KR101917564B1 - Method for exterminating scutica - Google Patents

Abstract

As a means for solving the problem, the present invention provides an environmentally-friendly scuticociliate control method which can help with scuticociliatosis-causing organisms by selecting at least one method from a method using a low frequency wave device for parasite control and a method of using a trivalent iodine (I_3) resin filter device. Non-antibiotic plaice can be cultivated in the control of the scuticociliatosis which is the major disease cause of death of raised plaice.

Description

{Method for exterminating scutica}

More particularly, the present invention relates to a method using a low frequency wave device for parasite rescue, a method using a trivalent iodine (I ₃ ) resin filtration device, Of the flounder is selected by selecting one or more of the flounder, approximately 40% of the flounder is known to be the causative organism Sukutika sacrifice is not an antibiotic or a chemical method, And a remedy method.

Figure 1 shows the annual variation in production and production of domestic aquaculture during the last decade (2007-2016). The cultivation of flounder in Korea started in 1985 in Jejudo, and the annual average production and average annual production amount of the last 10 years (2007-2016) were 42,476 tons / year and 455 billion won / It accounted for 49.6% of the annual production of contrast fish (85,710 tons / year) and 55.2% of annual production (824.8 billion won / year). In particular, the production and production of flounder in Jeju Island are 24,317 tons and 260.4 billion won, respectively, which is an important key industry, accounting for 62.7% of production and 62.0% of production, respectively.

However, recent flounder aquaculture has faced a serious crisis as a disease. The amount of disease caused by diseases in Jeju flounder aquaculture is increasing from 5,601 tons in 2010 to 6,928 tons in 2013 and 7,889 tons in 2014 respectively. Disease mortality in cultured flounder is known to be about 65.6% on the basis of the number of flocks during the period from stocking to shipment.

Diseases caused by cultured flounder include bacterial diseases, parasitic diseases, viral diseases and the like, but the main cause disease is scuticociliatosis, which is a parasitic disease known as Scutica.

Scuticaria is a parasitic disease which refers to an infection caused by histophagous ciliates belonging to the order Scuticociliaitda. As shown in FIG. 2, the mortality rate is 61.0% of the disease mortality rate (65.6%) The number of flounder mortalities caused by S. scutica is 39.4%, and it is fatal from fever to sexually transmitted disease.

Unlike most ciliates, scuticociliate, a causative organism of scuticasia, infects not only kidneys and blood vessels, but also brain tissue, resulting in a high mortality rate. In Korea, especially scuticociliate is fatal to the cultured flounder.

Three species of Uricama marinum , Pseudocohnilembus persalinus , and Miamiensis avidus have been reported in domestic cultured flounder, but Uracil has been known to infect fish tissues, internal organs, nerves, blood vessels and brain tissues, The species is known as Miamiensis avidus .

It is dependent on compound bathing at the farming site for the treatment of squid vesicular disease in cultured flounder. However, it is known that the treatment with vaccine is the only one if Sucutika is infiltrated into the body. Thus, abuse of antibiotics in farms poses a serious threat to food safety and increases coastal environmental pollution.

As a countermeasure against scuticacidosis, formalin has almost been approved as a scuticacid remedy, but its concentration is high to 100-200ppm, which can cause stress to the body. In recent years, the toxicity of formaldehyde It is a reality that a problem is emerging.

As a result, we have developed and used a scuticacid remover for the substitution of formalin, such as a scuticacid insecticide using natural substances. We have also developed a vaccine for the prevention and treatment of scuticacid infection, and developed natural products such as resveratrol Although there are studies on the effect of Hanskutika in vitro, there have been few reports on the effect of application on the size of aquaculture site as well as expenses. Therefore, it is necessary to develop a technique that can reduce the damage of cultured flounder caused by Sukutika.

Korean Patent No. 10-1434553 discloses a method for producing a fish which is composed of chloramine-T and hydrogen peroxide, wherein the chloramine-Ti and hydrogen peroxide are sequentially administered irrespective of the order of administration. A composition for relieving scuticacid or pathogenic bacterium, and a composition for scuticacid and pathogenic bacterium remedy for fishes, which sequentially bathe fishes in the order of irregularly to a chemical solution containing chloramine-thi and hydrogen peroxide, and a remedy method therefor . Korean Patent No. 10-1171069 discloses a composition for scuticacid elimination of fish, which is selected from the group consisting of gold, cloves, rhododendron, lacquer, and iron oxide, or 100% antiparasitic effect, And citric acid, citric acid, clove and citric acid, hydrogen peroxide, ferric sulfate and hydrogen peroxide, or sulfur dioxide and hydrogen peroxide as active ingredients, and a method for relieving scutchaca of fish using the composition. Korean Patent No. 10-1298097 discloses that the feed additive composition contains Kamphen (camphene), which is excellent in insecticidal action of Sucutica, as an active ingredient of a feed additive for fish culture, A composition for scutika saccharide remediation containing Kampen as an active ingredient, which is capable of replacing formalin, which is an existing toxic remedy, and which has an effect of preventing marine environmental pollution in advance, has been disclosed have. Korean Patent No. 10-0379026 discloses the use of ketoconazole to rescue the infected Sukutika infecting the inside and outside of cultured flounder. In addition, oral administration of ketoconazole (KC) to the flounder Sukutika charcoal of the present invention The method can minimize the stress of the flounder due to the use of the therapeutic agent as compared with the conventional method of using external parasitic salvage agent, and it is also possible to relieve the infected Sucutika infestation in the body. Therefore, And discloses a method for relieving scutica in a flounder.

In order to solve the above-mentioned problem that most of the techniques of scuticociliatosis causing scuticociliatosis, which is the most serious damage to cultured flounder, depend on antibiotics or chemotherapy, (I ₃ ) resin filtration device, which can be utilized as an infrastructure technology for industrialization of flounder culture technology, using a low frequency wave device for parasitic relief, or a combination of these methods.

The present invention as means for solving the foregoing problems are methods using the low frequency wave device for parasite remedy 3 is iodine (I ₃₎ the resin was filtered and a method using the device each or in combination of plural methods Surgical urticae increase induced biological Uronema marinum , Pseudocohnilemdus persalinus , Miamiensis avidus of the present invention is rescued.

The low-frequency wave device for relieving parasites includes a low-frequency transmission electrode including positive and negative poles, a low-frequency transmission line connected to the end of the electrode, a low-frequency transmission line connected to the low- An electrode rod is connected to the end of the low-frequency transmission line connected to the information signal output terminal of the low-frequency wave device, so that the end of the electrode can be locked in the seawater feeding water infested with the creature infected with the scuticacid- And the electric current of the low frequency wave transmission line of 20 mA is activated to rescue the scuticacid evoking organism.

Wherein the trivalent iodine resin filtering device comprises a motor pump, a cylindrical filter, and a primary filtration device and a secondary filtration device filled with a trivalent iodine resin having a spherical shape of 300-600 탆, both ends of the tube of the filtration device And a motor pump was operated to pass iodine water through primary and secondary filtration apparatus so that the concentration of iodine in the water was raised to 8.2 ppm-12.5 ppm, Wherein the scuticacid-evoking organism is rescued by maintaining the scutchase-evoking organism.

The effect of the environmentally friendly scuticacid remediation method of the present invention and the remedial effect of the present invention are effective in the control of scuticacidosis which is a major causative disease of cultured flounder, and the non-antibiotic flounder culture can be effected.

Figure 1 shows the annual variation in production and production of domestic aquaculture during the last decade (2007-2016).
FIG. 2 is a graph showing the percentage of disease-causing causative strains in Jeju cultured flounder.
3 is a schematic diagram of a low-frequency wave generating device for parasitic relief of the present invention.
4 shows a schematic diagram of a low-frequency wave generating device for parasitic relief of the present invention.
5 shows the inside and the outside of the low frequency wave generator for parasitic relief of the present invention.
6 shows an experimental procedure of a low frequency wave generating apparatus for parasitic relief of the present invention.
Fig. 7 shows experimental results of a low frequency wave generating apparatus for parasitic relief of the present invention.
Fig. 8 shows a typical electrolysis scheme of seawater.
Fig. 10 shows the results of experiments of scuticacid remediation using a low frequency wave generator for parasite rescue.
FIG. 11 shows changes in water quality factors (water temperature, salinity, dissolved oxygen, pH, and residual chlorine) according to time for each test after operation of a low frequency wave generator for parasite rescue.
Fig. 12 shows the vitality of the specimen Sukutika pond according to the operation of the low frequency wave device for remedying parasites.
Fig. 13 shows a triode resin filtering apparatus used in an experimental example of the present invention.
FIG. 14 is a photograph of a remedial experiment process using the triple ood filter of the present invention.
Fig. 15 shows a micrograph of a Sukutika sac exposed to a trivalent iodine resin.
Figure 16 shows photographs of trivalent iodine resin (above) and regular solid iodine (below).

The environmentally friendly scuticacid remediation method of the present invention can save one or more of the methods using a low frequency wave device for parasite rescue, a method using a trivalent iodine resin filter device, and the like. The trivalent iodine resin of the present invention is commercially available under the trade name LST iodine resin.

The scuticacid causing organism may be at least one selected from Uronema marinum , Pseudocohnilemdus persalinus , and Miamiensis avidus . Hereinafter, the method and the effect of the present invention will be described in detail with reference to experimental examples related to the environmentally-friendly scuticacid remediation method.

Example  1. Using low-frequency waves Scutica  Remedy

There are three species of scuticociliatosis caused by Flounder Paralichthys olivaceus , Uronema marinum , Pseudocohnilemdus persalinus , and Miamiensis avidus , which are reported to be the most common species in flounder. M. avidus and was selected as the subject species of the experimental example according to the present invention.

The culture is given the pre-sale of about 2 ml (100,000 cells / ml) to the in order to use in the experiment Miamiensis avidus separated / identified in Jeju National Research Center for vaccine cultured in sterile growth chamber. The prevalent M. avidus was inoculated with a certain amount of seawater (20-30% of the volume of the container) in a plastic container and then cultured while feeding.

Cultivation was carried out by subculture (subculture). Sterile seawater was used for seawater, and the flounder meat was boiled in boiling water at 100 ℃ for 20 minutes and sterilized. The viability, density and morphology of the cells were observed under a microscope during the incubation period.

The low frequency wave generator for parasite relief according to the embodiment of the present invention refers to a conventional low frequency wave generator. All materials have particles and waves at the same time, and they have quantum energy (hereinafter, low frequency) that contains information of matter.

In addition, it is known to change the low frequency of a substance or supply a low frequency beneficial substance to prevent toxic removal, deodorization and decay. Generally, a low-frequency generating apparatus generates an electromagnetic wave by using electromagnetic waves, and supplies an electromagnetic force to an energy field of a material. A low-frequency electromagnetic field is transmitted to free electrons generated by an electromotive force. .

The low frequency wave device for relieving parasites according to an embodiment of the present invention includes an information signal transmitting electrode including a positive electrode and a negative electrode, an information signal transmitting line connected to the end of the electrode, And an information signal output terminal for operating the low frequency wave device. However, the present invention is not limited thereto.

3 is a structural schematic diagram of a low frequency wave generator for parasite relief according to an embodiment of the present invention. Fig. 4 shows a design diagram of a low-frequency wave generating device for parasitic relief of the present invention. 5 shows photographs of inside and outside of a low frequency wave generator for parasitic relief of the present invention. Table 1 shows specifications of a low-frequency wave generator for parasite rescue.

Specification of low frequency wave generator for parasite relief Enclosure specification 450 mm (w) x 900 mm (h) x 350 mm (d) Power Source AC 220 V / 1 ØHz Power Consumption Within 20 VA Energy output power Within 1 KVA Information signal output Max 5-40 ㎃

The experimental example according to the present invention is to confirm the effect of the remedy by using low frequency waves for parasitic relief, and after inoculating the squid cocoon into an arbitrary chamber, a low frequency wave for parasitic relief (Vital Generator) was used to infuse low frequency waves and to determine the effect of remediation by determining the vitality or death of the Sutuca cordata.

end. Using low frequency waves Scutica  Preliminary experiment

6 shows a preliminary experimental procedure of the low frequency wave generator for parasitic relief of the present invention. In the preliminary experiment, 180 liters of underground salt water were filled in two 1 L beakers, respectively, and the experimental sphere and the control were made by inoculating Sututika crab Miaminensis avidus .

As shown in FIG. 6, an electrode was connected to the end of the information signal transmission line connected to the information signal output terminal of the low-frequency wave generating device, so that the tip of the electrode could be immersed in the experimental water in the beaker inoculated with the scutica. After installation, the low frequency wave generator was started. At this time, the current of the low-frequency wave transmission line was 20 mA. After the operation of the low-frequency wave generator, the vitality or the extinction of the Sutuca cord was observed using an optical microscope at intervals of 30 minutes.

Fig. 7 shows a preliminary experimental result of the low-frequency wave generating device for parasitic relief of the present invention. At the start of the experiment, there was active movement of Sukutika in both the experimental and control groups. However, no change was detected in the vitality in the control at 30 minutes and 60 minutes, And only some of the entities attached to the organic matter or the organic matter penetrated into the organic matter but the movement was observed. This phenomenon was also observed in repeated experiments.

From these results, it can be concluded that the experiment of scuticacid remediation using a low frequency wave generator for parasite rescue is very meaningful, that is, it results in the death of scuticaccharum by low frequency wave. However, as shown in FIG. 7 and FIG. 8, in the experimental period, considering the fact that chlorine gas was generated by the electrolysis due to the current (20 mA) flowing in the electrode, unlike the control, In order to determine whether the cause of the death of Ticaca suffers from the effects of low-frequency waves or toxic effects of residual chlorine caused by electrolysis, it is necessary to exclude the influence of residual chlorine under the experimental conditions in order to determine whether low- Respectively. This experiment was performed as follows.

I. Using low frequency waves Scutica  This experiment

9 is a schematic view of a remediation experiment and a photograph of an experimental procedure of the Sukutika charge test using the low frequency wave of the present invention. In a rectangular acrylic container with a width of 15 cm, a width of 240 cm and a height of 15 cm, three test pieces (capacity 20 ml, treated with 20 ㎛ mesh of mesh with about 60% of the side surface of Bayer) were set at regular intervals, (Two ㎝ in diameter) openings so as to minimize the flow of water without affecting the propagation of low - frequency waves.

The (+) and (-) poles of the information signal transmitting electrode were installed at both ends of the experimental tank respectively. Subsequently, the underground saline (about 41 L) was filled in, and each specimen was inoculated with Sucutika insect at the same density for about 5 minutes, and the low frequency wave generator for parasite rescue was activated. After 30 minutes interval, the changes of the vitality of Suktika pond were examined and the changes of water quality (water temperature, salinity, dissolved oxygen, pH, residual chlorine, etc.

The reaction of the sututa crab was observed using an optical microscope. Water temperature, salinity, dissolved oxygen and pH were measured using YSI Professional Plus (YSI Inc., USA) and residual chlorine was measured using Poket colorimeter ^TM Ⅱ (HACH Com., USA).

Fig. 10 shows the results of experiments of scuticacid remediation using a low frequency wave generator for parasite rescue. * 1, * 3, * 5 in FIG. 10 means the place close to the bacterium of the scuticum inoculation, and * 2, * 4, * 6. It means inside the bacterium inoculation of the scutica. "ND" and "-" mean non-detection and non-detection respectively. FIG. 11 shows changes in water quality factors (water temperature, salinity, dissolved oxygen, pH, and residual chlorine) according to time for each test after operation of a low frequency wave generator for parasite rescue.

There was no difference in water temperature between experimental sites. At 19 hours after the start of the experiment, it was 11.6 ℃ lower than the water temperature (17.6 ℃). There was no difference in salinity between the experimental period and the water temperature. It increased slightly with time, which is considered to be the effect of natural evaporation.

Dissolved oxygen was not different between the experimental groups. But the increase in the solubility of oxygen as the water temperature decreases is considered to be the result. pH was significantly different from that of water temperature, salinity and dissolved oxygen.

In Experiment 2, there was almost no change with time, but it was continuously decreased in Experiment 1 and continuously increased in Experiment 3. Residual chlorine also showed a large difference between the experimental and control groups.

In experiment 1, which was the closest to the anode, the concentration of residual chlorine increased rapidly after the start of experiment. In Experiment 2, nearest to the anode, there was a gradual increase in the concentration of residual chlorine. .

From the above results, it can be seen that in Experiment 1 near the anode, the pH was decreased with time and the residual chlorine rapidly increased, whereas the pH was increased in Experiment 3 near the cathode, but the residual chlorine hardly changed, It is judged to be the effect of electrolysis of water.

Experiment 1 is an experiment where the anode of the low frequency wave generator is placed near the anode. In the electrolysis of sea water, _two water molecules (H ₂ O) lose electrons (e ^- ) in the anode (+) and decompose into 4H ⁺ and O ₂ and, 2NaCl is digested with 2Na ⁺ and Cl _2.

At this time, dissolved Cl ₂ combines with H ₂ O to form HCl and HClO. Through such a series of steps, the pH is lowered. In Experiment 3, which is located near the cathode (-), 2H ₂ O is decomposed into 2OH ^- and H ₂ by receiving electrons (e ^- ) and decomposed 2OH ^- combines with 2NaCl to form 2NaOH and 2Cl ^- . In this way, the pH gradually increases due to the production of NaOH.

Fig. 12 shows the vitality of the specimen Sukutika pond according to the operation of the low frequency wave device for remedying parasites. As the time elapsed after the start of the experiment, there was a difference in the reaction (vitality degree) of the test specimens Sukutika. Experiment 1 died at 4 hours and 30 minutes, and all of them died at 19 hours in Experiment 2. In contrast, in Experiment 3, there was no change in vitality until the end of the experiment.

As a result of the experimental example of the present invention, the wave generated by the low-frequency wave generating device has the same effect on each experimental point theoretically in the same structure as the present experiment. Therefore, if a low-frequency wave is injected into an experimental tank to relieve the sutucca insect, the sutucca insides within it should show the same response at the same time from any location.

However, in this experiment, three test pieces were installed in a long rectangular water tank having a length of 240 cm, a width of 15 cm and a height of 15 cm, and an electrode was installed at both ends of the tank in the longitudinal direction. As a result of the experiment observing the reaction of Sukutika, the reaction of Sukutika was different according to the experiment.

In Experiment 3, which is the closest to the cathode, there was no change in vitality until the end of the experiment. On the other hand, in Experiment 1 nearest to the anode, all of them died in 4 hours and 30 minutes. It took 19 hours to kill them all. As a result, the degree of the effect on the vitality of Sukutika was found to be weaker from the anode to the cathode.

On the other hand, in Experiment 1 near the anode by electrolysis of the experimental water after the start of the experiment, the pH was decreased with time and the residual chlorine rapidly increased, whereas in Experiment 3 near the cathode, . In electrolysis of seawater, _two water molecules (H ₂ O) lose electrons (e ^- ) in the anode (+) and decompose into 4H ⁺ and O ₂ , and 2NaCl is decomposed into 2Na ⁺ and Cl ₂ .

At this time, dissolved Cl ₂ combines with H ₂ O to form HCl and HClO. Through such a series of steps, the pH is lowered. In Experiment 3, which is located near the cathode (-), 2H ₂ O is decomposed into 2OH ^- and H ₂ by receiving electrons (e ^- ) and decomposed 2OH ^- combines with 2NaCl to form 2NaOH and 2Cl ^- . In this way, the pH gradually increases due to the production of NaOH. When Cl ₂ (gas) generated during electrolysis of seawater dissolves into Cl ₂ (dissolved), HCl and HClO are formed. HClO is a material of chlorine disinfectant and has strong sterilizing ability.

From the above results, it is considered that the death of Suktica is not caused by the low frequency wave but by the toxic effect of the residual chlorine caused by the electrolysis of the experimental water in the Sukutika sedimentation experiment using the low frequency wave generator for parasite rescue.

Example 2. Experimental experiment of scutica using a trivalent iodine resin filter

Experimental examples of the present invention are to investigate the possibility of using trivalent iodine resin for scuticacid dyestuffs. In order to investigate the possibility of using a trivalent iodine resin in a scuticacid dentifrice, a scuticacid dentifrice experiment using a trivalent iodine resin filter and a reaction of a scuticacid exposed to a trivalent iodine resin Experiments were performed.

Surgical urticae charged used in this embodiment is an experiment Miamiensis avidus, two kinds of sources and the culturing process the experiment in Example 1 was carried out in the same manner as for the. The trivalent iodine resin can be prepared by the following method.

1) Triiodide is formed by the combination of iodine (I ₂ ) and iodine ion (I ^- ) of one molecule I ₂ + NaI === H ₂ O ===> Na ⁺ + I ₃ ^-

2) Na ⁺ in I ₃ and Na ⁺ in I ₃ are replaced with I ₃ ^- , adsorbing Triiodide to mineral or resin, and fermentation at 70-80 ° C using filamentous bacteria and actinomycetes, followed by drying to give trivalent iodine resin .

After the above treatment, the cells were stored in a distillation energy solution containing energy through a cell activation device for 24 hours, and then dried again at high temperature to immerse the triiodide in the activated distillation energy solution. Pack and store.

Fig. 13 shows a triode resin filtering apparatus used in an experimental example of the present invention. The triple-odored resin filtration apparatus of the present invention comprises a motor pump, a primary filtration apparatus, and a secondary filtration apparatus. The primary and secondary filtration apparatuses are formed by adding a spherical tri-valent iodine resin having a diameter of 300-600 μm to a cylindrical tube And both ends of the tube are finished with a net having a mesh of 250 占 퐉.

FIG. 14 is a photograph of a remedial experiment process using the triple ood filter of the present invention. This experiment was carried out by inoculating cultured Sutuka spp into seawater to make an experimental water and observing the activity of Sututika sphagnum in the experimental water. Then, using this motor pump attached to a trivalent iodine resin filter, After passing through the filtration apparatus in succession, the presence or absence of the sututa crab was confirmed in the filtered water. The water quality (water temperature (℃), salinity (psu), dissolved oxygen (DO, mg / L), pH) of the experimental water before and after the filtration was measured using YSI Professional Plus (YSI Inc., USA). The experiment was repeated twice.

In order to examine the direct reaction of the Sucutika to the trivalent iodine resin, the Sucutica spp. Was exposed to the trivalent iodine resin. Fig. 15 shows a micrograph of the Sucutica spp. Exposed to the trivalent iodine resin. Table 2 shows the trivalent iodine resin exposure test method. * The Sututika sacrificed in the experiment was purchased from Cheju National University and was not cultivated separately.

Experimental method of reaction of Sucutika to 3-valent iodine resin Type of experiment Sample preparation Observation method 20 ml of Bayer vessel (500 μl of stock solution of Sukutika + mass of solid iodine) Control sample: Sukutika filling solution Observed on hole slides after aliquot Collection immediately after initiation Sututika insect and trivalent iodine resin were collected together and observed continuously on the hole slide After 30 minutes, Sutuca japonica and trivalent iodine resin were collected and observed directly on the hole slide. Slide the hole (50 μl of stock solution of Sukutika + a fixed amount of solid iodine) - On the hole slide, only the undiluted solution of Sukutika was observed, and then a certain amount of trivalent iodine resin was added and observed continuously

Figure 16 shows photographs of trivalent iodine resin (above) and regular solid iodine (below). The trivalent iodine resin used in this study has a particle size in the range of 300-600 μm in diameter and a solid solid iodide in the range of 1500-3000 μm in size. Unlike the trivalent iodine resin, the solid solid iodine was identified as iodine which was released by itself, and the white paper on the bottom changed to yellowish brown.

In order to investigate the effect of iodine (I ₃ ) on the sutucca insect, the reaction of Sutica ku depending on the iodine concentration was examined. The concentrations of iodine were 0.3 ppm, 0.4 ppm, 8.2 ppm and 12.5 ppm, and 0.3 ppm and 0.4 ppm were iodine concentrations before and after passing through the trivalent iodine resin filtration device, respectively. 8.2 ppm and 12.5 ppm respectively dissolved general solid iodine in seawater It is made.

The thus prepared iodine solution was inoculated with scuticacid, and the reaction of the scuticacid was observed over time for 4 hours. Observation of Sututika was performed using an inverted optical microscope (AXIO Imager M2, Carl Zeiss, Germany).

3 iodine concentration before and after passing through the flexible resin filter Experiment
Order Iodine (I ₃ ) concentration before and after the passage through the trivalent iodine resin (ppm) Remarks Before passing After passing Primary 0.1 0.3 Iodine (I ₃ ) concentration was confirmed to be 0.8 ppm when subjected to circulation filtration for 18 hours. Secondary 0.1 0.3 Third 0.1 0.3 Fourth 0.2 0.3 5th 0.2 - 6th 0.2 - Mean (standard deviation) 0.2 (0.05) 0.3 (0.0)

Table 3 shows the results of comparing the iodine (I ₃ ) concentrations before and after passing through the trivalent iodine resin filter. * .'- 'in Table 3 means unmeasured. The iodine (I ₃ ) concentration (average) before and after the passage through the trivalent iodine resin filter was slightly increased after passing at 0.2 ppm and 0.3 pm, respectively. When subjected to circulation filtration for 18 hours, the iodine (I ₃ ) concentration increased to about 0.8 ppm.

Table 4 shows the results of the experiment of scutic acid removal using a trivalent iodine resin filter. In the experimental water before passing through the filtration device, the sututika insect was active, but in the experimental water passed through the filter, no sututika insect was observed at all. Among the factors of water quality of experimental water, only dissolved oxygen increased by about 1 ㎎ / L after passing through filter, and the remaining factors (water temperature, salinity and pH) showed little change between before and after filtration.

From the above results, it can be seen that there was no significant change in the water quality, except for slightly increased dissolved oxygen, in the experimental water which passed through the trivalent iodine resin filtration device.

Experimental results of Sucutica sludge remediation using a trivalent iodine resin filter Experiment
Order division Water quality environmental factor The presence or absence Remarks Water temperature (℃) salt
(psu) Dissolved oxygen
(Mg / L) pH Primary Before passing through the trivalent iodine resin filter 18.0 30.4 4.52 7.77 Extremely
Active After passing through a trivalent iodine resin filter, 19.5 30.6 6.05 7.70 Scutica
none Secondary Before passing through the trivalent iodine resin filter - - - - Extremely
Active After passing through a trivalent iodine resin filter, - - - - Scutica
none

Table 5 shows the results of observing the reaction of Sutica spp. By exposure to trivalent iodine resin. Sucutica spp. Exposed to trivalent iodine resin slowly lost its vitality over time and eventually died. The vitality was reduced, but the time of death was proportional to the amount of iodine resin added and exposure time.

Sucutica exudate exposed to trivalent iodine resin Type of experiment Sample preparation Sukutika response Remarks 20 mL of Bayer container (500 μl of Sukutika stock solution + a lot of solid iodine) Control sample: Sukutika filling solution Very active Collection immediately after initiation Lost in activity over time and almost died After about 30 minutes All died Slide the hole (50 μl of stock solution of Sukutika + a fixed amount of solid iodine) - Before the addition of the trivalent iodine resin, the sutucca larvae were very active, but after the addition of the trivalent iodine resin, they gradually lost their vitality and died.

Table 6 shows the response of Sutica cactus according to time by iodine (I ₃ ) concentration. In the vitality scale of Table 6, 0 indicates death and 1 indicates active. Iodine (I ₃₎ a scoop according to the Mathematica concentration of iodine (I ₃₎ in order to determine the effect of charge-Surgical urticae caterpillars reaction results, iodine (I ₃₎ concentration of 12.5 ppm in all in one hour Surgical after the start of the experiment urticae In the case of less than 8.2 ppm, the level of vitality was reduced for 4 hours, regardless of the concentration.

Response of Suticus ku depending on time by iodine (I ₃ ) concentration Iodine (I ₃ ) concentration
(ppm)
Vigorous activity of Sutica ku depending on time by iodine (I ₃ ) concentration 1 hours 2 hours 3 hours 4 hours 0.3 One One One One 0.4 One One One One 8.2 One One One One 12.5 0 0 0 0

(3) Iodine Resin, Iodine (I ₃ ) Concentration, Iodine (I ₃ ) Concentration, Iodine (I ₃ ) Concentration ppm, the increase in iodine concentration was lowered to about 0.1 ppm during the passage through the trivalent iodine resin filter, and even when the iodine concentration was reduced to about 0.8 ppm during the circulation filtration for 18 hours in the trivalent iodine resin filter, , The Sucutika spp. Is controlled not by the toxicity of iodine eluted from the trivalent iodine resin but by the filtration function of the trivalent iodine resin filter and the disinfection ability utilizing the attraction due to the negative charge on the surface of the iodine resin .

It is considered that iodine (I ₃ ) eluted when the trivalent iodine resin is exposed to seawater is very low in comparison with general solid iodine, and thus a trivalent iodine resin filter device can be utilized for controlling the concentration of squid tussock in the flounder farm.

From the above experiments, it has been found that the method using a low frequency wave device for parasiticidal remediation and the method using a _trivalent iodine (I ₃ ) resin filter device can be used for the detection of scuticacid- causing organisms Uronema marinum , Pseudocohnilemdus persalinus , Miamiensis Avidus is effective in relieving the disease . Any one or a plurality of methods may be selected and combined to prepare a scuticacid- inducing organism.

Since the production of the non-antibiotic-producing flounder of the present invention can enhance the food stability of the flounder, it can be applied to a large-scale farm, thereby contributing to the increase of the fishery income by improving the international competitiveness of the aquaculture technology, There is a potential for industrial availability.

Claims (5)

A combination of a method using a low frequency wave device for parasite rescue and a method using a trivalent iodine (I ₃ ) resin filtration device to produce an eco-friendly squeegee , which rescues at least one species selected from the group consisting of scuticacid- causing organisms Uronema marinum , Pseudocohnilemdus persalinus and Miamiensis avidus In the method for relieving tikka,
The low-frequency wave device for relieving parasites includes a low-frequency transmission electrode rod having positive and negative poles respectively installed at both ends of a water tank, a low-frequency transmission line connected to the end of the electrode, Frequency output terminal for operating a low-frequency wave device, and the tip of the electrode is installed so as to be submerged in the sea water containing the aquaculture-infested biological organisms, and a current of 20 mA is applied to activate the scutica aquatic organism ≪ / RTI >
Wherein the trivalent iodine resin filtering device comprises a motor pump, a cylindrical filter, and a primary filtration device and a secondary filtration device filled with a trivalent iodine resin having a spherical shape of 300-600 탆, both ends of the tube of the filtration device The triiodide resin is formed of a mesh of 250 탆 mesh,
I ₂ + NaI === H ₂ O ===> Na ⁺ + I ₃ ^-
Na ⁺ and I ₃ are formed by the combination of ^{_{(iodine ion) - - I 2}} (iodine) and I substituted for Na ⁺ of the trivalent iodine (I ₃ ^-) using fungi and actinomycetes was adsorbed only on mineral or resin Followed by high-temperature fermentation at a temperature of 70 to 80 DEG C, followed by drying to prepare a trivalent iodine resin,
The motor pump is operated to pass the feed water through primary and secondary filtration apparatus to maintain the concentration of iodine in the water to be 8.2 ppm to 12.5 ppm for 1 hour or longer, How to save environmentally friendly Sukutika delete delete delete delete

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