RU2206522C1 - Method of treating waste waters to remove cadmium-containing harmful impurities - Google Patents

Abstract

FIELD: waste water treatment. SUBSTANCE: multicomponent waste waters are subjected to sorption-mediated treatment to remove harmful impurities, such as cadmium, nickel, petroleum derivatives, anionic surfactants in dissolved and dispersed forms, in presence of ethylene glycol, polyvinyl alcohol, and mineral salts for use in mechanical engineering and chemical industry, in particular when manufacturing chemical power sources. Preliminarily, waste water is cleaned by two-step flocculation by adding 0.5- 2.2% (of the weight of solids) of cationic polyelectrolyte and removing in series suspended impurities (first step) and dissolved impurities. Subsequent sorption involves such sorbents as successively disposed thermally modified dolomite and activated carbon. Cationic polyelectrolyte, in particular, is copolymer of dimethylaminoethyl methacrylate dimethyl sulfate salt and acrylamide containing at least 80 mol % cationic groups, each concentration in the first state being 0.8- 2.2% and, in the second step, 0.5-1.5% based on the weight of solids. Sorption operation is accomplished by passing waste water through sorbents at velocity 0.5 to 1 cu.dm/min, volume ratio of thermomodified dolomite to activated carbon being 4:1. EFFECT: improved cleaning quality and therefore created closed water supply circuit. 3 cl, 1 dwg, 1 tbl

Description

 The invention relates to methods for purifying multicomponent wastewater from harmful impurities, in particular cadmium, nickel, petroleum products, anionic surfactants in soluble and dispersed forms in the presence of ethylene glycol, polyvinyl alcohol and inorganic salts, and can be used in engineering and chemical industries in particular in the production of chemical current sources.

 A known method of deep wastewater treatment from heavy metals, including the stage of pre-treatment, desalination by reverse osmosis, disposal of the concentrate with evaporation to a dry residue and reuse of purified water, the preliminary treatment is carried out by reagent deposition and sorption on aluminosilicates at pH 8-11, desalination carried out in a reverse osmosis apparatus with a number of concentration steps of 3-5 at pH 5.5-6.5, the concentrate is treated on aluminosilicates at pH 8-9 before evaporation, and the regeneration of aluminosilicon deleterious sorbent is carried out in two stages, and regeneration is carried out in reverse osmosis desalination membranes mode at a pH of 8-11 for 2-5 h in 12-14 days of operation (RF Patent No. 2085518, IPC C 02 F 9/00).

 The disadvantage of this method is the complexity of the process, including several stages of purification, each of which is characterized by a narrow pH range.

 A known method of purifying industrial wastewater from ions of heavy metals, petroleum products, surfactants and other impurities, including galvanic coagulation using galvanic couples and separation of solid and liquid phases, while prior to galvanic coagulation, the wastewater is pre-treated in an averaging tank into which the precipitate is sent after galvanic coagulation, the resulting mixture is subjected to magnetoacoustic resonance, and galvanocoagulation of the previously purified liquid phase is carried out by the following But in two stages, the first stage of the galvanic pair formed of coke and iron particles, and the second of coke and aluminum particles (RF patent 2161137, IPC C 02 F 1/463).

 The disadvantage of this method is the use of expensive iron and aluminum for galvanic coagulation, as well as its high energy intensity.

 A known method of cleaning wash water after the operation of electroplating, including non-flow multi-stage washing and sorption on inorganic materials, using natural diatomaceous dispersed silica as a sorbent (RF patent 2074118, IPC C 02 F 1/28).

 However, this method is intended for the treatment of wastewater from heavy metals and is ineffective in wastewater treatment, including oil products, anionic surfactants and other pollutants.

 Closest to the proposed one is a method for treating wastewater from heavy metals, including nickel and cadmium ions, including purification by sorption on a composite sorbent, while galvanic sludge granulated with a polymer binder is used as a sorbent (RF patent 2125972, IPC С 02 F 1/62, 1/58).

 The disadvantage of this method is the low efficiency of treatment of multicomponent wastewater, including pollutants of inorganic and organic nature. In addition, the disadvantage of this method is the use of highly toxic galvanic sludge as a sorbent.

 The objective of the proposed method is to improve the quality of treatment of multicomponent wastewater from harmful impurities, in particular cadmium, nickel, petroleum products, anionic surfactants in soluble and dispersed forms in the presence of ethylene glycol, polyvinyl alcohol and inorganic salts while ensuring a closed water supply cycle.

 The problem is solved in that in the method of purification of wastewater from harmful impurities containing cadmium, including sorption, according to the proposed solution before purification by sorption, purification by flocculation is carried out by introducing into the wastewater a cationic polyelectrolyte in an amount of 0.5-2.2% of the dry concentration waste water substances, while flocculation is carried out in two stages, the first of which purifies harmful impurities in a dispersed state, and the second stage removes harmful impurities in a dissolved state, and as a sorb They use sequentially located thermally modified dolomite and activated carbon.

As a cationic polyelectrolyte, a dimethylaminoethyl methacrylate dimethyl sulfate-acrylamide copolymer containing at least 80% molar cationic groups is used, the amount of which in the first stage is 0.8-2.2%, and in the second stage 0.5-1.5% of the dry concentration waste water substances, and sorption purification is carried out by passing treated water through sorbents at a speed of 0.5-1 dm ³ / min, and the volume ratio of thermally modified dolomite and activated carbon is 4: 1, respectively.

 With the introduction of a cationic polyelectrolyte, the water is stirred until the copolymer is uniformly distributed in it.

 The method is as follows.

 The purification process consists of flocculation of pollutants in two stages, which leads to the formation of large flocs, sedimentation of the system, filtration of the supernatant, sorption of cations of nickel and cadmium, and the return of purified water to a closed water supply cycle.

 The schematic diagram of the cleaning is shown in the drawing.

According to the scheme, contaminated water after washing equipment, for example, the production of nickel-cadmium batteries from the tank 1, enters the multi-section sump 2. In the first section of the sump 2, the dispersed particles of pollutants are flocculated by cationic polyelectrolyte containing 80% molar cationic groups, in an amount of 0, 8-2.2% of the dry matter concentration of wastewater, resulting in the formation of large flocs and their rapid subsidence. To increase the efficiency of the flocculation process during the introduction of an aqueous solution of flocculant, the wastewater is mixed for 10-20 minutes until the copolymer macromolecules are evenly distributed throughout the entire volume of the first section of settling tank 2. In the process of filling the subsequent sections of settling tank 2 with water from the previous sections, settling takes place in them system. After the sump 2 is completely filled, the supernatant is periodically automatically pumped 3 by the pump 3 into the intermediate storage tank 4. After filling the tank 4, for example, after 6-8 hours, an aqueous flocculant solution is added to it, under the action of which oil products and anionic surfactants are added from the supernatant. active substances become dispersed. The flocculant is administered in an amount of 0.5-1.5% of the solids concentration of wastewater. The system is mixed with a mechanical stirrer for 10-20 minutes and kept at rest for 10-14 hours. Then, the supernatant is pumped by pump 5 through a mechanical filter 6 and adsorbers 7 at a speed of 0.5-1 dm ³ / min into storage tank 8, from where by gravity purified water enters the tank 1.

 When choosing a flocculant from a number of polymers, the best result of purification of multicomponent waters was obtained using cationic polyelectrolytes, in particular copolymers of quaternary ammonium salts. High cleaning efficiency was found when using a copolymer of dimethylaminoethyl methacrylate dimethyl sulfate and acrylamide with a high content of cationic groups (≥80 mol.%).

In addition, the choice of this flocculant is due to its high solubility in water, nontoxicity, the copolymer and polyelectrolyte nature of its macromolecules, and high molecular weight (1x10 ⁶ ). The optimal concentration of cationic polyelectrolyte for each flocculation step is also determined experimentally, selected from a concentration range of 1 × 10 ⁻⁴ -1 × 10 ⁻² g / dl and is 7.5 × 10 ⁻⁴ g / dl for stage 1, and 5.0 × 10 ⁻⁴ g for stage 2 / dl.

The choice of environmentally friendly natural material — dolomite and activated carbon — as sorbents ensures high cleaning efficiency and cost-effectiveness of the method. Moreover, they use thermally modified - by heat treatment at 800-900 ^o C for 6-8 hours - dolomite.

 The volume ratio of dolomite and activated carbon is 4: 1, respectively, and a water transmission rate of 0.5-1 dm / min are also determined experimentally and are optimal. Moreover, the transmission of water is carried out sequentially first through dolomite, then through activated carbon. These physico-chemical parameters provide high-quality water purification that meets the standards for washing water (see the Handbook "Electroplating". M .: Metallurgy. 1987. -P.736).

The following are examples for a closed water cycle. After washing the equipment, a cationic polyelectrolyte containing 80% molar cationic groups in various amounts from the dry matter concentration of the wastewater is introduced into the sedimentation tank section with contaminated water and a storage tank with supernatant. Thoroughly mix the system and leave it alone for 12 hours. Then the supernatant is pumped through the adsorbers at a given speed. The ratio of the concentration of flocculant to the concentration of dry substances of wastewater (C _f / C _sv ), the ratio of sorbents and the values of the rates of passage (V) through the sorbents were (see examples).

Example I. With _s.v. = 0.095 g / dl; With _f / S _sv = 0.79% (first stage); With _f / S _sv = 0.53% (second stage), the ratio of sorbents 4: 1; V = 0.5 dm ³ / min.

Example II C _s.v = 0.045 g / dl; With _f / S _sv = 1.67% (first stage); With _f / S _sv = 1.11% (second stage), the ratio of sorbents 4: 1; V = 0.8 dm ³ / min.

Example III With _s.v. = 0.034 g / dl; C _f / C _s.v = 2.2% (first stage); With _f / S _sv = 1.47% (second stage), the ratio of sorbents 4: 1; V = 1 dm ³ / min.

 The cleaning results are presented in the table.

 Thus, the proposed method allows you to create a closed cycle of water supply while providing a high degree of purification from harmful pollutants, in particular from especially environmentally hazardous cadmium.

Claims (3)

 1. The method of purification of wastewater from harmful impurities containing cadmium, including sorption, characterized in that before purification by sorption, purification by flocculation is carried out by introducing into the wastewater a cationic polyelectrolyte in an amount of 0.5-2.2% of the dry matter concentration of wastewater, in this case, flocculation is carried out in two stages, at the first of which they are purified from harmful impurities in a dispersed state, and at the second stage, from harmful impurities in a dissolved state, and sequentially located t rmomodifitsirovannyvy dolomite and activated carbon. 2. The method according to claim 1, characterized in that a dimethylaminoethyl methacrylate dimethyl sulfate and acrylamide copolymer is used as a cationic polyelectrolyte, containing at least 80% molar cationic groups, the amount of which in the first stage is 0.8-2.2%, and in the second stage - 0.5-1.5% of the dry matter concentration of wastewater, and sorption is carried out by passing treated water through sorbents at a speed of 0.5-1 dm ³ / min, and the volume ratio of thermally modified dolomite and activated carbon is 4: 1 respectively of course.  3. The method according to claim 1 or 2, characterized in that when the cationic polyelectrolyte is introduced, the water is mixed until the copolymer is uniformly distributed in it.

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