JP7266224B2 - Method for preventing adherence of marine organisms - Google Patents

Description

TECHNICAL FIELD The present invention relates to a method for preventing adhesion of marine organisms and an anti-adhesion agent used therein. More particularly, the present invention relates to a method for preventing adhesion of marine organisms and an anti-adhesion agent used therein, which can maintain its effect for a long period of time with the addition of a low-concentration agent and can prevent adhesion of a wide range of marine organism species.

A large amount of seawater is used as cooling water for industrial use, particularly as cooling water for condensers in thermal power plants and nuclear power plants. Therefore, a large amount of mussels such as mussels, barnacles, bryozoans, and other marine organisms adhere to the walls of the seawater intake channel, pipes, and heat exchangers, causing various problems. Among them, bivalves such as mussels, which are epiphytic by byssus threads, grow rapidly, and when they reach adulthood, they block part of the heat exchanger tube, obstructing the passage of seawater and causing turbulence. Causes problems such as erosion corrosion.

In order to prevent the dense growth (adherence) of these marine species, conventionally, chlorine generating agents such as sodium hypochlorite, electrolytic chlorine or chlorine gas (also referred to as "chlorine agents"), hydrogen peroxide or excess water are used. A hydrogen oxide generating agent (also referred to as a “hydrogen peroxide agent”) is added (for example, see JP-A-11-37666: Patent Document 1 and JP-A-2005-144212: Patent Document 2).

On the other hand, chlorine dioxide has a strong bactericidal power and does not form harmful organochlorine compounds, so it has the advantage of having little impact on the environment.
For example, Japanese Patent Application Laid-Open No. 1-275504 (Patent Document 3) discloses a technology related to a biofouling agent containing chlorine dioxide or a chlorine dioxide generating agent as an active ingredient. consists of continuously or intermittently injecting an aqueous solution of chlorine dioxide with a relatively high concentration into a waterway through which freshwater or seawater is installed in a facility using freshwater or seawater. A technique related to a method for preventing or controlling adhesion of living organisms is disclosed.
However, chlorine dioxide is extremely unstable as a chemical substance, and there is a problem in the sustainability of the effect of preventing adhesion of marine organisms.
In addition, the present applicant has proposed a method for preventing adhesion of marine organisms using both chlorine dioxide and hydrogen peroxide and an anti-adhesion agent used therein (Patent No. 5879596: see Patent Document 5).
Japanese Unexamined Patent Application Publication No. 2005-7254 (Patent Document 6) discloses a technique relating to a method for sterilizing bathtub water using both a chlorine-based chemical and chlorine dioxide as a sterilizing agent. However, the target water system of this technology is bath water, not seawater cooling water system, and its purpose is sterilization of Legionella bacteria and destruction of biofilm, not prevention of adhesion of marine organisms. or different purpose.

JP-A-11-37666 JP 2005-144212 A JP-A-1-275504 JP-A-6-153759 Japanese Patent No. 5879596 JP 2005-7254 A

In order to prevent adhesion of marine organisms, there is a movement to avoid using halogen-based agents such as chlorine and bromine agents in consideration of the impact on the environment. in some cases, and in other cases, chlorine-based compounds by-produced in the recycling process are effectively used.
Under these circumstances, it is desired to develop a chemical agent that can exhibit an excellent effect of preventing the adhesion of marine organisms while reducing the amount of chlorine agent used in consideration of the impact on the environment, and a method using the same. ing.

The present invention provides a method for preventing adhesion of marine organisms and an anti-adhesion agent for use therein, which can maintain its effect for a long period of time with the addition of a low-concentration chemical and can prevent the adhesion of a wide range of marine species and slimes. is the subject.

The inventors of the present invention have found that a combination of a chlorine agent or a bromine agent and chlorine dioxide can effectively prevent adhesion of a wide range of marine species including mussels such as mussels for a long period of time. It was found that effective adhesion prevention effect against marine organisms, slime, etc. can be obtained even if the amount of the agent added is reduced compared to the single use of chlorine agent or bromine agent and chlorine dioxide in the prior art, and the present invention was completed. I came to do it.

Thus, according to the present invention, a chlorine agent (excluding chlorine dioxide) or a bromine agent and 0.005 Chlorine dioxide is added in this order or reverse order or simultaneously with chlorine dioxide to a concentration of ~ 0.05 mg / L for 1 to 24 hours a day to prevent marine organisms from adhering to the seawater cooling water system. ,
wherein said chlorine agent is selected from sodium hypochlorite, N-chlorosulfamate and monochloramine, and said bromine agent is selected from sodium hypobromite, N-bromosulfamate and monobroramine; A method for preventing fouling of marine organisms is provided.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a method for preventing adhesion of marine organisms, which can maintain its effects for a long period of time with the addition of a low-concentration chemical agent and can prevent the adhesion of a wide range of marine species and slimes.
That is, in the method for preventing adhesion of marine organisms of the present invention, the chlorine agent or bromine agent and chlorine dioxide are added so as to have a synergistic effect in seawater. is exerted continuously for a certain period of time, and a small amount of addition can provide a more excellent effect of preventing adhesion of marine organisms than when a chlorine agent or a bromine agent and chlorine dioxide are used alone.
In addition, the method for preventing adhesion of marine organisms of the present invention is effective in preventing adhesion of a wide range of marine organism species, for example, mussels such as mussels, marine organisms such as barnacles and bryozoans, and slime.

In addition, the method for preventing adherence of marine organisms of the present invention further exhibits the above effects when any one of the following requirements is satisfied.
(1) Chlorine agent or bromine agent and chlorine dioxide are added to seawater so that the available chlorine concentration is 0.005 to 0.3 mg/L and the concentration is 0.002 to 0.2 mg/L, respectively. added.
(2) A chlorine or bromine agent and chlorine dioxide are added for 1 to 24 hours a day.
(3) Chlorine dioxide is added to the seawater of the seawater cooling water system to which the chlorine or bromine agent has been added, that is, the chlorine or bromine agent and chlorine dioxide are added in this order to the seawater of the seawater cooling water system.
(4) a chlorine or bromine agent,
(a) chlorine gas, calcium hypochlorite, sodium hypochlorite, chlorinated isocyanuric acid, sodium dichloroisocyanurate, potassium dichloroisocyanurate, sodium monochloroisocyanurate, potassium monochloroisocyanurate, sodium trichloroisocyanurate and trichloroisocyanurate Substances that generate hypochlorous acid in water at least one selected from potassium phosphate,
(b) one or more substances selected from sodium hypobromite, a reaction product of sodium bromide and sodium hypochlorite, and bromine water that generates hypobromous acid in water;
(c) seawater electrolyte, or (d) one or more combined chlorines or bonds selected from monochloramine, dichloramine, trichloramine, monobrolamine, dibrolamine, tribrolamine, N-chlorosulfamate and N-bromosulfamate. Bromine.

(Method for preventing adherence of marine organisms)
In the method for preventing adhesion of marine organisms of the present invention, a chlorine agent (excluding chlorine dioxide) or a bromine agent and chlorine dioxide are added in this order or in reverse order so that the concentration in the seawater of the seawater cooling water system exhibits a synergistic effect. or at the same time to prevent adhesion of marine organisms to the seawater cooling water system.

(chlorine agent or bromine agent)
Examples of the chlorine or bromine agent used in the present invention include known chlorine or bromine agents other than chlorine dioxide used in combination.
(a) chlorine gas, hypochlorite (calcium hypochlorite, sodium hypochlorite, etc.), chlorinated isocyanuric acid, dichloroisocyanurate (sodium dichloroisocyanurate, potassium dichloroisocyanurate, etc.), monochloroisocyanurate Substances that generate hypochlorous acid in water such as acid salts (sodium monochloroisocyanurate, potassium monochloroisocyanurate, etc.), trichloroisocyanurates (sodium trichloroisocyanurate, potassium trichloroisocyanurate, etc.),
(b) substances that generate hypobromous acid in water, such as sodium hypobromite, a reaction product of sodium bromide and sodium hypochlorite, and bromine water;
(c) seawater electrolyte (electrolyte containing hypochlorous acid obtained by electrolyzing seawater in an electrolytic cell), and (d) monochloramine, dichloramine, trichloramine, monobrolamine, dibrolamine, tribrolamine, N-chloro Combined chlorine (stabilized chlorine) or combined bromine (stabilized bromine) such as sulfamate and N-bromosulfamate
is mentioned. Among these, (a), (b) and (c) are preferable from the practical viewpoint of the effect of preventing adhesion of marine organisms, economic efficiency, and handleability, and from the viewpoint of industrial availability, Sodium hypochlorite and potassium hypochlorite are particularly preferred. Among (d), preferred are monochloramine and monobroramine, followed by N-chlorosulfamate and N-bromosulfamate, from the viewpoint of the effect of preventing adhesion of marine organisms.

N-chlorosulfamate and N-bromosulfamate can be prepared by known methods, for example, JP-A-2003-503323, JP-A-2006-022097, JP-A-11-506139, JP-A-2001- 501869, JP-A-2003-507326, JP-A-2014-101251 and JP-A-2017-159276, etc. It can be prepared by the method described.
In the present invention, a reaction product of sulfamic acid and hypochlorous acid and/or hypobromous acid can be preferably used.
Combined chlorine such as monochloramine can be prepared by methods described in Japanese Patent No. 4914146, Japanese Patent Application Laid-Open Nos. 2017-119245 and 2017-53054.

The chlorine and bromine agents described above may be diluted or dissolved in seawater or freshwater to obtain a desired concentration upon addition.
In addition, when (a) a substance that generates hypochlorous acid in water or (c) seawater electrolyte is added to seawater, hypochlorous acid reacts with bromide ions present in seawater, and quickly chlorine and bromine replaces For example, when sodium hypochlorite is added to seawater, it quickly becomes sodium hypobromite. Therefore, even if any of (a), (b) and (c) is used, the antifouling effect on marine organisms is equivalent.

The chlorine agent or bromine agent may be appropriately set according to the concentration of chlorine dioxide to be used in combination, the state of seawater to be added, etc., but usually the effective chlorine concentration of the chlorine agent or bromine agent to seawater is 0.005 to 0.00. Addition to a concentration of 3 mg/L is preferred.
As used herein, the concentration of chlorine or bromine agent means "available chlorine concentration."
If the concentration of the chlorine agent or the bromine agent is less than 0.005 mg/L, the combined use with chlorine dioxide may not be sufficiently effective in preventing adhesion of marine organisms. On the other hand, if the concentration of the chlorine agent or the bromine agent exceeds 0.3 mg/L, no further effect can be expected, which is not preferable from an economical point of view.
The concentration of the chlorine agent or bromine agent is more preferably 0.01-0.2 mg/L, more preferably 0.01-0.1 mg/L.

The addition time of the chlorine agent or bromine agent may be appropriately set depending on the concentration of chlorine dioxide to be added and the state of the seawater to be added, but it is usually 1 to 24 hours per day.
If the addition time is less than 1 hour per day, the combined use with chlorine dioxide may not be sufficiently effective in preventing adhesion of marine organisms.
A more preferable addition time of the chlorine or bromine agent is 14 to 24 hours per day, more preferably 18 to 22 hours per day.

(chlorine dioxide)
Since the chlorine dioxide used in the present invention is an extremely unstable chemical substance, its storage and transportation are very difficult. Therefore, it is preferable to manufacture (generate) chlorine dioxide on the spot by a known method and adjust the addition concentration before use.
For example, chlorine dioxide can be produced by the following reaction, and a commercially available chlorine dioxide generator (apparatus) can also be used.
(1) Reaction of sodium hypochlorite, hydrochloric acid and sodium chlorite NaOCl+2HCl+ _2NaClO2 → _2ClO2 +3NaCl+ _H2O
(2) Reaction of sodium chlorite and hydrochloric acid 5NaClO ₂ +4HCl → 4ClO ₂ +5NaCl+2H ₂ O
( ₃ ) Reaction with sodium chlorate, hydrogen peroxide and sulfuric acid _2NaClO3 + _{H2O2 + H2SO4} → _2ClO2 + _Na2SO4 + _{O2 + 2H2O}

Chlorine dioxide may be appropriately set depending on the concentration of the chlorine agent or bromine agent used in combination, the state of the seawater to be added, etc., but usually the concentration of chlorine dioxide is 0.002 to 0.2mg / L with respect to seawater. It is preferred to add
If the concentration of chlorine dioxide is less than 0.002 mg/L, the combined use with a chlorine agent or a bromine agent may not be sufficiently effective in preventing adhesion of marine organisms. On the other hand, if the concentration of chlorine dioxide exceeds 0.2 mg/L, no further effect can be expected, which is not preferable from an economical point of view.
A more preferred concentration of chlorine dioxide is 0.005 to 0.1 mg/L, more preferably 0.005 to 0.05 mg/L.

The addition time of chlorine dioxide may be appropriately set according to the concentration of the chlorine agent or bromine agent used in combination in the seawater, the state of the seawater to be added, etc., but it is usually 1 to 24 hours per day.
If the addition time is less than 1 hour per day, the combined use of the chlorine agent or the bromine agent may not be sufficiently effective in preventing adhesion of marine organisms.
A more preferable addition time of chlorine dioxide is 14 to 24 hours per day, more preferably 18 to 22 hours per day.

(Synergistic Effect of Chlorine Agent or Bromine Agent and Chlorine Dioxide in Seawater)
From the above, the chlorine agent or bromine agent and chlorine dioxide are adjusted to have an available chlorine concentration of 0.005 to 0.3 mg / L and a concentration of 0.002 to 0.2 mg / L in the seawater, respectively. It is preferably added.
Strictly speaking, the concentration of the chlorine agent or bromine agent and chlorine dioxide in seawater is not equivalent to the concentration of each compound added because the concentration of each compound in seawater decreases over time.
Therefore, in carrying out the present invention, depending on the conditions of seawater and marine organisms living there, the concentration of the chlorine agent or bromine agent and chlorine dioxide in seawater is adjusted to the above range. In anticipation of the decrease in concentration, the addition concentration and addition time may be appropriately set.
In view of the above, the chlorine or bromine agent and chlorine dioxide are preferably added for 1 to 24 hours a day.

(other additives)
In the method for preventing adhesion of marine organisms of the present invention, other additives known in the art may be used together as long as the effects of the present invention are not impaired.
Examples thereof include dialkyldithiocarbamates, antifouling agents for marine organisms such as cationic surfactants, iron-based metal corrosion inhibitors, antifoaming agents, and the like.

(Place of addition)
The seawater cooling water system includes, for example, water intake system equipment, equipment to be cooled such as a condenser and other equipment, and water discharge system equipment. The water intake system consists of a water conduit, a screen that removes foreign matter in the seawater, a circulating water pump (intake pump), and a circulating water pipe (intake pipe).

The place of addition of each agent in the present invention may be any of the intake channel, the pipe attached to the heat exchanger or the condenser, the water conduit, the inlet of the heat exchanger or the inlet of the condenser. From the point of view of the effect of preventing damage due to adherence of living organisms, the vicinity of the water intake of the water intake pump and the entrance of the heat exchanger or condenser are preferable.

In power plants, etc., chlorinating agents or brominating agents are added to the seawater taken in in order to obtain the effect of preventing adhesion of marine organisms. , the necessary chlorine or bromine concentration cannot be left in the heat exchanger (condenser), and a sufficient anti-adhesion effect may not be obtained. Therefore, according to the present invention, by adding low-concentration chlorine dioxide to such a seawater system to the upstream side of the condenser, a sufficient effect of preventing adhesion of marine organisms can be obtained within the above-described residual chlorine concentration regulation. Obtainable. Therefore, it is particularly preferable to add chlorine dioxide after adding the chlorine or bromine agent, that is, add the chlorine or bromine agent and chlorine dioxide in this order to the seawater of the seawater cooling water system.

(Addition method)
Examples of methods for adding each drug include a method using an injection pump, an air diffuser, an atomizer, or the like. Conventional physical means can be used in the present invention to rapidly and substantially uniformly diffuse a trace amount of a chemical into a seawater cooling water system. Specifically, installation of a diffuser, a stirring device, a baffle plate, or the like in the water system can be mentioned. In addition, since the equipment corresponding to these is attached to the seawater cooling water system, this may be diverted.

(Adhesion prevention agent for marine organisms)
The antifouling agent for marine organisms of the present invention is an antifouling agent for marine organisms used in the above method,
The anti-adhesion agent is
(a) chlorine gas, calcium hypochlorite, sodium hypochlorite, chlorinated isocyanuric acid, sodium dichloroisocyanurate, potassium dichloroisocyanurate, sodium monochloroisocyanurate, potassium monochloroisocyanurate, as a chlorine or bromine agent; one or more substances selected from sodium trichloroisocyanurate and potassium trichloroisocyanurate that generate hypochlorous acid in water;
(b) one or more substances selected from sodium hypobromite, a reaction product of sodium bromide and sodium hypochlorite, and bromine water that generates hypobromous acid in water;
(c) seawater electrolyte; or (d) one or more bound chlorine (stable chlorine) or combined bromine (stabilized bromine),
(1) a combination of sodium hypochlorite, hydrochloric acid and sodium chlorite as a chlorine dioxide generating source;
(2) a combination of sodium chlorite and hydrochloric acid; or (3) a combination of sodium chlorite, hydrogen peroxide and sulfuric acid.

The present invention will be specifically described by the following test examples, but the present invention is not limited by these.

[Test Example 1]
We confirmed the effectiveness of combined use of hypochlorous acid and chlorine dioxide to prevent adhesion of marine organisms.
A hydrographic test equipment was installed at a certain place on the coast of Wakayama Prefecture facing the Pacific Ocean, and tests were conducted.
Unfiltered seawater (pH 8) pumped using a submersible pump was passed through 15 branched channels (test area) at a flow rate of 1 m ³ /h for 70 days, and the following conditions were applied to each channel. The additive agents (hypochlorous acid and chlorine dioxide) prepared as described above were added at the addition time per day shown in Table 1 so that the agent concentration shown in Table 1 was obtained.
The chemical concentration is the set concentration in the acrylic column for confirming the anti-adhesion effect described below, and the concentration of hypochlorous acid is the effective chlorine concentration.
In addition, the amount of drug added was the same in test plots having the same drug concentration. For example, the amount of hypochlorous acid added in Examples 1, 2 and Comparative Example 1 is the same, and the amount of chlorine dioxide added in Example 2 and Comparative Example 6 is the same.

In addition, an acrylic column (inner diameter: 64 mm x length: 300 mm x thickness: 2 mm, surface area: 602.88 cm ² ) was inserted into each water channel to confirm the anti-adhesion effect. was measured to evaluate the anti-adhesion effect.
In addition, as a blank, the test was also performed without the addition of the drug.
The results obtained are shown in Table 1 together with each added agent, their concentration, and time.

(additive agent)
Chlorine dioxide is obtained by mixing aqueous solutions of sodium chlorite and hydrochloric acid, each of which is appropriately diluted with pure water, in a tube before the chemical addition point so that the chlorine dioxide concentration shown in Table 1 is obtained, and the retention time is 1 hour. An aqueous solution of chlorine dioxide generated by holding was added from before the acrylic column for checking the anti-adhesion effect using a metering pump. Regarding the generation of chlorine dioxide, it was confirmed in a preliminary test that no sodium chlorite remained.
Hypochlorous acid is adjusted to the chemical concentration to be added to seawater by diluting 12% sodium hypochlorite aqueous solution as effective chlorine with pure water as appropriate, and acrylic column for checking adhesion prevention effect similar to chlorine dioxide It was added using a metering pump from this side.

(Confirmation of anti-adhesion effect)
After the test, the mass Wa (g) of the column removed from the channel was measured. Together with the weight Wb of the column at the time of drying, which had been measured in advance before the test, the amount of adherent organisms (g) was calculated by the following formula.
Adhering biomass (g) = Wa - Wb
The sessile organisms are mainly derived from marine sessile organisms such as mussels such as mussels, barnacles, and bryozoans. In addition, detritus-like substances containing a large amount of organic matter such as excreta and corpses of adherent organisms and slimes, extracellular secretions, and viscous particles and suspended matter contained in seawater also adhere to the column. include.
Based on the state of adhesion of marine organisms to the blank, it can be judged that, in this test example, when the amount of adhered organisms is 15 g or less, there is a sufficient effect of preventing adhesion of marine organisms. In addition, when the amount of adhered organisms is 5 g or less, no adhesion of organisms or dirt is visually observed, and it can be judged that the adhesion of marine organisms is best prevented.

The results in Table 1 show the following.
(1) When hypochlorous acid was used alone, the additive concentration was 0.075 mg/L (Comparative Example 3), and when chlorine dioxide was used alone, the additive concentration was 0.030 mg/L (Comparative Example 3). Example 8) provides a sufficient effect of preventing adhesion of marine organisms (2). L (Example 1), that is, a sufficient effect of preventing adhesion of marine organisms can be obtained at concentrations of 1/3 and 1/6 of the above (1), respectively. (3) Hypochlorous acid and chlorine dioxide was added at concentrations of 0.025 mg/L and 0.010 mg/L (Examples 2 and 5), respectively, that is, when used together at an addition concentration of 1/3 and 1/3 of the above (1), respectively, Even if the addition time is shorter (18 hours / day) than in the case of (1) above (22 hours / day), the effect of preventing adhesion of marine organisms superior to that of (2) above is obtained (4) First When comparing the case of adding hypochlorous acid to and then adding chlorine dioxide (Example 2) and the case of adding chlorine dioxide first and then adding hypochlorous acid (Example 5), Although both have a sufficient effect of preventing adhesion of marine organisms, the former is superior.

(5) Above (1) above, that is, even if hypochlorous acid and chlorine dioxide are added at concentrations higher than the addition concentration that shows a sufficient effect of preventing adhesion of marine organisms by itself, the amount of adherent organisms is 8.7 g with chlorine. (Comparative Example 4), chlorine dioxide only reduces to 7.8 g (Comparative Example 8) (6). Example 2), 4.8 g (Example 3), 4.6 g (Example 4), and 6.1 g (Example 5) The above results show that hypochlorous acid and chlorine dioxide in seawater coexistence of both, that is, an effect corresponding to a synergistic effect. It is an unexpected fact that such a synergistic effect can be obtained by using hypochlorous acid together with chlorine dioxide, which is used as a substitute for hypochlorous acid (chlorine).

The anti-adhesion effect of chlorine-based oxidizing agents on marine organisms is generally considered to be proportional to the ORP of seawater after addition of the agents. ORP does not always show a constant value depending on the properties of seawater and water temperature, but in this test example, in Examples 1 and 2 in which hypochlorous acid and chlorine dioxide were used in combination, the ORP was 406 and 414, respectively. Even in Comparative Example 1 in which the same concentration of hypochlorous acid was used alone, the ORP was the same 412. From these results, it is speculated that a part of one or both of the agents is decomposed by the redox reaction when hypochlorous acid and chlorine dioxide are used in combination, and the synergistic effect described above cannot be obtained. It is inferred. However, it can be said that it is an unexpected fact that a person skilled in the art could not have easily conceived that such an excellent effect of preventing adhesion to marine organisms was obtained.

[Test Example 2]
Prevention of adhesion of marine organisms when using N-chlorosulfamate or monochloramine as a chlorine agent in combination with chlorine dioxide, and when using N-bromosulfamate or monobroramine as a bromine agent in combination with chlorine dioxide We confirmed the effect.
A hydrographic test equipment was installed at a certain place on the coast of Wakayama Prefecture facing the Pacific Ocean, and tests were conducted.
Unfiltered seawater (pH 8) pumped up using a submersible pump was passed once-through at a flow rate of 1 m ³ /h for 68 days through 17 branched channels (test plots). An additive agent prepared as described below was added to each water channel so as to have the agent concentration shown in Table 2 and the addition time per day shown in Table 2.
The chemical concentration is the set concentration in the acrylic column for confirming the anti-adhesion effect described below, and the chemical concentration of the chlorine agent and the bromine agent is the effective chlorine concentration (effective chlorine equivalent concentration).
In addition, the amount of drug added was the same in test plots having the same drug concentration. For example, the amount of N-chlorosulfamate added in Example 6 and Comparative Example 10 is the same, and the amount of chlorine dioxide added in Example 7 and Comparative Example 16 is the same.

In addition, an acrylic column (inner diameter 64 mm x length 300 mm x thickness 2 mm, surface area 602.88 cm2) was inserted into each channel to check the anti-adhesion effect. was measured and the anti-adhesion effect was evaluated.
In addition, as a blank, the test was also performed without the addition of the drug.
The obtained results are shown in Table 2 together with each additive agent, their concentration, and time.

(additive agent)
Chlorine dioxide was adjusted and added in the same manner as in Test Example 1.
N-chlorosulfamate and N-bromosulfamate are prepared by a known method (e.g., the method described in JP-A-2017-159276), and monochloramine and monobroramine are prepared by a known method (e.g., the method described in JP-A-2017-159276). 2017-53054), and then diluted with pure water as appropriate to adjust the chemical concentration to be added to seawater, and the acrylic column for checking the anti-adhesion effect in the same manner as chlorine dioxide. It was added from the front using a metering pump.

(Confirmation of anti-adhesion effect)
In the same manner as in Test Example 1, the amount of adherent organisms (g) on the column was calculated to confirm the effect of preventing adherence of marine organisms.

The results in Table 2 show the following.
(1) When a chlorine agent or a bromine agent is used alone, a sufficient effect of preventing adhesion of marine organisms cannot be obtained (Comparative Examples 10 to 12), but when used in combination with chlorine dioxide, sufficient marine organisms Obtaining an anti-adhesion effect for organisms (Examples 6 to 8)
(2) Sufficient anti-adhesion effect of marine organisms can be obtained when the chlorine agent alone is used (Comparative Example 14). When used in combination with chlorine, a sufficient effect of preventing adhesion of marine organisms can be obtained (Example 10)
(3) Even when a chlorine agent or a bromine agent is used alone, a sufficient effect of preventing adhesion of marine organisms can be obtained (Comparative Examples 13 to 15), but when used in combination with chlorine dioxide, the best marine organisms to obtain an anti-adhesion effect (Examples 9, 11 and 12)
(4) Sufficient anti-adhesion effect of marine organisms can be obtained When chlorine dioxide is used alone (Comparative Example 18), a sufficient effect cannot be expected at a chlorine dioxide concentration of 1/6 to 2/3. , When used in combination with a chlorine agent or a bromine agent, a sufficient effect of preventing adhesion of marine organisms can be obtained (Examples 6 to 12)
The above results show that the coexistence of N-chlorosulfamate, N-bromosulfamate, monochloramine, monobroramine, and chlorine dioxide in seawater produces an effect corresponding to the synergistic effect of both. This is thought to be due to

Claims (2)

Hypochlorite obtained by electrolyzing seawater so that the effective chlorine concentration in the seawater cooling water system is 0.01 to 0.3 mg / L and the concentration is 0.005 to 0.05 mg / L , respectively . Acid-containing electrolyzed seawater and chlorine dioxide are added in this order or reverse order or simultaneously for 1 to 24 hours a day to prevent adhesion of marine organisms to a seawater cooling water system. adhesion prevention method. 2. The method for preventing adhesion of marine organisms according to claim 1, wherein the hypochlorous acid-containing electrolyzed seawater and chlorine dioxide are added in this order to the seawater in the seawater cooling water system.