RU70243U1 - WATER SEASER "BEADS" - Google Patents

Abstract

Utility model The water bead "Beads" refers to the field of devices for enriching water with metal ions, in particular, devices for enriching water with silver ions. The enrichment of water with silver ions is carried out in the order of oligodynamic treatment of water in order to sterilize it. The proposed device is able to saturate water with silver ions to concentrations above the bactericidal limit in a time of ~ 10 minutes at a known (defined) value of the silver concentration in water. The improvement consists in the fact that silver is insoluble in water and inert with respect to humans, the carrier is a container made in the form of a porous body, which makes silver contact with water, and silver is in a chemically bound state in the form of a slightly soluble silver salt in water, the layer of which covers the walls pore container. A silver carrier - a container of the Aserebritant can be made in the form of a “tablet” made of porous ceramics, insoluble in water and inert to the human body, the pore walls of which are coated with a layer of silver insoluble in water. The principle of operation of the proposed Zaserebritel is that when a porous ceramic container is immersed in water, the pore walls of which are coated with a layer of one of the slightly soluble silver halides - chloride, bromide or silver iodide, water freely penetrates the pores and comes into contact with silver halide. As a result of the interaction, a saturated solution of these poorly soluble silver salts in water is formed. A saturated solution from the pore volume gradually passes into the total volume of the treated water. A silver chloride containing antifoam is intended for the preparation of a concentrated solution, which is recommended for external use and for disinfecting objects. You can drink water for drinking after diluting the solution 30 times. A silica fume containing silver bromide is intended for the preparation of drinking water by diluting the solution twice. A silica containing silver iodide is intended for the preparation of drinking water.

Description

The utility model relates to the field of devices for enriching water with metal ions, in particular, to devices for enriching water with silver ions. The enrichment of water with silver ions is carried out in the order of oligodynamic treatment of water in order to sterilize it.

The greatest progress in the field of human use of silver compounds has been achieved over the past 130 years. For example, the study of the effects of small amounts of silver and silver nitrate on microscopic life forms such as bacteria and mold began only in the last third of the 19th century. At the end of the 19th century - the beginning of the 20th century, silver nitrate powder and its ointment (colloidal silver in the form of an ointment) were used to treat wounds and skin diseases. In 1928, silver began to be used as a coating on filter systems for sterilizing water at home, and in 1929 research data were confirmed that all pathogens, including E. coli, were destroyed when silver was treated with water. Then it was found that silver treatment does not damage or destroy beneficial microorganisms in water and air.

These properties are associated with the so-called oligodynamic effect, when some metals (silver, copper, tin) are dangerous in large doses, but in microscopic quantities they can kill bacteria and fungi. (The meaning of the word oligodynamic is “effective in small quantities”).

Many researchers have tried to identify and explain how the oligodynamic effect actually works. However, a definite answer was never found, although the so-called bactericidal limit was set — the minimum concentration of silver ions equal to ~ 10 ^-10 mol / liter (~ 0.01 micrograms per liter), upon reaching which pathogenic and pathogenic microorganisms and bacteria die [1 ]. Moreover, the maximum permissible concentration (MPC) of silver ions in drinking water is set at 50 micrograms per liter [2]. Thus, the concentration of silver ions in drinking water to ensure the oligodynamic effect should exceed 0.01 micrograms per liter, but be less than the established limit of 50 micrograms per liter.

There are two main methods for saturating water with silver. The first is a method based on contacting water with silver or

silver-plated surfaces, the second - the enrichment of water with silver under the influence of electric current (electrochemical dissolution). Typically, devices for saturating water with silver ions in the first method are silver or silver-plated objects - silver carriers in contact with water, and devices in the second method are electrolyzers that saturate water with silver ions by passing an electric current between silver electrodes immersed in a saturated medium ( water).

The closest to a real useful sample (prototype) is the device [3], proposed by the Rubin State Scientific-Production Enterprise (Kharkov, Ukraine), which represents miniature silver-plated glass balls. Silver carriers - balls with a diameter of 3 to 40 mm, made of ordinary packaging ("food"), inert to the human body, glass. A thin layer of silver is deposited on their surface in an amount of about a hundredth of a gram per one ball. The amount of silver is calculated in such a way that it is enough to saturate and purify one liter of liquid during the year. One ball must be placed in a container with one liter of drinking water and kept in it at a temperature of + 5 ° C to + 30 ° C. It is recommended to drink water 72 hours after immersion in a silver ball. When treating drinking water in volumes of more than one liter, several balls can be used within one year with the calculation of one ball per one liter of water. With repeated use of the ball, the total presence of it in the same drinking water volume of one liter should not exceed one year. The shelf life of the ball is until silver disappears completely from its surface or until the silver coating darkens.

The use of the prototype requires considerable time for saturation of water with silver, which is not always acceptable, for example, in camping conditions, on vacation, in the country, etc. - that is, in conditions of time pressure. This is due to the low dissolution rate of metallic silver in water. In addition, when using the prototype, the achieved silver concentration in water was not determined. At the same time, there is a danger of both exceeding the MPC for the silver content in drinking water and not reaching the bactericidal limit.

The technical result of the development of this utility model is the creation of a device called the "Water Intake" (hereinafter referred to as Enterer)

capable of saturating water with silver ions to concentrations above the bactericidal limit in a time of ~ 10 minutes at a known (certain) value of the concentration of silver in water.

This result is achieved by improving the design of the device that carries out the process of converting silver ions from a bound state to an aqueous solution.

The improvement consists in the fact that silver is insoluble in water and inert with respect to humans, the carrier is a container made in the form of a porous body, which makes silver contact with water, and silver is in a chemically bound state in the form of a slightly soluble silver salt in water, the layer of which covers the walls pore container.

The silver carrier is the Zaserebritel’s container (hereinafter referred to as the container) can be made in the form of a “tablet” made of porous ceramics insoluble in water and inert to the human body, the pore walls of which are coated with a layer of poorly soluble silver halide.

In one embodiment, the ceramic tablet of the container is made of low-melting glass C82-3, the porosity of the ceramic tablet is 30%. At the same time, the density of porous ceramics is 30% lower than the density of compact ceramics of the same composition, since about 30% of the volume of the tablet is occupied by the pore volume. The pore walls of the tablets are coated with a thin layer of silver chloride, which has a solubility in water at 25 ° C equal to 1.35 · 10 ^-5 mol / liter (~ 1.8 mg / liter, which gives ~ 1.4 milligrams of silver ions per liter of water). The amount of silver chloride in the container was determined from the condition of dissolution of the whole substance in a given volume of water. In particular, porous ceramic tablets containing 0.09 were made; 0.9; 2.7 milligrams of silver chloride, capable of forming saturated solutions, respectively, at 0.05; 0.5; 1.5 liters of water.

In other embodiments, the ceramic porous containers of the Asylum, contained silver bromide having a solubility in water at 25 ° C of 7.75 · 10 ^-7 mol / liter (~ 139 micrograms / liter, which gives ~ 80 micrograms of silver ions per liter of water) or iodide silver, having a solubility in water at 25 ° C equal to 10 ^-8 mol / liter (~ 2.35 micrograms / liter, which gives ~ 1.1 micrograms of silver ions per liter of water). The amount of these silver halides in the Zaserebritel containers varied from 3 micrograms to 1 milligram.

The principle of operation of the proposed Zaserebritel is that when immersed in water a porous ceramic container, the pore walls of which are covered

a layer of one of the sparingly soluble silver halides - chloride, bromide or silver iodide, water freely penetrates the pores and comes into contact with silver halide. As a result of the interaction, a saturated solution of these poorly soluble silver salts in water is formed. A saturated solution from the pore volume gradually passes into the total volume of the treated water due to diffusion, convection, mixing, etc. In a saturated solution, equilibrium exists between the soluble substance and the molecules of the same substance in the solution. When salts are dissolved, ions pass into the solution, forming an electrolyte. An equilibrium is established between the solid salt and the ions that have passed into solution. In our case, the process takes place:

where Gal is one of the halogens (chlorine, bromine, iodine).

The equilibrium constant for this process is described by the equation:

K = [Ag ⁺ ] [Gal ^- ] / [AgGal]

where the symbols in square brackets indicate the concentration of these ions or substances.

The denominator of the fraction is the concentration of solid salt. It is a constant value, therefore, and the concentration of K ⁱ = [Ag ⁺ ] [Gal ^- ] is a constant value. Thus, in a saturated solution of sparingly soluble electrolyte, the product of the concentration of its ions is a constant value at a given temperature. This value quantitatively characterizes the ability of an electrolyte to dissolve in water. The values of solubility products for our case are:

AgCl → K ¹ = 1.8 · 10 ^-10

AgBr → K ² = 6 · 10 ^-13

AgI → K ³ = 1 · 10 ^-16

The given values of solubility products for sparingly soluble silver halides make it possible to determine the amount of silver ions in a saturated aqueous solution. If there are no halogen ions in the water, then the amount of silver ions in

a saturated solution is: for AgCl → ~ 1.4 milligrams of silver ions per liter; for AgBr → ~ 80 micrograms of silver ions per liter; for AgI → ~ 1.1 micrograms of silver ions per liter. Thus, the use of Zaserebritel allows you to provide a certain, previously known concentration of silver ions in solution. The time to reach saturation of solutions at a water temperature of ~ 20 ° C and with periodic stirring of water does not exceed 5 minutes.

The porous structure of the Zaserebritel container has a very developed surface coated with silver halide, which allows to accelerate the production of a saturated solution. In addition, this structure ensures the retention of silver halide in the volume of the container and allows multiple use of the Zaserebritel (subject to one-time treatment of water of a smaller volume than the volume of water calculated by the amount of silver). The use of silver carriers in the Zarebereritel of a simple form, for example, in the form of balls similar to the prototype, but coated with a layer of a sparingly soluble silver compound, does not allow their repeated use for water treatment. This is due to the fact that for some duration of contact with water, the silver-containing layer is crumbled from the surface of the carrier and is irretrievably lost. The use of a porous structure of a silver carrier in the Zerebryazhnel eliminates the loss of the working substance and ensures the normal functioning of the device until the silver-containing compound is fully developed.

In water at a temperature of 25 ° С, the concentration of silver ions when using a Zaserebitel containing silver chloride is 28 times higher than the established MPC [2]. When using Zaserebritel containing silver bromide, the concentration exceeds the MPC by 1.6 times, when using Zaserebritel containing silver iodide, the concentration is less than the MPC by 45 times. The bactericidal limit of ~ 0.01 micrograms of silver per liter of water is exceeded even in the latter case by more than 100 times, which guarantees the purification and disinfection of water from pathogenic and pathogenic microorganisms and bacteria for all the described variants of the Zarebolitel.

A silver chloride containing antifoam is intended for the preparation of a concentrated solution, which is recommended for external use and for disinfecting objects. You can drink water for drinking after diluting the solution 30 times.

A silica fume containing silver bromide is intended for the preparation of drinking water by diluting the solution twice.

A silica containing silver iodide is intended for the preparation of drinking water.

Sources of information used:

[1] - NL Glinka “General Chemistry”. Chemistry, Leningrad Branch, 1982, p. 579.

[2] - Sanitary Rules and Norms “Drinking water. Hygienic requirements for quality ... "2.1.4.1074-01

[3] - http://rubin-ukraine.narod.ru/preparat.html

Claims (5)

1. A device for saturating water with silver ions, consisting of a water-insoluble and inert in relation to humans silver carrier coated with a layer of silver-containing substance, characterized in that the silver carrier is a container made in the form of a porous body that makes silver contact with water, and silver is in a chemically bound state in the form of a slightly soluble silver salt in water, a layer of which covers the pore walls of the container. 2. A device for saturating water with silver ions according to claim 1, characterized in that the silver carrier is a container made in the form of a tablet. 3. A device for saturating water with silver ions according to claim 1, characterized in that silver chloride is used as a slightly soluble silver salt in water, a layer of which covers the pore walls of the container. 4. A device for saturating water with silver ions according to claim 1, characterized in that silver bromide is used as a slightly soluble silver salt in water, a layer of which covers the pore walls of the container. 5. A device for saturating water with silver ions according to claim 1, characterized in that silver iodide is used as a slightly soluble silver salt in water, a layer of which covers the pore walls of the container.