JP6630563B2 - Water sterilization method - Google Patents

Description

  The present invention relates to a method for disinfecting water containing a trihalomethane precursor and bromide ions.

  As a bactericidal method for suppressing aqueous slime, an oxidizing bactericide such as hypochlorous acid or hypobromite is used as a slime suppressant (bactericide).

  However, when hypochlorous acid is added as a disinfectant to water containing a trihalomethane precursor, there is a problem that trihalomethane such as chloroform is generated. In particular, in the case of water containing bromide ions such as seawater, even if the disinfectant to be added is a chlorine-based disinfectant such as hypochlorous acid, a large amount of bromine-based trihalomethane such as bromoform is generated, As a result, the total trihalomethane concentration increases.

  For example, Patent Literature 1 describes that the higher the concentration of bromide ions present in water, the higher the production of brominated trihalomethane and the higher the total trihalomethane concentration. Patent Document 1 discloses that at least one of chloride ion concentration, bromine ion concentration and electric conductivity in raw water is continuously monitored, and when the concentration is high, the granular activated carbon treatment is performed by biological activated carbon treatment and granular activated carbon adsorption. There is described an advanced water purification treatment method capable of efficiently and remarkably reducing the concentrations of both chlorine-based trihalomethane and brominated-based trihalomethane by performing the treatment in two steps. However, the method of Patent Document 1 requires equipment for activated carbon treatment. Further, Patent Document 1 does not disclose a difference in trihalomethane-forming ability between a normal halogen such as hypochlorous acid and a stabilized halogen such as stabilized hypobromous acid.

  Patent Literature 2 discloses that in an electrolysis sterilizer for sterilizing treated water containing seawater, a brominated trihalomethane that is easily volatilized by aeration is controlled by controlling the sterilization with substantially only hypobromous acid. It is described to be formed selectively so that no residual trihalomethane occurs. However, the method of Patent Document 2 requires an electrolysis sterilizer. Further, Patent Document 2 does not describe stabilized hypobromous acid and the like.

JP-A-7-124593 JP-A-11-253958

  An object of the present invention is to provide a method for disinfecting water that can easily suppress the production of trihalomethane while suppressing the production of slime in water containing a trihalomethane precursor and a bromide ion.

The present invention relates to a treatment water containing a trihalomethane precursor and a bromide ion, wherein a bromine-based oxidizing agent, or a reactant of a bromine compound and a chlorine-based oxidizing agent, and a sulfamic acid compound are present , the concentration of trihalomethane precursors of water, and the 0.01 mg / L or more as trihalomethane formation potential, the concentration of bromide ions in the water to be treated, 5 mg / L Ru der least a method for sterilizing water.

In the present invention, a reaction product of a bromine-based oxidizing agent or a reaction product of a bromine compound and a chlorine-based oxidizing agent with a sulfamic acid compound is present in water to be treated containing a trihalomethane precursor and a bromide ion. , the concentration of trihalomethane precursors of the water to be treated, and at 0.01 mg / L or more as trihalomethane formation potential, the concentration of bromide ions in the water to be treated is, 5 mg / L Ru der above, in a method of sterilizing water is there.

The present invention, in the for-treatment water containing the trihalomethane precursors and bromide ions, a mixture of bromine and sulfamic acid compound, or, in the presence of reaction products of bromine and sulfamic acid compound, trihalomethane precursors of the water to be treated the concentration of the substance, and the 0.01 mg / L or more as trihalomethane formation potential, the concentration of bromide ions in the water to be treated, 5 mg / L Ru der least a method for sterilizing water.

  In the method of disinfecting water, a reaction product of the bromine and the sulfamic acid compound is obtained by a method including a step of adding bromine to a mixed solution containing water, an alkali and a sulfamic acid compound and reacting the mixture under an inert gas atmosphere. It is preferably obtained.

  In the water disinfection method, it is preferable that the trihalomethane precursor contains humic substances.

  In the present invention, a bromine-based oxidizing agent or a reactant of a bromine compound and a chlorine-based oxidizing agent is present in water to be treated containing a trihalomethane precursor and a bromide ion; By reacting a sulfamate compound with a reactant of a chlorine-based oxidant and a bromine-based oxidant or a reaction product of a bromine-based compound and a chlorine-based oxidant with a sulfamic acid compound The presence of a mixture of bromine and a sulfamic acid compound; or the presence of a reaction product of a bromine and a sulfamic acid compound, thereby easily producing trihalomethane while suppressing the production of slime. It can be suppressed.

It is a figure which shows the total trihalomethane concentration (mg / L) in the treated water with respect to the bromide ion concentration (mg / L) in the treated water in an example and a comparative example.

  An embodiment of the present invention will be described below. The present embodiment is an example for implementing the present invention, and the present invention is not limited to the present embodiment.

<Water sterilization method>
The method of disinfecting water according to the embodiment of the present invention is a method in which a “bromine-based oxidizing agent” is present as a slime inhibitor in the water to be treated containing a trihalomethane precursor and a bromide ion, or a method such as hypobromous acid. This is a method in which "a reaction product of a bromine compound and a chlorine-based oxidizing agent" is present.

  The method for disinfecting water according to the embodiment of the present invention is a method of causing a slime inhibitor to contain a `` bromine-based oxidizing agent '' and a `` sulfamic acid compound '' in water to be treated containing a trihalomethane precursor and bromide ions, Alternatively, this is a method in which a “reacted product of a bromine compound and a chlorine-based oxidizing agent” and a “sulfamic acid compound” are present. Thereby, it is considered that a hypobromite stabilized composition is formed in water.

  In addition, the method for disinfecting water according to the embodiment of the present invention is a method for disinfecting water containing a trihalomethane precursor and bromide ions, as a slime inhibitor with a `` reaction product of a brominated oxidizing agent and a sulfamic acid compound ''. A method for causing a hypobromite-stabilized composition to exist, or a hypobromite-stabilized composition that is a `` reaction product of a bromine compound and a chlorine-based oxidizing agent with a sulfamic acid compound '' It is a way to make it exist.

  Specifically, the method for disinfecting water according to the embodiment of the present invention includes, in the water to be treated containing a trihalomethane precursor and a bromide ion, for example, `` bromine '', `` bromine chloride '', `` hypobromous acid '' or This is a method in which “a reaction product of sodium bromide and hypochlorous acid” is present.

  The method for disinfecting water according to the embodiment of the present invention is a method for dissolving water to be treated containing a trihalomethane precursor and a bromide ion, for example, “bromine”, “bromine chloride”, “hypobromite” or “sodium bromide”. And a reactant with hypochlorous acid and a sulfamic acid compound.

  In addition, the method for disinfecting water according to the embodiment of the present invention includes a method of treating water to be treated containing a trihalomethane precursor and bromide ions, for example, a "reaction product of bromine and a sulfamic acid compound", and "bromine chloride and sulfamine. This is a method in which a "reaction product of an acid compound" or a "reaction product of a reaction product of sodium bromide and hypochlorous acid with a sulfamic acid compound" is present. Although it is not clear what kind of compound is generated as `` reaction product of bromine and sulfamic acid compound '', it is assumed that `` bromosulfamic acid '' which is a hypobromite stabilized compound is generated. Conceivable.

  According to these methods, it is possible to easily suppress the production of trihalomethane while suppressing the production of slime in water containing a trihalomethane precursor and a bromide ion.

  When bromide ions are contained in water (for example, 5 mg / L or more) and trihalomethane precursors such as humic substances are added as in seawater, hypochlorous acid is mainly added as a slime inhibitor. Produces brominated trihalomethane. Since brominated trihalomethane has a larger molecular weight than chlorinated trihalomethane, the total trihalomethane concentration becomes larger.

  Slime inhibitors such as "hypobromite" or "stabilized hypobromite in which a brominated oxidizing agent and sulfamic acid coexist" used in the water sterilization method according to the embodiment of the present invention are hypochlorous acid. Exhibits a slime-inhibiting effect (bactericidal effect) equivalent to or higher than acid. When a trihalomethane precursor and a bromide ion are present in the system, a brominated trihalomethane is mainly produced. However, these “hypobromite” and “stabilized hypobromite” are different from ordinary hypochlorous acid in that the amount of trihalomethane produced hardly increases with an increase in bromide ion concentration. Therefore, according to the method for disinfecting water according to the present embodiment using a slime inhibitor such as "hypobromite" or "stabilized hypobromite in which a brominated oxidizing agent and sulfamic acid coexist," bromide It is considered that the concentration of trihalomethane generated in water containing ions is lower than in the case of using hypochlorous acid.

  On the other hand, `` stabilized hypochlorous acid '' such as chlorosulfamic acid is stabilized, and although trihalomethane generation ability is suppressed, it is converted to `` hypobromite '' or `` stabilized hypobromite ''. In comparison, the bactericidal activity is low, and a sufficient slime control effect cannot be obtained.

  The slime inhibitor used in the method for disinfecting water according to the present embodiment has a slime inhibitory effect equal to or greater than that of hypochlorous acid, but when the treated water contains bromide ions, Compared to chloric acid, it produces less trihalomethane. Therefore, the method for disinfecting water according to the present embodiment is suitable as a method for disinfecting water containing a trihalomethane precursor and bromide ions.

  As described above, the water disinfection method according to the present embodiment can perform a disinfection treatment that minimizes the trihalomethane concentration in the water to be treated while having a high slime suppression effect.

  Among the sterilization methods for water according to the present embodiment, a method for causing a “brominated oxidizing agent” and a “sulfamic acid compound” to exist, a “reactant of a bromine compound and a chlorine-based oxidizing agent” and a “sulfamic acid compound” A method of causing a `` reaction product of a bromine-based oxidizing agent and a sulfamic acid compound '' or a `` reaction product of a reaction product of a bromine compound and a chlorine-based oxidizing agent with a sulfamic acid compound '' The method of causing the presence of a `` bromine-based oxidizing agent '' or the method of causing the `` reactant of a bromine compound and a chlorine-based oxidizing agent '' compared to the method of presenting a trihalomethane generation amount because the oxidizing power of the drug is low. It is more suitable as a sterilization method for water containing a small amount of a trihalomethane precursor and bromide ions.

  In the method for disinfecting water according to the present embodiment, when the “bromine oxidant” or the “reactant of the bromine compound and the chlorine oxidant” is bromine, the chlorine oxidant does not exist, and thus the treatment is performed. The amount of trihalomethane generated in water is also reduced, which is more suitable as a method for sterilizing water containing a trihalomethane precursor and bromide ions. When a chlorine-based oxidizing agent is contained, chloric acid may be generated.

  Trihalomethane refers to one in which three hydrogen atoms of methane are substituted with halogen, and examples thereof include chloroform, bromodichloromethane, dibromochloromethane, and bromoform. The trihalomethane precursor is not particularly limited as long as it is a substance that becomes a precursor of trihalomethane, and examples thereof include a compound having a 1,3-diketone structure and a compound having a 1,3-dihydroxybenzene structure. Specific examples of the trihalomethane precursor include, for example, humic substances including humic acid and fulvic acid. Here, humic substances (humic substances) are organic components formed by humification of leaves and stems of plants. Called fulvic acid.

  The trihalomethane precursor can be measured as a trihalomethane generating ability (THMFP) (mg / L) by a measurement method based on the “Special Law on Conservation of Water Quality in Tap Water Source Areas for Prevention of Specific Water Use Failure”. Specifically, the sample was produced under the condition of adding sodium hypochlorite so that the sample had a pH of 7.0, a temperature of 20 ° C., a reaction time of 24 hours, and a free residual chlorine concentration of 24 mg / L after 24 hours. In this method, the amount of trihalomethane produced is measured and measured by simultaneous analysis using a purge trap-gas chromatograph-mass spectrometer. The trihalomethane precursor can also be measured by a TOC meter or the like.

  When the trihalomethane precursor is present in an amount of 0.001 mg / L or more as a trihalomethane generating ability (THMFP) (mg / L), trihalomethane is easily generated. Therefore, the trihalomethane generating ability of the water to be treated containing the trihalomethane precursor and bromide ion is low. When the amount is 0.001 mg / L or more, preferably 0.01 mg / L or more, and more preferably 0.02 mg / L or more, the method for sterilizing water according to the present embodiment exhibits more effects. The upper limit of the trihalomethane generating ability of the water to be treated is not particularly limited, but is, for example, 1 mg / L or less.

  Further, if the trihalomethane precursor is present in an amount of 0.5 mg / L or more as TOC, trihalomethane is easily generated. Therefore, the TOC in the water to be treated is 0.5 mg / L or more, preferably 5.0 mg / L or more, and more preferably 10. When the amount is 0 mg / L or more, the method for sterilizing water according to the present embodiment is more effective. The upper limit of the TOC in the water to be treated is not particularly limited, but is, for example, 100 mg / L or less. In addition, when measured by the below-mentioned Example, the trihalomethane formation ability 0.01 mg / L is equivalent to 5.0 mg / L of TOC.

  In particular, when the trihalomethane precursor contains humic acid, the presence of 0.89 mg / L or more of humic acid easily produces trihalomethane. Therefore, the amount of humic acid in the water to be treated is 0.89 mg / L or more, preferably 8.9 mg / L. When the amount is L or more, more preferably 890 mg / L or more, the method for sterilizing water according to the present embodiment exhibits more effects. The upper limit of humic acid in the water to be treated is not particularly limited, but is, for example, 180 mg / L or less. In addition, when measured by the below-mentioned Example, the trihalomethane formation ability 0.01 mg / L is equivalent to humic acid 8.9 mg / L.

  In particular, when the bromide ion is present in the water to be treated in an amount of 5 mg / L or more, the concentration of bromide ion in the water to be treated is 5 mg / L or more, preferably 18 mg / L or more, because trihalomethane is easily generated in the case of hypochlorous acid. If there is, the method of sterilizing water according to the present embodiment exhibits more effects. The upper limit of the concentration of bromide ions in the water to be treated is not particularly limited, but is, for example, 1000 mg / L or less.

  In the method for disinfecting water according to the present embodiment, for example, a "bromine-based oxidizing agent" or a "reacted product of a bromine compound and a chlorine-based oxidizing agent" is used as a chemical in water to be treated containing a trihalomethane precursor and bromide ions. Injection may be performed by a pump or the like. The “bromine compound” and the “chlorine-based oxidizing agent” may be separately added to the aqueous system, or the stock solutions may be mixed and then added to the aqueous system.

  For example, in the water to be treated containing a trihalomethane precursor and bromide ions, a “bromine-based oxidant” or a “reactant of a bromine compound and a chlorine-based oxidant” and a “sulfamic acid compound” are injected with a chemical injection pump or the like. May be injected. The "bromine-based oxidant" or "reactant of a bromine compound and a chlorine-based oxidant" and the "sulfamic acid compound" may be separately added to an aqueous system, or mixed with stock solutions and then added to an aqueous system. It may be added.

  Further, for example, in the water to be treated containing a trihalomethane precursor and bromide ion, a `` reaction product of a bromine-based oxidant and a sulfamic acid compound '' or `` a reaction product of a bromine compound and a chlorine-based oxidant, The reaction product of the sulfamic acid compound ”may be injected by a chemical injection pump or the like.

  The ratio of the equivalent of the “sulfamic acid compound” to the equivalent of the “bromine oxidant” or the “reactant of the bromine compound and the chlorine oxidant” is preferably 1 or more, and more preferably 1 or more and 2 or less. Is more preferable. When the ratio of the equivalent of “sulfamic acid compound” to the equivalent of “bromine-based oxidizing agent” or “reacted product of bromine compound and chlorine-based oxidizing agent” is less than 1, the stability of the active ingredient is insufficient. If it exceeds 2, the manufacturing cost may increase.

  The effective halogen concentration in the water to be treated is preferably 0.01 to 100 mg / L in terms of the effective chlorine concentration. When the amount is less than 0.01 mg / L, a sufficient slime suppressing effect may not be obtained, and when the amount is more than 100 mg / L, corrosion of a metal material such as a pipe may be caused.

  Examples of the bromine-based oxidizing agent include bromine (liquid bromine), bromine chloride, bromate, bromate, hypobromite and the like.

  Among these, the preparation of "bromine and sulfamic acid compound (mixture of bromine and sulfamic acid compound)" or "reaction product of bromine and sulfamic acid compound" using bromine is described as "hypochlorous acid and bromine compound and As compared with the preparations of "sulfamic acid" and the preparations of "bromine chloride and sulfamic acid" and the like, the amount of trihalomethane produced is smaller, and thus they are more preferable as slime inhibitors. Since stabilized hypobromous acid produced from bromine chloride contains a part of hypochlorous acid, the amount of trihalomethane produced may increase.

  That is, in the method for disinfecting water according to the embodiment of the present invention, bromine and a sulfamic acid compound are present in the water to be treated containing a trihalomethane precursor and a bromide ion (a mixture of bromine and a sulfamic acid compound is present). Preferably). Further, it is preferable that a reaction product of bromine and a sulfamic acid compound be present in the water to be treated containing a trihalomethane precursor and a bromide ion.

  Examples of the bromine compound include sodium bromide, potassium bromide, lithium bromide, ammonium bromide, and hydrobromic acid. Of these, sodium bromide is preferred from the viewpoints of formulation cost and the like.

  Examples of the chlorine-based oxidizing agent include chlorine gas, chlorine dioxide, hypochlorous acid or a salt thereof, chlorite or a salt thereof, chloric acid or a salt thereof, perchloric acid or a salt thereof, chlorinated isocyanuric acid or a salt thereof. And the like. Among these, examples of the salt include alkali metal hypochlorites such as sodium hypochlorite and potassium hypochlorite, and alkaline earth hypochlorite such as calcium hypochlorite and barium hypochlorite. Metal salts, alkali metal chlorites such as sodium chlorite and potassium chlorite, alkaline earth metal chlorites such as barium chlorite, and other metal chlorites such as nickel chlorite And alkali earth chlorates such as ammonium chlorate, sodium chlorate and potassium chlorate, and alkaline earth chlorates such as calcium chlorate and barium chlorate. One of these chlorine-based oxidizing agents may be used alone, or two or more thereof may be used in combination. As the chlorine-based oxidizing agent, sodium hypochlorite is preferably used from the viewpoint of handleability and the like.

The sulfamic acid compound is a compound represented by the following general formula (1).
R ₂ NSO ₃ H (1)
(In the formula, R is independently a hydrogen atom or an alkyl group having 1 to 8 carbon atoms.)

  As the sulfamic acid compound, for example, in addition to sulfamic acid (amidosulfate) in which both R groups are both hydrogen atoms, N-methylsulfamic acid, N-ethylsulfamic acid, N-propylsulfamic acid, N- One of two R groups such as isopropylsulfamic acid and N-butylsulfamic acid is a hydrogen atom, and the other is an alkyl group having 1 to 8 carbon atoms; a sulfamic acid compound; N, N-dimethylsulfamic acid; Two R groups such as N-diethylsulfamic acid, N, N-dipropylsulfamic acid, N, N-dibutylsulfamic acid, N-methyl-N-ethylsulfamic acid and N-methyl-N-propylsulfamic acid; One of two R groups such as a sulfamic acid compound in which both are an alkyl group having 1 to 8 carbon atoms and N-phenylsulfamic acid is An atom, the other is sulfamic acid compound or a salt thereof, such as an aryl group having 6 to 10 carbon atoms. As the sulfamate, for example, sodium salts, alkali metal salts such as potassium salts, calcium salts, strontium salts, alkaline earth metal salts such as barium salts, manganese salts, copper salts, zinc salts, iron salts, cobalt salts, Other metal salts such as nickel salts, ammonium salts, guanidine salts and the like. One of these sulfamic acid compounds and salts thereof may be used alone, or two or more thereof may be used in combination. As the sulfamic acid compound, it is preferable to use sulfamic acid (amidosulfuric acid) from the viewpoint of environmental load and the like.

  In the method for sterilizing water according to the present embodiment, an alkali may be further present. Examples of the alkali include alkali hydroxides such as sodium hydroxide and potassium hydroxide. Sodium hydroxide and potassium hydroxide may be used in combination from the viewpoint of product stability at low temperatures. The alkali may be used as an aqueous solution instead of a solid.

  In the water disinfection method according to this embodiment, the pH of the water to be treated is preferably in the range of 3 to 10, and more preferably in the range of 5 to 9. If the pH of the water to be treated is less than 3, the active ingredient may be easily volatilized, and if it exceeds 10, the sterilization performance may be reduced.

  The application target of the water sterilization method according to the present embodiment is not particularly limited as long as it is an aqueous system containing a trihalomethane precursor and a bromide ion, and specifically, slime suppression in a seawater desalination step, ballast water, and the like. Is mentioned.

<Slime inhibitor composition for water>
The water slime inhibitor composition according to this embodiment contains a `` bromine-based oxidant '' or a `` reactant of a bromine compound and a chlorine-based oxidant '', and a `` sulfamic acid compound '', and It may contain an alkali.

  In addition, the slime inhibitor composition for water according to the present embodiment is a "reaction product of a brominated oxidizing agent and a sulfamic acid compound" or "a reactant of a brominated compound and a chlorine oxidizing agent, and a sulfamic acid compound. And a reaction product of, and may further contain an alkali.

  The bromine-based oxidizing agent, bromine compound, chlorine-based oxidizing agent, and sulfamic acid compound are as described above.

  As the slime inhibitor composition for water according to the present embodiment, those containing bromine and a sulfamic acid compound (containing a mixture of bromine and a sulfamic acid compound), from the viewpoint that the amount of trihalomethane produced is small, For example, a mixture of bromine and a sulfamic acid compound and an alkali and water, or a mixture containing a reaction product of bromine and a sulfamic acid compound, for example, a reaction product of bromine and a sulfamic acid compound, an alkali, and water And mixtures thereof.

  The slime inhibitor composition for water according to the present embodiment has a higher oxidizing power as compared with a bound chlorine slime inhibitor such as chlorosulfamic acid. Have been. Therefore, it is most suitable as a slime inhibitor for water.

  Unlike the hypochlorous acid, the water slime inhibitor composition according to the present embodiment has a reduced trihalomethane generation ability, and thus has little effect on the quality of treated water. Further, since the concentration can be measured on site similarly to hypochlorous acid or the like, more accurate concentration control is possible.

  The pH of the composition is, for example, above 13.0, more preferably above 13.2. When the pH of the composition is 13.0 or less, the effective halogen in the composition may become unstable.

  The concentration of bromate in the slime suppressant composition for water is preferably less than 5 mg / kg. When the concentration of bromate in the slime inhibitor composition for water is 5 mg / kg or more, the concentration of bromate ion in the treated water may increase.

<Production method of water slime inhibitor composition>
The slime suppressant composition for water according to the present embodiment is obtained by mixing a brominated oxidizing agent and a sulfamic acid compound, or by mixing a brominated compound and a chlorinated oxidizing agent with a sulfamic acid compound. Obtained, and an alkali may be further mixed.

  Bromine and a water slime inhibitor composition containing a sulfamic acid compound, or a method for producing a water slime inhibitor composition containing a reaction product of bromine and a sulfamic acid compound include water, alkali and Including a step of adding bromine to a mixed solution containing a sulfamic acid compound under an inert gas atmosphere to cause a reaction, or a step of adding bromine to a mixed solution containing water, an alkali and a sulfamic acid compound under an inert gas atmosphere Is preferred. By adding and reacting under an inert gas atmosphere, or by adding under an inert gas atmosphere, the bromate ion concentration in the composition decreases, and the bromate ion concentration in permeated water such as RO permeated water is reduced. Lower.

Used but are not limited to inert gas, at least one and preferably one in terms of nitrogen and argon, such as production, nitrogen is particularly preferred from the viewpoint of production cost and the like.

  The oxygen concentration in the reactor at the time of adding bromine is preferably 6% or less, more preferably 4% or less, further preferably 2% or less, and particularly preferably 1% or less. If the oxygen concentration in the reactor during the reaction of bromine exceeds 6%, the amount of bromic acid generated in the reaction system may increase.

  The addition ratio of bromine is preferably 25% by weight or less, more preferably 1% by weight or more and 20% by weight or less based on the total amount of the composition. If the bromine addition rate exceeds 25% by weight based on the total amount of the composition, the amount of bromic acid generated in the reaction system may increase. If it is less than 1% by weight, the bactericidal activity may be poor.

  The reaction temperature at the time of adding bromine is preferably controlled in the range of 0 ° C. or more and 25 ° C. or less, but is more preferably controlled in the range of 0 ° C. or more and 15 ° C. or less from the viewpoint of production cost and the like. If the reaction temperature at the time of adding bromine exceeds 25 ° C., the amount of bromic acid produced in the reaction system may increase, and if it is lower than 0 ° C., it may freeze.

  Hereinafter, the present invention will be described in more detail with reference to Examples and Comparative Examples. However, the present invention is not limited to the following Examples.

When a hypobromite stabilized composition which is a "reaction product of a brominated oxidizing agent and a sulfamic acid compound" is used as a slime inhibitor (Example 1), a "brominated oxidizing agent" is used ( In the case of using Reference Example 2) and hypochlorous acid, which is a general slime inhibitor (Comparative Example 1), hypochlorous acid stable which is a "reaction product of hypochlorous acid and a sulfamic acid compound" The effect on the trihalomethane concentration in the treated water and the sterilization performance was compared with the case of using the activated composition (Comparative Example 2).

[Preparation of Composition 1]
Under a nitrogen atmosphere, liquid bromine: 16.9% by weight (wt%), sulfamic acid: 10.7% by weight, sodium hydroxide: 12.9% by weight, potassium hydroxide: 3.94% by weight, water: residual The components were mixed to prepare Composition 1. The pH of composition 1 was 14, and the effective halogen concentration (concentration in terms of effective chlorine) was 7.5% by weight. The detailed preparation method of the composition 1 is as follows.

  While controlling the flow rate of nitrogen gas with a mass flow controller so that the oxygen concentration in the reaction vessel is maintained at 1%, 1436 g of water and 361 g of sodium hydroxide are added to a 2 L four-necked flask sealed by continuous injection. After mixing and then adding 300 g of sulfamic acid and mixing, 473 g of liquid bromine was added while maintaining the cooling of the reaction solution at 0 to 15 ° C., and 230 g of a 48% potassium hydroxide solution was further added. Thus, a target composition 1 was obtained in which the weight ratio of sulfamic acid to the total amount of the composition was 10.7%, the bromine content was 16.9%, and the equivalent ratio of sulfamic acid to the equivalent weight of bromine was 1.04. The pH of the resulting solution was 14, as measured by the glass electrode method. The bromine content of the resulting solution was 16.9% as measured by a method of converting bromine to iodine with potassium iodide and then performing redox titration with sodium thiosulfate, and the theoretical content was 16.9%. ) Was 100.0%. The oxygen concentration in the reaction vessel during the bromine reaction was measured using "Oxygen Monitor JKO-02 LJDII" manufactured by Jiko Corporation. The bromate concentration was less than 5 mg / kg.

[Composition 2]
A 9% by weight aqueous solution of sodium hypobromite (Kanto Chemical, deer grade 1) was used as composition 2.

[Composition 3]
A 12% by weight aqueous solution of sodium hypochlorite was used as composition 3.

[Composition 4]
Composition 4 was prepared by mixing a 12% aqueous sodium hypochlorite solution: 50% by weight, a sulfamic acid: 10% by weight, a sodium hydroxide: 8% by weight, and a water: residue. The pH of composition 4 was 14, and the effective halogen concentration (concentration in terms of effective chlorine) was 6% by weight.

<Example 1 , Reference Example 2, Comparative Examples 1 and 2>
Under the following conditions, Compositions 1 to 3 were added to the raw water, respectively, and the total trihalomethane concentration in the treated water was compared. The following simulated water was used as raw water.

(Test condition)
-Raw water: Simulated water having a trihalomethane generating ability of 0.01 mg / L (pure water: 8.9 mg / L of humic acid (manufactured by Wako Pure Chemical Industries) as a trihalomethane precursor, and sodium bromide (manufactured by Kanto Chemical) as a bromide ion source , Special grade) to a concentration of 0.1 to 300 mg / L)
-Drug: Compositions 1 to 3 are added so that the effective halogen concentration (concentration in terms of effective chlorine) becomes 3 mg / L.-Raw water pH: adjusted so that the pH of test water becomes 8 after adding the drug.-Test temperature: 25 ° C
Trihalomethane-forming ability measurement method: pH 7.0, temperature 20 ° C., reaction time 24 hours, under the condition that sodium hypochlorite was added such that the free residual chlorine concentration after 24 hours was 1-2 mg / L. And the amount of generated trihalomethane was determined by simultaneous analysis using a purge trap-gas chromatograph-mass spectrometer. The purge trap apparatus used was "Tekmar Stratum" manufactured by TEKMAR, the gas chromatograph used was "7890" manufactured by Agilent, and the mass spectrometer used was "5975C manufactured by Agilent".
-Measuring method of effective halogen concentration: Measured by DPD method using residual chlorine measuring device ("DR-4000" manufactured by Hach))

(Evaluation method)
[Total trihalomethane concentration in treated water]
Compositions 1 to 3 were added to the simulated water as shown in Table 1 and the pH was adjusted to 8, the water temperature was adjusted to 25 ° C, and the mixture was stirred for 4 hours. Four hours after stirring, the total trihalomethane concentration (mg / L) in the treated water was measured. The results are shown in FIG. Here, the total trihalomethane refers to four substances of chloroform, bromodichloromethane, dibromochloromethane and bromoform.

  The total trihalomethane concentration was measured by a simultaneous analysis method using a purge trap-gas chromatograph-mass spectrometer in accordance with the method specified by the Minister of Health, Labor and Welfare based on the regulations of the Ministry of Health, Labor and Welfare based on the regulations of the Ministry of Health, Labor and Welfare. .

[Comparative test of sterilization power]
Under the following conditions, Compositions 1 and 4 were respectively added to the simulated water, and the sterilizing power was compared.

(Test condition)
・ Water: Simulated water prepared by adding ordinary bouillon to Sagamihara well water and adjusting the number of general bacteria to 10 ⁵ CFU / ml ・ Drugs: Compositions 1 and 4 as effective halogen concentrations (effective chlorine equivalent concentrations), respectively Added to 1 mg / L (Measurement method of effective halogen concentration: measured by DPD method using residual chlorine measuring device ("DR-4000" manufactured by Hach))

(Evaluation method)
-The number of general bacteria 24 hours after the addition of the drug is measured using a bacteria count kit (Bio-Checker TTC, manufactured by Sanai Petroleum)

  Table 1 shows the test results.

Thus, in the embodiment 1, as compared with Comparative Examples 1 and 2, while suppressing the generation of slime in a water containing the trihalomethane precursors and bromide ions, it is possible to suppress the generation of trihalomethanes easily Was.

Claims (5)

In treated water containing a trihalomethane precursor and bromide ion,
A bromine-based oxidant, or a reaction product of a bromine compound and a chlorine-based oxidant,
A sulfamic acid compound;
Exist ,
The concentration of the trihalomethane precursor in the water to be treated is 0.01 mg / L or more as a trihalomethane generating ability,
The concentration of bromide ions in the water to be treated is, a method of sterilizing water, characterized in der Rukoto than 5 mg / L. In treated water containing a trihalomethane precursor and bromide ion,
A bromine-based oxidant, or a reaction product of a bromine compound and a chlorine-based oxidant,
A sulfamic acid compound;
In the presence of the reaction product,
The concentration of the trihalomethane precursor in the water to be treated is 0.01 mg / L or more as a trihalomethane generating ability,
The concentration of bromide ions in the water to be treated is, a method of sterilizing water, characterized in der Rukoto than 5 mg / L. In treated water containing a trihalomethane precursor and bromide ion,
A mixture of bromine and a sulfamic acid compound, or a reaction product of bromine and a sulfamic acid compound ,
The concentration of the trihalomethane precursor in the water to be treated is 0.01 mg / L or more as a trihalomethane generating ability,
The concentration of bromide ions in the water to be treated is, a method of sterilizing water, characterized in der Rukoto than 5 mg / L. A method for sterilizing water according to claim 3 ,
The reaction product of the bromine and the sulfamic acid compound is obtained by a method including a step of adding bromine to a mixed solution containing water, an alkali, and a sulfamic acid compound under an inert gas atmosphere to cause a reaction. A method for disinfecting water, characterized in that: A method for sterilizing water according to any one of claims 1 to 4 ,
The method for disinfecting water, wherein the trihalomethane precursor contains humic substances.