JP4470121B2 - Disinfecting and algae killing method of circulating cooling water system - Google Patents

Description

  The present invention relates to a bactericidal algicide composition, an aqueous bactericidal algicide method, and a method for producing a bactericidal algicide composition. More specifically, the present invention relates to a bactericidal algicidal composition that is less susceptible to decomposition of active ingredients due to the influence of ultraviolet rays and copper ions when left and stored outdoors or used outdoors, etc. The present invention relates to an algal method and a method for producing a bactericidal algicidal composition.

In various water systems, various obstacles have occurred due to fungi and algae. For example, in an open-circulation cooling water system, bacteria such as zoom glial bacteria, filamentous bacteria, iron bacteria, sulfur bacteria, nitrifying bacteria, sulfate-reducing bacteria, fungi such as water mold and blue mold, cyanobacteria, green algae, diatoms, etc. Algae grow, and slime and sludge are generated by adhesion and accumulation of soft mud-like contaminants formed by mixing these inorganic substances such as earth and sand and dust, etc., mainly with these microorganisms. Slime and sludge not only cause a decrease in thermal efficiency and water flow, but also cause local corrosion of equipment and piping. In addition, there are cases where fungi grown in the water system directly cause damage to the human body, such as a local illness caused by Legionella bacteria scattered from the cooling tower. Even in the papermaking process water system, various bacteria, fungi, yeast, etc. grow to form slime, causing defects such as holes, spots, eyeballs, etc. in the product, not only reducing product quality, but also causing paper breakage. And productivity is reduced.
Conventionally, a chlorine-based oxidizing agent such as hypochlorite has been added to an aqueous system in order to prevent such damage caused by fungi and algae. Generally, if the residual chlorine concentration in water is 5 mgCl / L or more, it is said that the growth of fungi and algae can be suppressed. However, chlorine-based oxidizers such as hypochlorite are easily decomposed by ultraviolet rays, and if they are stored and left outdoors, such as in a plastic container filled with a bactericidal algicide, chlorine is an active ingredient due to ultraviolet rays. System oxidizer decomposes. Further, after the bactericidal algicide is added to the water system, it is difficult to completely block the cooling water from light in an open circulation cooling water system or the like. Furthermore, when copper or a copper alloy is used as a material for water-based pipes or heat exchangers and the copper ions are eluted, the decomposition of a chlorine-based oxidant such as hypochlorite is further promoted.
A technique for stabilizing an effective chlorine component by adding sulfamic acid or a salt thereof to hypochlorite to form N-monochlorosulfamic acid or N, N-dichlorosulfamic acid or a salt thereof is known. ing. However, even when stabilized with sulfamic acid or a salt thereof, there is a problem in the stability of the drug when the chemical tank is outdoors and exposed to sunlight. For this reason, there is a need for a bactericidal algicidal composition and an aqueous bactericidal algicidal method that can be stored or used in an environment that is exposed to ultraviolet radiation, or in which copper ions are present, with little loss of active ingredients. It was.
Japanese National Patent Publication No. 11-506139 International Publication No. 00/58532 Pamphlet Japanese Patent Publication No.41-15116 JP-A-9-176873 JP 9-94598 A

  The present invention relates to a bactericidal algicidal composition that is less susceptible to decomposition of active ingredients due to the influence of ultraviolet rays and copper ions when left standing, stored or used outdoors etc. It is made for the purpose of providing the manufacturing method of an algicidal composition.

As a result of intensive studies to solve the above-mentioned problems, the present inventors have determined that the pH of a bactericidal algicidal composition containing a chlorine-based oxidizing agent and sulfamic acid or a salt thereof is 13 or more, Decomposition of oxidizers can be suppressed. Furthermore, by containing an azole compound, it is possible to more effectively prevent decomposition of chlorinated oxidants and maintain a high residual chlorine concentration. As a result, the present invention has been completed based on this finding.
That is, the present invention
(1) A composition containing 3-12% by weight of a chlorine-based oxidizing agent and an azole-based compound, 0.05-3, when adding a chlorine-based oxidizing agent, an azole-based compound and sulfamic acid or a salt thereof to the circulating cooling water system. The addition weight ratio of the chlorine-based oxidant to the azole-based compound is set to a ratio of 3 to 12: 0.05 to 3 by adding a composition containing% by weight , and 1 mol of effective chlorine in the chlorine-based oxidant Circular cooling water system sterilizing algaecide, characterized in that the sulfamic acid or a salt thereof is added to the circulating cooling water system in a ratio of 0.3 to 1.5 mol,
Is to provide.
Furthermore, as a preferred embodiment of the present invention,
(2) The circulating cooling water system sterilization algaecide method according to (1) above, wherein the chlorinated oxidant is hypochlorous acid or a salt thereof, and
(3) The sterilizing and killing method for circulating cooling water according to the above (1), wherein the azole compound is benzotriazole or tolyltriazole,
Can be mentioned.

  According to the bactericidal algicide composition and the water-based bactericidal algae method of the present invention, the coexistence of a chlorinated oxidant and sulfamic acid is maintained at an alkaline pH of 13 or higher, so that decomposition of the active ingredient is prevented and high residual Chlorine concentration is maintained. Furthermore, since an even higher residual chlorine concentration is maintained by blending an azole compound, aqueous sterilization and algae killing can be performed effectively. According to the method for producing a bactericidal algicidal composition of the present invention, it is possible to produce a bactericidal algicidal composition that is safe and has no decrease in residual chlorine concentration.

The first aspect of the bactericidal algicidal composition of the present invention is a bactericidal algicidal composition having a pH of 13 or more, comprising a chlorine-based oxidizing agent and sulfamic acid or a salt thereof. The second aspect of the bactericidal algicidal composition of the present invention is a bactericidal algicidal composition comprising a chlorine-based oxidizing agent, an azole-based compound, and sulfamic acid or a salt thereof. In the second aspect of the present invention, the bactericidal algicidal composition preferably has a pH of 13 or more. The aqueous sterilizing algaecidal method of the present invention is a sterilizing algaecidal method in which a chlorine-based oxidizing agent, an azole compound and sulfamic acid or a salt thereof are added to an aqueous system. According to the composition of the present invention or the method of the present invention, the decomposition of active ingredients is suppressed even in an environment subject to ultraviolet rays, the residual chlorine concentration is maintained high, effective sterilization and algae killing, cooling water system, etc. Generation of slime can be prevented and the adhered slime can be peeled off.
There is no restriction | limiting in particular in the chlorine-type oxidizing agent used for this invention, For example, chlorine gas, chlorine dioxide, hypochlorous acid or its salt, chlorous acid or its salt, chloric acid or its salt, perchloric acid or its salt, Examples thereof include chlorinated isocyanuric acid or a salt thereof. In these, hypochlorous acid or its salt can be used conveniently. Examples of hypochlorite include sodium hypochlorite, potassium hypochlorite, calcium hypochlorite, barium hypochlorite and the like. In the composition of the present invention, the content of the chlorine-based oxidizing agent is not particularly limited, but is preferably 3 to 12% by weight, and more preferably 4 to 8% by weight.

The sulfamate used in the present invention is not particularly limited, and examples thereof include sodium sulfamate, potassium sulfamate, calcium sulfamate, strontium sulfamate, barium sulfamate, iron sulfamate, and zinc sulfamate. The sulfamic acid and these sulfamic acid salts can be used alone or in combination of two or more.
Hypochlorite ion and sulfamic acid react as shown in the following formula to form N-monochlorosulfuramic acid ion or N, N-dichlorosulfamic acid ion to stabilize the active ingredient of the chlorinated oxidant.
ClO ⁻ + H ₂ NSO ₃ H → HClNSO ₃ ⁻ + H ₂ O
2ClO ⁻ + H ₂ NSO ₃ H + H ⁺ → Cl ₂ NSO ₃ ⁻ + 2H ₂ O
In the composition of the present invention, the content of sulfamic acid or a salt thereof is not particularly limited, but is preferably 0.3 to 1.5 mol per mol of effective chlorine in the chlorine-based oxidizing agent, and preferably 1 to 1.5. More preferably, it is a mole.
In the first embodiment of the composition of the present invention containing a chlorine-based oxidizing agent and sulfamic acid or a salt thereof, the pH of the composition is 13 or more, more preferably 13.5 or more. In the second embodiment of the composition of the present invention containing a chlorine-based oxidizing agent, an azole compound and sulfamic acid or a salt thereof, the pH of the composition is preferably 13 or more, more preferably 13.5 or more. . If the pH of the composition is less than 13, the stabilizing effect of the chlorine-based oxidant is reduced, and the rate of decrease in residual chlorine concentration may be increased.

The azole compound used in the present invention is an aromatic compound having a five-membered ring containing two or more heteroatoms. Examples of the azole compounds used in the present invention include monocyclic azole compounds such as imidazole, pyrazole, oxazole, thiazole, triazole, and tetrazole, benzimidazole, benzoxazole, benzisoxazole, benzothiazole, mercaptobenzimidazole, and mercapto. Condensed polycyclic azole compounds such as methylbenzimidazole, mercaptobenzothiazole, benzotriazole, tolyltriazole, indazole, purine, imidazothiazole, pyrazolooxazole, and other compounds that form salts among azole compounds. Examples thereof include salts thereof. These azole compounds can be used alone or in combination of two or more. In the composition of the present invention, the content of the azole compound is not particularly limited, but is preferably 0.05 to 3% by weight, and more preferably 0.1 to 2% by weight.
There is no restriction | limiting in particular in the water system to which the sterilization algae method of this invention is applied, For example, a cooling water system, a paper pulp process water system, a dust collection water system, a scrubber water system, a fountain system etc. can be mentioned. In the bactericidal and algicidal method of the present invention, there are no particular limitations on the method of adding the chlorinated oxidant, the azole compound and the sulfamic acid or a salt thereof. For example, the chlorinated oxidant, the azole compound, the sulfamic acid or the salt thereof. Can be added separately, two of these components can be added simultaneously and the remaining one component can be added separately, or three components can be added simultaneously. Among these addition methods, a method in which a bactericidal algicidal composition containing a chlorine-based oxidizing agent, an azole-based compound and sulfamic acid or a salt thereof is prepared in advance and the composition is added to an aqueous system is preferable. By preparing a bactericidal algicidal composition containing a chlorine-based oxidizing agent, an azole-based compound and sulfamic acid or a salt thereof, loss due to decomposition of the active ingredient of the drug can be prevented.
According to the composition of the present invention and the method of the present invention, a high residual chlorine concentration is maintained even in an environment in which sunlight is irradiated or in an aqueous system in which copper or a copper alloy material is used for piping, heat exchangers, and the like. Therefore, aqueous sterilization and algae killing can be performed effectively.
As the pH adjuster used in the present invention, a general alkali compound can be used, and sodium hydroxide, potassium hydroxide and the like can be preferably used.
In the method for producing a bactericidal algicidal composition of the present invention, the method for preparing an aqueous solution containing sulfamic acid or a salt thereof and a pH adjuster is not particularly limited, and may contain azoles and / or other chemicals. Good. Moreover, there is no restriction | limiting in particular also in the addition order of water, sulfamic acid, or its salt.
According to the method for producing a bactericidal algicidal composition of the present invention, the bactericidal algicidal composition of the present invention can be produced safely and without reducing the active ingredient concentration.

Hereinafter, the present invention will be described in more detail with reference to examples, but the present invention is not limited to these examples.
In Examples and Comparative Examples, the residual chlorine concentration was measured by JIS K 0101 28.3 iodine titration method.
Moreover, in Reference Examples 1-9, Examples 10-13, and Comparative Examples 1-5, after preparing the mixed aqueous solution of other chemical | medical agents and water except a sodium hypochlorite, a bactericidal algicide composition, Prepared by adding aqueous sodium hypochlorite solution.
In Reference Examples 1 to 4 and Comparative Examples 1 to 3, the prepared bactericidal algicidal composition was put into a white polyethylene bottle with a capacity of 100 mL, respectively, and a constant temperature bath at 40 ° C. with light from the outside blocked. Or it left still in a 60 degreeC thermostat, and the residual chlorine density | concentration in a composition was measured on the lapsed days 0 days, 6 days, 14 days, and 20 days.
Reference example 1
A bactericidal algicidal composition was prepared by blending 12.4 g of water, 15.6 g of 48 wt% aqueous sodium hydroxide, 12.0 g of sulfamic acid and 60.0 g of 12 wt% aqueous sodium hypochlorite. The pH of this bactericidal algicidal composition was 13.4.
The residual chlorine concentration of this bactericidal algicidal composition was 7.2% by weight immediately after preparation, 7.0% by weight after 6 days, 6.9% by weight after 14 days, 6.8% after 20 days when left at 40 ° C. % By weight. Moreover, when it stood still at 60 degreeC, they were 7.2 weight% immediately after preparation, 6.2 weight% after 6 days, 4.9 weight% after 14 days, and 4.8 weight% after 20 days.
Reference Example 2
A bactericidal algicidal composition was prepared in the same manner as in Reference Example 1 except that the amount of water was 8.7 g and the amount of 48 wt% aqueous sodium hydroxide was 19.3 g. The pH of this bactericidal algicidal composition was 13.8. In the same manner as in Reference Example 1, the residual chlorine concentration was measured.
Reference example 3
Formulated with 11.9 g of water, 15.6 g of 48% by weight aqueous sodium hydroxide, 12.0 g of sulfamic acid, 60.0 g of 12% by weight aqueous sodium hypochlorite and 0.5 g of benzotriazole A product was prepared. The pH of this bactericidal algicidal composition was 13.4. In the same manner as in Reference Example 1 , the residual chlorine concentration was measured.
Reference example 4
A bactericidal algicidal composition was prepared in the same manner as in Reference Example 3 except that the amount of water was 8.2 g and the amount of 48 wt% sodium hydroxide aqueous solution was 19.3 g. The pH of this bactericidal algicidal composition was 13.8. In the same manner as in Reference Example 1, the residual chlorine concentration was measured.

Comparative Example 1
39.5 g of water, 60.0 g of 12 wt% sodium hypochlorite aqueous solution and 0.5 g of benzotriazole were blended to prepare a bactericidal algicidal composition. The pH of this bactericidal algicidal composition was 13.0.
The residual chlorine concentration of this bactericidal algicidal composition was 7.2% by weight immediately after preparation, 5.7% by weight after 6 days, 4.4% by weight after 14 days, and 4.2% after 20 days when left at 40 ° C. % By weight. Moreover, when it left still at 60 degreeC, they were 7.2 weight% immediately after preparation, 3.7 weight% after 6 days, 2.4 weight% after 14 days, and 2.4 weight% after 20 days.
Comparative Example 2
Composition of 16.9 g of water, 10.6 g of 48 wt% sodium hydroxide aqueous solution, 12.0 g of sulfamic acid, 60.0 g of 12 wt% sodium hypochlorite aqueous solution and 0.5 g of benzotriazole A product was prepared. The pH of this bactericidal algicidal composition was 12.0. In the same manner as in Reference Example 1, the residual chlorine concentration was measured.
Comparative Example 3
17.4 g of water, 10.6 g of 48 wt% sodium hydroxide aqueous solution, 12.0 g of sulfamic acid and 60.0 g of 12 wt% sodium hypochlorite aqueous solution were blended to prepare a bactericidal algicidal composition. The pH of this bactericidal algicidal composition was 12.0. In the same manner as in Reference Example 1, the residual chlorine concentration was measured.
The results of Reference Examples 1 to 4 and Comparative Examples 1 to 3 are shown in Table 1.

As can be seen in Table 1, the disinfectant algicidal composition of Comparative Example 1 containing benzotriazole but not containing sulfamic acid and having a pH of 13.0 has a fast decomposition rate of sodium hypochlorite. The residual chlorine concentration is rapidly decreasing.
The fungicidal and algicidal compositions of Comparative Examples 2 and 3 containing sulfamic acid but having a pH of 12.0, the decomposition of sodium hypochlorite is very fast regardless of the presence or absence of benzotriazole. Concentration is decreasing rapidly.
The amount of the sodium hydroxide aqueous solution was further increased, and the bactericidal algicidal composition of Reference Examples 1 and 3 adjusted to pH 13.4 and the bactericidal algicidal composition of Reference Examples 2 and 4 adjusted to pH 13.8 were Regardless of the presence or absence of triazole, the decrease in residual chlorine concentration is slow, and by mixing sodium hypochlorite and sulfamic acid and setting the pH to 13 or more, decomposition of sodium hypochlorite is effectively suppressed. I understand that. In addition, the stability at high temperatures is improved by increasing the amount of sodium hydroxide.

In Reference Examples 5 to 9 and Comparative Examples 4 to 5, the prepared bactericidal algicidal composition was put in a white white-mouthed bottle made of polyethylene each having a capacity of 100 mL, and 7 bottles were arranged side by side to Atsugi from May 10 to 30 Residual chlorine concentration in the composition was measured on the 0th, 6th, 14th and 20th days of the lapse of days.
Reference Example 5
A bactericidal algicidal composition was prepared by blending 12.4 g of water, 15.6 g of 48 wt% aqueous sodium hydroxide, 12.0 g of sulfamic acid and 60.0 g of 12 wt% aqueous sodium hypochlorite. The pH of this bactericidal algicidal composition was 13.4.
The residual chlorine concentration in this bactericidal algicidal composition was 7.2% by weight immediately after preparation, 6.1% by weight after 6 days, 4.0% by weight after 14 days, and 3.0% by weight after 20 days.
Reference Example 6
Formulated with 12.4 g of water, 15.6 g of 48 wt% sodium hydroxide aqueous solution, 12.0 g of sulfamic acid, 60.0 g of 12 wt% sodium hypochlorite aqueous solution and 0.2 g of benzotriazole A product was prepared. The pH of this bactericidal algicidal composition was 13.4.
The residual chlorine concentration in this bactericidal algicidal composition was 7.2% by weight immediately after preparation, 6.4% by weight after 6 days, 5.2% by weight after 14 days, and 4.4% by weight after 20 days.
Reference Example 7
Except that the amount of benzotriazole was 0.5g, the same procedure as Reference Example 6, a microbicidal and algicidal composition was prepared, the pH was measured and the residual chlorine concentration.
Reference Example 8
A bactericidal algicidal composition was prepared in the same manner as in Reference Example 6 except that the amount of benzotriazole was 1.0 g, and the pH and residual chlorine concentration were measured.
Reference Example 9
A bactericidal algicidal composition was prepared in the same manner as in Reference Example 6 except that 0.5 g of tolyltriazole was added instead of benzotriazole, and the pH and residual chlorine concentration were measured.
Comparative Example 4
A bactericidal algicidal composition was prepared by blending 24.4 g of water, 15.6 g of a 48 wt% aqueous sodium hydroxide solution and 60.0 g of a 12 wt% aqueous sodium hypochlorite solution. The pH of this bactericidal algicidal composition was 14.0.
The residual chlorine concentration in this bactericidal algicidal composition was 7.2 wt% immediately after preparation, 5.7 wt% after 6 days, 3.9 wt% after 14 days, and 2.8 wt% after 20 days.
Comparative Example 5
A bactericidal algicidal composition was prepared in the same manner as in Comparative Example 4 except that 2.0 g of benzotriazole was added, and the pH and residual chlorine concentration were measured.
The results of Reference Examples 5 to 9 and Comparative Examples 4 to 5 are shown in Table 2.

As seen in Table 2, in Reference Examples 5 to 8 in which sulfamic acid or sulfamic acid and benzotriazole were blended, the residual chlorine concentration after aging was high, and the decomposition of the active ingredient was suppressed. As the blending amount of benzotriazole increases, the residual chlorine concentration increases, indicating that benzotriazole contributes to the suppression of decomposition of the active ingredient. Moreover, also in Reference Example 9 in which sulfamic acid and tolyltriazole were blended, the residual chlorine concentration after aging was high, and the decomposition of the active ingredient was suppressed.
On the other hand, in Comparative Example 4 in which neither an azole compound nor sulfamic acid was blended, the residual chlorine concentration after aging was lower than that in Examples, and the effect of suppressing the decomposition of active ingredients did not appear. Further, in Comparative Example 5 in which only benzotriazole is blended, the residual chlorine concentration is lower than in Comparative Example 4, and when benzotriazole is blended alone, the effect of promoting the decomposition of the active ingredient appears. By using sulfamic acid, which has a weak effect of suppressing the decomposition of the active ingredient alone, and an azole compound, which has the effect of promoting the decomposition of the active ingredient, alone, it exhibits a very specific synergistic effect on both. The decomposition can be effectively suppressed and a high residual chlorine concentration can be maintained.

In Examples 10-13, the circulating water system provided with the water tank 1, the pump 2, the flowmeter 3, and the copper tube 4 shown in FIG. 1 was used. The amount of water retained in this water system is 15 L, and the copper tube has a length of 1,350 mm and an inner diameter of 19 mm. In this water system, using Atsugi City water as test water, adding 3.0 g of the prepared bactericidal algicidal composition, circulating water at a water temperature of 30 ° C. and a flow rate of 10 L / min, 24 hours and 72 hours later The residual chlorine concentration in water was measured.
Example 10
A bactericidal algicidal composition was prepared by blending 12.4 g of water, 15.6 g of 48 wt% aqueous sodium hydroxide, 12.0 g of sulfamic acid and 60.0 g of 12 wt% aqueous sodium hypochlorite. The pH of this bactericidal algicidal composition was 13.4.
The residual chlorine concentration in the circulating water to which this bactericidal algicidal composition was added was 13.0 mg / L after 24 hours and 10.5 mg / L after 72 hours. The residual ratio of the residual chlorine concentration after 72 hours was: It was 72.9%.
Example 11
Combining 12.15 g of water, 15.6 g of 48 wt% sodium hydroxide aqueous solution, 12.0 g of sulfamic acid, 60.0 g of 12 wt% sodium hypochlorite aqueous solution and 0.25 g of benzotriazole, A product was prepared. The pH of this bactericidal algicidal composition was 13.4.
The residual chlorine concentration in the circulating water to which this bactericidal algicidal composition was added was 13.5 mg / L after 24 hours and 13.0 mg / L after 72 hours. The residual ratio of the residual chlorine concentration after 72 hours was: It was 90.3%.
Example 12
A bactericidal algicidal composition was prepared in the same manner as in Example 11 except that the amount of water was 11.9 g and the amount of benzotriazole was 0.5 g, and the pH was measured and added to the circulating water system. Then, the residual chlorine concentration in water was measured.
Example 13
A bactericidal algicidal composition was prepared in the same manner as in Example 11 except that the amount of water was 11.4 g and the amount of benzotriazole was 1.0 g, and the pH was measured and added to the circulating water system. Then, the residual chlorine concentration in water was measured.
The results of Examples 10-13 are shown in Table 3.

As seen in Table 3, in Examples 12 to 13 using the bactericidal algicidal composition containing benzotriazole, compared to Example 11 using the bactericidal algicidal composition not containing benzotriazole. When the concentration of residual chlorine after aging is high and the decomposition of the active ingredient is suppressed and the concentration of benzotriazole in the circulating water is 1.0 mg / L or more, the residual chlorine concentration is not lowered at all for 72 hours.
Example 14
In a 200 mL glass beaker, weighed 6.7 g of water, 19.3 g of a 48 wt% aqueous sodium hydroxide solution, 2.0 g of benzotriazole and 12.0 g of sulfamic acid in this order. The bottom 12 wt% sodium hypochlorite aqueous solution 60.0g was added and stirred to produce a bactericidal algicidal composition.
Although some bubbles were generated, the bactericidal algicidal composition could be produced without bumping. In addition, the residual chlorine concentration of the obtained bactericidal algicidal composition was 7.2% by weight.
Comparative Example 6
In a 200 mL glass beaker, 6.7 g of water, 19.3 g of 48 wt% sodium hydroxide aqueous solution, 2.0 g of benzotriazole and 12.0 g of sulfamic acid were weighed in this order, and each drug was dissolved by stirring. When this solution was added little by little to a 200 mL glass beaker in which 60.0 g of a 12 wt% sodium hypochlorite aqueous solution had been weighed in advance, bubbles started to occur in the middle of mixing, and then suddenly boiled. Occurrence was observed.

  The present invention relates to a bactericidal algicidal composition, and the present invention maintains an alkaline pH of 13 or higher, thereby preventing decomposition of active ingredients and maintaining a high residual chlorine concentration. Can be sterilized and algae killed. According to the present invention, it can be used as a fungicidal algicidal composition that is safe and does not cause a decrease in residual chlorine concentration.

FIG. 1 is a system diagram of a circulating water system used in Examples.

Explanation of symbols

1 Water tank 2 Pump 3 Flow meter 4 Copper tube

Claims (1)

When adding a chlorine-based oxidizing agent, an azole-based compound and sulfamic acid or a salt thereof to the circulating cooling water system, a composition containing 3-12% by weight of the chlorine-based oxidizing agent and 0.05-5% by weight of the azole-based compound the addition weight ratio of chlorine-based oxidizing agent to azole compounds by adding a composition containing 3 to 12: the ratio of 0.05 to 3, and, sulfamic of available chlorine per mole of the chlorine-based oxidizing agent A method for sterilizing a circulating cooling water system comprising adding an acid or a salt thereof in a ratio of 0.3 to 1.5 mol to the circulating cooling water system.

Images