RU2336231C2 - Method of water pyrification - Google Patents

Abstract

FIELD: chemistry, technological processes.

SUBSTANCE: water purification is performed by impact of electric discharge radiation and further action of chemically active particles and radicals, formed during electric discharge in filled with oxygen-containing gas space between sectioned metal electrode and water surface. Electric discharge is realised in filled with oxygen-containing gas space, separated from sections of sectioned metal electrode with thin dielectric layer from material, resistant to action of electric discharge and chemically active particles and radicals, formed during electric discharge. Material has electric strength more than 300 MV/m, relative dielectric permeability 5÷50, specific volume resistance 10¹⁰÷10¹⁷ Ohm·m, specific surface resistance at temperature 20°C and relative humidity 70% more than 10¹⁰ Ohm and heat conductivity coefficient more than 6 W/(m·K).

EFFECT: invention reduces energy consumption for water purification.

1 dwg

Description

The invention relates to electrical technology and can be used in the design of new installations for cleaning and disinfecting water with increased productivity with low energy consumption for water treatment.

A known method of water purification by exposure to radiation of an electric discharge and the subsequent exposure to chemically active particles and radicals generated by an electric discharge directly in a mixture of water with an oxygen-containing gas (RF patent 2233244, MKI C02 F1 / 46. Reactor for processing liquids. B. G. Shubin ., M.B.Shubin // Asked. 04/22/03., Publ. 07/27/04. BIMP No. 35).

The disadvantage of this method of water treatment is the high energy consumption for water treatment, due to the negative shunt effect of electric water jumpers periodically formed in the discharge gap, which leads to significant additional energy losses.

A known method of water purification by exposure to radiation of an electric discharge and subsequent exposure to chemically active parts and radicals generated during an electric discharge in the gap filled with an oxygen-containing gas between the sectioned metal electrode and the surface of the water (Effect of a torch discharge on water. V.M. Lelevkin, A.V. . Tokarev et al. Abstract of the conference dedicated to water: Ecology and technology (EKVATEK-98). M., May 26-30, 1998, SIBIKO I. Publishing House, 1998. - S.660) .

The disadvantage of this method of water treatment is the high energy consumption for water treatment, which is due to the low radiation intensity and low yield of chemically active substances and radicals generated by the electric discharge of the form used, as well as the low efficiency of the main factors of the electric discharge on the treated water (the effect is actually only surface layer of treated water).

A known method of water purification by exposure to radiation of an electric discharge and the subsequent exposure to chemically active particles and radicals generated during an electric discharge in the gap filled with an oxygen-containing gas between the sectioned metal electrode and the surface of the water (Ppskarev I.M., Aristova N.A. Generation of ozone-hydroxyl mixture and its application // Thesis report of the conference on ozone and other environmentally friendly oxidizing agents M., June 7–9, 2005, Publishing House “Book House University”, 2005. - P.184).

The specified method of water purification is the closest in technical essence to the invention and is considered as a prototype.

The disadvantage of this method of water treatment is the high energy consumption for water treatment, which is due to the low radiation intensity and low yield of chemically active substances and radicals generated by the electric discharge of the form used, as well as the low efficiency of the main factors of the electric discharge on the treated water (the effect is actually only surface layer of treated water), the instability and unevenness of the electric discharge.

The invention is aimed at solving the problem of reducing energy costs for water treatment, which is the purpose of the invention.

This goal is achieved by the fact that in the method of water purification by exposure to radiation of an electric discharge and subsequent exposure to chemically active particles and radicals generated by an electric discharge in the gap filled with an oxygen-containing gas between the sectioned metal electrode and the surface of the water, an electric discharge is created in the gap filled with an oxygen-containing gas, separated from sections of a sectioned metal electrode by a dielectric layer of a material resistant to staying true electric discharge and chemically active species and radicals produced under electrical discharge having a dielectric strength of more than 300 MV / m, a relative permittivity of 5 ÷ 50, volume resistivity October ¹⁰ ÷ October ¹⁷ ohm-m, the surface resistivity at a temperature of 20 ° With a relative humidity of 70% and more than 10 ¹⁰ Ohms and a thermal conductivity of more than 6 W / (m · K).

A significant difference that characterizes the invention is the reduction of energy consumption for water treatment, which is achieved by increasing the intensity of radiation of the electric discharge, intensifying the synthesis processes and increasing the yield of chemically active substances and radicals generated by the electric discharge, more efficient and full use of all active factors of the electric discharge during processing water, changing the shape of the electric discharge, increasing its stability and uniformity.

Reducing energy costs for water treatment is the technical result obtained, due to new actions, the order of their implementation in the inventive method of water purification, that is, the hallmarks of the invention. Thus, the distinguishing features of the proposed method for water purification are essential.

The drawing shows a functional diagram of a reactor with structural elements for implementing the inventive method of water purification, explaining the new principle of electric discharge in the gap filled with oxygen-containing gas between the partitioned metal electrode and the surface of the treated water. The reactor contains a tank 1, partially filled with the treated water, with nozzles 2 for supplying the source and discharging the treated water, with a dispersant 3 located in the lower part for introducing oxygen-containing gas into the treated water, a sectioned metal electrode 4 mounted above the treated water with a gap 5 filled an oxygen-containing gas separated from the sections of the sectioned metal electrode by a dielectric layer 6, a power source 7, the terminals of which are connected to the sectioned metal Ceska electrode terminal 8 and, placed in the treated water.

The method of water purification is implemented by the following steps. Oxygen-containing gas is subjected to preliminary treatment, preparation for composition and cooling. The prepared gas is introduced into the water through the dispersant 3 in the lower part of the tank 1. The gas is introduced by supplying it through the porous element of the dispersant 3 with porosity and pore sizes (30 ÷ 100 μm), which ensure uniform mixing of the oxygen-containing gas and the treated water at a given pressure of the oxygen-containing gas with given sizes of gas bubbles. An electric discharge develops in the gap 5 filled with an oxygen-containing gas between the sectioned metal electrode 4 and the water surface, separated from the sections of the sectioned metal electrode 4 by a dielectric layer 6 of a material resistant to electric discharge and chemically active particles and radicals generated by an electric discharge having an electric strength more than 300 MV / m, relative dielectric constant 5 ÷ 50, specific volume resistivity 10 ¹⁰ ÷ 10 ¹⁷ Ohm · m, specific e surface resistance at a temperature of 20 ° C and a relative humidity of 70% more than 10 ¹⁰ Ohms and a thermal conductivity coefficient of more than 6 W / (m · K)

Water purification is carried out by combining the main factors of the electric discharge (ultraviolet radiation, chemically active substances and radicals, including ozone produced in the electric discharge, electric field, pressure, temperature, ultrasound, cavitation). An important role is played by the processes of oxygen photodissociation and ozone photosynthesis by ultraviolet radiation of an electric discharge. An electric discharge has the form of a barrier discharge.

The reactor for implementing the method of water purification works as follows. Under the action of the external voltage of the power supply 7 applied between the sectioned metal electrode 4 and the surface of the treated water, which performs (together with pin 8) the role of the second electrode, in the gas layer of the gap 5 between the sectioned metal electrode 4, the sections of which are separated from the discharge gap 5 by the dielectric layer 6, and an electric barrier discharge is excited by the surface of the water. The discharge has the structure of individual microdischarges, relatively evenly distributed over the surface of the dielectric layer 6, both in the discharge gap (mainly) and gas bubbles in the layer of treated water. In microdischarges, oxygen molecules dissociate. Oxygen atoms formed as a result of dissociation interact with oxygen molecules, as a result of which ozone molecules are formed. At the same time, atomic oxygen itself is chemically active, and part of it participates in oxidative reactions on its own, since there are conditions for the prompt action of an oxygen-containing gas on the treated water and the implementation of oxidative reactions in it. Another chemically active radical that forms in an electric discharge in the presence of water vapor is a hydroxyl radical. The hydroxyl radical is one of the most powerful oxidizing agents known. Since an electric discharge is excited directly in the gap above the surface of the water, as well as in oxygen-containing gas bubbles in the layer of the treated water, and intense mass transfer processes take place, it is possible to quickly transfer all chemically active substances and radicals capable of participating in reactions with impurities to the treated water . The development of an electric discharge in gas bubbles in a water layer significantly increases the efficiency of the synthesis of chemically active substances and radicals, including ozone, capable of participating in reactions with impurities in the treated water, as well as the efficiency of their mixing with water, exposure to impurities and oxidative chemical reactions . An electric barrier discharge in a gas is a source of intense ultraviolet radiation, including in the vacuum region. The implementation of the electric discharge in oxygen-containing gas bubbles directly in the water layer allows the efficient use of ultraviolet radiation to intensify both the electric discharge and the synthesis of chemically active substances and radicals, including ozone, as well as carrying out oxidative reactions in the treated water. The electric discharge of the claimed form is characterized by high stability and relative uniformity. Preliminary treatment and cooling of oxygen-containing gas increase the uniformity and stability of the electric discharge in the discharge gap and in oxygen-containing gas bubbles in the layer of treated water.

Oxygen-containing gas enters the discharge gap through the pores in the structure of the porous element of the dispersant 3. Oxygen-containing gas is supplied into the porous element under excess pressure. By changing the excess pressure of the oxygen-containing gas, stabilization and regulation of the water treatment process and the parameters of the barrier electric discharge are possible. Input to the reactor and withdrawal of the treated water from the reactor is carried out through nozzles 2 in the tank 1.

As the material of the dielectric layer 6, titanium dioxide (rutile), alumina (sapphire) and some ceramics based on alumina (polycor), crystalline quartz (silica), composite oxide ceramics (celsian, anorthite), nitride ceramics can be used ( boron nitride, aluminum nitride). The dielectric strength of more than 300 MV / m corresponds to the dielectric strength of a pure material (film property 0.0001 ÷ 0.3 mm).

The sections of the sectioned metal electrode 4 in the installation were made of titanium rods with a diameter of 8 mm, coated with rutile with a thickness of 2 mm. The discharge gap 5 is selected equal to 7 mm for the operating voltage at the partitioned metal electrode 4 of not more than 40 kV. In this case, the energy consumption for the synthesis of 1 kg of ozone from a mixture of technical oxygen (90 vol.%) And argon (10 vol.%) In the new installation was about 15 kW · h. In the absence of a dielectric layer, the specific energy consumption for electrosynthesis (under the same conditions) increased to 35 kWh / kg.

Compared with the prototype, there is a significant reduction in energy costs for water treatment, which is achieved by reducing additional unproductive energy losses, intensifying radiation and the synthesis of chemically active substances and radicals, making fuller use of all active factors of the electric barrier discharge (ultraviolet radiation, chemically active substances and radicals including ozone generated in an electric discharge, electric field, pressure, temperature, ultrasound, cavitation) at water flow, stability and uniformity of a new form of barrier electric discharge in the gap filled with an oxygen-containing gas, separated from the sections of the sectioned metal electrode by a thin dielectric layer, resistant to the effects of electric discharge and chemically active particles and radicals formed during electric discharge, between the sectioned metal electrode and the surface water, as well as in gas bubbles in a layer of water. The parameters of a dielectric layer having an electric strength of more than 300 MV / m, a relative permittivity of 5 ÷ 50, a specific volumetric resistance of 10 ¹⁰ ÷ 10 ¹⁷ Ohm · m, a specific surface resistance at a temperature of 20 ° C and a relative humidity of 70% of more than 10 ¹⁰ Ohm and the thermal conductivity coefficient of more than 6 W / (m · K), provides an energy-optimal mode of electric barrier discharge, characterized by low energy consumption for water treatment.

Energy costs for water treatment (compared with the prototype) can be reduced by 2.5 ÷ 3.0 times.

Claims (1)

The method of water purification by exposure to radiation of an electric discharge and the subsequent exposure to chemically active particles and radicals generated during an electric discharge in the gap filled with an oxygen-containing gas between the sectioned metal electrode and the surface of the water, characterized in that the electric discharge is created in the gap filled with an oxygen-containing gas separated from the sections sectioned metal electrode with a dielectric layer of a material resistant to electrical st discharge and chemically active species and radicals produced under electrical discharge having a dielectric strength of more than 300 MV / m, a relative permittivity of 5 ÷ 50, volume resistivity October ¹⁰ ÷ October ¹⁷ ohm-m, the surface resistivity at 20 ° C and relative humidity of 70% more than 10 ¹⁰ Ohms and the coefficient of thermal conductivity of more than 6 W / (m · K).