UA20623U - Method for purification of aqueous solutions with electric erosion coagulation - Google Patents

Abstract

A method comprises passing aqueous solution through the layer of metallic granules, located in the discharge chamber, impact on metallic granules with electric pulses till formation of coagulants and destroying granules at an action of spark discharges and obtaining aqueous solution of a necessary purity. The aqueous solution is divided before passing through the layer of metallic granules into two fractions, creating acid medium in the first fraction, and alkaline medium in the second one. Thereafter every fraction is passed through the separate discharge chamber with the layer of metallic granules, filtrating acid and alkaline fractions, creating alkaline medium in the first fraction, and acid medium in the second fraction, and repeatedlypass every fraction through the separate discharge chamber with the layer of metallic granules.

Description

Description of the invention

The useful model refers to methods for complex processing of industrial, communal, medical, 2 rainwater and other effluents in order to improve their biological properties and can be applied in industry and agriculture to obtain water suitable for use.

A known method of water purification for the purpose of obtaining drinking water, which includes the operations of preliminary purification of water from harmful and poisonous substances, cooling of water, obtaining the required thickness of ice, thawing and drainage of condensate. Declaration patent of Ukraine Mo 51330, MIZH" СО2Е 9/00. Publ. 15.11 .2002. Bull. Mo111. The disadvantage of the described method is its complexity and low efficiency, which does not allow cleaning in running water.

The closest to the proposed method in terms of the number of essential features is the method of cleaning aqueous solutions by electroerosive coagulation, which includes the operations of passing an aqueous solution through a layer of metal granules placed in a discharge chamber, acting on the metal granules with electric impulses to form coagulants, and destroying the granules under the action of spark discharges ( Shydrovsky A.K., Shcherba A.A., Zakharchenko S.N. Prospects for the use of spark-ignition coagulation in water treatment systems of heat networks, J. Water and water treatment technologies Mo2 (6), 20031.

The disadvantage of the described method is its low efficiency, which becomes less as the speed of liquid flow through the layer of metal granules increases. This does not allow cleaning in running water.

The basis of the proposed method is the task of increasing the efficiency of cleaning aqueous solutions.

The task is solved by increasing the ionic strength of the aqueous solution, which allows the ionized solution to effectively remove impurities with the help of coagulants and effectively disinfect water.

The proposed, as well as the known, method includes the operations of passing an aqueous solution through a layer of metal granules placed in a discharge chamber, acting on the metal granules with electric pulses until the formation of 29 coagulants and destroying the granules under the action of spark discharges and obtaining an aqueous solution of the required purity, according to proposals, the aqueous solution before passing through a layer of metal granules is divided into two fractions, an acidic environment is created in the first fraction, an alkaline environment is created in the second, after which each fraction is passed through a separate discharge chamber with a layer of metal granules, the acidic and alkaline fractions are filtered, created in the first fraction alkaline environment, in the second acidic environment and repeatedly pass each fraction through a separate discharge chamber with a layer of metal granules. At the same time, the acidic medium of the fraction has a pH of no more than 5, and the alkaline medium of the SM fraction has a pH of no less than 9.

In the proposed method, the aqueous solution is divided into two fractions, an acidic environment is created in the first fraction, and an alkaline environment is created in the second. At the same time, an acidic environment has a pH of no more than 5, and an alkaline environment has a pH of no less than 9. At such pH values, a high concentration of hydrogen ions H-- in an acidic environment and a high concentration of hydroxyl ions OH- in an alkaline environment are created, which significantly increase the ionic strength of the solution. In acidic and slightly alkaline environments, reactions proceed differently and have different directions. At the same time, the processes of removing heavy metals and organic compounds are activated.

Each fraction is passed through a separate discharge chamber with a layer of metal granules, which are affected by electric pulses. During the passage of current pulses through the chains formed by metal ЗзЗ granules, electric discharges occur between individual granules and electrodes. At the same time, due to electrical erosion, coagulants are formed in an aqueous solution. In discharge channels, the temperature 1" reaches 10,000 degrees Celsius. At such a temperature, pyrolysis of substances in water occurs, oxides and hydroxides of the metal whose granules are loaded into the discharge chamber are formed. These oxides and hydroxides are coagulants that adsorb heavy metal ions, organic compounds, etc. yuyu 395 Under the action of epectric discharges between metal granules in an aqueous solution, cavitation occurs, which leads to the appearance of a large number of cavitation bubbles in the liquid, which, when collapsed, emit electromagnetic energy into the liquid (ав) in the optical range with a spectrum up to the ultraviolet region, which has a detrimental effect on b" biological objects in water. At the same time, powerful ultrasonic shock waves are generated. Powerful shock waves arising during the collapse of bubbles destroy foreign inclusions in the water and have a detrimental effect on bacteria. ko 50 After filtering the solution, an alkaline environment is created in the fraction where there was an acidic environment, and an acidic environment is created in the fraction where there was an alkaline environment. This allows you to change the direction of reactions in each fraction and carry out a deep cleaning of each fraction. Each fraction is again passed through a separate discharge chamber with a layer of metal granules, which are affected by electric pulses.

As an installation for implementing the proposed method, a traditional installation for 59 electroerosion processing of metals can be used (as an example: A.L. Livshits, I.S. Rogachev, M.Sh. Otto. Generators of impulses. M., with "Znergia", 1970, p. 2134, as well as a standard DC power supply unit (as an example: B5b-47) and a semi-permeable ion exchange membrane for creating, by electrolysis of an aqueous solution, fractions with a high concentration of hydrogen ions He" and hydroxyl ions OH-.

The method is carried out as follows. because the aqueous solution to be purified is divided into two fractions. There is a semi-permeable ion exchange membrane between the fractions. Through the aqueous solution, divided into fractions, a constant electric current is passed from the current source. Since there is a semipermeable ion exchange membrane in the path of the electric current in the aqueous solution, this leads to the fact that an acidic environment is formed in the first fraction, where the anode is located, and an alkaline environment is formed in the second fraction, where the cathode is located. As a device for obtaining fractions with an acidic and alkaline environment, a traditional electrolytic cell can be used (as an example: Skorcheletti V.V. fraction has a pH of no more than 5, and the alkaline environment of the fraction has a pH of at least 9. At such pH values, a high concentration of hydrogen ions H.- is created in an acidic environment and

High concentration of hydroxyl OH- ions in an alkaline environment, which significantly increase the ionic strength of the solution. In environments divided into fractions, reactions proceed differently and have different directions. In one fraction, hydrogen ions H-- in an aqueous solution are combined with ions that will be removed, and the charge of which is opposite in sign to the charge of hydrogen ions. In the other fraction, hydroxyl ions OH- in an aqueous solution are combined with ions that will be removed, and the charge of which is opposite in sign to the charge of hydroxyl. An acidic environment with a pH of no more than 5 has a pronounced antimicrobial effect, and in an alkaline fraction with a pH of no less than 9, the processes of removing heavy metals and organic compounds are activated. Each fraction is passed through a separate discharge chamber with a layer of metal granules that are affected by electric pulses.

In discharge chambers made of dielectric material, metal granules (for example, steel) are placed in an even layer on their bottoms, where the electrodes are installed. The electrodes are connected to a 7/5 pulse generator. Fractions of the aqueous solution to be purified enter the discharge chambers. Electrical impulses are applied to the electrodes. At the same time, electric discharges occur between the granules and the electrodes. Due to electric erosion, coagulants are formed in the aqueous solution, which absorb ions of heavy metals, organic compounds, etc.

Under the action of electric discharges in a liquid medium, significant hydrodynamic forces develop and ultrasonic waves occur, which lead to cavitation. During cavitation, a large number of cavitation bubbles appear, which, when collapsed, release energy that destroys foreign inclusions in the water. Cavitation is accompanied by sonoluminescence. During cavitation, an ultrasonic wave in the rarefaction phase causes great tension in the liquid, which leads to a local rupture of the continuous medium and the creation of a bubble in it, filled with water vapor and gases dissolved in water. After half a period, under the action of the compressive effect of ultrasound and the forces of surface tension, this bubble collapses. At this moment, a flash of sonoluminescent radiation bursts out of the bubble. A cloud of plasma that ignites in the center of the collapsing bubble emits light. The bubble collapse speed is 1-1.5 km/sec. Supersonic motion generates powerful shock waves in a liquid. After the shock wave reaches the center, it is reflected and begins to spread outward.

As a result, the shock wave passes through this point of the substance twice, while the temperature increases. The temperature of the plasma during sonoluminescence is tens of thousands of degrees. The spectrum of radiation during sonoluminescence is continuous, growing into the ultraviolet region. At such a high temperature, active pyrolysis of substances in water occurs, oxides and hydroxides of Ge metal are formed in the entire volume of the liquid. Shock waves and ultraviolet radiation lead to the death of bacteria in the liquid. Under the influence of ultrasonic waves, acoustic coagulation occurs, the essence of which is that during the propagation of ultrasonic waves in a liquid, forces arise that bring together particles suspended in water, which contributes to their sticking together and, as a result, helps to purify aqueous solutions.

The aqueous solution that has passed through the discharge chambers is subjected to filtration. Then, in the fraction where there was an acidic environment, an alkaline environment is created, and in the fraction where there was an alkaline environment, an acidic environment is created. This is done by passing a constant electric current through both Fractions separated by a semi-permeable ion exchange membrane. At the same time, the cathode is placed in the first fraction of the aqueous solution, and the anode is placed in the second fraction of the aqueous solution. This polarity of the electrodes allows creating an alkaline environment in the first fraction, where the cathode is located, and an acidic environment in the second fraction, where the anode is located.

This leads to a change in the direction of reactions in each fraction and allows for deep purification of each fraction. Each fraction is again passed through a separate discharge chamber with a layer of metal granules that act on it

GI electric pulses.

Thus, the complex effect on the aqueous solution, based on the increase in the ionic strength of the aqueous solution, the effect on the aqueous solution by cavitation, ultraviolet radiation coming from inside the liquid in its entire volume by

Thanks to sonoluminescence, the use of freshly prepared coagulants, which are formed during electroerosion, 5p allows you to effectively remove impurities and carry out cleaning in running water. name) with"

Claims (2)

The formula of the invention 1. A method of cleaning aqueous solutions by electroerosive coagulation, which includes passing an aqueous solution through a layer of metal granules placed in a discharge chamber, acting on the metal granules with electric pulses until the formation of coagulants and destroying the granules under the action of spark discharges, and obtaining an aqueous solution of the required purity, which differs the fact that the aqueous solution, before passing through a layer of metal granules, is divided into two fractions, an acidic environment is created in the first fraction, and an alkaline environment is created in the second, after which each fraction is passed through a separate discharge chamber with a layer of metal granules, the acidic and alkaline fractions are filtered , create an alkaline environment in the first fraction, an acidic environment in the second, and repeatedly pass each fraction through a separate discharge chamber with a layer of metal granules. 2. The method of purifying aqueous solutions by electroerosion coagulation according to claim 1, which differs in that in the acidic fraction a pH of no more than 5 is created. less than 9. Official bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits", 2007, M 2, 15.02.2007. State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. - so sch (Se) "c) s " no s i" name) ("c) (22) with 50 syu" p. 60 b5