RU2258116C1 - Method for plumbing installation disinfection - Google Patents

Abstract

FIELD: domestic plumbing installations, methods for disinfection thereof, particularly for large reservoirs.

SUBSTANCE: method involves applying disinfectant on installation surface and flushing installation with fresh water after disinfection operation finishing. Disinfection is performed by aerosol treatment carried out by accelerating anolyte particles up to speed of not less than 100 m/c. Anolyte with active chlorine concentration of not less than 100 mg/dm³ taken in amount of not less than 200 ml per 1 m² of installation surface area is used as the disinfectant. Anolyte is used as aerosol with dispersity up to 100 microns and residence time of disinfectant on installation surfaces is not less than 30 min at positive temperature. Anolyte is sprayed by nozzle, centrifugal aerosol generator or high-pressure pump.

EFFECT: increased disinfection quality along with keeping ecological rules related to installation treatment and staff safety, increased depth of disinfectant penetration in installation surface and prevention of installation damage.

4 cl, 3 ex

Description

The technical solution relates to the disinfection of water supply lines, and in particular to the disinfection of waterworks, in particular tanks of large capacity.

Disinfection of waterworks (wells, reservoirs and pressure tanks, sumps, mixers, filters, water supply network) can be preventive (before commissioning of new facilities, after periodic cleaning, after repair and emergency work), as well as epidemic indications (in case of pollution of structures, as a result of which there is a threat of outbreaks of intestinal infections).

Currently, disinfection of waterworks is carried out using chlorine.

Flushing and disinfection of water supply facilities and networks is carried out by forces and means of a construction organization (before putting them into operation) or the water supply administration (after repair and emergency work) in the presence of representatives of the sanitary and epidemiological service. The results of the work are documented in an act that indicates the dosage of anolyte for active chlorine, the duration of contact and final washing, the data of control analyzes of water. Based on these materials, the local authorities of the sanitary-epidemiological service give a conclusion on the possibility of commissioning the facilities.

With the relatively low cost of liquid chlorine, the technology of its use for disinfection of water supply facilities requires large monetary expenses for the strictest compliance with the Safety Rules for the production, storage, transportation and use of chlorine (ПБ-99). When using liquid chlorine, bleach and sodium hypochlorite (disinfection with bound chlorine) with high disinfection efficiency for common and thermo-tolerant coliform bacteria, sharp fluctuations in the level of drinking water pollution by coliphages and spores are observed (coefficient of variation 120-140%).

Existing technologies and equipment for disinfection of structures, designed in 1950-60, do not fully comply with the requirements of current regulatory documents both to ensure the safety of production processes for the use and transportation of liquid chlorine, and the quality of disinfection against viral contaminants. There is a wide variation in the values of coli phages and spores of sulfite-reducing clostridia, which is primarily due to the insufficient disinfecting ability of the reagents used. This also applies to viruses, in particular hepatitis, but they are not detected in tap water.

The revealed dependences indicate, on the one hand, the insufficient effectiveness of the applied disinfection methods, and on the other hand, the need to take into account the processes occurring in the water distribution network, where, due to a decrease in the concentration of residual chlorine and developed corrosion processes, a secondary increase in the number of sulfite-reducing clostridia is possible.

Replacing liquid chlorine with sodium hypochlorite (imported concentrated or obtained locally by electrolysis of sodium chloride) will solve only the safety problem during transportation and storage, but will not solve the problem of eliminating viruses and spore bacteria (1, 2).

To solve this problem requires the use of other methods and new non-traditional disinfectants.

Known disinfection technologies for waterworks: irrigation method and volumetric method. In the first method, the concentration of the solution for active chlorine should be at least 200-250 mg / l (based on 0.3-0.5 l per 1 m ^{2 of the} inner surface of the tank). With the volumetric method, the container is filled with a disinfectant solution and the residual active chlorine is brought to 75-100 mg / l at a contact of 5-6 hours or 20-25 mg / l at a daily contact. With both methods of disinfection, personnel work in gas masks (3).

The existing system of disinfection of waterworks as an element of sanitary and epidemiological measures is not effective enough and in some cases is a source of additional danger to personnel and the environment. For example, the traditional technique, which consists in immersing, irrigating and rubbing surfaces with subsequent exposure (exposure) for a certain time, does not always give the desired result. In practice, irrigation and wiping of large internal surface areas with significant biodestructive damage, microporous structure (concrete, etc.) is ineffective and leads to adverse side effects. These methods allow you to apply the drug only on accessible external surfaces. In this case, due to capillary phenomena and surface tension, the disinfectant does not penetrate into the depth of developed surfaces - the main niche of extraneous production microflora.

When applying irrigation and wiping in conditions of processing large areas, the required completeness of contact of the disinfectant with sources of microbial infection is not achieved. As a result of this, a population with increased resistance to the drug is artificially selected from the initial microorganism population, which is heterogeneous in resistance. It was experimentally established that after three cycles of ineffective decontamination, microflora is formed that is completely resistant both to the applied preparation and to preparations with which microorganisms were not in contact (other disinfectants). Such microorganisms are multiresistant and differ from parent microorganisms in morphological, biological and other characteristics. This significantly complicates their identification, and disinfection becomes an intractable problem.

The objective of the present invention is to improve the quality of disinfection of waterworks in compliance with environmental processing standards and personnel safety, and the technical result is the penetration of the disinfectant into the depth of the developed surfaces of the treated structures and eliminating the possibility of damage to the treated surface.

For this, a method for disinfecting waterworks using a disinfectant is proposed, characterized in that aerosol disinfection of the structures is carried out, and anolyte is used as a disinfectant.

Aerosol disinfection is carried out by accelerating the anolyte particles at least 100 m / s and keeping the anolyte aerosol in the building at a positive temperature for at least 30 minutes.

The structure is washed with clean water.

Anolyte with a concentration of active chlorine of at least 100 mg / dm is used.

Use anolyte in an amount of at least 200 ml per 1 m ^{2 of the} surface of the structure.

Anolyte is used in the form of an aerosol dispersion up to 100 microns.

Anolyte is sprayed using a nozzle, a centrifugal aerosol generator or a high pressure pump.

Safe and relatively inexpensive in implementing the solution to the problem of disinfection of waterworks is the development of aerosol disinfection technology based on new disinfectants - an electrochemically activated (ECA) solution of sodium chloride (anolyte). This technology will allow safe and effective disinfection of waterworks.

The technology uses modern environmentally friendly disinfection methods based on ECA solutions. Processing is carried out by an aerosol method with an increased disinfecting effect.

The equipment used allows you to quickly create the required concentration of the drug in the entire volume of the structure, while both surfaces and air are processed. A similar effect of the drug eliminates the occurrence of disinfectant resistant microflora.

After treatment, the preparations used decompose to water, therefore, subsequent neutralization is not required, and the facilities can be returned to the production cycle 2-3 hours after treatment.

The present invention is illustrated by a number of examples.

Example 1

Aerosol disinfection of waterworks is carried out using anolyte synthesized, for example, in STEL devices and sprayed in the form of a fine aerosol using technical means (for example, nozzles). The amount (volume) of anolyte is calculated based on the surface area of the treated structure. In this case, aerosol disinfection is carried out by accelerating the anolyte particles to 120 m / s with a dispersion of 70-80 microns and keeping the anolyte aerosol at a temperature of + 15 ° C for 45 minutes.

In this case, the waterworks are washed with clean water 1 hour after treatment.

Example 2

Aerosol disinfection of waterworks is carried out using anolyte synthesized in the Emerald SI plants and sprayed in the form of a fine aerosol using technical equipment (for example, a high pressure pump). The amount (volume) of anolyte is calculated based on the surface area of the treated structure. In this case, aerosol disinfection is carried out by accelerating anolyte particles to 180 m / s with a dispersion of 50-60 μm and keeping the anolyte aerosol at a temperature of + 5 ° C for 90 minutes and using anolyte with an active chlorine concentration of 200 mg / dm ³ .

Example 3

Aerosol disinfection of waterworks is carried out using anolyte synthesized in STEL devices and sprayed in the form of a fine aerosol using technical equipment (for example, a centrifugal aerosol generator). The amount (volume) of anolyte is calculated based on the surface area of the treated structure. In this case, aerosol disinfection is carried out by accelerating anolyte particles to 200 m / s with a dispersion of 30-40 microns and keeping the anolyte aerosol at a temperature of + 10 ° C for 60 minutes and using anolyte with an active chlorine concentration of 300 mg / dm ³ and using anolyte in the amount (volume) of 300 ml per 1 m ^{2 of the} surface of the structure.

Before disinfection of waterworks in all cases, they must be pre-cleaned and flushed. The water supply network, the cleaning of which is difficult, is intensively washed for 4-5 hours at the maximum possible water velocity (at least 1 m / s).

Disinfection of the water supply network with a diameter of 200-1400 mm is carried out by filling the pipes with anolyte aerosol using appropriate technical means with a concentration of 100 mg / dm ³ for active chlorine (depending on the degree of contamination of the network, its deterioration and the sanitary and epidemic situation). The introduction of aerosol into the network section is continued until anolyte aerosol begins to emerge at the end of the treated section. From this moment, the further supply of the anolyte aerosol is stopped and the filled area is left for at least 30 minutes. At the end of the processing time, the network is washed with clean tap water. The conditions for the discharge of water from the network are determined on the spot in agreement with the bodies of the sanitary-epidemiological service. If it is impossible to discharge water from the network, for example, into a reservoir of fishery value, etc., without washing, fill the pipeline with water and when the content in the water is up to 0.3-0.5 mg / dm ^{3 of} residual chlorine, samples are taken from the network for control bacteriological analysis. Disinfection is considered complete with the favorable results of two tests taken sequentially from one point.

The benefits of the aerosol disinfection method are as follows:

- achieving complete disinfection of surfaces and the air, especially in hard-to-reach places and hidden cavities of processed objects;

- a significant reduction in the amount of anolyte disinfectant;

- the use of the cheapest and most effective disinfectant-anolyte;

- reduction of labor costs for disinfection;

- the exclusion of personnel contact with the disinfectant during the work due to remote injection of anolyte aerosol;

- elimination of the possibility of damage to the treated surface;

environmental friendliness in aerosol technology due to the relaxation (decomposition) of the anolyte after its application to environmentally friendly components.

This invention can also be used in other sectors of the economy.

Sources of information

1. "Heating, plumbing, sewage" (Designer Guide), Stroyizdat, 1975, p. 245.

2. A.N. Belan. "Water supply technology", Academy of Sciences of the Ukrainian SSR, Kiev, Naukova Dumka, 1985, p. 203.

3. RULES for the technical operation of systems and structures of public water supply and sanitation (official publication), State. Committee of the Russian Federation for construction and housing and communal services, M., 2000, pp. 62-63.

Claims (4)

1. The method of disinfection of waterworks, including the use of a disinfectant and washing facilities with clean water at the end of the treatment time, characterized in that the disinfection is aerosol, anolyte with an active chlorine concentration of at least 100 mg / dm ³ in an amount of at least 200 ml per 1 m ² of the surface structures in the form of an aerosol dispersion to 100 microns which is held in structures at a positive temperature of not less than 30 minutes, wherein said aerosol disinfection carried Anolyte dissolved acceleration of particles is not less than 100 m / s. 2. The method according to claim 1, characterized in that the anolyte is sprayed using a nozzle. 3. The method according to claim 1, characterized in that the anolyte is sprayed using a centrifugal aerosol generator. 4. The method according to claim 1, characterized in that the anolyte is sprayed using a high pressure pump.