RU2494973C1 - Direct-flow electroactivator of water - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: invention can be used in technology of electroactivation processing of water, used for drinking purposes in medicine and agricultural production. Direct-flow water electroactivator includes case (2), divided with cup (5) from microporous semipermeable plastic into chambers with located in them external (3) and internal (6) electrodes. Case (2) is made from stable to electrochemical impact plastic in form of cylindrical segment of tube with connecting threaded tips. Electrodes (3, 6) are made corrugated from perforated stainless sheet steel, perforation holes (4, 7) are located on entire surface of electrodes (3, 6). To supply electric potential to electrodes (3, 6) clamps (10, 11) are provided. Guide apparatus (13), which has blades (14) of left-sided direction, made from dielectric material, is placed on input part of case (2). Output part of case (2) is covered with replaceable threaded lid (9), made from plastic material, stable to electrochemical impact, and provides possibility of output of one or two flows of electroactivated water.

EFFECT: invention makes it possible to simplify construction and increase coefficient of efficiency of water electroactivator, as well as to obtain flows of activated water with specified redox potential.

2 dwg

Description

The invention relates to a technology for increasing the biological activity, energy and vitality of water used for drinking purposes in medicine and agricultural production, which, when interacting with living organisms, provides an increase in their energy level and vitality.

The main processes that ensure the vital activity of any organism are redox reactions, i.e. reactions associated with the transfer or attachment of electrons. The energy released during these reactions is spent on maintaining and regenerating the cells of the body - to ensure the vital processes of the body.

The most significant factor in regulating the parameters of redox reactions occurring in a liquid medium is the activity of electrons, i.e. redox potential (ORP) of this medium.

If the water entering the body has an ORP close to the value of the ORP of the internal environment of the body, then the electric energy (the vital energy of the body) is not spent on the correction of the activity of electrons in the water and the water is immediately absorbed, since it has biocompatibility in this parameter.

It is known that a water molecule is formed by the combination of two hydrogen atoms and one oxygen atom and is electrically polarized. The hydrogen side is more positive and the oxygen side is more negative, and two hydrogen atoms are attached to the oxygen atom at an angle of 104.5 °.

One of the most important properties of water is its ability to ionize.

During ionization, the water molecule splits into two parts, which are called the hydrogen ion (H ⁺ ) and the hydroxyl ion (OH ^- ). Water in which H ⁺ ions predominate is called acid (dead) water, and if OH ^- ions predominate, it is called alkaline (living) water.

The ratio of H ⁺ ions to the entire water molecule is known as the pH value. With equal amounts of H ⁺ and OH ^- ions, the pH of the water is determined by the number 7, and the water is neutral. An increase in pH means that OH ^- ions predominate in water.

A natural function of water molecules is their rotation along their axis, while the molecule can rotate either from left to right (clockwise), or from right to left.

In diseased cells of the body, molecules have a right-handed rotation, and in healthy cells, left-handed.

The change in the redox potential is provided using known electroactivation plants.

A known electrolyzer for water treatment, comprising a housing divided by a diaphragm into the anode and cathode chambers with perforated electrodes placed therein, pressed against the diaphragm, the surface of the electrodes facing the diaphragm is coated with an insulating material, and the perforation of the electrodes is made coaxially (SU, copyright certificate No. 882944 A, M. Cl. C02F 1/46).

The disadvantages of the known device include low productivity, the inability to obtain a continuous stream of activated water, as well as the inability to control the amount of water with a given potential.

It is also known a device for electrochemical processing of liquid, containing a dielectric casing, divided by a diaphragm into the anode and cathode chambers with anode and cathode located in them, respectively, connected to a direct current source, while the electrode chambers are connected by a transfer channel, the input of which is located in the cathode chamber near it bottom near the diaphragm, and the exit is in the anode chamber at the upper edge of the electrode, and in the channel at its ends there are mesh electrodes connected to an additional source of constant so that the mesh electrode at the channel inlet is the cathode, and at the output it is the anode, and the negative pole of the additional current source is connected to the positive pole of the main current, and the transfer channel is made in the device’s casing (SU, copyright certificate No. 1634643, A1, IPC ⁵ C02P 1/46).

The disadvantages of this device include increased energy consumption for water treatment due to the fact that part of the energy is unproductively spent on electrolysis of the water layer located between the electrodes, the low productivity of the device, the inability to obtain a continuous stream of activated water, the inability to control the flow of water with a given potential.

A known electrolyzer for water treatment, comprising a housing divided by a diaphragm into the anode and cathode chambers with the anode and cathode located in them, with vertical ribs installed on the surface of the electrodes from the side of the interelectrode space, pressing the diaphragm against the surface of the opposite electrode, and on the anode and cathode of the rib installed in alternating order and made of conductive material (SU, copyright certificate No. 1468867, A1, IPC ⁴ C02F 1/46).

The disadvantages of this device include the complexity of the design, the inability to control the flow of water flowing through the cathode and anode chambers, and to create a given potential of the supplied water for irrigation.

A known installation for the electrochemical activation of irrigation water, mainly for drip irrigation systems, comprising a housing divided by partitions into anode and cathode chambers with anodes and cathodes located in them and equipped with nozzles for separate removal of treated water with negative and positive potentials, while the cathode and anode the chambers are divided by semipermeable corrugated partitions made in a vertical plane with a height equal to the distance between the cathode and anode, while the cathode The nodal and anode chambers are housed in a dielectric casing and are equipped with a common water supply pipe, and the nozzles for water drainage are equipped with valves for changing the flow rate of activated water (RU Patent No. 2224722, IPC ⁷ C02F 1/46).

The disadvantages of this installation include the increased cost of electrical energy and the low efficiency of electrochemical processing due to the laminar flow of the treated water and insufficient contact of the flow particles with the electrodes.

The closest technical solution is a device for electrochemical water treatment, comprising a housing divided by a glass of microporous semipermeable plastic into chambers with anode and cathode placed in them, while the cathode is made of profiled alloy steel sheet and covers a glass of microporous semipermeable plastic, and the anode made of profiled alloy steel sheet, installed with the span of the central rod and placed inside the cup of microporous semipermeable plate tmassa, the cathode has shelves for fastening to a cover made of dielectric material, the anode is fixed on one side by a stop, and on the other by a cover by means of a nut, the anode and cathode are placed on the cover and made removable (RU, patent No. 2281915, C02F 1/46 )

The disadvantages of the device include the inability to obtain a continuous stream of electroactivated water, a given redox potential, low efficiency.

This device for the electrochemical treatment of water is accepted by us as the closest analogue.

The problem to which the present invention is directed is to obtain a continuous stream of activated water of a given redox potential.

The technical result is a simplification of the design, providing the possibility of obtaining flows of activated water of a given ORP, increasing the efficiency of the water electroactivator.

The specified technical result is achieved in that the direct-flow electroactivator of water includes a housing divided by a glass of microporous semipermeable plastic into chambers with anode and cathode placed in them, while the housing is made of plastic that is resistant to electrochemical effects in the form of a cylindrical pipe segment with connecting threaded ends, inside the housing contains two electrodes, the outer and the inner ones, separated by a glass of semipermeable microporous plastic, the electrodes are made corrugated made of perforated stainless steel sheet, terminals are provided for supplying electric potential to the electrodes, a guide apparatus is placed on the input part of the housing, which has left-hand blades made of dielectric material, the output part of the housing is closed with a replaceable threaded cover, which allows the release of one or two flows of electroactivated water, the cover is made of plastic material resistant to electrochemical effects.

The invention is illustrated by drawings.

Figure 1 shows a device for electroactivation of water, a diametrically vertical section.

Figure 2 is the same, a top view, without a guide apparatus.

Information confirming the possibility of implementing the claimed invention are as follows.

Direct-flow water activator includes a supply pipe 1 connected by a threaded connection to a housing 2 made of plastic resistant to electrochemical effects. Inside the housing 2, with respect to its inner wall, an external electrode 3 is installed, made of corrugated sheet of perforated stainless steel. Perforation holes 4 are placed over the entire surface of the electrode 3. The outer electrode 3 is separated by a cup 5 from the inner electrode 6. The cup 5 is made of microporous semipermeable plastic. The inner electrode 6 is made of corrugated perforated stainless steel sheet. Perforation holes 7 are placed on the entire surface of the electrode 6. The protrusions of the corrugations of the electrode 6 are pressed against the central rod 8. The output part of the housing 2 is closed by a replaceable threaded cover 9. Terminal 10 is used to supply the electric potential to the electrode 6, and to supply the electric potential to the electrode 3, terminal 11. Terminal 10 has a dielectric isolation 12 from the electrode 3. In the input part of the housing 2 there is a guide apparatus 13 having left-hand blades 14. When using direct-flow electric water activator for the preparation of activated water used in the food industry or medicine, the electrodes 3, 6, 8 are made of titanium.

Direct-flow electric activator of water works as follows.

To get one catholyte stream - water with negative ORP - negative potential is applied to terminal 10, and positive to terminal 11. A cover 9 of the structure shown in FIG. 1 is mounted on the output part of the housing 2. Through the inlet pipe 1 a flow of running water is supplied. When interacting with the blades 14 of the guide vane 13, the flow acquires a rotational movement of the left-side orientation. In a rotating stream of left-side orientation, water molecules change their structure, which ensures an increase in its energy and vitality. The counterclockwise flow flows to the electrodes 3, 6. When water interacts with the electrodes, the electrons from the electrode 3 through the walls of the cup 5 go to the electrode 6. In this case, the water located between the corrugations of the electrode 3 acquires a positive ORP, and the water located between the corrugations electrode 6, receives a negative ORP. If the lid shown in Fig. 1 is mounted on the outlet of the housing 2, the consumer receives a catholyte with negative ORP, which can be used to increase the biological activity of living organisms, for example, seeds of agricultural crops. To obtain one anolyte stream, a positive potential of an electric current source is connected to terminal 10, and a negative potential to terminal 11. Turns on flowing water, which comes from the inlet pipe 1 to the guide apparatus 13, the blades 14 of which provide rotation of the left-side flow, providing maximum contact of the electrodes with the flowing water and increase its biological activity. Rotating counterclockwise flow enters the electrodes 3, 6.

In the interaction of water with the electrodes, the electrons from the electrode 6 enter through the walls of the cup 5 to the electrode 3, while the flow of water located between the corrugations of the electrode 6 acquires a positive potential, and the water located between the corrugations of the electrode 3, a negative potential.

Water with a positive potential through the hole in the lid 9 enters the consumer and can be used to destroy pathogens and pests, as well as in medicine.

To obtain two flows of anolyte and catholyte, the cover 9 is replaced by a cover having two outlet openings - for water flows leaving the external and internal electrode (not shown in the drawing).

The developed design ensures the production of activated water flows of a given electrical potential, while the efficiency of the electroactivator is increased due to perforation of the electrodes.

Claims (1)

Direct-flow electroactivator of water, comprising a housing divided by a glass of microporous semipermeable plastic into chambers with anode and cathode placed in them, characterized in that the housing is made of plastic resistant to electrochemical effects in the form of a cylindrical pipe segment with connecting threaded tips, two electrodes are placed inside the housing : outer and inner, separated by a glass of semipermeable microporous plastic, the electrodes are corrugated from perforated sheets stainless steel, for supplying electric potential to the electrodes, terminals are provided, on the input part of the housing there is a guide apparatus having left-side blades made of dielectric material, the output part of the housing is closed with a replaceable threaded cover, which allows the exit of one or two flows of electro-activated water, the cover made of plastic material resistant to electrochemical effects.

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