RU2808311C1 - Method for waste water purification - Google Patents

Abstract

FIELD: water purification.

SUBSTANCE: invention relates to the purification of natural and wastewater, including galvanic production, from inorganic impurities. The method of wastewater treatment includes simultaneous adsorption and electrochemical treatment, affecting the adsorbent (quartz sand) and the water passed through it with a uniform electric field, the lines of force of which are directed parallel to the direction of water movement, and further settling. A uniform electric field is created using an alternating current source by applying voltage to the graphite anode and cathode, between which the adsorbent is located. The uniform electric field strength ranges from 40 V/m to 100 V/m.

EFFECT: simplification of equipment with high efficiency of water purification.

1 cl, 1 dwg, 3 ex

Description

The method relates to the purification of natural and waste waters, including galvanic production, from inorganic impurities.

There is a known method for purifying groundwater from heavy metals and petroleum products (patent RU2712692). The method consists in filtering groundwater in a crossed electric field consisting of transverse and longitudinal electric fields created by electrochemical current sources located sequentially along the length of the geochemical barrier, and the direction of the electric field strength vector in adjacent electrochemical current sources is reversed, filtered in In mineral granular material, water is collected by perforated collectors located with a slope similar to the slope of water in the river, water is supplied to wells evenly spaced along the length of the geochemical barrier, in which the separation of oil products, water and sediment is carried out. The geochemical barrier is filled with mineral calcite, in which electrochemical current sources are placed, generating a coagulant. The sediment extracted from the purified water is composted, and the purified water is reused.

The optimal value of the transverse electric field strength E _trans = 1 V/m, the longitudinal electric field strength E _prod = (0.10-0.16) V/m at a distance between adjacent current sources of 6-10 m. Water is treated in a crossed electric field , consisting of transverse and longitudinal electric fields created by electrochemical current sources located sequentially along the length of the geochemical barrier. Moreover, the direction of the electrochemical field strength vector in neighboring electrochemical current sources is changed to the opposite.

A galvanic cell consisting of electropositive graphite and electronegative aluminum in the form of cylindrical rods is used as a current source.

The disadvantages of the above method are the high consumption of materials due to the dissolution of the aluminum electronegative electrode and the bulkiness of the device. In addition, a non-uniform electric field strength is created between the cylindrical rods, which leads to a deterioration in the polarization of the sorbent (calcite fraction) and a decrease in the degree of water purification.

There is a known method of water purification (patent RU2219135), which includes electrochemical treatment of water in an apparatus by exposing the water flow to a pulsating electric current in the direction perpendicular to the direction of movement of the water flow, then the water flow is divided according to its pH value and sent for sedimentation (settling), after which the flows are combined in the container of the sedimentation module, where they are neutralized and sent for sorption or ion exchange purification. This method is adopted as a prototype.

The disadvantages of this method are: the multi-stage cleaning process, which leads to bulkiness and complexity of the equipment, as well as high metal consumption, which makes the process more expensive.

The objective of the invention is to optimize the cleaning process and reduce its cost while maintaining high efficiency.

This task is achieved by the fact that in the known method of wastewater treatment, including simultaneous adsorption and electrochemical treatment, influencing the adsorbent - quartz sand and the water passed through it with a uniform electric field, the lines of force of which are directed parallel to the direction of water movement, and further settling, according to the invention , a uniform electric field is created using an alternating current source by applying voltage to the graphite anode and cathode, between which the adsorbent is located, and the intensity of the uniform electric field ranges from 40 V/m to 100 V/m.

The technical result, which consists in optimizing the cleaning process and reducing its cost, is achieved by simultaneously exposing the adsorbent (quartz sand) and the water passed through it to a uniform electric field with a strength of 40 V/m to 100 V/m from an alternating current source.

The invention is illustrated by the drawing.

In fig. a device is presented in which the claimed method of wastewater treatment is implemented.

The cleaning device consists of an alternating current source 1 with output voltage regulation, a working tank 2, an upper tank 3 intended for filling with waste water, a tank for purified water 4. In the upper and lower parts of the working tank 2 are placed parallel to each other and perpendicular to the direction of movement water, a graphite electrode-anode 5 and a graphite electrode-cathode 6 with current leads 7. Using a clamp 8, the water flow is regulated. The container is filled with adsorbent 9 (quartz sand).

The claimed method is implemented as follows. When voltage is applied to the graphite electrode-anode 5 and the graphite electrode-cathode 6, between which there is quartz sand 9, an electric field of equal strength appears in the working container 2, the lines of force of which are directed parallel to the direction of water movement, and the electric field strength is 40-100 V/m. The water to be purified enters the upper part of the working tank 2, then enters the interelectrode space, where it begins to be exposed to a field of equal strength, is filtered through quartz sand 9 and passes through the anode 5, and the cathode 6 into the lower part of the working tank, entering further into the tank for purified water 4.

When the voltage is less than 40 V/m, a decrease in the degree of water purification is observed. When the voltage increases to more than 100 V/m, the results of water purification change slightly, and specific energy consumption increases, which indicates the advisability of sticking to the voltage range from 40 to 100 V/m.

As a result of exposure to a uniform electric field, polarization of quartz sand particles located in the interelectrode space occurs, due to which the ability of quartz sand particles to retain impurities dissolved in the water being purified increases. Polarization leads to the formation of bound charges on their surface and, accordingly, the fixation of heavy metal ions with the subsequent formation of metal oxides and hydroxides. The application of an electric field to quartz sand granules leads to an increase in its activity and dynamic volumetric capacity, and therefore it can compete with more expensive zeolites and ion exchange resins. Atomic oxygen released at the insoluble anode promotes the oxidation of harmful impurities that are adsorbed by granules of quartz sand subjected to charge separation in the dielectric (polarization). The electric field enhances adsorption processes by increasing the polarization passing on the surface of the sorbent.

An increase in the degree of purification is observed with an increase in the electric field strength in the gap between the anode and the cathode, or with an increase in the specific amount of electricity passed through the water.

Example 1. Purified wastewater containing Fe (III) salts with an average ion concentration of 3.75 mg/l is fed into working tank 2. Wastewater fills the space between the perforated graphite anode 5 and the cathode 6, which contains the adsorbent 9. Quartz sand is used as an adsorbent. The electrodes are supplied with an alternating voltage of 5 V, a current of 45 mA, and an electric field strength of 100 V/m. Using clamp 8, the required flow rate of the purified water is set. Water sedimentation is carried out in container 4 for 8 hours. After purification, the concentration of iron ions in the water was 0.29 mg/l. The degree of purification corresponds to 90%.

Example 2. Before the experiment, Cu salts were dissolved in water at an average ion concentration of 2.00 mg/l. Waste water fills the space between the perforated graphite anode 5 and the cathode 6, in which the adsorbent 9 is located. Quartz sand is used as an adsorbent. The electrodes are supplied with an alternating voltage of 3.5 V, a current of 30 mA, and an electric field strength of 70 V/m. Using clamp 8, the required flow rate of the purified water is set. Water sedimentation is carried out in container 4 for 8 hours. After settling the water, the copper content is 0.3 mg/l. The degree of purification is 80%.

Example 3. Mn ²⁺ salts were dissolved in water at an average ion concentration of 0.80 mg/l. Waste water fills the space between the perforated graphite anode 5 and the cathode 6, in which the adsorbent 9 is located. Quartz sand is used as an adsorbent. The electrodes are supplied with an alternating voltage of 2 V, a current of 18 mA, and an electric field strength of 40 V/m. Using clamp 8, the required flow of purified water is set. Water sedimentation is carried out in container 4 for 8 hours. After sedimentation of water in container 4, the concentration of manganese salts was 0.2 mg/l. The degree of purification is 70%.

Simultaneous carrying out of water filtration processes, electrochemical action and activation of the adsorbent in a field of equal strength makes it possible to simplify the equipment and reduce the cost of water purification.

Claims (1)

A method of wastewater treatment, including simultaneous adsorption and electrochemical treatment, affecting the adsorbent - quartz sand and water passed through it with a uniform electric field, the lines of force of which are directed parallel to the direction of water movement, and further settling, characterized in that a uniform electric field is created using an alternating current source when voltage is applied to the graphite anode and cathode, between which the adsorbent is located, while the uniform electric field strength ranges from 40 V/m to 100 V/m.