RU2321548C2 - Method of purification of sewage water - Google Patents

Abstract

FIELD: electrochemical purification of sewage water.

SUBSTANCE: sewage water is passed between electrodes of electrolyzer to which air oxygen is additionally fed; difference of potentials exceeding overvoltage of hydrogen and oxygen evolution is formed on electrodes; this difference shall be sufficient for beginning of emission of electrons from cathode (more than 4 V). Auxiliary electrode is additionally mounted in between cathode and anode; its surface does not exceed surface of cathode; air oxygen is fed in the double amount as compared with hydrogen evolving on cathode. Sulfates and/or chlorides are additionally introduced into sewage water, mainly in equimolar ratio at concentration not exceeding concentration of contaminants in sewage water.

EFFECT: enhanced efficiency of removal of organic substances.

2 cl, 7 ex

Description

The present invention relates to the field of electrochemistry, in particular to methods for electrochemical wastewater treatment. The preferred area of use of the method: wastewater treatment, containing dissolved organic substances, at the enterprises of the food, chemical and oil industries.

For the treatment of wastewater from soluble and dispersed impurities, various electrochemical methods are used - anodic oxidation and cathodic reduction, electrocoagulation, electrofloculation and electrodialysis.

A known method of water purification / Patent of the Russian Federation No. 2057080, C02F 1/46, 1996 /, comprising passing water with pre-introduced oxygen in the air through a charge of a mixture of iron chips and carbon-containing material, activated carbon granules are used as the carbon-containing material, and air is introduced dispersing through purified water and loading, while simultaneously applying an electric current to it supplied from an external current source to an additional anode and cathode.

The disadvantage of this method is the low efficiency of the removal of organic substances, secondary water pollution with iron ions.

A known method of wastewater treatment / Application WO No. 03008340, C02F 1/46; C02F 1/72; C02F 1/66; C02F 1/58; C02F 101/38, 2005 /, including the measurement and, if necessary, regulation of the pH and electrical conductivity of the solution, maintaining (maintaining) the optimum pH and / or electrical conductivity during the process, and then involving partial or complete decomposition of organic materials. An electric arc is passed between the electrodes, producing and maintaining an electric current of at least 0.5 A / cm ² (current density) and at a voltage of at least 70 V and a symmetrical alternating current, preferably having a frequency of at least 10 Hz; with the decomposition of organic compounds in water, carbon dioxide, and nitrogen.

The disadvantages of this method are the high energy consumption due to the need to maintain the arc in an aqueous medium, the destruction of the electrode material by high arc temperatures and the secondary pollution of the water with the material of the electrodes during electric arc corrosion.

A known method of treating industrial wastewater / RF Patent No. 2130433, C02F 9/00, C02F 1/46, 1999 /, comprising supplying gases to wastewater, treating them in a galvanic couple field, followed by separation of the solid phase. Carbon dioxide and air are introduced into the wastewater under pressure, and after treatment in the galvanic couple field, the wastewater is passed through an ultrasonic field and then through a magnetic field, the separation of the solid phase is carried out first in a thin-layer sump, and then on a sand filter.

The disadvantage of this method is the low efficiency of the removal of organic substances from wastewater.

A known method of wastewater treatment / Auth. St. No. 1611886, C02F 1/463, 1990 /, including the passage of water through a porous layer of iron particles in the presence of coke, simultaneously with coke oxygen is supplied to the water to be purified in an amount of 0.3-0.6% of the volume of water being purified and the cleaning process lead at an overpressure of 0.05-0.15 Pa.

The disadvantage of this method is the low efficiency of removing organic matter from wastewater, secondary pollution of purified water with iron ions.

A known method of water purification / Patent of the Russian Federation No. 2049733, C02F 1/46, 1995 /, including water purification by passing it between the electrodes of the electrolysis cell, followed by separation of the coagulated sediment, a suspension obtained by electroerosive dispersion of ferrous metals is introduced into the purified water before being fed into the electrolysis cell. in water.

The closest analogue is a method of wastewater treatment by electrolysis / RF Application No. 95102444, C02F 1/46, 1996 /. According to this method, an oxidizing agent is fed into the interelectrode space. In this case, chain reactions of oxidation of organic substances by atmospheric oxygen are initiated. After electric treatment, the wastewater enters the sorbent with catalytic centers, the voltage is increased by at least 4 V, an oxidizing agent, for example, oxygen, is added to the interelectrode space, and the surfaces of the electrodes are modified with transition metal compounds.

The disadvantage of this method is the low efficiency of removing organic matter from wastewater, secondary pollution of purified water with iron ions.

The objective of the invention is to provide a method for wastewater treatment, increasing the efficiency of the method by removing organic matter from wastewater and reducing secondary pollution of treated water with iron ions

This object is achieved in that in a method of wastewater treatment, including passing purified water between the electrodes of the electrolyzer, to which additional oxygen is supplied, and at the electrodes create a potential difference in excess of the overvoltage of hydrogen and oxygen evolution on the electrodes, and sufficient to start the emission of electrons from the cathode (more than 4 V), between the cathode and the anode an auxiliary electrode is additionally installed with a surface not larger than the surface of the cathode, and air oxygen is supplied in an amount, in two or more times the amount of hydrogen released at the cathode.

Sulfates and / or chlorides are additionally added to the wastewater, mainly in an equimolar ratio, in a concentration not exceeding the concentration of pollutants in the wastewater.

The method is as follows:

An oxidizing agent, in particular oxygen, is fed into the interelectrode space. The electrode potential is increased to the threshold of electron tunneling through a double electric layer. At the same time, a potential difference of 500-10000 V is created on the electrodes, exceeding the overvoltage of hydrogen and oxygen evolution on the electrodes, initiating chain reactions of oxidation of organic substances by atmospheric oxygen. It is possible to supply both air and oxygen, the calculation is carried out according to oxygen, which in the air, as you know, is 20% by volume. Accordingly, 1 volume of hydrogen requires 5 volumes of air or more. The oxidation of one g-equivalent of organic matter requires 2-10 times less amount of electricity passed through a solution (10000-50000 coulomb) than with anodic oxidation. Additionally, an auxiliary electrode is placed (from a titanium mesh). Titanium is coated with an oxide film and therefore the pulse duration does not matter, the arc does not ignite. To ensure this process, special additives are needed. As special additives, it is preferable to use sodium chloride, sodium sulfate as catalysts. After electrolysis, waste water contains hypochlorites and persulfates. This water is supplied to a sorbent material containing metals with variable valency, for example, manganese ions. Peroxide compounds, hypochlorites and traces of organic substances react with each other on the surface of the sorbent, forming water and carbon dioxide. The pollutant equivalent is determined by the formula E = C / M, where C is the concentration of the pollutant, M is the g-equivalent of the pollutant. In particular, for COD it is M = 30 g / g-eq. The precipitate is removed from the reaction zone, while the energy consumption for oxidation is reduced. During the oxidation of one molecule of organic matter, one or more molecules of organic acids are formed.

Example 1

In the electrolyzer, with a system of electrodes, an adsorber equipped with electrodes for the directed movement of ions to the surface of the catalyst, wastewater containing 1200 mg / l of organic substances is fed. Air flow rate 1.3 l / s. A voltage of 24 V is applied to the zinc-coated titanium electrodes at the cathode. When processing for 1 hour, 1 cubic meter of industrial wastewater at a current of 50 A, followed by purification on a column with a sorbent-catalyst (0.8 m long and cross section 0, 2 sq. M. Granule size 5-8 mm) based on silica gel with catalytic centers included in the structure containing 237 mg / g of manganese compounds, water is purified to a COD of 212 mg / l. The cost of the amount of electricity is 180,000 to 1 kg COD or 180 pendant per g COD of organic substances.

Example 2

In the electrolyzer of example 1, an auxiliary electrode 1 dm ^{2 in area is} made of a titanium mesh with a 1 mm cell between the graphite anode and the metal cathode and an additional voltage is applied to it in the form of a positive potential relative to the cathode 80 V, current density 0.5 A / dm ² and 1 μs pulse. Processing time and other parameters are the same as in example 1 and is 1 μs.

Before cleaning After cleaning COD 218 8 Weighted 620 6 Oil products 47 0.05 Fe 2 0.12

After treatment, the water is clear, transparent. The precipitate is dense, flocculated.

After electrolysis, water is fed to a ODM-2F sorbent layer 40 mm thick in a column with a diameter of 10 mm (containing iron and vanadium ions). Purified water contains less than 2 mg per liter of COD.

Example 3

The electrolyzer containing a chamber for electrolysis under pressure with a capacity of 1.25 dm, a chamber for electrolysis under atmospheric pressure, a capacity of 1.25 dm interconnected by 6 holes 1 mm in diameter, a graphite anode in the pressure chamber and a metal cathode of lead in the pressure chamber, circulating pump, fill with wastewater, turn on the pump, which creates a pressure in the pressure chamber of 2.0 atmospheres, delivers air 25 l / h and voltage as in example 1, after processing water is left to stand for 1 hour.

Before cleaning After cleaning COD 218 3 Weighted 620 3 Oil products 47 0.01

After treatment, the water is clear, transparent. The precipitate is dense, flocculated.

After electrolysis, water is fed to a ODM-2F sorbent layer 40 mm thick in a column with a diameter of 10 mm (containing iron and vanadium ions). Purified water contains less than 2 mg per liter of COD.

Example 4

An electrolyzer containing a chamber for electrolysis under pressure with a capacity of 1.25 dm ³ , a chamber for electrolysis under pressure, with a capacity of 1.25 dm ³ interconnected by 6 holes 1 mm in diameter, a graphite anode in a pressureless chamber and a metal cathode of lead in the pressure chamber , the circulating pump, filled with waste water, turn on the pump, which creates a pressure in the pressure chamber 2.0 atmosphere, serves air 25 l / h and voltage as in example 1, after treatment, the water is left to stand for 1 hour.

Before cleaning After cleaning COD 218 3 Weighted 620 3 Oil products 47 0.01 Fe 2 0,03

Example 5

An electrolyzer containing a chamber for electrolysis under pressure with a capacity of 1.25 dm ³ , a chamber for electrolysis under atmospheric pressure with a capacity of 1.25 dm ³ interconnected by 6 holes 1 mm in diameter, a graphite anode in a pressureless chamber and a metal cathode of lead in the pressure chamber, the circulating pump, filled with waste water, turn on the pump, which creates a pressure in the pressure chamber of 2.0 atmospheres, delivers air 25 l / h and voltage as in example 1, after treatment, the water is left to stand for 0.5 hours.

Before cleaning After electrolysis purification COD 218 39 Weighted 620 31 Oil products 47 0.5 Fe 2 0.2

After electrolysis, a surfactant (potassium soap) is added to water at a concentration of 2 mg / l, irradiated with visible light (200 W incandescent lamp from a distance of 50 mm), for 1.5 hours. At the same time, air is supplied. After sedimentation of the sample for 10 minutes, the COD content decreased to 0.5 mg / L.

Example 6

A model solution containing 1000 mg / l ethylene glycol is fed into an electrolyzer with an electrode system. 1200 mg per liter of calcium hydroxide is added to the solution. Air flow rate 1.2 l / s. A voltage of 42 V is applied to lead-coated iron electrodes at a cathode during processing for 1 hour at a current density of 50 A ² / g. The concentration of organic substances by COD after electrolysis and sedimentation, centrifugation and filtration through a sand filter does not exceed 4 mg per liter. The cost of electricity is 82,000 K per kg of ethylene glycol or 82 pounds per g.

Example 7

In the electrolyzer, with a system of electrodes, wastewater containing 418 mg / l of organic substances is supplied. Air flow rate 1.35 l / s. A voltage of 42 V is applied to the zinc-coated titanium electrodes at the cathode. When processing for 1 hour, 1 cubic meter of industrial wastewater at a current of 50 A, followed by treatment on a column with anion exchange resin AB-17-8 (length 0.8 m and with a cross section of 0.2 square meters, the granule size is 2 mm) with a SOE of 3.9 mEq / g in the OH form, water is purified to a COD value of 30 mg / L.

The proposed method can significantly improve the cleaning efficiency by post-treatment of organic impurities, reduce energy consumption and intensify the process.

Claims (2)

1. A method of wastewater treatment, including passing purified water between the electrodes of the electrolyzer, which is additionally supplied with atmospheric oxygen, and on the electrodes create a potential difference exceeding the overvoltage of hydrogen and oxygen evolution on the electrodes and sufficient to start the emission of electrons from the cathode (more than 4 V) , characterized in that between the cathode and the anode an auxiliary electrode is additionally installed with a surface not larger than the surface of the cathode, and air oxygen is supplied in an amount two or more times higher reducing the amount of hydrogen released at the cathode. 2. The method according to claim 1, characterized in that sulfates and / or chlorides are additionally introduced into the wastewater, preferably in an equimolar ratio, in a concentration not exceeding the concentration of pollutants in the wastewater.