UA75305C2 - Polyfunctional foam composition for degassing, disinfection, disinsection, deactivation and screening surfaces, volumes and objects against dangerous agents and substances, foam, a method for degassing, disinfection, disinsection, deactivation and screening (variants), concentrate for preparing work solutions of composition - Google Patents

Abstract

An agent and methods for a complex degassing, disinfection, disinsection, deactivation and screening areas and volumes where it is detected or provided for the availability of potent toxic agents, toxic agents, chemical weapons, pathogenic microorganisms, toxic products, vital activity thereof, insects and radioactive substances, and also those for extinguishing the ignition of flammable liquids or prevention of ignition of spills of volatile flammable liquids. The agent based on active substance of clatrate didecylmethyl ammonium halogenide with carbamide and additives.

Description

Description of the invention

The invention relates to the means and methods of complex degassing, disinfection, disinfestation, decontamination and 2 shielding of areas and volumes where the presence of potent poisonous substances (POS), poisonous substances (OR), chemical weapons (Х3), pathogenic microorganisms ( MO), toxic products (TP) of their vital activity, insects, including carriers of pathogens of human and animal diseases, radioactive substances (RR), as well as for extinguishing the ignition of flammable liquids or preventing the ignition of spills of flammable liquids (LZR). 70 The invention can be used in liquidation of the consequences of the use of weapons of mass destruction (WMD), liquidation of the consequences of man-made accidents and emergency situations (NS), in extinguishing and preventing ignition, by processing territories, areas or volumes contaminated with toxic chemical, biological, radioactive substances or in case of spills of flammable liquids for the purpose of: - destruction of toxic chemicals (degassing); - disinfection; - disinsection; - deactivation; - shielding the source of potential danger from the atmosphere and excluding its spread into the surrounding environment; - shielding of PPE from contact with air; - dust removal, including toxic dust.

The invention ensures the fulfillment of any of the specified goals or any combination thereof. In this regard, the term "degassing, disinfection, disinfestation, decontamination and shielding" means the complex performance of any task or any combination of the tasks indicated above, and are covered by the term "special treatment" or "special treatment "accepted in this field. Go)

The invention can be used both in the case of establishing the fact of contamination or spillage, that is, when eliminating the consequences, and in the case of suspicion of such contamination or spillage, since both the used agent and its decomposition products are not toxic.

Many substances are known that are used for degassing, disinfection, disinfestation, decontamination, and shielding. However, these substances are used, as a rule, to solve mainly one problem. Some substances are known that allow solving a complex of two tasks, for example, carrying out degassing and disinfection, disinfection and disinfestation, or deactivation and extinguishing. For example, chloramines, peroxide compounds, alkaline solutions, etc., are used as a complex means for degassing and disinfection. Gaseous chlorine or formalin is used for disinfection and disinfestation. For partial degassing and deactivation, that is, for removing toxic and radioactive substances from the surface, the use of surface-active substances is known. Solutions of surface-active substances are used in extinguishing area fires and to prevent the danger of ignition of hazardous waste spills.

However, until now, no substance was known, on the basis of which it would be possible to create a composition to "solve any of the problems associated with potential chemical, biological, radiation and fire C 70 danger, or to shield the source of danger, or to solve several of them in any c arbitrary set.

This is due to the fact that liquids or solutions containing an active substance or a complex of substances that interacted and neutralized a dangerous agent were traditionally and predominantly used in this field. Then this liquid with neutralization products was removed from the treated surface with one degree or another of completeness. In the case of extinguishing or prevention of ignition, the liquid was stored on the surfaces until the conditions were created, which exclude combustion or ignition. sl Thus, the set of contradictory requirements precluded the possibility of creating universal preparations and means suitable for complex use as a means of special treatment in the event of an emergency, man-made accidents or the use of weapons of mass destruction. aw! 20 In addition, the factor of uncertainty in the source of the danger takes place during an emergency or the danger of its occurrence. That is, when an emergency is suspected, there is a certain period of time when the source of the danger, its type and scale, is not yet reliably identified, and there is no forecast of the immediate danger and remote consequences of the emergency. At the same time, an error in making a decision to eliminate the alleged cell is not excluded, in the absence of a real danger to people or the environment. In this connection, there is an additional requirement to minimize 29 damage in case of liquidation of the intended cell, in its actual absence.

GF) The authors of this invention proposed "the use as an active agent that provides a complex action, in particular for degassing, disinfection, disinfestation, deactivation and shielding, of a quaternary ammonium compound, such as didecylmethylammonium halide clathrate with urea, while the composition based on this active substance is used in in the form of foam. Because clathrates of didecylmethylammonium halide with urea (KDHK) are best known in the form of chlorides, bromides, iodides and fluorides. They are an odorless crystalline powder. These clathrates have surface-active properties.

The most characteristic representative of this group of compounds, which is produced on an industrial scale, is clathrate of didecylmethylammonium bromide with urea. because KDGK are recognized bactericides | see, for example, KO 2214837, 200 Zr.; KO 2095086, 1997.

However, the presence of these compounds with good surface-active properties allowed us to consider these compounds as potential active agents for creating foam compositions of complex action.

In the state of the art, air-mechanical foams are known, which are used in fire extinguishing, in the localization of oil spills. These foams are formed due to surface-active substances (surfactants), which are included in foam-forming compositions. However, to achieve the functionality of the purpose of foam compositions in them, in addition

Surfactants include active substances that provide a solution to a specific problem. For example, adsorbents (absorbents) are introduced into foams for the localization of oil spills, when extinguishing fires, the "active component" of the foam composition is water, which provides temperature reduction and flame isolation due to vaporization. 70 The purpose of this invention was to create a multifunctional composition and means of its application for degassing, disinfection, disinfestation, deactivation and shielding of surfaces and areas where a dangerous agent (agents) or substance (substances) is present or is expected to be present.

The authors of this invention proposed the use of didecylmethylammonium halide clathrate with urea (KDGK) as an active ingredient in compositions. The use of KDGK ensures the complex action of 7/5 foam compositions, namely degassing, disinfection, disinfestation, deactivation and shielding, while KDGK is both an active (active) substance with multifunctional properties and a foaming agent.

The liquid polyfunctional composition based on KDHK contains up to 590 KDHK by mass. Preferably, but not necessarily, KDGK is a clathrate of didecylmethylammonium bromide with urea.

The composition may optionally contain additional auxiliary components. Such components include 2о thickeners, dyes, oxidizers, additional surfactants (surfactants), compatible with CHAS, co-solvents

KDGK, as well as substances that regulate the physical and chemical parameters of the foam, in the amount of up to 1000 by weight of the original solution of the composition.

The use of antifreeze, for example, higher alcohols, glycerin, ethylene glycol, etc., ensures the use of the composition at negative temperatures. In addition, these substances can perform the functions of extractants for chemical compounds-contaminants that are poorly soluble in water.

Polyvinyl alcohol, carboxymethyl cellulose, methyl or ethyl cellulose, polyvinylpyrrolidone, (8) polyvinyl acetate, liquid glass, etc. can be used as thickeners to increase the viscosity of the solution and, therefore, the half-life of the foam. In addition, thickeners increase the adhesive properties of the foam, contributing to the improvement of its binding to the surface being treated, and the longer stay of the foam on it in adverse environmental conditions.

Dyes can be added to improve the visualization of the foam layer. Dyes can be fluorescent, for example, rhodamine, fluorescein, etc. to ensure visualization of the foam layer in the dark.

Oxidizers, such as hydrogen peroxide, or compounds that, when dissolved in water, emit active oxygen or a halogen, such as chlorine, without significantly affecting the physical parameters of the foam, provide an increase in its degassing, disinfecting or disinfecting activity.

Additional surfactants compatible with CHAS can be added to the composition to increase the stability of the foam, adjust the size of the bubbles, and the thickness of the liquid film between the bubbles. The concentration of additional surfactant in the composition can reach a value of up to or by mass, depending on the value of the critical concentration of micelle formation.

ХККМ) for this South African Republic. At the same time, the upper limit of the surfactant concentration, as a rule, may not exceed its value with CCM. Compatible surfactants include nonionic surfactants, cationic surfactants, or weakly cationic surfactants.

The composition is used in the form of foam with a multiplicity from 30 to 1000. The multiplicity of the foam is a ratio; volume of foam to the volume of the initial solution. The value of the multiplicity of the foam, varying in the interval from 40 to 200, is optimal, but not mandatory. The multiplicity of air-mechanical foams is established, as a rule, by the mode of dispersion and/or the concentration of the dispersed composition. The value of the multiplicity of the foam can be adjusted depending on the tasks to be solved and the requirements for the foam that is obtained.

High-multiplicity foams, with a multiplicity of more than 100, are sometimes called "dry" foams, because they contain a small volume of liquid per unit volume of foam. In such foams, liquid films have a small thickness, which makes it difficult to draw oo particles into the foam, and the half-life time is significantly reduced.

Foams of low multiplicity (less than 30) contain a larger amount of liquid per unit volume and the thickness of the liquid film that limits the bubbles is higher. In the process of syneresis of such foams, there is a more intense sedimentation of foreign particles, initially absorbed by the foam, back to the surface.

Foams of medium multiplicity have optimal parameters of stability (foam half-life), the ability to detach foreign particles from the surface on which the foam is applied, and retain them in a liquid film between gas bubbles during foam syneresis.

The foam composition is a dispersed system consisting of cells, in which the dispersive medium is a solution, and the dispersed phase is a gas. If the foam is formed by an air-mechanical method, the gas is air. In this case, the foam can be obtained using various known foam generators, such as bubble generators, centrifugal type foam generators, air-foam barrels, net type generators, etc. The foam can contain a gas other than air as a dispersed phase, for example, carbon dioxide, nitrogen and similar gases , which are used as propellant gases in balloon-type foam generators, where the solution is pushed out under the action of the gas and, optionally, additionally mixed with air, forms foam.

The mechanism of action of the KDGK foam composition, when it is applied to the surface, is briefly described as follows. 65 At the first stage, a primary stable system is formed, when the surface on which the foam is applied is wetted, and the surface is isolated from the surrounding atmosphere. At this time, the transition of pollutants into the foam layer and their dissolution is carried out. If the particles are not soluble in the liquid composition, the particles are detached from the surface and drawn into the foam layer. If the pollutant (contaminant) is present in the form of a film, then its destruction occurs and the pollutant in the form of a colloid or suspension is drawn into the foam layer.

Further, due to syneresis, the foam begins to collapse, the height of the layer that separates and isolates the treated surface from the atmosphere decreases. The thickness of the walls between the bubbles increases, the particles begin to move more intensively in the liquid film under the action of alternating forces, while the mass transfer, including mass transfer at the molecular level, increases.

Eventually, the foam layer is completely destroyed and only a part of the 7/0 composition that does not evaporate, in the form of a film, remains on the treated surface. At the same time, the particles that were drawn into the foam layer and their decomposition products, if they do not dissolve in the liquid phase of the composition, are covered with a thin layer of KDHK, additional components of the foam composition, if they are present in the composition.

Since the composition based on KDHA has high wetting properties, when the foam is applied, wetting of the surface on which the foam is applied takes place. If the foam is applied on open ground, /5 dry brickwork, concrete or powdered cement, the depth of wetting is several centimeters.

Foam coatings have good adhesion to the surfaces of objects of the surrounding environment and to paint coatings, have stability on vertical and inclined surfaces (including those with a negative angle of inclination).

The foam obtained from the composition according to the present invention preferably has the size of bubbles from 0.5 to 1.5 mm, which constitute a large part (by volume) of the foam at the time of foam generation.

The optimal thickness of the foam layer above the treated surface is at least 10 cm, while the half-life of the foam, according to the criterion of liquid flowing out of it, is from 10 to 30 minutes, with the time of complete foam decomposition (that is, until the appearance of zones or areas of the surface without foam, which is visually determined) not less than 3 hours.

Applying the foam with the required layer, i.e. with a thickness of at least 10 centimeters, can be done once or by repeated application of additional layers, to maintain the required layer thickness and/or the duration of the foam's existence. It is advisable to reapply the foam when using the composition in adverse conditions that contribute to faster foam destruction. and)

When foam is applied to a water surface, the lifetime of the foam decreases slightly, but not significantly. The lifetime of the foam in this case is enough for the neutralization reaction of the toxic substance or agent on the water surface to pass. If necessary, an additional layer of foam can be applied until the moment of its destruction.

The application of foam is carried out using various foam generators, such as foam generators of the bubbling type, centrifugal type, air-foam barrels, mesh generators, etc. The foam may contain, as a dispersed phase, a gas other than air, for example carbon dioxide, nitrogen and the like, which are used as propellant gases in balloon-type foam generators, where the solution is pushed out under the action of gas o and, optionally, additionally mixed with air , forms foam. In particular, a balloon-type foam generator can be used, where a propellant gas is used that dissolves under pressure in a liquid composition. This gas can be carbon dioxide, in the case of aqueous compositions, or freons, in the case of use as a solvent for aqueous-organic solutions or suspensions.

If necessary, the foam layer can be quickly destroyed by applying defoamers, such as cement, gypsum, etc. inorganic binders, as a result of which a solidifying mass is formed, which can be quickly removed and taken away for further disposal. As substances that destroy the foam formed from . compositions according to the present invention, traditional organosilicon defoamers, such as polymethylsiloxanes, or polymethylsiloxanes in a mixture with silicon dioxide, and the latter can be in a form that promotes the adsorption of degradation products. Lower alcohols and ketones can be used as defoamers.

One of the advantages of using foam according to the invention is that the foam applied to the surface isolates it from the surrounding atmosphere. The pollutant (contaminant) moves into the foam layer and can dissolve in it. If the contaminant in the foam layer is not destroyed for one reason or another, for example, due to a limitation or insufficient time for destruction or neutralization, in particular, to reduce the time for eliminating the consequences, then the foam layer, in which the contaminant has already been absorbed, can be additionally applied a composition or preparation containing another agent more effectively destroying this contaminant. For example, if the contaminant turns out to be spore forms of microorganisms, for effective disinfection of which with the foam according to the invention it takes about 3 hours under normal climatic conditions, then if the fact of the presence of spores is quickly established, on a layer of foam into which spores from the surface have already been drawn , which is processed, another disinfectant can be applied, for example, a composition that contains formalin, which in this case will ensure even more effective destruction of spores. A similar example is the option when the foam is applied to a surface infected with mustard gas, which is weakly hydrolyzed to low-toxic products in the foam with an almost neutral pH value. Itzrit,

F) extracted into the foam layer can be completely destroyed by treating the foam layer with a more effective degasser, for example, an alkaline chlorine-containing solution applied to the foam layer. At the same time, it should be noted that applying foam to a surface with a contaminant shields it from the surrounding environment, excluding 6o emission of the contaminant into the atmosphere, "preserving" it for exposure, if necessary, for additional treatment.

The advantages of using foam compositions include the low consumption of solutions required for covering surfaces. The rate of consumption of traditional liquid preparations for disinfection, degassing and decontamination of objects in the environment is about three liters per square meter of surface. At the same time With liters of foam-forming solution, with an average foam multiplicity equal to 50, and the necessary thickness of the foam layer of 10 65 centimeters, it is possible, theoretically, to process 150 square meters of the surface.

Taking into account the real situation, namely, adverse weather conditions contributing to the destruction of the foam,

due to the need for repeated treatments to maintain a layer of foam with a thickness of at least 10 cm for at least 3 hours, the actual area treated with foam based on 195 KDGK, in extremely unfavorable conditions, amounted to about

From square meters.

Foams according to the present invention are prepared by dissolving KDHA in water or aqueous solutions containing additional components. KDHK can be presented in the form of pure KDHK in the form of powder, granules, etc. Concentrated preparations containing KDHA, such as "Veltolen", "Veltox" or similar preparations, can also be used. KDGC solution can be prepared on water, aqueous solutions of antifreezes, provided that the antifreeze used does not have a negative effect on the properties of the foam. For example, glycerin, ethylene glycol, etc. can be used as antifreeze.

The concentrate for preparing the composition can be in both liquid and solid form. In this case, the excipients included in the composition of the concentrate will provide its characteristics necessary for long-term storage of the concentrate, increasing the rate of its dissolution when obtaining working solutions for foam generation. Then, in the composition of the concentrate, in addition to the active agent - KDGK and optional additives - /5 of the additional auxiliary components indicated above, it may contain co-solvents (for example - lower alcohols, antifreezes (for liquid concentrates) and substances that contribute to the dissolution of the solid form - disintegrants and fillers). The concentrate can be packaged in containers convenient for the consumer, such as polymer bags, hermetic rigid containers, etc.

Examples

The following examples illustrate the present invention, but do not limit it to specific embodiments, as equivalent or similar technical solutions are clear to those skilled in the art.

Example 1

Foam-forming compositions based on KDBK

The composition of the prepared compositions and the characteristics of the foam obtained from them are given in Table 1

Aqueous solutions based on didecylmethylammonium bromide clathrate with urea (KDBK) were prepared in water, foam was obtained from the solutions by the method of air ejection or bubbling, and indicators of the obtained foam were determined (time and) disintegration of half of the foam column, time of its complete disintegration, dispersion indicators) under normal climatic conditions .

Io) with and mass of foam foam, min. foam, min. Bubbles), mm foam 1 Y1101101186 FD 61011118 Yu.11011016 from 96190111 t B11Y011110111016 51111111186 Yui Volo "and 0 Y1Y01Y01101101101111111016 - Yuh. sle e - foam obtained by ejection of the KDBK solution through a metal mesh. oz Foams with similar characteristics were obtained by generating foam from a tank under carbon dioxide pressure. At the same time, the foam, depending on the type of nozzle on the dispersing head, was formed as a dispersed system in which the gas phase was only carbon dioxide or a mixture of carbon dioxide with air. sl Foams in which the gas phase was only carbon dioxide were characterized by a lower multiplicity: from 40 to 100.

Example 2

Effect of additives on foam properties

Introduction of hydrogen peroxide in a concentration of up to 0.595 to a solution containing 1.090 KDEK; dye (polychem blue) at a concentration of up to 1.096, led to an insignificant decrease in the multiplicity of the foam (up to 90) and the half-life (up to 5 Ohv), with the initial parameters of the 1.095 KDBK solution: the multiplicity - 100, the half-life - bohv.

KDGK solution (195 by mass), prepared on 2095 glycerol, retained its foaming performance with increased foam lifetime.

The solution containing 5906 KDGK allowed obtaining foam with a multiplicity from 30 to 1000, depending on the mode of foam generation, while the lifetime of the foam was more than 3 hours.

A solution containing 595 KDGK allowed the introduction into it of up to 595 by mass of OP-7 nonionic surfactant without significant changes in the parameters of foam stability. 65 KDGK solution (195 by mass) prepared with the addition of carboxymethyl cellulose (0.595 by mass) had higher foam lifetimes.

Example C

Evaluation of bactericidal properties of air-mechanical foam based on KDBK

Foam characteristics: multiplicity - 100, dispersion - at least 0.5 mm, half-life - at least 30

Minutes, the time of complete disintegration is not less than one hour, the thickness of the foam layer is about 10 cm above the treated surface.

The influence of air-mechanical foam containing 1 and 295 by weight of KDBK, formed by the bubbling method, on the inactivation of the test microorganism E. soya was studied.

Test preparations were applied to glass substrates, then a layer of foam was applied to the bottom. The exposure was 60 7/0 minutes, the air temperature was 2020. Then washings were made from the substrates, and the washing liquid, samples from the destroyed foam and controls were analyzed.

As a result, it was determined that there was no growth of microorganisms in the wash from the surface of the test plate after its foam treatment, in the liquid sample from the destroyed foam and in the sample from the preserved foam. A control representing a washout from an untreated substrate showed continuous growth of E. soya.

Parallel experiments with KDBK solutions without foam formation showed a similar result.

The effect of air-mechanical foam containing 295 by mass of KDBK, formed by the bubbling method, on the inactivation of test spores of anthrax, strain STI-1, was investigated.

Test preparations were applied to glass substrates, then a layer of foam was applied to the bottom. The exposure was 180 minutes, the air temperature was 2020. Then washings were made from the substrates, and the washing liquid, samples from the destroyed foam and controls were analyzed.

As a result, it was determined that there was no growth of microorganisms in the wash from the surface of the test plate after its foam treatment, in the liquid sample from the destroyed foam and in the sample from the preserved foam. A control representing a washout from an untreated substrate showed persistent growth of microorganisms.

Parallel experiments with KDBK solutions without foam formation showed a similar result. Ha

The effect of air-mechanical foam containing 295% by weight of KDBK, formed by the bubbling method, on the inactivation of test spores of B. zybtsiv was investigated. and)

Test preparations were applied to glass substrates, then a layer of foam was applied to the bottom. The exposure was 180 minutes, the air temperature was 2020. Then washings were made from the substrates, and the washing liquid, samples from the destroyed foam and controls were analyzed. Io)

As a result, it was determined that there was no growth of microorganisms in the wash from the surface of the test plate after its foam treatment, in the liquid sample from the destroyed foam and in the sample from the preserved foam. The control, which is a washout from an untreated substrate, showed persistent growth of microorganisms. Go)

Parallel experiments with KDBK solutions without foam formation showed a similar result.

Thus, it was established that foams with a concentration of, for example, about 0.595 of the active substance and with an exposure of about 30 minutes are effective against vegetative microorganisms, and at a concentration of, for example, about 195 of the active substance and an exposure of 90-120 minutes, they are effective against spores of microorganisms.

The obtained results are equivalent to the results of disinfection carried out with a solution of KDBK, which makes it possible to use data on the assessment of the disinfecting activity of KDBK solutions, both as such and with various additives, to predict the disinfecting ability of foams based on clathrates of didecylmethylammonium halide with 70 urea. - с Example 4 a Shielding and localization of LZR spills with KDBK-based foam "» To evaluate the shielding properties of the foam, a 0.595 solution of KDHA was used, in particular, obtained by dissolving 2.596 by weight of Veltolen in water. In the experiments, foam with a multiplicity of 40-60 was used, as the least stable,

With a thickness of the applied layer of about 10 cm. - and Since the foam is a dispersed system with many barrier layers "gas-liquid" formed from liquid films between gas bubbles, the diffusion of toxic gases (for example, chlorine, hydrogen sulfide), as well as LZR vapors (gasoline) through the layer foam about 10 cm thick was practically absent. Odors appeared only after (95) destruction of the foam layer (after more than 3 hours). at 50 The foam provided excellent shielding properties. After covering the test plates with hydrophobic aerosol powder applied to them with a layer of foam, no secondary aerosol from aerosol particles was detected. similar results were obtained using talcum powder labeled with a dye.

Kerosene film applied to metal plates, after treatment with foam based on 0.595 KDGK, was destroyed in less than 3 hours. The suspension of kerosene that was formed in the KDGC solution did not ignite under normal conditions. 5B Example 5

Degassing of foam based on KDBK o Degassing of foam based on KDBK is carried out due to hydrolysis. ORs or potent poisonous substances (i.e.) (SCOR), insoluble in water, are extracted or detached from the surface subject to degassing, and change into a colloidal form, being drawn into the film of liquid between the bubbles. At the same time, the reaction zone, that is, the contact zone of 60 ОР/water increases, and the rate of hydrolysis increases significantly. Water-soluble ORs diffuse into the liquid layer and are hydrolyzed. Highly resistant OR or SDOR, the rate of hydrolysis of which is quite low, are neutralized due to absorption and shielding by a layer of foam.

If the foam contains oxidizing additives, such as hydrogen peroxide, or compounds that form active oxygen or chlorine when dissolved, the degassing ability of the foam increases. 6E The results of the experimental evaluation of the degassing and shielding properties of foams are given in Tables 2 and 3.

In the course of the experiments, metal plates, including those coated with ХВ enamel, or samples of rubberized fabric, into which ORs are absorbed, were applied ORs of the ХХ type and mustard gas. The concentration of OR on the test plates was monitored before the foam coating and during the exposure. In some experiments, the level of OR concentration (as dangerous or safe) above the foam layer at the end of the exposure was determined.

As a foam composition, a 0.595 KDHA solution was used, in particular, obtained by dissolving Veltolen in water. The foam density is 60-100, the thickness of the foam layer is 10 cm, the full exposure time of the foam is approx.

The concentration of OR above the surface of the metal plates and C deobrobkitnya | Fields of gray foam treatment - and in fmalkhvyaiv 10000005 bin 2 0 proumovana tanya 111111111100300111110000000 bin 11111111

For the degassing of mustard gas, that is, its destruction in the foam layer, the addition of calcium hypochlorite in the amount of 1.595 times the weight of the degassing composition was required. with

Example 6 Ge)

Foam deactivation based on KDBK

A drug containing 998 g was applied to metal test plates painted with KhV-518 enamel, as well as to a rubberized fabric. The samples were dried, and the power of the exposure dose of gamma radiation was controlled.

Then a foam layer of 0.595 aqueous solution of KDBK with a multiplicity of 40-60 and a thickness of 30 6-10 cm was applied to the tested samples. The exposure was 15 minutes, after which the samples were dried, and the power of the residual (α) exposure dose of gamma radiation was determined.

It was established that in the case of test plates covered with ХВ-518 enamel, the power of the exposure dose of gamma radiation decreased by an average of 15 times, and in the case of rubberized fabric - by 12 times. i am

The examples presented above are not of a limiting nature, but serve to illustrate the implementation of this invention with the achievement of the claimed effects. hey

Claims (23)

The formula of the invention "t0 1. A multifunctional composition for degassing, disinfection, disinfestation, deactivation and shielding 8 of surfaces, volumes and objects from dangerous agents and substances, in the form of foam, which is a solution "of didecylmethylammonium halide clathrate with urea, as an active substance, in an amount from 0.1 to 595 by weight, and additives in an amount up to 695 by weight. 2. The composition according to claim 1, where the clathrate of didecylmethylammonium halide with urea is the clathrate of 45 didecylmethylammonium chloride with urea and/or the clathrate of didecylmethylammonium bromide with urea. 7 Z. The composition according to claim 71, where the clathrate of didecylmethylammonium halide with urea is the clathrate of didecylmethylammonium bromide with urea. 4. The composition according to claim 1, where additives are thickeners, dyes, oxidizers, additional surface-active substances (surfactants), compatible with quaternary ammonium compounds, co-solvents / clathrate av | 20 didecylmethylammonium halide with urea. 5. The composition according to claim 4, where the thickener is carboxymethyl cellulose in an amount up to 0.595. sl 6. The composition according to claim 4, where the oxidizing agent is hydrogen peroxide in an amount up to 0.595. 7. The composition according to claim 4, where the additional surfactant (surfactant), compatible with quaternary ammonium compounds, is OP-7 or OP-10 in an amount up to 195% by weight of the composition. 8. The composition according to claim 4, where the co-solvent of didecylmethylammonium halide clathrate with urea is alcohol, HF) selected from the group consisting of methyl, ethyl, propyl, butyl, isobutyl alcohols, in the amount of up to 595% by weight of the composition. 9. The composition according to claim 4, where the solvent is water. 10. The composition according to claim 4, where the solvent is an aqueous solution of antifreeze. 60 11. The composition according to claim 10, where the antifreeze is glycerin or ethylene glycol, in an amount up to 20965. 12. The foam obtained from the composition according to claim 1, having a multiplicity from 3 to 1000. 13. The foam according to claim 12, which is an air-mechanical foam. 14. The method of degassing, disinfection, disinsection, deactivation and shielding of surfaces, volumes and objects from dangerous agents and substances, which involves applying the composition according to claim 1 in the form of foam to the surface or filling the treated volume or volume with foam the object where the contaminant is located or is expected to be located. 15. The method according to claim 14, which includes the stage of applying a defoamer to the foam layer for its destruction after a certain time of exposure to the contaminant. 16. The method according to claim 14, where the foam is applied in a layer with a thickness of at least 6 cm. 17. The method according to claim 14, where foam with a multiplicity from 3 to 1000 is used. 18. The method according to claim 14, where air-mechanical foam is used. 19. A method of degassing, disinfection, disinfestation, deactivation and shielding of a surface, volume or object, which involves: 70 applying the composition according to claim 1 in the form of foam to the surface where the contaminant is located and additional stages, which include: applying to a layer foam of another composition effective for inactivating the contaminant and/or applying a defoamer to the foam layer for its destruction. 20. The method of degassing, disinfection, disinsection, deactivation and shielding of surfaces in closed volumes, 75. WHAT involves filling the specified volumes with foam obtained from the composition according to claim 1. 21. Concentrate for the preparation of working solutions of the composition according to claim 1, containing as an active substance clathrate of didecylmethylammonium halide with urea, auxiliary components from the number of thickeners, dyes, oxidizers, additional surfactants compatible with quaternary ammonium bases, co-solvents and compatible excipients, while the content of active substance in the concentrate is from 10 to 9090 by mass. 22. The concentrate according to claim 21, which is a liquid. 23. The concentrate according to claim 21, which is a solid substance. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2006, MZ, 15.03.2006. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. o IF) «c) (ze) IF) and - - and? -i 1 (95) («c) sl ime) 60 b5