RU2519412C1 - Method of purifying sewage waters from ions of heavy metals - Google Patents

Abstract

FIELD: chemistry.

SUBSTANCE: electric processing of sewage waters from ions of heavy metals is carried out by direct current with current density 6-9 A/m² and voltage 12 V for 10-15 min; formed sludge, containing ions of heavy metals is lifted to water surface by means of hydrogen bubbles, released on aluminium cathodes, and is removed from water surface.

EFFECT: reduction of costs for aluminium and electric energy consumption, increased efficiency and rate of sewage water purification from ions of heavy metals.

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Description

The invention relates to the field of wastewater treatment from heavy metal ions, for example nickel, copper, zinc and iron, and can find application in machine-building, metallurgy and other industries, in addition, the claimed invention relates to such a priority area of development of science and technology, as "Treatment of industrial or domestic wastewater characterized by the nature of pollution."

Wastewater containing toxic heavy metal ions, on the one hand, has a harmful effect on the environment, and on the other hand, contain a significant amount of valuable components.

A known method of wastewater treatment in galvanic production from heavy metal ions of nickel, iron, copper and zinc (SU No. 1643464, IPC C02F 1/24, published 04/23/1991), including wastewater treatment by combining electrochemical and flotation methods. To increase the degree of extraction and the speed of water purification from toxic metal ions, the purification is carried out sequentially in coagulators and a pneumatic columned floatation apparatus with a pulsating aerator.

Common signs of the proposed method with an analogue are wastewater treatment of electroplating electrocoagulation and removal of sludge during flotation from the surface of the water.

The disadvantages of this method are the additional costs associated with the fact that the wastewater treatment process is a two-stage process, including electrocoagulation carried out in a coagulator, and flotation carried out in a pneumatic columned flotation apparatus with a pulsating aerator.

A known method of electrocoagulation wastewater treatment (RU No. 2159531, IPC C02F 1/463, published 04/27/1999), including polarization of soluble and insoluble electrodes using alternating polarity current and separate regulation of the amplitudes of the anode and cathode current.

Common features of the proposed method with an analogue is wastewater treatment by electrocoagulation with a soluble electrode.

The disadvantages of this method are the high costs associated with the fact that the wastewater treatment takes place in the range of higher current densities from 50 to 200 A / m ² and, as a result, a higher energy consumption.

As a prototype adopted the method of wastewater treatment from heavy metals (RU No. 2023670, IPC C02F 1/46, published 11/30/1994).

According to the known method, wastewater of light industry containing salts of heavy metals, in particular chromium, is treated to a pH of 6.0-8.0, filtered, and then subjected to electrical treatment with alternating current at a current density of 10-30 A / m ² and a voltage of 6, 0-10.0 V using a soluble aluminum anode, the resulting precipitate was separated by filtration.

Common signs of the proposed method with the prototype is the preliminary treatment of water before electrocoagulation, resulting in a decrease in the content of insoluble conglomerates of heavy metals, such as trivalent chromium hydroxide, which reduces the consumption of coagulant and, consequently, the energy consumption.

The disadvantages of this method are the additional cost of filtering wastewater before and after electrocoagulation, also the relatively high cost of electrocoagulation associated with a higher current density of 10-30 A / m ² , as well as the use of a less secure electrocoagulation device operating on alternating current . In the case of passivation of the aluminum electrode, which is not excluded when working with aluminum, the use of an alternating current with a frequency of 50 Hz during electrolysis will lead to the formation of explosive gas at the anode and cathode. This is because each of the electrodes is a cathode 50 times a second and anode 50 times, in the first case two volumes of hydrogen are released on it, and in the second one volume of oxygen. Therefore, in order to avoid explosion, it is better not to use alternating current during the electrolysis of aqueous solutions. The use of alternating current of a higher frequency than 50 Hz leads to a complete cessation of electrolysis.

The task to which the invention is directed is to reduce the harmful effects of wastewater from galvanic shops on the environment through the completeness of the extraction of ions of nickel, copper, zinc and iron from effluents, to the MPC and below.

The technical result of the claimed invention is to reduce the cost of consuming aluminum and electricity, as well as to increase the efficiency and speed of wastewater treatment from heavy metal ions.

The technical result is achieved by the fact that in the method of wastewater treatment from heavy metal ions, including their treatment with an alkali solution to pH = 7.6 and electric treatment using soluble aluminum anodes, according to the invention, the electric treatment of wastewater from heavy metal ions is carried out by direct current at current density 6-9 A / m ² and a voltage of 12 V for 10-15 minutes, and the resulting slurry containing heavy metal ions is raised to the surface of the water with hydrogen bubbles released on the aluminum cathodes and removed from the surface water.

The difference between the proposed technical solution and the prototype is the removal of sludge generated during electrocoagulation from the surface of the water by mechanical means without the use of flotation reagents, the elimination of the stages of pre-filtration of water before electrocoagulation, the introduction of the sedimentation stage and the elimination of re-filtration after electrocoagulation, the use of electrocoagulation equipment operating on direct current.

The physico-chemical essence of the proposed method is based on the fact that before electrocoagulation, the wastewater is treated with alkali to a pH of 7.6, while the content of iron ions is reduced by 40%, as a result, wastewater with a low iron content (1-2 mg / k) and after electrochemical treatment of water, small particles of coagulated aluminum hydroxide are formed, which adsorb heavy metal ions on their surface, and hydrogen bubbles released on aluminum cathodes pick up these small particles and the surface of the water without the use of special flotation reagents.

If electrocoagulation is subjected to wastewater with an iron content higher than 5 mg / l, then after exposure to direct current, sufficiently large particles of iron hydroxide are also formed, which, under the action of gravity, settle to the bottom of the electrocoagulator. By minimizing the iron content in water before electrocoagulation, it is possible to obtain smaller particles of aluminum hydroxide, which can be raised by hydrogen bubbles released at the cathodes to the water surface without the use of special flotation reagents. The formed aluminum hydroxide particles are removed from the surface of the water using a scraper conveyor.

The effect of increasing the efficiency and speed of wastewater treatment from heavy metal ions and reducing the cost of electricity for electrocoagulation occurs:

- by eliminating the clogging of electrode systems with iron hydroxide and the occurrence of short circuits;

- by collecting the resulting sludge from the surface of the water;

- due to the introduction of electrocoagulation at optimal pH and current density parameters, at which the maximum extraction of heavy metal ions from the effluent occurs.

Comparative analysis of the proposed method with the prototype shows that the claimed method differs from the known exception of two stages of filtration before and after electrocoagulation, the introduction of the sedimentation stage and the stage of collecting electrocoagulation sludge from the water surface, as well as the introduction of the process at constant current and optimal conditions for electrocoagulation extraction of heavy ions metals at pH = 7.6 and a current density of 6-9 A / m ² .

To prove compliance of the claimed invention with the criterion of "inventive step", a comparison was made with other technical solutions known from sources included in the prior art. Widely known methods of wastewater treatment, in which the resulting sludge is removed from the surface of the water, such as electroflotation. During wastewater treatment by electroflotation, oxygen bubbles appear on the anode, and hydrogen appears on the cathode. Rising in wastewater, these bubbles float suspended particles. In this case, hydrogen bubbles released at the cathode also play the main role in electroflotation. The size and intensity of the formation of hydrogen bubbles depend on the contact angle, on the material of the electrodes, their shape, current density, etc. The optimal value of the current density for electroflotation is 200-260 A / m ² , as a rule, special flotation agents are additionally used for flotation, for example , weak surfactants are used as foaming agents, as xanthogenates, dithiophosphates, etc. are used as reagents that betray particles of hydrophobic properties. In addition, electroflotation does not always provide the required degree of wastewater treatment, which necessitates the intensification of the process by the additional use of coagulants or by saturation of the treated liquid with gases in pressure electrolytic saturators. In the inventive method for the production of hydrogen bubbles of the required size using cathodes made of sheet aluminum, the optimal value of the current density during electrocoagulation is 6-9 A / m ² . Hydrogen bubbles formed at the cathode raise particles of about 120-140 nm in size coagulated aluminum hydroxide with sorbed heavy metal ions to the water surface. Surfaced sludge is removed from the surface of the water, as with electroflotation, eliminating the additional costs of flotation equipment and reagents.

Examples of the use of the proposed method

Example 1. For experimental verification of the proposed method used model wastewater containing individual ions of Nickel, copper, zinc and iron. Electrocoagulation treatment of water was carried out in a neutral medium at a pH of 7.6 for 10 minutes at a voltage of 12 V and a current density of 6-9 A / m ² . Aluminum hydroxide, formed as a result of electrocoagulation, coagulates, collecting heavy metal ions on its surface. Table 1 presents the cleaning results and the sizes of the particles formed in this process.

During electrocoagulation of wastewater containing individual ions of nickel, copper and zinc, nanosized particles are formed, which hydrogen bubbles released at the cathode raise to the surface of the water, and in the case of wastewater containing iron ions, larger particles are formed, which under the action of force severity settles to the bottom of the electrocoagulator.

Example 2. Wastewater containing ions of Nickel, copper, zinc and iron, was sent to electrocoagulation treatment, which was carried out at pH = 7.0-7.6 for 15 minutes at a voltage of 12 V, current density 6-9 A / m ² .

As can be seen from the above data, during electrocoagulation of wastewater, particles are formed that, under the action of gravity, settle to the bottom of the electrocoagulator.

Example 3. Wastewater containing ions of Nickel, copper, zinc and iron, was directed to electrocoagulation treatment, which was carried out at pH = 7.0-7.6 for 15 minutes at a voltage of 12 V, current density 6-9 A / m . ²

As can be seen from the above data, during electrocoagulation of wastewater containing less than 5 mg / l of iron ions, nanosized particles are formed, which hydrogen bubbles released on aluminum cathodes rise to the surface of the water.

Example 4. Rinsing wastewater of galvanic production containing nickel 2.23 mg / l, copper 7.52 mg / l, zinc 13.75 mg / l, iron 1.57 mg / l, having a pH = 2.13, mixed with alkali to obtain a pH of 7.6. After 1-2 minutes of mixing, the water enters electrocoagulation. The time of electrocoagulation treatment of water is 10-15 minutes, voltage 12 V, current density 9 A / m ² . The results of the main stages of cleaning are given in table 4.

The resulting slurry is removed from the surface of the water using a scraper conveyor and sent to a dewatering apparatus. Table 5 presents the main indicators of purification.

Table 5 Key performance indicators Name of toxic pollution The efficiency of wastewater treatment,% Specific energy consumption, kWh / m ³ Current output,% Ni ²⁺ 96.5 0.21-0.46 98-99 Cu ²⁺ 99.9 Zn ²⁺ 99.8 Fe ³⁺ 99.9

Using the claimed invention allows to reduce the cost of electricity, as well as the consumption of aluminum and to increase the efficiency and speed of wastewater treatment from heavy metal ions.

Claims (1)

A method of treating wastewater from heavy metal ions, including their treatment with an alkali solution to pH = 7.6 and electric treatment using soluble aluminum anodes, characterized in that the electric treatment of wastewater from heavy metal ions is carried out by direct current at a current density of 6-9 A / m ² and a voltage of 12 V for 10-15 minutes, and the resulting slurry containing heavy metal ions is raised to the surface of the water with hydrogen bubbles released on the aluminum cathodes and removed from the surface of the water.