RU2437842C2 - Diaphragmless electrolytic cell for activation of products and media, and device including electrolytic cell (versions) - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: activation is performed by bringing electrodes into direct contact with activated product. Electrolytic cell includes at least one tank with electrodes located in it - at least with one anode and at least with one cathode, DC power supply in the form of controlled voltage source. In electrolytic cell at least one anode or one cathode, or at least one anode and one anode have the surface in the form of grain from spatial pyramids, each of which has pointed vertex and pointed fins. Domestic appliances are reservoirs filled with activated products, made in the form of electric kettle, cup, saucepan, cooler, bath, in which electrolytic cell is installed and electrochemical activation of products is performed.

EFFECT: contact electrochemical activation of natural and artificially obtained water-bearing products with various density and consistence by using domestic appliances.

15 cl, 12 dwg, 2 tbl

Description

The invention relates to the electrochemical activation of liquids, as well as natural and artificially obtained products of various densities and consistencies, containing water as an essential ingredient. The invention can be used in the food industry, in the perfumery and cosmetics industry, in the industry of hygiene products, as well as in the pharmaceutical industry in order to improve the quality of various products. The invention relates to an electrolytic cell for electrochemical activation of liquids and devices for implementing the method. including household appliances, the design of which will improve the quality of products by activating them.

Electrochemical activation as a physicochemical process is a combination of the electrochemical effect of a dissolved substance on a liquid or water-containing medium in the space charge region at the electrode surface during nonequilibrium charge transfer through the electrode-electrolyte interface by electrons.

In the aspect of our development, it is appropriate to mention only some characteristics of water, such as: pH - this indicator can determine water by its chemical orientation at almost any level of the acid-base scale; ORP (redox potential), which determines the electric charge of water in millivolts; and the structure of water, which is estimated in the number of interconnected water molecules in the so-called clusters.

Almost all life-supporting processes in the human body occur in a weak alkaline environment. The environment of all organs and tissues is water, occupying a significant volume of the organ. Therefore, the water should be slightly alkaline. The size of water clusters determines the ability to penetrate into various structural components of the body and the finer the structure of water. thus, water can penetrate into a greater variety of cells. The surface tension of the fine-grained water is also low, which gives the water greater fluidity and dissolving power.

One of the most important parameters of water is its redox potential (redox potential). The metabolic processes in the cell are carried out through its membrane, which has an electrical potential of approximately - 70mV. For activation or opening of micropores of the membrane and metabolism, a slightly prevailing electric potential must be present in the intercellular space, which permutes the rearrangement of the potential between the inner and outer sides of the membrane, which opens the gate to the cell. Water exchange in the body is one of the most voluminous processes, and if water does not bring a minimum of 70mV when entering the body, it makes up for the deficiency at the expense of other carriers, depleting energy reserves for other important processes. Such a violation of the routine leads to premature aging and the occurrence of any possible pathology. Therefore, water for oral administration must be saturated with a sufficient number of electrons. It is this water that long-livers use. Most elements and structures are comparable to the aquatic environment and willingly react with it. And if water is saturated with a larger charge than it needs, which is observed in mineral waters from some healing sources, then it calmly gives away excess to surrounding compounds, and, being the most reactive, free radicals are saturated in the first place, turning into a neutral safe form. Energy is needed not only to neutralize free radicals. Many elements must first be activated by going into ionic form in order to be able to participate in metabolic processes. Thus, water can calmly fulfill the role of an absolute antioxidant if saturated with a sufficient electric charge. Antioxidants protect body cells from oxidation processes, thereby preventing the development of many diseases. Numerous studies confirm that insufficient intake of antioxidants can increase the risk of many diseases.

Antioxidants are estimated by the redox potential (ORP) and the number of electrons that they can give to neutralize the harmful effects of free radicals and to enhance at the atomic level the main life-supporting biochemical processes. The lower the AFP, the stronger the antioxidant activity of a product (Kruglyakova K.E., Shishkina LN. General ideas about the mechanism of action of antioxidants. Collection of scientific articles "The study of synthetic and natural antioxidants in vitro and in vivo". Moscow, Science 1992, p. 5-8).

It is known that the greatest amount of antioxidants are found in fresh vegetables and fruits, as well as in freshly squeezed juices. But with prolonged storage of products and in juices made from concentrates, their amount decreases sharply. Dairy products are rich in carotenoids. A sufficient amount of antioxidants is found in tea, coffee, wine, beer. Antioxidant additives are introduced into the formulation of cosmetics, not only to protect the skin, but also to prevent peroxidation of oils containing polyunsaturated fatty acids. There are a huge number of factors that determine the effectiveness of a cosmetic product containing antioxidants. Active components must be stable, delivering a therapeutic effect to the skin, and only under these conditions positive results can be expected. The most common antioxidants in cosmetics are: vitamins E, C, F, A and carotenoids (β-carotene and lycopene), bioflavonoids, coenzyme Q10, lipoic acid and selenium. It is known that any biological substance has its own frequency range. By acting on it with this frequency, as well as using high tension and minimal heat, you can change the structure of the object without changing its chemical composition. In this case, free electrons are formed in the substance: which give it antioxidant properties and make it healing. All the ingredients that make up this substance are activated, it is filled with pristine strength and energy.

With electrochemical activation, which is carried out in both diaphragm and non-diaphragm electrolyzers, an acid anolyte and alkaline catholyte are produced. In diaphragm electrolyzers, as a result of cathodic (catholyte) treatment, the liquid acquires an alkaline reaction, its ORP decreases, the amount of dissolved oxygen and nitrogen decreases, the concentration of hydrogen, free hydroxyl groups increases, and the electrical conductivity decreases. During the anodic (anolyte) electrochemical treatment, the acidity of water increases, the ORP increases, the surface tension decreases slightly, the conductivity increases, the amount of dissolved oxygen, chlorine increases, the concentration of hydrogen and nitrogen decreases (Bakhir V.M. Theoretical aspects of electrochemical activation. Second international symposium. Electrochemical activation. Abstracts and short reports. Part 1. 1999, S.39-49.)

Currently existing devices for electrochemical activation are mainly of diaphragm type and are designed to activate water and produce acid anolyte and alkaline catholyte.

Moreover, in order to enhance activation, mesh electrodes are used in them. Due to this design of the electrodes, the activation surface is effectively increased and the ionization power is increased without the application of high voltages (Pat. RF. No. 2190572 "Method for the electrochemical treatment of water and a device for its implementation", MKI C02F 1/46. Publ. Bull. No. 28. 2002 )

The most promising devices that allow flowing water with excellent antioxidant properties. are installations - water ionizers manufactured by Delphi Water Ionizers (Canada). Delphi water activators use "mesh electrode", which effectively increase the area of activation. However, these diaphragm-type devices are designed exclusively to improve the quality of drinking water, and are not structurally adapted to solve other problems, for example, to improve the properties of products and environments, including in food, cosmetics, pharmaceuticals, etc. industry.

There is a method and device for non-contact electrochemical activation of water, water-containing natural and artificially obtained products and media (Pat. RF No. 2299859 “Device for activating a liquid”, MKI C02F 1/46, publ. 2007.05.27).

According to the goal and objectives of electrochemical activation, the device according to this invention is closest to the objects we declare, and we made this technical solution as a prototype.

The disadvantages of the device:

1. Contact activation is used only to activate technical aqueous solutions: to obtain solutions of sodium hypochlorite. technological solutions to prevent the formation of scale and corrosion in heat exchangers.

2. The device cannot be used to activate products, including food, cosmetic, hygienic, pharmaceutical, etc. of different density and consistency, because the design of electrolytic electrodes made with holes or in the form of a grid does not allow activating products of different densities and consistencies in such an electrolytic cell: small grids will be clogged by product particles, electrodes need careful maintenance - repeated cleaning, washing, and in some cases their replacement with new ones.

3. For the operation of the device requires a sufficiently high current strength, which is able to destroy unstable vitamins and other elements, for example, in food products, coagulating proteins, etc.

The first objective of the invention is the development of an electrolytic cell for contactless diaphragm-free electrochemical activation of products of various densities and consistencies.

The second goal is the development of household devices for implementing the method of contact activation of products of various densities and consistencies.

The first objective of the invention is achieved by creating a diaphragmless electrolyzer for contact electrochemical activation of products of different densities and consistencies. A diaphragmless electrolyzer contains at least one capacitance with electrodes located in it - at least one anode and at least one cathode, a DC power source in the form of an adjustable voltage source, and the electrodes of the electrolyzer can be of various shapes - round, oval, plate, tubular with different sizes holes, and with a different surface - smooth, rough, cellular, etc. Electrodes of any shape are placed or fixed to the element in the form of a pin, or spacers, or plates, made made of tourmaline or tourmaline ceramic or serve as a support for the electrodes, or interconnected using an element of tourmaline or tourmaline ceramic.

In a diaphragmless electrolyzer, at least one anode or one cathode, or at least one cathode and one anode are made with a surface in the form of a texture of spatial pyramids, each of which has a sharp apex and sharp edges, while the surfaces of the cathode and anode with the sharp vertices of the pyramids facing to each other. Electrodes - at least one cathode and one anode are placed directly in an activated medium of various densities and consistencies, which is hot or cold drinks (tea, coffee, milk), yogurts, protein drinks and mixtures, fruit and vegetable juices (natural, freshly squeezed, obtained from concentrate, with vitamin and other additives, etc.), fruit drinks, fortified drinks, soft drinks, non-carbonated and carbonated soft drinks based on natural and artificial ingredients, drinks and mixtures for food, any alcoholic beverages (vodka, beer, cognac, cocktails, wine, whiskey, etc.), fruits and vegetables, vegetable and fruit purees and jelly-like mixtures, soups, broths, as well as cosmetics (creams, perfumes, lotions, cosmetic milk, etc.), hygiene products (gels, shampoos, liquid soap, ointments, pastes), foaming, flavoring agents, pharmaceuticals (liquid extracts of plant infusions, rhizomes of herbs, etc.).

The second goal is realized by creating household devices for the electrochemical activation of products of various densities and consistencies.

A diaphragmless electrolytic cell for electrochemical activation, which is a container made in the form of an electric kettle filled with an activated liquid, with DC and AC sources placed in its bottom and a medium heater, the cathode serving as the bottom of the kettle and the anode as a horizontal spiral insulated plate placed above the cathode with support on a tourmaline-ceramic pin.

Diaphragmless electrolyzer for electrochemical activation. which is a container in the form of a cup with a lid (or without a lid) filled with an activated medium, a direct current source placed in its bottom, and the electrodes - an anode and two cathodes are placed vertically in the tank, the free ends of which are fixed on a tourmaline-ceramic spacer, either in the bottom or in the cap.

Diaphragmless electrolyzer for electrochemical activation. representing a container in the form of a pan with a lid filled with an activated medium, with sources of direct and alternating current and a medium heater located in its bottom, and the electrodes - the anode and cathodes are placed in the container and vertically fixed in the pan lid, the free ends of the anode and cathodes are fixed to tourmaline-ceramic spacer.

The diaphragmless electrolyzer for electrochemical activation, which is a container in the form of a mixer for grinding and mixing various products and subsequent activation, is equipped with a lid with electrodes vertically mounted in it - anode and cathodes, the free ends of which are fixed on a tourmaline-ceramic spacer.

The diaphragmless electrolyzer for electrochemical activation, which is a container in the form of a mixer for grinding and mixing various products and subsequent activation, is equipped with a removable lid with a chopper-knife with an electric motor and DC and AC sources located in the bottom of the vessel, the DC current was supplied to the lid with electrodes flexible wire.

The diaphragmless electrolyzer for electrochemical activation is made in the form of an elongated handle and is designed to activate various cosmetic products or hygiene products by placing electrodes in small containers, while the electrodes - the anode and cathodes are mounted on one end of the handle on a tourmaline-ceramic spacer, and on the other end A wire is placed to connect to a DC source.

The diaphragmless electrolyzer for electrochemical activation is designed to activate cosmetic or hygiene products and is made of two parts - the base with half-spherical containers located on its surface, and the cap with hemispherical protrusions made on its lower surface located above the half-containers. moreover, the inner surface of each of the recess containers serves as a cathode, the tourmaline-ceramic spacers are fixed in the center of the recess containers, and the outer surface of each protrusion is used as an anode, and stops are made on the lower surface of the lid, and the direct current source is located in the lower parts of the base.

Diaphragmless, electrolyzer for electrochemical activation of solid food products (fruits, vegetables, etc.) is made in the form of elongated wedge-shaped flat needles. fixed in the handle and serving as the anode and cathode, and the tips of the wedge-shaped flat needles are inserted into the tissue of the activated products, while the connection to the DC source is made by a flexible wire.

The diaphragmless electrolyzer for electrochemical activation is designed to activate liquid in large containers and is made in the form of a set of flat electrodes - an anode and two cathodes, fixed with a tourmaline-ceramic spacer to the tube, which serves to supply power to the anode and cathodes and a float for regulating the immersion depth electrodes into the activated fluid.

Diaphragmless electrolyzer for electrochemical activation, designed to activate liquid in large containers and is made in the form of a set of electrodes - anode and cathode in the form of outer and inner cones, fixed by means of a tourmaline-ceramic spacer to the tube for supplying power to the anode and cathode and a float for regulation the depth of immersion of the electrodes in the activated fluid, while the anode is made with holes on the surface of the cone in the form of windows for the removal of gases in the activation process.

The diaphragmless electrolyzer for electrochemical activation is made in the form of a cooler and is designed to supply cold and hot water, as well as room temperature water, and is made with three containers, the bottom of which is covered with a tourmaline-ceramic plate, and of which each container is designed to activate water, respectively, one of temperature characteristics, and in the bottoms of each of the tanks mounted on a set of electrodes - anodes and cathodes, and DC and AC sources are mounted in the bottom of the housing cooler.

Figure 1 shows a General view of the electrolyzer for contactless diaphragm activation with the surfaces of the electrodes - the anode and cathode, made in the form of a texture of spatial pyramids, with sharp vertices of the pyramids directed towards each other.

Figure 2 presents a General view of the electrolyzer for contactless activation without contact with the surfaces of the electrodes - the anode and cathode, made in the form of a texture of spatial pyramids with sharp pyramid vertices on the cathode surface, directed towards the anode with an offset of ¹ / ₂ steps.

Figure 3 presents the device - type "kettle" (for hot drinks water, coffee, tea) with a built-in electrolyzer for contactless activation.

Figure 4 (A, B) shows a device of the type "mug" (for cold drinks - water, juices, drinks based on juices) with an integrated device for contactless activation (option A - with the placement of electrodes in the bottom, option B - with the placement of the electrodes in the lid).

Figure 5 presents a device of the type "pan" for contactless diaphragm activation of heated liquid or jellied products (broths, hot sauces, etc.).

Figure 6 shows a device of the type "mixer" for grinding and mixing food products with subsequent contactless activation.

Fig. 7 (A, B) shows a device in the form of an elongated handle for contactless activation of chilled food products of various densities and consistencies (juices, fruits, vegetables, berries and other purees, etc.).

On Fig (A, B) presents a device for contactless diaphragm activation of cosmetic or hygiene products.

Figure 9 (A, B) shows the device made in the form of elongated wedge-shaped flat needles fixed in the handle for contactless activation of solid food products (fruits, vegetables).

Figure 10 shows a device for contact activation of large volumes of liquid (bath, tank, barrel, etc.) with flat electrodes.

11 (A, B) shows a device for contact activation of large volumes of liquid (bath, tank, barrel, etc.) with cone-shaped electrodes.

On Fig presents a device of the type "cooler" for contact activation of drinking water.

Diaphragmless contact electrochemical activation of products and media of various densities and consistencies is based on the phenomenon of the formation of resonant microclusters in liquids — resonance systems from oscillating “dipoles” of water (ions, molecules, OH-, etc.) near the anode and cathode during activation. Activated media and products are in direct contact with the surface of the anode or cathode and pass into a metastable state, which can be called the structural, activated state of a particular medium. As a result, changes in the properties of the medium, the redox potential — ORP, and the microcluster structure occur. In this case, only the structure changes, and the pH of the substance, i.e. chemical composition - does not change, which indicates the physiological processes occurring during this treatment. Comparative characteristics of the electrochemical activation of various food and household products in a non-contact and claimed manner are shown in table 2.

The electrochemical activation of the invention is carried out contactlessly in a diaphragmless electrolyzer. In this case, an activated product is placed in one of the listed devices. The device is connected to a direct current source and the product is activated. The activation time from 30 seconds to 15 minutes depends on the quality and volume of the activated product. Contact-activated media - liquids, drinks, gels, creams, shampoos, fruits, vegetables, etc. they come into direct contact with the surface of the anode, cathode and tourmaline ceramic, turn into a metastable state, are saturated with far-infrared waves, are magnetized under the influence of a low-frequency magnetic field - there is a change in the properties of the ORP and the microcluster structure of the products. As a result of metabolism, free radicals are formed in the body, which are reactive compounds in the form of atoms, molecules and ions with an unpaired number of electrons in the outer orbit of atoms, which puts them in the category of strong oxidizing agents. They participate in many vital physiological processes - the destruction of bacteria, unwanted impurities, the regulation of vascular tone, etc. However, the presence of the required amount of free radicals in the body is in a delicate ratio with the possible physiological mechanisms of neutralizing their excess. Radicals can undesirably interfere with ongoing vital biochemical processes, disrupting their performance, thereby creating toxic products that destroy or harm cells. Reacting with DNA, free radicals can lead to their mutation with subsequent disruption of the mitotic cycle and the onset of the development of the cancer process. Diseases such as Alzheimer's, schizophrenia, diabetes mellitus, Parkinson's disease, arthritis, psychosis, neurodegenerative conditions, etc. it is customary to attribute the results of side effects of free radicals.

The relevance of neutralizing the excess of free radicals formed in the body during metabolism is widely covered in modern medical literature. Physiology has established mechanisms that contribute to reducing damage caused by radicals and repair damage. Among them, antioxidants play a key role.

The essence of the beneficial effects of antioxidants is to block the oxidation process by neutralizing free radicals, which can only be achieved by filling up the unpaired orbits of free radicals with the missing number of electrons. As a result of this, the antioxidant itself is oxidized, and the antioxidant loses its biochemical value. Therefore, their constant replenishment in the body is necessary.

Activation is carried out to ORP values at which the antioxidant activity of the product reaches a maximum level. So, for example, fruits and vegetables contactly activate up to ORP values from -75 to -88 mV, which corresponds to the maximum antioxidant activity of products from 1.9 to 2.6 mg / l .; alcoholic beverages: vodka, cognac, cocktails, beer and non-alcoholic carbonated and non-carbonated drinks contactly activate up to OPV values from -115 to -185 mV, which corresponds to the maximum antioxidant activity of drinks from 1.5 to 2.5 mg / l .; mixtures for baby food, protein shakes contactly activate up to OPV = from -260 to -280 mV, which corresponds to the maximum antioxidant activity of drinks from 4.5 to 24.2 mg / l; cosmetics and hygiene products (gels, shampoos, liquid soap, ointments, pastes, creams, perfumes, lotions, cosmetic milk) are activated by contact to OPV values from -370 to -385 mV, which corresponds to the maximum antioxidant activity of products from 1, 4 to 1.8 mg / l; milk, milk drinks contact activate up to ORP values from -452 to -460 mV, which corresponds to the maximum antioxidant activity of drinks 6.2-6.8 mg / l; fruit and vegetable juices , fruit drinks, vegetable soups, broths, vegetable and fruit purees clear and jelly-like mixtures, wine contact activates up to ORP values from -520 to -570 mV, which corresponds to the maximum values of the antioxidant activity of drinks 35.5-38.6 mg / l; pharmaceuticals (liquid extracts of infusions of ragenia, rhizomes and herbs), as well as tea, coffee contact activate up to OPV values from -610 to -675 mV, which corresponds to the maximum antioxidant activity of the products 25.2-35.2 mg / l. Activation is carried out for 0.5-15 minutes, depending on nature and volume of the activated product.

The diaphragmless electrolyzer according to the invention is characterized in that the anode and cathode can be made in the form of a plate, a rod, a cylinder, or any other shape. Moreover, to enhance activation, their surface can be made in the form of a texture of trihedral or polyhedral spatial pyramids with sharp edges and apex, and the surface of the pyramids must be smooth. When changing the device for activating another product, electrodes with a smooth surface can be easily cleaned, rinsed, etc. Depending on the selected size and number of spatial pyramids, it is possible to control the surface of the electrode. For example, if you take a rectangular electrode with an area of 421.3 mm ² , then in the presence of pyramids with a height of 0.5 mm, an area of 599.217 mm ^{2 is formed} . A comparative characteristic of the activation and relaxation times of various food and household products with flat and pyramidal electrodes is given in Table 1. The electric field strength (it affects the medium in which it is placed, and the medium remembers the state it goes into) largely depends on surface shapes of electrodes. It is very high near the tip and the “sharper” the tip, the higher the tension. Charges flow down from the tip even at very low supplied voltages; they simply cannot be held. Even along with acting on the medium in a purely field way, an electrode with a high curvature (having a tip) locally charges the medium. This can lead to the formation of stable finely structured clusters, and thus activated water, subject to the same storage conditions, holds negative ORP for much longer than water activated by an electrode with a smooth, or even mesh surface.

The vertices of the pyramids of the anode and cathode are directed towards each other. Moreover, each of the spatial pyramids has an acute angle formed by edges. The electric field generated by the direct current source also depends on the magnitude of the pyramid apex angle, and the smaller the magnitude of the pyramid apex, the higher the electric field near the pyramid apex.

In our electrolyzer we use tourmaline - a natural semiprecious stone; it belongs to the group of boron-containing aluminosilicates to the subgroup of minerals. Tourmaline has a number of useful properties, so it has found application in medicine and in everyday life. Comparative characteristics of the electrochemical activation and relaxation of various products with tourmaline and without tourmaline are given in table 3.

Tourmaline crystals are characterized by the manifestation of pyro- and piezoelectricity (they are electrified by heating, friction, pressure). In this case, negative ions are synthesized. which are used in medical devices for the manufacture of special mattresses, water activation, etc.

Giving off the charge, tourmaline simultaneously receives it from the medium in which electrochemical activation occurs, with the formation of a large number of free electrons. Thus, it is constantly charging, its properties are enhanced and its life is extended.

Tourmaline creates a low-frequency magnetic field when heated, similar to a person’s natural magnetic field. By acting on the body, it enhances cellular metabolism, local blood flow and improves nutrition in organs and tissues, strengthens the immune system, and contributes to the balance of the autonomic nervous system. The natural properties of tourmaline allow it to be used in medicine to stimulate and treat the body, positively affecting its functions (US Pat. RF. No. 2030910, 1995, IPC A61H 39/00 “Means for influencing the body”). Tourmaline produces long-wave infrared radiation. This part of the infrared radiation corresponds to the radiation of the human body itself with a maximum at a wavelength of about 10 microns.

Therefore, any external radiation with such wavelengths is perceived by our body as our own.

By acting on the human body in the long-wavelength part of the infrared range, you can get a phenomenon called "resonant absorption", in which external energy will be actively absorbed by the body. As a result of this effect, the potential energy of the body’s cells increases, and unbound water leaves it, the activity of specific cellular structures increases, the level of immunoglobulins increases, it contributes to the destruction and removal of heavy metal salts from the body, it has bactericidal and antiseptic properties, while the activity of enzymes and estrogen, other biochemical reactions occur. This applies to all types of body cells and blood. Therefore, the use of tourmaline in the inventive electrolyzer will enhance the properties of activated products.

The life of tourmaline is limited, giving away negative ions, it gradually discharges and loses its properties. The use of tourmaline in the proposed devices will significantly increase their duration due to the saturation of tourmaline with free electrons in the electrolysis process.

The electrolyzer for contactless diaphragm activation 1.1 (Fig. 1, Fig. 2) contains a container 1.2 for an activated product with electrodes located in it - at least one anode 1.3 and at least one cathode 1.4. The electrodes are located on a tourmaline-ceramic base 1.5. The surfaces of the electrodes — the anode 1.3 and cathode 1.4 — are made in the form of a texture of spatial pyramids 1.6, each with sharp edges 1.7 and sharp peaks 1.8, with the spatial pyramids at the cathode and anode with sharp peaks facing each other. The electrodes are connected to a DC 1.9 power supply in the form of an adjustable voltage source.

Electrolysis 1.1 (2), wherein the spatial pyramid 1.6 1.4 at the cathode and anode is 1.3 1.7 sharp vertices face each other so that the tops of the pyramids on the cathode surface of 1.4 displaced relative vertices of the pyramids on the anode surface of 1.3 _^1/2 steps.

ORP meter and pH meter can be installed separately.

The direct current source can be equipped with an automatic or semi-automatic ORP controller. ORP meter, pH meter and DC source with ORP regulator can be made in the form of a single unit.

The feedback of the ORP meter with a direct current source with an ORP regulator can be implemented, moreover, to maintain a given value of the ORP during activation, the ORP regulator changes the voltage of the current source supplied to the electrodes.

The optimal distance from the anode to the cathode should be close enough to ensure the least potential loss under the condition of free circulation of the activated fluid. In cases with liquid, it is advisable to keep a distance of 1.5-3 mm. When activating products containing solid ingredients, it is advisable to set the distance between the anode and cathode within 1.5-7 mm.

The devices according to the invention are variants of devices for various purposes, including household appliances that functionally perform the task of contact electroactivation using the claimed electrolyzer.

In figures 3-12 but the invention presents embodiments of a diaphragmless electrolyzer in the form of household devices (hereinafter referred to as "the device").

Figures 3-12 show, by way of example, electrolytic electrodes made with a surface in the form of a texture of spatial pyramids, each of which has a sharp apex and sharp ribs, while the cathode and anode surfaces with the sharp vertices of the pyramids facing each other, are shown in FIG. .12.

The device (figure 3) for contactless activation of drinks is made in the form of an electric kettle 3.1, filled with an activated liquid placed in its bottom 3.2 with a medium heater, current sources - constant 3.3 and variable 3.4. The cathode 3.5 in the kettle is its bottom, hermetically adjacent to the body of the kettle along its perimeter. At the same time, the same cathode 3.5 serves as a heating plate, under which is a heater isolated from cathode 3.5. Conducting a constant electric current for the purpose of activation and heating with an isolated gel heating occur simultaneously. Anode 3.6 is a perimeter-insulated plate in the form of a horizontal spiral placed above the cathode 3.5 and supported by a ceramic pin made of tourmaline 3.7. This anode 3.6 design allows fluid to circulate between the electrodes.

The device (Fig. 4) (A, B) for contact activation is made in the form of a circle 4.1 with a cover 4.2 (or without a cover) filled with an activated medium with a direct current source 4.4 placed in its bottom 4.3, and the electrodes of the anode 4.5 and cathodes 4.6 are placed in the mug 4.1 and fixed either in its bottom 4.3 (A) on a tourmaline ceramic base 4.7, or in the entire lid 4.2 (B), the spatial pyramids (in Fig. 1.2) on the cathode 4.6 and anode 4.5 with sharp peaks facing each other to a friend.

The device (Fig. 5) for contact activation is made in the form of a pan 5.1 with a lid 5.2 filled with an activated liquid, with current sources placed in its bottom 5.3 - constant 5.4 and variable 5.5 and a medium heater 5.6, placed in the pan, and the electrodes - anode 5.7 and cathodes 5.8 are placed in a pan and fixed in its cover 20 on a tourmaline - ceramic plate 5.9, the spatial pyramids (but Figs. 1, 2) on the cathode 4 and anode 3 with sharp peaks 7 facing each other, while supplying direct current to cover 5.2 is made of flexible wire 5.10.

The device (Fig.6) is made in the form of a mixer 6.1 for grinding and mixing various products (preparation of juices, fruits, vegetables, berries and other purees, etc.) with their subsequent activation and is equipped with DC 6.3 sources placed in its bottom 6.2 and alternating current 6.4. as well as a removable cover 6.5 with a chopper knife 6.6 with an electric motor and a cable 6.7 for supplying electricity and a replaceable cover 6.8 with electrodes fixed in it - anode 6.9 and cathodes 6.10 with a tourmaline spacer 6.11, and the spatial pyramids (according to Figs. 1, 2) on the cathode and anode, the sharp peaks face each other, while the DC current supply to the cover 6.8 is made with a flexible wire 6.12.

The device (Fig.7) is made in the form of an elongated handle 7.1 and is designed to activate various products (juices, fruits, vegetables, berries and other purees, shampoos, gels, etc.) in small volumes, and the electrodes - anode 7.2 and cathodes 7.3 are fixed at one end of the handle 7.4, consisting of tourmaline ceramic, and at the other end there is a 7.5 wire for connection to a direct current source (in Fig. 8A), and the spatial pyramids (in Figs. 1, 2) at the cathodes and anode with sharp peaks facing each other.

The device (figa, - a General view, 8B is a fragment of figa) for contact activation of cosmetic or hygiene products is made of two parts - the base 8.1 and the lid 8.2, while one or more containers-recesses 8.3, for example, spherical for placement of cosmetic or hygiene products in them, located on the surface of the base 8.1; a direct current source 8.4 is located in the lower part of the base; protrusions 8.5 in the form of hemispheres located above the recess containers 8.3 are made on the lower surface of the lid, their inner surface serves as cathodes 8.6, tourmaline-ceramic spacers 8.7 are fixed in the center of the recess containers; hemispherical protrusions 8.5 serve as anodes 8.8, and the surface texture of the electrodes - anodes and cathodes is made in the form of spatial pyramids (Fig.1, 2), facing sharp vertices to each other; on the lower surface of the lid 8.2, stops 8.9 are made, which determine the relative position of the protrusions and recesses relative to each other and limit the number of activated media in the recess containers 8.3. At the base 8.1, there is a socket for connecting the power cable 7.5 of the handle 7.1 (Fig.7) to a direct current source 8.4.

The device (Fig. 9A is a general view, Fig. 9B is a side view) for contact activation of solid food products (fruits, vegetables, etc.) is made in the form of elongated wedge-shaped flat needles 9.1, fixed in the handle 9.2 and serving as the anode 9.3 and the cathode 9.4, the spatial pyramids (Figs. 1, 2) on the cathode and anode with sharp peaks are facing each other, and the tips of the wedge-shaped flat needles 9.1 are embedded in the tissue of the activated products, while the connection to the DC source 9.5 is made by a flexible wire 9.6.

The device (figure 10) for contact activation of large volumes of liquid (bath, tank, barrel, etc.) is made in the form of a set of flat electrodes - anode 10.1 and cathodes 10.2, mounted on a tourmaline-ceramic base 10.3, the surfaces of which are made in the form textures from spatial pyramids with sharp vertices of the pyramids on the surface of the cathodes, directed toward the anode with an offset relative to the vertices of the pyramids (Fig.2); the tube 10.4 and the float 10.5 are used to control the depth of immersion of the electrodes in the activated liquid when moving and fixing the float on the tube.

A device (figa, b) for contact activation of large volumes of liquid (bath, tank, barrel, etc.), in which the electrodes are made in the form of cones - anode 11.1 and cathode 11.2, mounted on a tourmaline-ceramic base 11.3. The surfaces of the anode and cathode are made in the form of outer and inner cones in the form of a texture of spatial pyramids (Figs. 1, 2) with sharp vertices of the pyramids directed towards each other. The anode 11.1 is made in the form of a cone (Fig.11B) with holes in the form of windows 11.4 through which gases are removed during the activation process. The device is equipped with a tube 11.5 for supplying power to the anode and cathode, a float 11.6 to control the depth of immersion of the electrodes in the activated fluid.

The device (Fig), made in the form of a dispenser for water (cooler) 12.1. Designed to supply cold, hot water, as well as water at room temperature, combining the functions of heating and cooling water. The device consists of three containers 12.2, 12.3, 12.4, each of which is designed to activate water, respectively, according to one of the above temperature characteristics. In the bottom of each tank, consisting of tourmaline ceramic 12.5, 12.6, 12.7, mounted on a set of electrodes - anode 12.8 and cathodes 12.9, the surfaces of which are made in the form of a texture of spatial pyramids, with sharp peaks facing each other. There are taps (pos. Not shown in FIG.) For water extraction connected to each of the containers. The heating-cooling element 12.10 is located between the containers 12.2 and 12.3. Sources of direct and alternating current (positions not specified) are mounted in the bottom of the cooler body 12.1. The device can be made both for connecting to a plumbing system, and for the possibility of autonomous water supply.

In the aspect of the practical operation of the devices we represent, we consider it rational to use three electrodes: one anode and two cathodes.

In this arrangement of electrodes, two surfaces of the anode are used, from which the charge emanates, and along one surface of two cathodes, mapped on both sides of the anode, which make up for the conditions for creating an electric field. We do not exclude, depending on the needs of using a particular promising device, the use of electrodes with a different number of anodes and cathodes.

The proposed technical solutions will allow to obtain products, including food products with the above properties, aimed at improving the body.

Claims (15)

1. Diaphragmless electrolyzer for electrochemical activation, containing a DC power source in the form of an adjustable voltage source and a capacitance with electrodes located in it - at least one anode and at least one cathode of various shapes - round, oval, plate, tubular with different-sized holes, mesh and with a smooth surface, characterized in that the electrodes are placed on the element in the form of a pin, or spacers, or plates made of tourmaline or tourmaline ceramic. 2. Diaphragmless electrolyzer for electrochemical activation, characterized in that the electrodes are at least one anode or one cathode, or at least one cathode and one anode are made with a surface in the form of a texture of spatial pyramids, each of which has a sharp apex and sharp edges , while the surface of the cathode and anode with the sharp vertices of the pyramids facing each other. 3. The diaphragmless electrolyzer for electrochemical activation according to claim 1, characterized in that the electrodes - at least one cathode and one anode are placed directly in a container with an activated medium of various consistencies, which is hot and cold drinks (tea, coffee,), yogurts, protein drinks and mixtures, fruit and vegetable juices (natural, freshly squeezed, obtained from concentrate, with vitamin and other additives), fruit drinks, fortified drinks, soft drinks, non-carbonated and carbonated soft drinks, prepared based on natural and artificial ingredients, drinks and mixtures for baby food, alcoholic beverages (vodka, beer, cognac, cocktails, wines, balms, whiskey), fruits and vegetables, vegetable and fruit purees and jelly-like mixtures, soups, broths, and also cosmetics (creams, perfumes, lotions, cosmetic milk), hygiene products (gels, shampoos, liquid soap, ointments, pastes), foaming, flavoring agents, pharmaceuticals (liquid extracts of plant infusions, grass rhizomes). 4. The diaphragmless electrolyzer for electrochemical activation according to claim 2, characterized in that the electrodes - at least one cathode and one anode are placed directly in a container with an activated medium of different consistencies, which is hot and cold drinks (tea, coffee), yoghurts, protein drinks and mixtures, fruit and vegetable juices (natural, freshly squeezed, obtained from concentrate, with vitamin and other additives), fruit drinks, fortified drinks, soft drinks, non-carbonated and carbonated soft drinks, prepared f based on natural and artificial ingredients, drinks and mixtures for baby food, alcoholic beverages (vodka, beer, cognac, cocktails, wines, balms, whiskey), fruits and vegetables, vegetable and fruit purees and jelly-like mixtures, soups, broths, and also cosmetics (creams, perfumes, lotions, cosmetic milk), hygiene products (gels, shampoos, liquid soap, ointments, pastes), foaming, flavoring agents, pharmaceuticals (liquid extracts of plant infusions, grass rhizomes). 5. The diaphragmless electrolyzer for electrochemical activation according to claim 1, characterized in that the capacitance is made in the form of an electric kettle filled with an activated liquid, with direct and alternating current sources and a medium heater placed in its bottom, the cathode serving as the bottom of the kettle, and the anode being a plate insulated around the perimeter in the form of a horizontal spiral placed above the cathode supported by a tourmaline-ceramic pin. 6. The diaphragmless electrolyzer for electrochemical activation according to claim 1, characterized in that the container is made in the form of a mug with a lid (or without a lid) filled with an activated medium with a direct current source located in its bottom, and the electrodes - the anode and cathodes are placed in capacity vertically, the free ends of which are fixed on a tourmaline-ceramic spacer, either in its bottom or in its lid. 7. The diaphragmless electrolyzer for electrochemical activation according to claim 1, characterized in that the container is made in the form of a pan with a lid filled with an activated medium, with direct and alternating current sources and a medium heater located in its bottom, and the electrodes - the anode and cathodes are placed in capacity and vertically fixed in the lid of the pan, the free ends of the electrodes are fixed on a tourmaline-ceramic spacer. 8. The diaphragmless electrolyzer for electrochemical activation according to claim 1, characterized in that the container is made in the form of a mixer for grinding and mixing products of different consistencies with subsequent activation and is equipped with a lid with vertically mounted electrodes in it - anode and cathodes, the free ends of which are fixed to tourmaline-ceramic spacer. 9. The diaphragmless electrolyzer for electrochemical activation according to claim 1, characterized in that the tank is made in the form of a mixer for grinding and mixing products of various consistencies with subsequent activation and is equipped with a removable lid with a chopper knife with an electric motor and constant and variable sources located in the bottom of the tank current, and the direct current supply to the cover with electrodes is made by a flexible wire. 10. Diaphragmless electrolyzer for electrochemical activation, characterized in that it is made in the form of an elongated handle and is designed to activate various cosmetic products or hygiene products by placing electrodes in small containers, while the electrodes - anode and cathodes are mounted on one end of the handle on a tourmaline - a ceramic spacer, and on the other end there is a wire for connecting to a DC source. 11. Diaphragmless electrolyzer for electrochemical activation, characterized in that it is intended for activation of cosmetic or hygienic products and is made of two parts - a base with half-spheres in the form of recesses located on its surface, and a lid with protrusions made on its lower surface in the form hemispheres located above the recess containers, the inner surface of each of the recess containers serving as a cathode; in the center of the recess containers, a tourmaline ceramic s spacer and the outer surface of each protrusion serves as an anode, while on the lower surface of the cover stops made, and constant current source is placed at the bottom of the base. 12. Diaphragmless electrolyzer for electrochemical activation, characterized in that it is designed to activate media in the form of solid food products and is made in the form of elongated wedge-shaped flat needles fixed in the handle and serving as an anode and cathode, while the tips of the wedge-shaped flat needles are inserted directly into the fabric activated products, and the connection to a constant current source is made by a flexible wire. 13. A diaphragmless electrolyzer for electrochemical activation, characterized in that it is designed to activate liquid in large containers and is made in the form of a set of flat electrodes - the anode and cathodes, fixed with a tourmaline-ceramic spacer to the tube, which serves to supply power to the anode and cathodes and float to control the depth of immersion of the electrodes in the activated fluid. 14. Diaphragmless electrolyzer for electrochemical activation, characterized in that it is designed to activate liquid in large containers and is made in the form of a set of electrodes - anode and cathode in the form of outer and inner cones, fixed by means of a tourmaline-ceramic spacer to the tube for supplying power to the anode and the cathode and the float to control the depth of immersion of the electrodes in the activated fluid, while the anode is made with holes on the surface of the cone in the form of windows for the removal of gases in the process of activation. 15. Diaphragmless electrolyzer for electrochemical activation, characterized in that it is made in the form of a cooler and is designed to supply cold and hot water, as well as room temperature water and is equipped with three containers, the bottom of which is covered with tourmaline-ceramic plates, and of which each container is designed for activation of liquid media, respectively, according to one of the temperature characteristics, and in the bottoms of each of the tanks mounted on a set of electrodes - anode and cathodes, and sources of constant and variable eye mounted in the bottom of the cooler housing.

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