RU2299862C2 - Water disinfection composition - Google Patents

Abstract

FIELD: water treatment.

SUBSTANCE: invention, in particular, relates to disinfection of drinking water under extremal conditions, under field conditions, or when consuming water from surface sources in residential sites having no centralized water-treating and water-supply systems. Solid composition comprises chlorine-containing disinfectant: dichloroisocyanuric acid sodium or potassium salt (2-25%), sodium or potassium chloride (10-75%) and additionally acetic or phosphoric acid alkali metal salt or trichloroisocyanuric acid (1-30%). Proposed composition can be used in the form of dispensable dozed packaging as powder, granules, capsules, or tablets. Composition is further supplemented with binding agents, dispersants, colorant, odorant, whereas activated carbon is added to neutralize excess active chlorine formed. Composition of invention is inexpensive and nontoxic preparation, easy to use, and providing higher biocide efficiency, shortened disinfecting time, and lower concentration as compared to known compositions based on hypochlorites and dichloroisocyanurates.

EFFECT: increased water disinfection efficiency and reduced cost.

12 cl, 1 tbl, 7 ex

Description

The invention relates to compositions for water treatment, in particular for disinfecting water, designed to provide a person with benign drinking water in extreme conditions, in the field or when consuming water from surface sources in settlements that do not have centralized water treatment and water supply systems.

A known composition for water purification based on a chlorine-containing disinfectant - lithium hypochlorite, which additionally contains sodium hydroxide, as well as alkali metal chlorides - sodium and potassium (RU 2192392).

The disadvantage of this composition is the use of the composition of sodium hydroxide, which gives an alkaline reaction medium solutions, which leads to displacement of the dissociation of the molecules in the direction of lithium hypochlorite ion formation OCl ^- and as a consequence, to decrease the activity of a disinfecting composition. The use of expensive lithium hypochlorite slightly compensates for this decrease.

For inactivation of vegetative forms of bacteria with this composition for 5-30 minutes, a concentration of active chlorine of 25-100 mg / dm ³ is required, and for the suppression of spore forms of bacteria within 1-3 hours, a concentration of active chlorine of 1000 to 3000 mg / dm is required ³ .

Closest to the proposed one is a solid composition in the form of a metered package for processing relatively small, pre-determined volumes of water, including a chlorine-containing disinfectant - sodium dichloroisocyanurate and a coagulant - aluminum polyhydroxochloride, having the general formula:

[Al _x (OH) _y Cl _3x-y ] _n .

The composition may additionally contain sodium chloride and sodium bicarbonate (RU 2106311).

The disadvantages of the known disinfecting composition are its multicomponent, the complexity of manufacture, the need for filtering due to the introduction of a water-insoluble component in the composition, a narrow range of requirements for temperature and pH, which leads to a decrease in disinfectant activity.

The examples in the patent RU 2106311 concern only the disinfection of water containing polio viruses, for which the inactivation time is 55 minutes at an active chlorine concentration of 13 mg / dm ³ and 1.5 hours at an active chlorine concentration of 10.5 mg / dm ³ . There is no information in the patent for the inactivation of spore forms, but it is known that such forms require much higher concentrations of active chlorine and a longer exposure time.

The objective of the claimed invention is the creation of a solid chemical preparation for disinfecting water, having a cheaper composition, which ensures better homogenization of the ingredients included in the composition, simplifies its use in water treatment, less toxic, does not require adjustment of the pH of the medium, while maintaining the stability of high disinfecting properties, exhibiting activity against a wide range of pathogenic microflora, including spore forms of bacteria, including disputes of anthrax, and not worsening consumer properties of treated water.

The problem is solved by the proposed solid composition for disinfection of predefined volumes of water, which includes a chlorine-containing disinfectant - sodium or potassium salt of dichloroisocyanuric acid (sodium or potassium dichloroisocyanurate, NaDCA or CDCC), stabilizer - alkali metal chloride - sodium or potassium, as well as an alkali metal salt acetic or phosphoric acid or trichloroisocyanuric acid (TCCC) in the following components, wt.h .:

sodium or potassium salt dichloroisocyanuric acid 2-25 alkali metal chloride 10-75 alkali metal salt of acetic or phosphoric acid or trichloroisocyanuric acid 1-30.

In preferred embodiments, the proposed composition is used in the form of a single unit dose packaging for treating small, predetermined volumes of water. The drug can be used in the form of powder, granules, capsules, tablets. When using the composition in the form of granules and tablets, it additionally contains binders, moreover, magnesium stearate, calcium stearate, talc, starch, carboxymethyl cellulose, methyl cellulose, and also mixtures thereof can be used as binders. To accelerate the destruction of granules and tablets, the composition additionally contains dispersants, which are used as carbonates of alkali and alkaline earth metals, as well as mixtures thereof. The composition may further contain a dye and / or fragrance. In addition, to neutralize the resulting excess active chlorine, the composition further comprises activated carbon. Activated carbon is used in the form of powder, granules, tablets, carbon fiber tissue, as well as mixtures thereof. When using the composition in combination with activated carbon, it is made in the form of a bicomponent single dose packaging.

High and stable disinfecting activity of the claimed composition is achieved by the addition of additives in the form of alkali metal chloride in combination with alkali metal salts of weak acid (acetic or phosphoric) or with weak trichloroisocyanuric acid, enhancing the general disinfecting effect, in addition to the main active ingredient - sodium or potassium dichloroisocyanuric acid .

The biocidal effectiveness of the claimed composition is higher than the biocidal effectiveness of the known compounds for the following reasons.

Firstly, the claimed composition when dissolved in water has a much lower pH (5.3-5.8) than solutions of known compounds: based on lithium hypochlorite (8.5-11.5) and based on sodium isocyanurate (7 , 92-6.5), which gives a higher percentage of undissociated hypochlorous acid formed as a result of hydrolysis of DHCC salts.

HOCl dissociation is pH dependent. This dependence is shown in the table below:

Table Wednesday PH value % HOCl (at 20 ° C) acidic 5,0 99.74 5.5 99.18 6.0 97.45 6.5 92.37 neutral 7.0 79.29 7.5 54.77 8.0 27.69 alkaline 8.5 10.8 9.0 3.69 9.5 1.19 10.0 0.38

It is believed that the lethal effect on microorganisms is due to the chlorination of systems of cellular proteins or enzymes under the influence of undissociated molecules of hypochlorous acid, which leads to the hydrolysis of peptide chains of cell membranes of pathogenic microorganisms.

The introduction of a composition containing hypochlorite (RU 2192392), an additive in the form of an alkali metal chloride (potassium or sodium) shifts the dissociation equilibrium towards undissociated HOCl molecules in an insufficient amount due to the presence of sodium hydroxide (strong alkaline component), which explains its lower bactericidal ability.

In the patent RU 2106311, there are either no additives in the composition at all (if it is used in powder form), or additives are added in order to more quickly destruct the agent (tablets) and do not affect bactericidal activity.

In addition to the alkali metal chloride, alkali metal salts of acetic or phosphoric acid, for example, potassium dihydrogen phosphate, or weak trichloroisocyanuric acid, which have a combined effect and not only enhance the disinfecting activity, are added to the claimed composition in addition to reducing the dose of the disinfectant containing active chlorine, thereby reducing the amount of toxic chlorine-containing organic compounds, but also improve the performance of purified and disinfected drinking water.

Secondly, only part of all active chlorine is free in the solutions obtained using the claimed composition, while the rest is reduced to the form of mono - or dichloroisocyanurates due to a shift in the equilibrium of dissociation with the introduction of additional components. The equilibrium between free and bound chlorine remains stable up to the use of free chlorine, then bound chlorine is released in order to restore disturbed balance.

This release of latent chlorine (in the form of HOCl) provides the creation of higher biocidal capabilities.

To obtain the proposed composition, these ingredients in solid form and appropriate proportions are mixed, granulated or tabletted and packaged in single doses to keep the drug dry.

The drug can be used both in powder form and in the form of granules, capsules or in the form of tablets and can be produced with different contents of the main active substance (sodium dichloroisocyanurate) depending on the composition and amount of treated water.

As a result of the disinfection of the proposed preparation in water, in some cases a rather high level of residual concentration of “active” chlorine may form, which does not allow the use of water immediately after treatment due to a specific smell and taste. To remove them, activated carbon can be added to the treated water, which will absorb undesirable impurities. Activated carbon can be used as a separate component, or in the form of a powder, granules, tablets, carbon fiber tissue in a separate package that is included in a bicomponent, in which in another separate package the described disinfectant composition is in the form of powder, granules, capsules, tablets.

In this case, you should first use one package containing a disinfectant, and after the time of guaranteed destruction of all pathogenic microflora expires, it is supposed to introduce another package with activated carbon into the treated water to completely neutralize the excess "active" chlorine.

In the proposed composition for water disinfection, the combined action of a chlorine-containing disinfectant - sodium or potassium dichloroisocyanurate, sodium or potassium chloride and a weak acid alkali metal salt - acetic or phosphoric, or trichloroisocyanuric acid provides complete disinfection of all types of pathogenic microflora, including fungicidal and tuberculosis the destruction of spore forms, including anthrax, at lower concentrations of active chlorine than the known chlorine-containing disinfectant compositions and.

Example 1

Water was contaminated with vegetative forms of E. coli bacteria to a concentration of microorganisms of 1.8 · 10 ⁵ CFU · dm ^-3 . 1 liter of water was treated with various compounds:

a) pure sodium dichloroisocyanurate (Na DHCC) in an amount of 6 mg;

b) a powdery mixture of 6 mg (2 parts by weight) of NaDCA and 30 mg (10 parts by weight) of potassium chloride;

c) a powdery mixture of 6 mg (2 parts by weight) of NaDCA and 3 mg (1 parts by weight) of TCCA;

d) a powdery mixture of 6 mg (2 parts by weight) of NaDCA, 30 mg (10 parts by weight) of potassium chloride and 3 mg (1 part by weight) of TCCC.

The analysis showed a complete absence of E. coli bacteria during exposure time:

a) 40 minutes;

b) 30 minutes;

c) 30 minutes;

d) 20 minutes.

This example shows the advantage of the proposed composition compared with compositions in another combination of components. Moreover, in comparison with the known compositions, the used concentration of active chlorine is 3-8 times lower.

Example 2

When using a single dose of a granular composition made using a carboxymethyl cellulose binder with a ratio of components in the direction of increasing additives - alkali metal chloride, for example: 6 mg (2 parts by weight) of a disinfectant - sodium dichloroisocyanurate, 225 mg (75 parts by weight) ) potassium chloride and 3 mg (1 parts by weight) of TCA, for disinfection of 1 liter of water with a bacterial contamination level of St.aureus 1.3 · 10 ⁶ CFU dm ^-3 , the analysis showed the complete absence of microorganisms after 15 minutes.

Example 3

The composition becomes even more effective when increasing the amount of all additives. Thus, a complete disinfection of 1 liter of water used in Example 2 with a granular composition made using methylcellulose binder containing 6 mg (2 parts by weight) of a disinfectant - sodium dichloroisocyanurate, 225 mg (75 parts by weight) of potassium chloride and 90 mg (30 parts by weight) of potassium dihydrogen phosphate occurred in 10 minutes.

In the above examples 2, 3, a tendency to enhance the disinfecting properties of the composition due to the combined action of the components is evident.

Example 4

To disinfect 1 liter of water with a biological concentration of hepatitis A virus, a single dose of the composition in the form of an encapsulated composition was used using starch as a binder with the content of components: 20 mg (2 mph) of a disinfectant - sodium dichloroisocyanurate, 100 mg (10 mph) .) - potassium chloride and 300 mg (30 parts by weight) of sodium acetate. At a temperature of + 4 ° C after 20 minutes, and at a temperature of + 35 ° C after 10 minutes, microorganisms died completely. For comparison, 1 liter of water was disinfected with pure sodium dichloroisocyanurate in an amount of 20 mg at a temperature of + 20 ° C. The time required exposure was equal to 45 minutes. However, in these cases, the residual concentration of active chlorine remains in the range of 7.1-7.9 mg.

To improve organoleptic characteristics, 3 g BAU-A activated carbon powder was added to the disinfected water from a bicomponent package to neutralize excess active chlorine.

Repeated tests for active chlorine showed its complete absence, as a result of which the water acquired normal consumer quality.

Example 5

To study the fungicidal efficacy, 1 liter of water infected with Candida albicans and Trichophytou gypseum fungi was treated with a tablet formulation using calcium stearate as a binder, potassium carbonate as a dispersant and dye. The composition contained 20 mg (25 parts by weight) of the disinfectant — sodium dichloroisocyanurate, 60 mg (75 parts by weight) —potassium chloride and 0.8 mg (1 parts by weight) of trichloroisocyanuric acid. Complete disinfection was observed after 10 minutes and 15 minutes, respectively. Under the action of an equivalent amount of pure sodium salt of dichloroisocyanuric acid, disinfection occurred in 25 minutes and 30 minutes.

Example 6

To study the tuberculocidal efficacy, 1 liter of water with a concentration of Mycobacterium B ₅ 1.8 · 10 ⁴ CFU · dm ^{-3 was} treated with an encapsulated composition containing perfume. The composition contained 20 mg (25 parts by weight) of a disinfectant - sodium dichloroisocyanurate, 8 mg (10 parts by weight) of potassium chloride and 24 mg (30 parts by weight) of sodium acetate. An analysis carried out after 20 minutes showed the absence of microorganisms compared with the treatment with 20 mg of pure sodium salt of dichloroisocyanuric acid, where the processing time was 40 minutes.

Example 7

The agar culture of B.anthracis (vaccine strain STI-1) with a microorganism content of 1.3 · 10 ⁶ CFU · dm ^{-3 was} treated for 40 minutes with 80 mg of pure sodium salt of dichloroisocyanuric acid and a composition in the form of tablets containing a talc binder and a dispersant sodium carbonate containing 76 mg (19 parts by weight) of the disinfectant - NaDCA, 40 mg (10 parts by weight) of potassium chloride and 4 mg (1 part by weight) of trichloroisocyanuric acid. In the case of pure sodium isocyanurate, only a decrease in the concentration of microorganisms to 1.7 · 10 CFU · dm ^{-3 was} noted, and treatment with the composition completely destroyed the spores.

The above examples show the high efficiency of the proposed composition for disinfecting water due to the combined synergistic action of its constituent components, shortening the processing time and reducing the applied doses for similar forms of microorganisms compared to pure sodium salt of dichloroisocyanuric acid and other compositions based on it.

Claims (12)

1. A solid composition for disinfecting water for treating predetermined volumes of water and comprising a chlorine-containing disinfectant and an alkali metal chloride - sodium or potassium, characterized in that it contains a sodium or potassium salt of dichloroisocyanuric acid and an additional alkali metal salt of acetic or phosphoric as a chlorine-containing disinfectant acid or trichloroisocyanuric acid in the following components, parts by weight: Sodium or potassium salt dichloroisocyanuric acid 2-25 Alkali metal chloride 10-75 Acetic alkali metal salt or phosphoric acid or trichloroisocyanuric acid 1-30 2. The composition for disinfecting water according to claim 1, characterized in that it is used in the form of a single unit dose packaging. 3. The composition for disinfecting water according to claim 1, characterized in that the composition is a powder, granules, capsules, tablets. 4. The composition for disinfecting water according to claim 3, characterized in that the composition in the form of granules and tablets additionally contains binders. 5. The composition for disinfecting water according to claim 4, characterized in that magnesium binders, calcium stearate, talc, starch, carboxymethyl cellulose, methyl cellulose, and also mixtures thereof can be used as binders. 6. The composition for disinfecting water according to claim 4, characterized in that it further comprises dispersants to accelerate the destruction of granules and tablets. 7. The composition for disinfecting water according to claim 6, characterized in that the dispersants used are carbonates of alkali and alkaline earth metals, as well as mixtures thereof. 8. The composition for disinfecting water according to claim 1, characterized in that it further comprises a dye. 9. The composition for disinfecting water according to claim 1, characterized in that it further comprises a perfume. 10. The composition for disinfecting water according to claim 1, characterized in that it further comprises activated carbon to neutralize excess active chlorine. 11. The composition for disinfecting water according to claim 10, characterized in that the activated carbon is used in the form of powder, granules, tablets, carbon fiber tissue, as well as mixtures thereof. 12. The composition for disinfecting water according to claim 10, characterized in that the composition is made in the form of a bicomponent dosage package.