RU2148414C1 - Method for making room disinfection - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves spraying neutral anolyte having pH=7.0- 8.2 and reduction-oxidation potential magnitude from +400 to +1000 mV relative to chloro-silver comparison electrode. The anolyte is produced by sequentially treating sodium chloride solution of 0.5-5.0 g/l concentration in cathode and anode chambers of membranous electrochemical cell keeping anode chamber flow volume discharge rate at the level of 0.999-0.5 times of cathode chamber flow volume discharge rate. Spraying is carried out in achieving 5-50 mcm fine aerosol not later than in 30 min after producing neutral anolyte under normal climatic conditions with mass concentration of aerosol being equal to 50-100 mg/m³. EFFECT: enhanced effectiveness, ecological safety and reliability of the method; wide range of functional applications. 5 cl, 1 tbl

Description

 The invention relates to medicine and is intended for emergency, ongoing prophylactic and final disinfection of premises, sanitary equipment, tools and medical supplies for intestinal and drip infections of bacterial and viral etiology, for candidiasis and dermatomycosis, for tuberculosis, as well as for prevention nosocomial infections in infants and young children.

 In addition, the invention can be used in microbiology, virology, agriculture, food industry and other industries for disinfection, sterilization, as well as sanitization of premises and the equipment located in them - containers, implements, raw materials, finished products and staff clothing.

 There are various methods of disinfection and sterilization, based on thermal (hot water or steam under pressure, hot air) and electromagnetic treatment (RF and microwave electromagnetic fields), in which the destruction of microorganisms occurs in connection with the temporary creation of physical conditions for irreversible destruction of cells or intracellular structures. Impacts of this kind are considered environmentally friendly, as do not leave toxic effects.

 The main disadvantages of physical methods are, in some cases, the need to use high temperatures (heat treatment), which is not acceptable when disinfecting and sterilizing heat-sensitive objects or increasing the processing time when changing the temperature regime, and in other cases, complex hardware design and process technology that requires high staff qualifications, a narrow range of technological parameters (plasma exposure) and, as a result, a low technological and economic effect. In addition, exposure to RF and microwave electromagnetic fields is limited to the processing of non-metallic objects and cannot be used for processing rooms, since it requires a high exposure power, which is associated with a large specific energy consumption, requires expensive equipment. In addition, the impact of HF and microwave is unsafe for maintenance personnel in case of non-compliance with safety regulations.

 Also known are the radiation methods of antimicrobial exposure (UV-treatment with γ- and β-rays, neutrons directed by electron beams, etc.), which require expensive and complex equipment, high radiation protection, are limited by the need for directional exposure exposure and well-defined exposure parameters, which significantly limits the range of application of these methods.

 For disinfection of a wide range of objects, chemical disinfection methods based on the use of disinfecting chemicals (formaldehyde, glutaraldehyde, salts of di- and trichloroisocyanuric acids, quaternary ammonium bases, peracetic acid, hydrogen peroxide, ozone, phenolic, cresol, iodoform solutions are most suitable antiseptics, etc.). Disinfectants are used in the form of vapors, which reduces the concentration of oxidizing agents and the corrosive and destructive activity of the disinfectant with respect to disinfectable materials.

 For example, a known method of producing formaldehyde vapor for disinfection [1]. Formaldehyde vapors are obtained by mixing formalin with an oxidizing agent, which is used as bleach with up to 28% active chlorine in bleach.

 However, formaldehyde is an extremely toxic drug and is practically not used for these purposes.

It is known the use of hydrogen peroxide vapor for disinfection and sterilization [2]. However, the use of vapors requires an elevated temperature of 60-66 ^o C, as well as a relatively long contact time - up to 24 hours. These shortcomings do not allow the use of a well-known solution for disinfection of premises.

 The closest in technical essence is the method of obtaining aerosol used in the disinfection of rooms [3]. To obtain an aerosol, the disinfecting effect of which is manifested at room temperature, chlorine lime is mixed with ammonium nitrate in the presence of water, immediately there is a rapid release of gaseous products: chlorine, hydrogen chloride and ammonium chloride, which, when condensed with water vapor released during heating of the mixture, form highly dispersed aerosol.

 The disadvantage of this method is the pollution of the processed objects with toxic products, the removal of which requires additional measures. At the same time, these methods are not environmentally friendly, since they are associated with the use of chemical agents that are slowly degrading in the environment and are equally harmful to all forms of protein life - from bacteria to humans, since they have a depressing effect on humans, regardless of their concentration in the body. In addition, after the intended use, biocidal solutions and aerosols of persistent chemicals enter the environment in various ways, polluting it.

 The technical result of using the invention is to increase the efficiency and reliability of disinfection, expand the functionality of the method, create conditions for mobile disinfection technologies, reduce the consumption of the disinfectant, increase the antimicrobial activity of the aerosol while increasing its durability and, in addition, ensuring environmental cleanliness and safety.

 This result is achieved by the fact that in the method of disinfection of premises, including filling the disinfected room with aerosol obtained by spraying a disinfectant, a neutral anolyte with a pH of 7.0-8.2 and an oxidation-reduction potential (ORP) of plus is used as a disinfectant 400 to plus 1000 mV relative to the silver chloride reference electrode obtained using sequential treatment of a solution of alkali metal chloride in the cathode and anode chambers electrochemical cell while maintaining the volumetric flow rate through the anode chamber at a level of 0.999-0.5 of the volumetric flow rate through the cathode chamber, spraying is carried out by mechanical crushing of the neutral anolyte without mixing with air until the aerosol dispersion of 5-50 microns is achieved. For example, spraying is carried out by an aerosol generator with a high-speed rotating disk (rotation speed of at least 20,000 rpm), and spraying is carried out no later than 30 minutes after receiving a neutral anolyte. To obtain a solution of neutral anolyte, a solution of sodium chloride with a concentration of 0.5-5.0 g / l and an electrochemical cell with an ultrafiltration or nanofiltration diaphragm made of ceramic based on zirconium oxide or based on zirconium oxide with the addition of aluminum and yttrium oxides are used.

In addition, spraying is carried out in normal climatic conditions in the mode of mass aerosol concentration of 50-100 mg / m ³ .

 The essence of the invention lies in the fact that the neutral anolyte has a high bactericidal activity due to the high AFP (from plus 400 to plus 1000 mV) and the content of highly active biocidal agents and at the same time is not corrosive, due to the relatively high pH. This result is achieved by treating the solution sequentially in the cathode and anode chambers of the diaphragm electrolyzer. A change in the sequence of the duct will not lead to the achievement of a result, since it is essential that the fluid flow from the cathode chamber together with the released hydrogen enters the anode chamber for processing. The change in the volumetric ratio of the ducts in the chambers is due to the requirements for the pH of the resulting solution.

 Obtaining a neutral anolyte from an aqueous solution of sodium chloride makes the method more preferable because of its environmental safety, since the concentration of active chlorine does not exceed 300 mg / L as a result of aerosol formation, free chlorine is not released, the formation of which occurs when aerosols are obtained from sodium or calcium hypochlorite solutions .

 It is advisable to use when producing a neutral anolyte an electrochemical cell with a zirconium oxide-based ceramic diaphragm, for example, a cell according to RF patent N 2078737. Such cells have a high service life and are made on a modular basis, which makes it easy to provide the required performance by connecting several modular cells into a reactor .

 During spraying with an aerosol generator, the neutral anolyte undergoes disintegration due to mechanical crushing to aerosol particle sizes of 5-50 microns. Thereby, the electrical and chemical activity of the neutral anolyte aerosol molecules is enhanced, as a result of which the aerosol penetration into small pores and its sporicidal activity in the total disinfection volume (space or area) are increased due to a decrease in the surface tension of the neutral anolyte solution and an increase in the fraction of the gas phase, which leads to complete disinfection of the object.

 At the same time, fine particles of neutral anolyte during deposition also provide for the deposition and disinfection of harmful aerosol particles suspended in the air of the treated room, as well as the neutralization of harmful gases.

 This increases the efficiency and reliability of the disinfection process when using this method of disinfection of objects of various functional purposes (premises, as well as objects, materials, tools, equipment located in the premises).

 Therefore, the expansion of functionality is ensured precisely through the use of a neutral anolyte aerosol, which makes it possible to disinfect objects of various purposes in the most inaccessible places, the processing of which cannot be ensured by other available methods, and the high activity of the disinfectant allows this processing to be performed qualitatively and reliably.

 The use of aerosol leads to a significant reduction in the consumption of disinfectant. In addition, the proposed method can be implemented using portable, small-sized devices - installations for producing a neutral anolyte and aerosol generator, which allows for high mobility of the technology.

 The method is as follows.

 To obtain a disinfectant - a neutral anolyte, a device was used to obtain detergent and disinfectant solutions according to RF patent N 2088539.

The physicochemical parameters of the obtained neutral anolyte are pH 7.8 - 8.0, the redox potential of the redox potential is from plus 674 to plus 682 mV relative to the silver chloride reference electrode. The temperature of the solution is 21.4 ^o C.

 A KGA-1 centrifugal aerosol generator with a disk rotation speed of 23,000 rpm was used as an aerosol generator (atomizer).

A room with a volume of about 160 m ³ (floor area - 6.0 by 7.0 m, height - 3.8 m) was taken as an object of treatment, while the aerosol generator was installed at a height of 2.5 m in the center of the room.

The mode of maintaining the mass concentration of aerosol in the room 50-100 mg / m ^{3 was} provided by an aerosol generator, which after the initial filling of the room with a fog of a dense aerosol cloud for 3 min (t _rasp = 3 min) automatically provided a “dusting” mode by switching on the generator every 10 min for 1 min The total processing time was 60 minutes The consumption of a neutral anolyte was 8 liters.

Test objects — plastic plates measuring 10 x 10 cm in size — were installed in various areas and levels of the room, and three test objects (on a tablet) were placed on each of the test points. The culture of S. Marcesens pcs. 3107 with an infection density of 1.6 • 10 ⁵ m cells / cm ² .

 Determination of the density of spores on the plates before and after processing was carried out according to standard methods (washing and imprinting methods).

 The results of the evaluation of the disinfecting ability of the proposed method are shown in the table.

 The results of microbiological analysis of the samples after treatment with fog showed the absence of colony growth, which allows us to conclude that the goal has been reached.

 High biocidal activity at a low concentration of active chlorine (not more than 300 mg / l in a neutral anolyte solution used to obtain aerosol), the possibility of disinfection at room temperature, small volumes of biocidal agent at a constant concentration of active ingredients throughout the entire disinfection time allow this A method for disinfecting metallic and non-metallic surfaces, as well as heat and moisture sensitive objects. The absence of the formation of toxic substances at all stages of the technological cycle, including the stage of obtaining a neutral anolyte, and the analysis of spent aerosol indicate the environmental safety of this method of disinfection.

Sources of information
1. Auth. St. USSR N 337131, A 61 L 2/18, 1966.

 2. US N 4,169,123,422 / 29, A 61 L 13/00, 1979.

 3. Auth. St. USSR N 365150, A 61 L 2/22, 1970.

Claims (5)

 1. The method of disinfection of premises, including filling the room with an aerosol obtained by spraying a disinfectant, characterized in that a neutral anolyte with a pH of 7.0 - 8.2 and a redox potential of plus 400 to plus 1000 mV is used as a disinfectant relative to the silver chloride reference electrode obtained using sequential processing of a solution of alkali metal chloride in the cathode and anode chambers of the diaphragm electrochemical cell while maintaining volume flow rate through the anode chamber at the level of 0.999 - 0.5 volume flow rate through the cathode chamber, spraying is carried out by mechanical crushing of the neutral anolyte, without mixing it with air until the aerosol dispersion reaches 5 - 50 microns, and spraying is carried out no later than after 30 min after receiving a neutral anolyte.  2. The method according to claim 1, characterized in that they use a solution of sodium chloride with a concentration of 0.5 to 5.0 g / L.  3. The method according to claims 1 and 2, characterized in that the processing uses an electrochemical cell with an ultrafiltration or nanofiltration diaphragm made of ceramic based on zirconium oxide, or based on zirconium oxide with additives of aluminum and yttrium oxides.  4. The method according to claims 1 to 3, characterized in that the mechanical crushing of the neutral anolyte is carried out by high-speed rotation of the disk of the aerosol generator with a speed of at least 20,000 rpm. 5. The method according to PP. 1 to 4, characterized in that the spraying is carried out in normal climatic conditions in the mode of mass aerosol concentration of 50 to 100 mg / m ³ .

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