increase nitrifying bacteria. By expressing its activity, the oxidation reaction of ammonia nitrogen is promoted, and the breeding of various bacteria is suppressed by the ionization of breeding water, so that the breeding tank 51 can be made an environment suitable for breeding of aquatic organisms. .
[0075]
Thus, the breeding water to be treated is treated by the magnetic treatment main body A-1. Since the magnetic field is generated by facing the pair of permanent magnets 7 and 7-1, the magnetic force that penetrates the breeding water flow at a right angle is strong, and the corners of the magnet holding cases 3 and 3-1 are Since the bending angle is greater than or equal to 56 degrees, there is no leakage of the magnetic field lines to the outside, and the magnetic treatment of the breeding water can be smoothly performed. Adverse effects can be suppressed.
[0076]
In addition, not only when the combination of the outer tube 24A and the inner tube 24B is the above-described gold (Au) and titanium (Ti), but also when the combination is platinum (Pt) and titanium (Ti). A potential difference occurs between the outer tube 24A and the inner tube 24B, and this potential difference destabilizes the ionic bond of the mineral component.
[0077]
The above-mentioned breeding facility 50 is of an integrated type with an upper filtration type, but the magnetic processing apparatus A is also arranged in an externally filtered breeding facility 50-1 shown in FIG. The breeding facility 50-1 includes a breeding water circulation system 62 that circulates breeding water in the breeding tub 61, which is provided separately from the breeding tub 61.
[0078]
The breeding water circulation system 62 is configured by connecting a pumping unit 64 to a filter unit 63, and a suction side of the pumping unit 64 is provided with a filtering material (not shown) in the filter unit 63 (for example, Zeolite filter). A suction side pipe 64b is connected to a suction port 63a provided in the filter unit 63, and the front side of the suction side pipe 64b is installed in the water of the breeding tank 61, and a pumping pump unit is provided. The tip side of the discharge-side tube 64 a is installed in the water of the breeding tank 61.
[0079]
The discharge-side pipe 64a and the suction-side pipe 64b constitute a part of a circulation pipe which is a flow pipe, and a magnetic processing device A is disposed in the discharge-side pipe 64a. The magnetic processing device A is arranged on the discharge-side pipe 64a by connecting the magnetic processing device A to the discharge-side pipe 64a using the joint 9 of the connection pipe 24 of the magnetic processing device A.
[0080]
Therefore, similarly to the case where the magnetic processing device A is arranged in the breeding facility 50 described above, the lines of magnetic force F generated in the magnetic circuit of the magnetic processing device A penetrate the connection pipe 24, and the inner and outer flow paths 32 in the connection pipe 24, A magnetic field perpendicular to the flow of the breeding water flowing as a treatment target flowing through the base 31 is applied, and the breeding water changes its properties by its own flow velocity and application of a magnetic force. Water purification by plankton can be promoted, and nitrifying bacteria grow and express their activity to promote the oxidation reaction of ammonia nitrogen, and also suppress the propagation of various bacteria by ionizing the breeding water. Thus, the environment inside the breeding tank 61 can be made suitable for breeding underwater organisms.
[0081]
The underwater breeding equipment includes breeding facilities such as live fish breeding facilities, goldfish breeding facilities, and ornamental aquarium facilities such as aquariums, in addition to fish farming facilities. By providing a magnetic treatment device A in the circulating system of breeding water in a breeding facility such as an aquarium for aquariums for aquariums, and applying a magnetic force to the breeding water, the clusters of the breeding water flowing at a predetermined flow rate are magnetized. It is subdivided by force to promote water purification by phytoplankton in the breeding water area, and also to proliferate nitrifying bacteria and express their activity to promote the oxidation reaction of ammonia nitrogen, and also to ionize the breeding water The breeding water area is made an environment suitable for breeding underwater organisms by suppressing the propagation of various bacteria.
[0082]
【The invention's effect】
As described above, according to the underwater breeding apparatus of the present invention, the underwater breeding apparatus uses a magnetic treatment device to apply magnetic force to the breeding water, so that the breeding water flows at the predetermined flow rate. Clusters can be subdivided by magnetic force to promote water purification by phytoplankton in breeding waters, and also to promote nitrification bacteria and express their activity to promote oxidation of ammonia nitrogen, In addition, the propagation of various bacteria can be suppressed by ionizing the breeding water, and the breeding water area can be made an environment suitable for breeding underwater organisms.
[0083]
In addition, according to the underwater breeding apparatus of the present invention, the breeding water is given a flow rate of, for example, 1.2 m to 1.6 m per second, so that the breeding water flows in a pipe (connection pipe). Static electricity (for example, 0.06 mA at 1.2 m / s, flow rate of 1 / s) is applied to a charged body (charged particles) such as metal elements (calcium, sodium, magnesium, potassium, aluminum, iron, and titanium) contained in a small amount in breeding water. At 0.6 m, 0.08 mA) is generated, and a potential difference is generated between the outer tube and the inner tube in the connecting tube, thereby destabilizing the ionic bond, and at the same time, making one anisotropic magnetic body and the other anisotropic. An electromotive force is generated by applying a magnetic field having a magnetic field of, for example, 4000 to 8000 Gauss to the connecting tube between the magnetic poles of the connecting tube and the anisotropic magnetic body, thereby causing the charged body to react with + ions of the material of the connecting tube. hand It can be turned of.
[0084]
In this way, the breeding water can be subdivided into clusters of the breeding water by magnetic force, flow, and potential difference, to promote water purification by phytoplankton in the breeding water area, and to proliferate nitrifying bacteria and reduce their activity. When expressed, it promotes the oxidation reaction of ammonia nitrogen and suppresses the propagation of various bacteria by ionization of breeding water, thereby making the breeding water area an environment suitable for breeding aquatic organisms.
[0085]
Moreover, according to the underwater breeding apparatus of the present invention, a difference (potential difference) between the potentials (H = 0 V reference standard potential) of each of the two types of non-ferrous metals can be reliably generated. For this reason, the ionic bond of breeding water can be made more unstable.
[0086]
Further, according to the aquatic organism breeding apparatus of the present invention, the cation exchange function and the adsorption function of zeolite are added to the breeding water in addition to the function of subdividing the breeding water clusters by magnetic force, flow and potential difference. Can promote the purification of water by phytoplankton in the breeding water area, and also promote the nitrification bacteria to express their activity to promote the oxidation reaction of ammonia nitrogen, The propagation of various bacteria can be suppressed by ionization of the water, so that the breeding water area can be made an environment suitable for breeding underwater organisms.
[0087]
Further, according to the underwater breeding apparatus of the present invention, in a breeding facility such as an aquarium facility such as a fish breeding facility, a live fish breeding facility, a gold fish breeding facility, and an aquarium, a magnetic force is applied to the breeding water by a magnetic processing device. By giving, the cluster of breeding water flowing at this predetermined flow rate can be subdivided by magnetic force to promote water purification by phytoplankton in the breeding water area, and also to grow nitrifying bacteria and increase their activity. To promote the oxidation reaction of ammonia nitrogen and suppress the propagation of various bacteria by ionizing the breeding water, thereby making the breeding water area an environment suitable for breeding underwater organisms.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating the configuration of an underwater breeding apparatus according to the present invention.
FIG. 2 is a perspective view of a magnetic processing apparatus.
FIG. 3 is a side view of the magnetic processing apparatus.
FIG. 4 is a sectional view taken along line XX of FIG. 3;
FIG. 5 is a front view of a magnetic processing body in the magnetic processing apparatus.
FIG. 6 is a perspective view of the magnetic processing body with a part thereof omitted.
FIG. 7 is an explanatory view of the configuration of another underwater breeding apparatus according to the present invention.
FIG. 8 is a configuration explanatory view of another underwater breeding apparatus according to the present invention.
FIG. 9 is a perspective view of a magnetic treatment device used in the water treatment device.
FIG. 10 is a perspective view of the magnetic processing apparatus in an exploded state.
[Explanation of symbols]
1 One magnetic processing body
2 The other magnetic processing body
3 One magnet holding case
3-1 The other magnet holding case
3a Seam
3a-1 Seam
6 groove
6-1 Groove
7. One permanent magnet (one anisotropic magnetic body)
7-1 The other permanent magnet (the other anisotropic magnetic body)
24 Connecting pipe
24A outer tube
24B inner tube
30 Fish farming facilities
31 Fish ponds (breeding waters)
35 Breeding water circulation system
36 Circulation pump
37 Filter
50 Breeding facilities
50-1 Breeding Facilities
51 Breeding tank (breeding waters)
52 Breeding water circulation system
53 Circulation pump
54 Filter
61 Breeding tank (breeding waters)
62 Breeding water circulation system

Claims (7)

A breeding device for aquatic creatures, wherein the breeding water is caused to flow into a breeding water area of a breeding facility by driving a water pump, so as to breed the underwater creatures in the breeding water area,
The breeding water flow pipe is provided with a magnetic processing device that subdivides the breeding water cluster flowing at a predetermined flow rate by magnetic force, and makes the breeding water area an environment suitable for breeding the aquatic organisms. A breeding device for underwater creatures, characterized in that: The magnetic processing apparatus includes one magnetic processing body in which one anisotropic magnetic body of a square cube is housed in one magnet holding case made of a magnetic body, and the other anisotropic magnetic body of a square cube made of a magnetic body. And the other magnet holding case is magnetically attracted to the other magnet holding case so as to form a magnetic induction double-pole closed circuit at a joint thereof. The other magnetic processing body to be connected, comprising a non-magnetic connecting pipe through which the breeding water flows, at the joint of the one and the other magnet holding cases, and magnetically attracted to each other at the joint, The breeding water flows between the magnetic poles of the one anisotropic magnetic body and the other anisotropic magnetic body while making the one and the other magnet holding cases a part of the magnetic induction double pole closed circuit. Magnetic field perpendicular to Breeding apparatus of aquatic organisms according to claim 1, characterized in that formed in which applying the magnetic field to the breeding water. The connecting pipe has an outer pipe made of a non-ferrous metal, and a flow path that is housed inside the outer pipe and passes through the connecting pipe from the inlet side to the outlet side between the inner wall and the outer pipe. And an inner tube made of a different non-ferrous metal from the outer tube. A potential (H) of each of the two types of non-ferrous metals is provided between the outer tube and the inner tube. 3. The breeding apparatus for underwater organisms according to claim 2, wherein a difference (potential difference) of (= 0 V reference standard potential) exists. The outer tubular body is formed of a non-ferrous metal tube having a monopolar potential having a positive potential of monovalent and divalent or trivalent physicochemical properties, and the inner tubular body has a monopolar potential of a negative potential. The underwater breeding apparatus according to claim 3, wherein the apparatus is formed of a nonferrous metal tube having physicochemical properties. The underwater according to claim 4, wherein the two types of non-ferrous metals are one of gold (Au) and titanium (Ti), platinum (Pt) and titanium (Ti). Organism breeding equipment. The breeding water area is provided with a breeding water circulation system having the water pump that circulates the breeding water, a zeolite filter is disposed in the breeding water circulation system, and the water pump is driven to pass the magnetic processing device. The breeding apparatus for aquatic organisms according to any one of claims 1 to 5, wherein the breeding water is filtered through the zeolite filter and circulated through the breeding water area. The underwater breeding apparatus according to any one of claims 1 to 6, wherein the breeding facility is a fish farm, a live fish breeding facility, a goldfish breeding facility, an aquarium for an aquarium, or the like.

Images