SU1717556A1 - Method of biochemical cleaning of sewage - Google Patents

Abstract

The invention relates to the treatment of water, can be used in the purification of industrial wastewaters of paint and varnish production, and allows an increase in the degree of purification from hard-to-destroy organic substances and heavy metal ions. Wastewater from the paint production is successively treated under anaerobic and aerobic conditions by soil-adapted microorganisms immobilized. At the aerobic stage, activated sludge is used, on anaerobic - a mixture of activated sludge and fermented sludge with a mass ratio of 1: 0.7-1.5 in the presence of nitrates and sulfates with a mass ratio of organic substances (COD) nitrates and sulfates, equal to 1: 0.3- 0.38: 0.06-0.08. The method allows to increase the degree of water purification from organic compounds by 28 times, from heavy metal ions by 16 times. At the same time, the degree of purification by COD with a load on structures of 20,000 g / M Suet is 94.6%, and by ions of heavy metals 98%. 2 tab. with

Description

The invention relates to the treatment of water and can be used in the treatment of industrial wastewaters of the paint and varnish industry of the petrochemical industry.

Wastewater of the paint and varnish industry is a mixture of chemical substances of different structure: xylene, toluene, butanol, phthalic and maleic anhydrides, cyclohexanone, acetone, butyl acetate, white spirit, acrolein, solvent, fatty acids, oils. The percentage of each individual component is not constant. CODbichr is 5-15 kg / m-. The zones contain heavy metal ions: Pb, Co, Zn, Cd, Fe, Cu, Ni in a total concentration of 15-25 g / m3.

Nowadays, highly concentrated wastewater paint

manufactures are burned, and low concentrated are diluted with process water and discarded unpurified, which is environmentally unsafe.

The aim of the invention is to increase the degree of purification of wastewaters of paint and varnish production from hard-to-break organic substances and heavy metal ions.

In order to implement the process, the wastewaters of the paint and varnish industry are sequentially treated under anaerobic and aerobic conditions with the help of adapted to the contaminant immobilized on a fibrous nozzle with a developed surface, for example, VIA, microorganisms. At the anaerobic stage, an adapted mixture of activated sludge and fermented sludge is used at a mass ratio of J ate about

1: 0.7-1.5. The process is carried out in the presence of nitrates and sulfates with a mass ratio of organic substances (COD), nitrates and sulfates, equal to 1: (0.3-0.38): (0.06-0.08). The anaerobic treatment time is 5-6 hours. Aerobic after-treatment is carried out using adapted microorganisms of activated sludge immobilized on the VIA nozzle. The residence time in an aerobic bioreactor is 20-24 hours.

The process of treating actual wastewaters of the paint and varnish industry is carried out in a facility with a total volume of 1,250 m3 consisting of an anaerobic bioreactor with a volume of 250 m3 and an aerobic volume of 1000 m3. The volume of wastewater is 1000-1200 m3 / day. COD 3-7 kg / m3. The load on the anaerobic stage of construction is 12-28 kg COD / m3 day. The concentration of heavy metal ions is 13.7-24.8 g / m. The load on heavy metal ions per anaerobic stage is 54.8-99.2 g / m day. The cleaning process is carried out at a pH of 7.0 ± 0.7. Nitric acid, potassium and ammonium nitrate are introduced into the water to be purified to the ratio of COD: MOH 1: (0.3-0.38). The adjustment of the sulfate content in real water to the COD: N03-: S042 1 ratio; (0.3-0.38) :( 0.06-0.08) is carried out with sulfuric acid or ammonium sulfate, depending on the pH of the effluent.

Adaptation of bacteria-destructors is carried out by double selection of microorganisms of activated sludge and fermented sludge - according to their ability to oxidize the organic components of wastewater with nitrates and sulphates, according to their ability to adhere to the nozzle used in cleaning.

To do this, 25 m3 of fermented sludge and 25 m3 of activated sludge are introduced into an anaerobic bioreactor with a VIY load of 250 m3; previously in contact with the wastewater of the paint and varnish production, 200 m3 of real wastewater with a COD of 5000 mg / dm3 are added there and salts of CMOZ, MH-ZMOZ, (NH4J2S04 are added to the COD: NOs-: S042 ratio of 1: (0.3 -0.38) :( 0.06-0.08). Phosphoric acid serves as a source of phosphorus. After reducing the COD by more than 60% and reducing most of the nitrates and sulfates, the liquid from the structure is poured and 250 m3 of real are again introduced into the bioreactor waste water with COD 5000 mg / dm and the content of nitrates and sulfates in it in the ratio: COD: 1: (0.3-0.38) :( 0.06-0.08).

Subsequently, the wastewater treatment process carried out microorganisms attached to the fibrous packing, using nitrate and sulfate as final acceptors during oxidation. After

about

significant reduction in COD, N03 and S04, the process is repeated again.

After seven passages, the flow-through supply of wastewater to the bioreactor is established, gradually increasing the load on the structure. From the anaerobic bioreactor, the water enters the aerobic reactor in which the VIA nozzle is located.

At the beginning of the launch of the facility on the duct in

0 an aerobic bioreactor introduces one-time 10 m3 of activated sludge to develop microorganisms using oxygen for air, sulfide-oxidizing, nitrifying, obligate heterotrophs, as well as

5 hydrobionts.

In tab. 1 presents data on the effectiveness of the cleaning process, depending on the value of the ratio of COD: MOH: S042- and the mass ratio of active

0 silt and fermented sediment.

In determining the optimal ratio of COD and oxidant (N03- and S04), it is assumed that a maximum decrease in COD and concentration of ionizing metals occurs, and oxidized forms of nitrogen (nitrates and nitrites) do not accumulate in purified water . This ratio is: COD: NOs: S042 1: (0.30 0.38) :( 0.06-0.08).

It is established that the proposed ratio provides a reduction in the COD of water by 90-94.5%. The residual value of the COD does not exceed 500 mg / dm3 (Table. 1, examples 1-17),

5 which allows to discharge wastewater to conventional biological treatment plants (PE). Purification of heavy metal ions occurs at 96.6-99.6%. The residual concentration is 0.09-0.66 mg / dm3 (table.

0 1, examples 1-17), and the concentration of each individual element in the purified water does not exceed the MPC of the discharge to the biofeedback.

For example, with a residual total concentration of heavy metal ions

5 in purified water, 0.66 mg / dm3, the content of each individual element is. mg / dm3: zinc 0.2; iron 0.15; copper 0.1; lead 0.06: cobalt, nickel and cadmium to 0.05.

0 Higher concentrations of nitrate prevent the reduction of the redox potential of the medium at a given load to values at which sulfate reduction is possible, as a result of

5 which does not precipitate heavy metals. Thus, at a ratio of 1: 0.4: 0.1 (Table 1, Example 19), the degree of purification by COD is 85.2%, and by heavy metal ions is 80.1%, which is higher than the MPC level for water discharge on biological treatment facilities. The nitrate content in the source water below the claimed value (Example 18) also leads to an insufficient degree of purification by COD and heavy metal ions for the supply of BFB - 82.3% and 79.9%, respectively. An extreme decrease in SCM2 concentration leads to a low degree of purification from heavy metals (Example 18), and an extreme increase in sulfate leads to the formation of an excess amount of H2S, toxic to nitrifying bacteria and protozoa, COD decreases by 83.6% (Example 20), the concentration heavy metals by 81.4%.

Similar results are achieved with the use of exorbitant amounts of activated sludge and fermented sludge (examples 21, 22), which also prevents the discharge of treated water to urban biological treatment plants.

Example 1. Sewage water containing xylene, toluene, butanol, phthalic and maleic anhydrides, cyclohexanol, acetone, white spirit, acrolein, solvent, fatty acids, COD oils 3000 mg / dm and ions of heavy metals Pb, CO, Zn, Cd , Fe, Cu, Ni in a total concentration of 13.7 mg / dm3, passed through anaerobic and aerobic bioreactors. COD load on anaerobic stage is 12000 g / m3. days, pH 7.4. Water is introduced in g / dm3: 0.5; 0.6; HPRO / i 0.04, sulphate concentration in water 0.2 g / dm3.

The results of the construction are given in Table. 2, example 1. The degree of water purification by COD is 98%, and by heavy metal ions is 98.6%.

Example 2. Sewage water with a COD of 5000 mg / dm and a heavy metal concentration of 15.1 mg / dm2 is treated in an anaerobic-aerobic structure using immobilized microorganisms. Load.on anaerobic stage 20,000 g / m3 day, pH 6.5. To the water is added, g / dm3: HN03: 0.83, NH4N03 0.8; KN03 0.2; H3P04 0.06; (NH4) 2S040.18.

Purification results: 94.5% for COD and 98% for heavy metal ions (Table 2, Example 2).

Example 3. Water purification with a COD of 7000 mg / dm3 is carried out sequentially by anaerobic and aerobic microorganisms. The concentration of heavy metal ions in water is 24.8 g / dm3. The load on the anaerobic stage is 28000 g / m3 day.pH 6.9. G / dm3: HNOs 1.2; MN4M3 1,2; CMOS 0,6; H3P04 0.08; (0.34. 5Cleaning occurs by 90% on COD and on

96.1 - for heavy metal ions (Table 2, example 3). As a result of this treatment, more than 25,000 g of COD / m day and about 95 g / m3 day are removed at the anaerobic stage.

0 tons of yellow metals.

To compare the effectiveness of the known and proposed methods, research was carried out on wastewater treatment of paint and varnish production using

.5 in the first stage of purification of the fermentation.

The cleaning results by a known method are given in table. 2, examples 4-6. From tab. 2 shows that the content of the components

0 wastewater after anaerobic treatment practically does not change, i.e. they are not fermented.

With the load on the anaerobic bioreactor 10,000 g / m3, the degree of water purification is

5 COD is 8%, the content of heavy metal ions is reduced by 11.3%. When the load on the structure is 20,000 g / m day, the cleaning efficiency is even lower.

The proposed method makes it possible to increase the degree of water purification from organic compounds by 28 times, from heavy metal ions by 16 times. At the same time, the degree of purification by COD with a load on structures of 20,000 g / m3 a day is 94.7%, and by ions of heavy metals 98%.

Claims (1)

The invention of the method of biochemical wastewater treatment, including the treatment of immobilized microorganisms of activated sludge sequentially in anaerobic and aerobic conditions, characterized in that, in order to increase the degree of wastewater treatment of paint and varnish production from 5 hard-to-destroy organic substances and heavy metal ions, treatment under anaerobic conditions is carried out with an immobilized adapted mixture of activated sludge and fermented sludge at 0 mass ratio of 1: 0.7 to 1.5 in the presence of nitrates and sulfates at a mass ratio of organic substances (COD). nitrates and sulfates, equal to 1: 0.30-0.38: 0.06-0.08. Table 1 Notice and e. COD of waste water part of heavy metal construction 5000 mg / dm3, anaerobic load 20000 g / m3 day, ion concentration (TM) 15.1 mg / dm3 The proposed method 13000 1200U 13.7 600 / 1998.0 25,000 20,000 15.1 2750,394.5 37000 28000 24.8 7000.97. 90.0 Known method 45000 5000 15.1 407012.218.6 55,000 10,000 15.1 460013.48.0 65000 20000 15.1 483014,23.4 table 2 98.6 98.0 96.1 19.0 N, 3 M