RU2422373C1 - Electric activator of water - Google Patents

Abstract

FIELD: process engineering. ^ SUBSTANCE: invention relates to electric vortex water treatment and may be used for production of drinking water, in medicine, microelectronics, etc. Proposed electric activator comprises electrodes 1 and 3 arranged coaxially and semi-permeable diaphragm 2 arranged there between. Note here that outer electrode 1 is made up of tube section with threaded tips 5 and 10 made from stainless steel, while inner electrode 3 is made up of helical spring with left-hand coiling from stainless steel. Said inner and outer electrodes are separated by said semi-permeable diaphragm 2 made from microporous plastic material. Outer electrode inner cavity is stopped by dielectric material covers 6 and 11 provided with tight seals 7 and 12 and discharge pipeline. Electric potential is fed to inner electrode outer surface, behind said cover of feed pipeline, while that to outer electrode is fed to its outer surface below cover of feed pipeline. To change electric potential, potential switch is provided. ^ EFFECT: simplified design, water with preset redox potential. ^ 1 dwg

Description

The invention relates to nanotechnology for increasing the biological activity of water through its electrovortex treatment, which provides an increase in its energy, and the vitality used for drinking purposes, in industry, medicine, microelectronics, and crop irrigation in drip irrigation systems with regulation of redox properties.

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).

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

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 the 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 output 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 standing 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 case (SU, copyright certificate No. 1634643).

The disadvantages of this device include increased energy consumption for water treatment due to the fact that part of the energy is wasted 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 and vital by force.

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 to 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).

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 and vitality supplied to the 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 ny and anode chambers are placed 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 value of the flow rate of activated water (RU patent No. 2224722).

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 analogue to the claimed object relates to a device for the electrochemical activation of water and aqueous solutions, including coaxially located positively and negatively charged electrodes, a semi-permeable diaphragm between them, lower and upper collector heads with hydraulic channels pulled together by a threaded connection, while mounted vertically and performing functions negatively charged electrode has the form of a hollow cylinder with a helical groove on the inner surface, A fully charged electrode in the form of a rod has a helical groove and threaded tips, the pitch of the helical groove on the rod is made equal to the pitch of the helical groove of the negative charged electrode, while the protrusions of the helical groove of the rod separated by a cylindrical separator from microporous plastic are opposite the hollows of the helical groove of the negatively charged electrode, and the length the helical groove of the positive electrode is less than the length of the helical groove of the negative electrode (RU, Patent No. 2277070).

The disadvantages of the device include increased energy consumption for water activation, significant hydraulic resistance and structural complexity, in addition, there is no possibility of obtaining one water stream with a given potential - anolyte or catholyte.

Ranjit Mohanti in his book (Mohanti R. The healing power of water. Secrets of Indian sages. - St. Petersburg: Peter, 2006. - 128 pp., Ill.) States that two stages are necessary for transforming dead water:

1. Vortex the water. It is necessary that she change the structure.

2. Magnetize it to increase its energy level.

The invention consists in the following.

The problem to which the invention is directed is to increase the efficiency of water activation, reduce energy consumption for processing and increase biological activity, vitality and efficiency.

The technical result is a simplification of the design, the possibility of obtaining one stream of water with a given potential.

The specified technical result is achieved by the fact that in the known water activator of water, including coaxially arranged electrodes, a semipermeable diaphragm between them, while the outer electrode is made in the form of a pipe segment with threaded stainless steel tips resistant to electrochemical corrosion, and the inner electrode is made in the form of a cylindrical spiral, made along the helix of the left-hand winding of stainless perforated pipe, while the inner and outer electrodes are separated by a floor permeable diaphragm made of microporous plastic, the INTERNAL cavity of the outer electrode is closed by covers of dielectric material, which have a tight seal at the inlet and outlet pipes, the supply of electric potential to the inner electrode is made to the outer surface behind the cover at the inlet pipe, and to the outer electrode to its outer surface below the cover of the supply pipe, to change the potential supplied to the electrodes, a potential switch is provided.

The invention is illustrated in the drawing, which shows a cross section of an electroactivator of water.

Information confirming the possibility of implementing the claimed invention are as follows. The water activator includes an external electrode 1 in the form of a piece of stainless steel pipe resistant to electrochemical corrosion. In the inner cavity of the electrode 1, separated by a diaphragm 2 made of microporous plastic, an internal electrode 3 is installed in the form of a cylindrical spiral made along a helical line of left-hand winding from a perforated pipe made of stainless steel resistant to electrochemical corrosion.

Perforation 4 is made over the entire surface of the electrode 3. Using thread 5 on the side of the supply pipe, the outer electrode 1 is closed by a cover 6 having a hermetic seal 7. The cover 6 is made of dielectric material. The supply of electric potential to the outer electrode 1 is made using the bus 8, and to the inner electrode 3 - using the bus 9. The output cavity of the outer electrode using the thread 10 is closed by a cover 11, which has a tight seal 12. The cover 11 is made of dielectric material.

The water electroactivator works as follows: to obtain catholyte-water with a negatively charged potential, the negative potential is supplied to the electrode 3 using bus 9, and the positive potential to the electrode 1 using bus 8.

The flow of water flowing in the inner cavity of the electrode 3 through the perforation 4 fills the entire inner cavity of the electroactivator, which ensures free movement of electrons from the anode to the cathode — the inner electrode 3 and the flow of water flowing in the inner cavity of the electrode 3 acquires a negative potential, therefore, at the output we get catholyte from the electroactivator.

It is known that if a constant electric current flows through water, then the entry of electrons into the water at the cathode and the removal of electrons from the water at the anode is accompanied by electrochemical reactions on the surfaces of the cathode and the anode, as a result of which new substances are formed, the system of intermolecular interactions, as well as the structure of water, change as a solvent. During cathodic treatment, the water acquires an alkaline reaction, its redox potential (ORP) decreases, the surface tension decreases, the content of dissolved oxygen and nitrogen decreases, the concentration of hydrogen, free hydroxyl groups increases, the electrical conductivity decreases, the structure of ion hydration shells and the free volume of water change, the pH value rises.

The pH value of pH is a quantitative characteristic of the acidity or alkalinity of water and is determined by the activity of hydrogen ions - the ratio of the concentration of hydroxonium ions H ₃ O ⁺ and hydroxyl OH ^- . In neutral water, pH = 7, which corresponds to the equality of the concentration of these ions. The activity of hydrogen ions is a thermodynamic characteristic of their chemical potential in water.

The redox potential (ORP) characterizes the activity of electrons in water. An increase in the ORP decreases the activity of electrons, and a decrease in the ORP increases the activity of electrons.

In activated water, molecules have additional degrees of freedom due to hydrogen bonds broken under the influence of an electric field. This factor affects the physicochemical and biological reactions, providing an increased ability of activated water to penetrate into the molecular spaces of various substances and through biological membranes, increase hydration shells around individual ions and molecules, as well as at phase boundaries, increase the solubility of sparingly soluble compounds, and enhance extraction activity of water.

The rotational movement, which acquires the flow in the inner electrode 3, enhances the action of the electric potential and increases the efficiency. The catholyte provides increased energy and vitality to all living organisms. So when exposed to catholyte on plants of crops, their productivity increases, and product quality improves.

To obtain anolyte - water with a positively charged potential - the positive potential is supplied to the electrode 3 using the bus 9, and the negative potential to the electrode 1 using the bus 8. The flow moving in the inner cavity of the electrode 3 acquires a rotational vortex motion and fills through the perforation 4 the internal cavity of the electroactivator, which allows electrons from the electrode 3 to move to the electrode 1, while the water flow acquires a positive potential, and at the exit of the electroactivator we get anol it.

During anodic electrochemical treatment, the acidity of water increases, the redox potential increases due to the formation of stable and unstable acids - sulfuric, hydrochloric, hypochlorous, supra sulfuric, as well as hydrogen peroxide, peroxosulphates, peroxocarbonates, oxygen-containing chlorine compounds and other compounds that arise during spontaneous decomposition and interaction named substances. Anode treatment reduces surface tension, increases the conductivity and content of dissolved chlorine, oxygen, reduces the concentration of hydrogen, nitrogen, and changes the structure of water.

The rotational movement, which acquires the flow in the inner electrode 3, enhances the action of the electric potential and increases the efficiency of the electroactivator.

Anolyte provides the destruction of pathogenic microbes and pests and disinfects living organisms. So when anolyte acts on plants, all harmful microflora is killed, favorable conditions are created for their growth and development, and productivity is increased.

Claims (1)

A water activator comprising coaxially arranged electrodes, a semi-permeable diaphragm between them, characterized in that the outer electrode is made in the form of a pipe segment with threaded stainless steel tips resistant to electrochemical corrosion, and the inner electrode is made in the form of a cylindrical spiral made along a helical line left windings from a perforated pipe made of stainless steel resistant to electrochemical corrosion, the inner and outer electrodes are separated by a floor permeable diaphragm made of microporous plastic, the inner cavity of the outer electrode is closed by covers made of dielectric material, which have a tight seal at the inlet and outlet pipelines, the supply of electric potential to the inner electrode is made to the outer surface behind the cover at the inlet pipe, and to the outer electrode to its outer surface below the cover of the supply pipe, to change the potential supplied to the electrodes, a potential switch is provided.