RU2736497C1 - Method of waste water treatment - Google Patents

Abstract

FIELD: waste water treatment.

SUBSTANCE: invention relates to wastewater treatment and can be used in municipal services and various industries for cleaning industrial and similar wastewater from metal ions, oil products, organic contaminants and odor. Wastewater treatment is carried out successively in mechanical cleaning unit containing sand trap, averaging device and horizontal settling tank with corridors. After wastewater are fed into averaging device, wastewater is analyzed to determine composition and concentration of pollutants. Depending on contamination of waste water, a composition of adsorption-filtering materials based on vegetable wastes is chosen. Adsorption-filtering material used is modified lignocellulose-containing materials – acid-treated barley hulls – ATBH, acid-treated oat hulls – ATOH, acid-treated wheat hulls – ATWH, thermally treated oat hulls – TTOH, as well as ground mixed leaf litter – MLL. Moreover, when used normally soiled wastewater composition adsorption -filtering materials from ATWH, TTOH MLL and ratio (3–1):(2–1):1, respectively. At contaminated wastes with predominance of oil products composition of adsorption-filtering materials from ATWH, TTOH and MLL is used at ratio of (3–1):(2–1):(0:1) respectively. At contaminated waste water with predominance of metal ions there used is composition an of absorption-filtering materials from ATBH, ATOH and TTOH in ratio of (3–1):(2–1):1, respectively. Composing adsorption-filtering materials into cassettes and loading into blocks, which are installed at the end of each corridor of horizontal settler, then, waste water is fed into a horizontal settling tank for sorption and settling at rate of 5 mm/s for 2 hours.

EFFECT: disclosed method for purifying waste water increases efficiency of purifying waste water, reduces load on biological treatment facilities and atmospheric air pollution by using sorption materials made from vegetable wastes.

1 cl, 3 dwg, 3 tbl

Description

The invention relates to the purification of wastewater from harmful impurities, including metal ions, oil products, organic pollution and odor, and can be used in municipal services and various industries for the purification of industrial and similar in composition wastewater.

A known method of wastewater treatment (Kaganovsky A.M., Klimenko N.A. and others. Treatment and use of wastewater in industrial water supply, Moscow: Chemistry, 1983, p. 238), including mechanical treatment, biological treatment and post-treatment by filtration using the following equipment: grates, sand trap, primary clarifier, aeration tank, secondary clarifier, activated sludge regenerator, mesh drum filter, granular filter, chlorination unit, contact tank, rinse water discharge tank, rinse water storage tank and sand pads.

The disadvantage of this method is that the treated water cannot be used to feed completely closed water recycling cycles, because Dissolved impurities cannot be effectively removed from wastewater.

Also known is a method of purification of wastewater containing oil and / or oil products (Rudin M.G., Arseniev G.A., Vasiliev A.V. General plant economy of an oil refinery. Publishing house "Chemistry", LO, 1978, pp. 190-195), with the disposal of cleaning products, including mechanical cleaning by passing wastewater through sand traps, oil traps, additional sludge settling tanks and flotation plants with capturing part of the sand and up to 95% of oil and returning it to the main technological process for electrical desalination and dehydration in electric dehydrators, atmospheric and / or atmospheric vacuum distillation, supply of sludge for processing with heating it using steam heaters, simultaneous direct injection of a part of the steam and ensuring homogeneity by forced circulation with a pump, supply of prepared sludge with a pump to a decanter, mechanical centrifugal separation of sludge into phases of different density - oil, water and solid, followed by sedimentation of the oil phase and its return to the raw material tanks of the oil refinery for further processing, as well as separate removal of the aqueous and solid phases.

The disadvantages of this method is the insufficient extraction of oil and / or oil products from wastewater, which negatively affects the output of the target product, the environmental situation, the amount of wastewater used in the recycling of production decreases, which leads to the need to replenish production water reserves from reservoirs. In addition, there is a high production cost due to the need to purchase steam on the side, required in certain production processes, as well as significant heat losses during the combustion of fuel and process gas in a flare.

Also known is a method for purifying wastewater from chromium (VI) ions (Patent RU No. 2547756, IPC CO2F 1/28, B01J 20/20, publ. 04/10/2015, bull. No. 10), including passing wastewater through an adsorbent bed at 0.5≤pH≤0.9, characterized in that the adsorbent is a carbon adsorbent with a particle size of 0.5-2 mm with a total porosity of at least 0.5 cm ³ / g and a specific surface area of at least 500 m ² / d, obtained on the basis of long-flame coal.

The disadvantage of this method is the impossibility of cleaning contaminated wastewater from other impurities, for example, metals, organic pollution.

The closest is the method of deep purification of wastewater at a treatment plant (Patent RU 2048457, IPC C02 F 3/30, 3/02, 3/34, 7/00, 9/00, publ. 20.11.1995), performed in block-modular design and containing a blending receiving tank with a pump, installed after a mechanical treatment unit containing a sand trap, a biological treatment unit containing a first stage aeration tank with a carrier for attached microflora in the aeration zone and thin-layer modules in the sedimentation zone, a second aeration tank stages with a ruff loading in the aeration zone and thin-layer modules in the settling zone, an aerobic sludge stabilizer with a ruff loading, a denitrifier and a bioreactor with layers of a carrier for attached microflora and granular loading located in it, a post-treatment unit including a carbon filter, and a disinfection unit using reagents ... The method of deep purification of waste water includes supplying waste water to a mechanical treatment unit containing a sand trap, then to an homogenizer, and then directing waste water to a tubular sump with corridors where waste water is clarified, then to biological treatment in an aeration tank.

The disadvantages of the known method are the cumbersomeness of the station, the complexity and high cost of implementing the method, since they use reactors that are complex in design, a large power consumption is required to supply compressed air to aeration tanks, a sediment stabilizer and a post-treatment bioreactor, as well as the use of reagents for disinfection and phosphorus removal.

The technical tasks are to increase the efficiency of wastewater treatment by increasing the degree of wastewater treatment from oil products, to reduce the cost of wastewater treatment at industrial enterprises through the use of sorption materials made from plant waste, to increase the stability of the technological mode of operation of treatment facilities, as well as to expand the range of sorbents for vegetable based.

Technical problems are solved by a wastewater treatment method, including the supply of wastewater to a mechanical treatment unit containing a sand trap, then to an equalizer, and subsequent direction of wastewater to a horizontal settling tank with corridors.

What is new is that after the wastewater is fed to the homogenizer, the wastewater is analyzed to determine the composition and concentration of pollutants, according to the composition and concentration of pollutants, wastewater is divided into moderately polluted wastewater, polluted wastewater with a predominance of oil products, polluted wastewater with a predominance of ions metals, depending on the wastewater pollution, a composition of adsorption-filtering materials based on plant waste is chosen, modified lignocellulose-containing materials are used as the adsorption-filtering material - acid-treated fruit shells of barley grains - KPOZYa, acid-treated fruit shells of oat grains - KPOZO, acid-treated fruit shells of grains wheat - KPOZP, thermally processed fruit shells of oat grains - TPOZO, as well as crushed mixed leaf litter - SLO, and with moderately polluted wastewater, a composition of adsorption-filtering material is used fishing from KPOZP, TPOZO and SLO in the ratio (3-1) :( 2-1): 1, respectively, for polluted wastewater with a predominance of oil products, a composition of adsorption-filtering materials from KPOZP, TPOZO and SLO is used in the ratio (3-1) : (2-1) :( 0: 1) respectively, for polluted wastewater with a predominance of metal ions, a composition of adsorption-filtering materials from KPOZYA, KPOZO and TPOZO is used, in the ratio (3-1) :( 2-1): 1 accordingly, a composition of adsorption-filtering materials is formed into cassettes and loaded into blocks, thus formed blocks of cassettes filled with adsorption-filtering material based on plant waste are installed at the end of each corridor of a horizontal settler, then wastewater is sent to a horizontal settler for sorption and settling at a speed of 5 mm / s for 2 hours.

FIG. 1 shows the sequence of implementation of the method of wastewater treatment, FIG. 2 shows loading blocks in the form of cassettes, where 1 is a sand trap, 2 is an homogenizer, 3 is a horizontal sump, 4 is a section for forming a loading of cassettes from adsorption filtering material, 5 is a block of cassettes.

The method is carried out as follows.

In industrial waste water, as a rule, metal ions and oil products are simultaneously present. For the purification of such polluted wastewater, it is proposed to use environmentally friendly sorbents, sorbents based on plant raw materials.

Contaminated wastewater is fed into a mechanical treatment unit (at the first stage of mechanical treatment), containing a sand trap 1 (Fig. 1), where fine particles (sand, slag, broken glass, etc.) are precipitated by gravity. Then the waste water flows into the equalizer 2 to achieve a uniform concentration of contaminants. After the wastewater is fed into the blender 2, the wastewater is analyzed to determine the composition and concentration of pollutants. According to the composition and concentration of pollutants, wastewater is divided into: moderately polluted wastewater, polluted wastewater with a predominance of oil products, polluted wastewater with a predominance of metal ions. Depending on the type of wastewater pollution, a composition of adsorption-filtering materials based on plant waste is chosen.

Modified lignocellulose-containing materials are used as adsorption-filtering material - acid-treated fruit shells of barley grains (KPOZYA), acid-treated fruit hulls of oat grains (KPOZO), acid-treated fruit-shells of wheat grains (KPOZP), thermally processed fruit hulls of oat grains (TPOZO) crushed mixed leaf litter (SLO), which are plant waste and adsorb the above contaminants.

KPOZYA, KPOZO, KPOZP - acid-treated fruit shells of barley, oats and wheat, respectively, modified with a solution of sulfuric acid. The modification is carried out as follows: 1% sulfuric acid solution and sorption material (for example, fruit shells of barley or oats or wheat grains) in a ratio of 10: 1, respectively, are loaded into a screw dehydrator, stirring is carried out for 1 hour at a temperature of 20 ± 5 ° FROM. Then the modifiers are separated from the aqueous phase through a filter and dried to constant weight.

TPOZO - thermally processed fruit shells of oat grains. Heat treatment is carried out in a continuous drum-type furnace with constant stirring at a temperature of 150-180 ° C for 30 minutes.

SLO - mixed leaf litter, is a mixture of fallen leaves of birch - 25-35%, poplar - 25-31%, linden - 10 -20%, maple - 10-15% and other types of trees - 15-30%, pre-crushed in a shredder-type shredder up to sizes not exceeding 10 × 10 mm.

Depending on the type of wastewater pollution, the composition and the optimal ratio of adsorption-filtering materials are selected to achieve maximum wastewater treatment.

So with moderately polluted wastewater, i.e. in the standard operating mode of the enterprise, the average daily concentration and composition of pollutants are in the range: Fe ²⁺ and Fe ³⁺ - 2-3.5 mg / dm ³ , Cu ²⁺ - 0.5-2 mg / dm ³ , oil products - 0.4-2 mg / dm ³ . In this case, the most effective is the composition of adsorption-filtering materials from KPOZP, TPOZO and SLO in the ratio (3-1) :( 2-1): 1, respectively.

With polluted wastewater with a predominance of oil products, the concentration and composition of pollutants are in the range: Fe ²⁺ and Fe ³⁺ - 0.05-2 mg / dm ³ , Cu ²⁺ - 0.1-0.5 mg / dm ³ , petroleum products –2 and more. In this case, the most effective is the composition of adsorption-filtering materials from KPOZP, TPOZO and SLO in the ratio (3-1) :( 2-1) :( 0: 1), respectively.

With polluted wastewater with a predominance of metal ions, the concentration and composition of pollutants are in the range: Fe ²⁺ and Fe ³⁺ - 3.5-10 mg / dm ³ , Cu ²⁺ - 2 and more, oil products - 0.03-0 , 4 mg / dm ³ . In this case, the most effective is the composition of adsorption-filtering materials from KPOZYA, KPOZO and TPOZO, in the ratio (3-1) :( 2-1): 1, respectively.

Pre-prepared adsorption-filtering material - the composition of adsorption-filtering materials is molded into cassettes at the site of formation of loading cassettes 4 and loaded into blocks 5 (Fig. 1-3). For example, for the purification of contaminated wastewater with a predominance of metal ions, a composition of adsorption-filtering materials from KPOZYA, KPOZO and TPOZO in a selected ratio is formed into cassettes. A cassette made of adsorption-filtering material is a metal-polyethylene frame filled with a composition of adsorption-filtering materials based on lignocellulose-containing materials, loading density 400-600 m ³ / kg , size 2-7 mm. The size of the cassettes is selected based on the dimensions of the corridor of the horizontal sump 3 (Fig. 1): for example, in the corridor of the horizontal sump 3 4200 mm wide and 2370 mm high, a frame block 5 (Fig. 1-3) of nine cassettes with a total size of 3600 × 3600 is installed × 1300 mm. The size of one cassette is 1000 × 1000 × 1300 mm. Block 5 of cassettes is fixed with hooks on anchor brackets located on the walls of the corridor of the horizontal sump 3 (Fig. 2). Blocks 5 (Figs. 1-3) of cassettes filled with adsorption-filtering material based on plant waste are technologically retrievable for replacement and washing. Replacement of cassettes (used adsorption-filtering material) is carried out once every 10-20 days, depending on the concentration of pollutants, by removing cassettes from block 5 (Fig. 1-3) using a mobile lifting mechanism of the crane-beam type.

The stage of forming the loading of cassettes takes place directly at the treatment facilities of the enterprise, which allows you to adjust the ratio of the proposed adsorption-filtering materials in block 5 of cassettes, depending on the composition and concentration of pollutants in the wastewater, as well as change the composition of the composition of the adsorption-filtering material depending on the concentration pollutants in wastewater entering the sump.

The cassette blocks 5 formed in this way, filled with adsorption-filtering material based on vegetable waste, are installed at the end of each corridor of the horizontal settler 3 (Fig. 1).

Further, the averaged wastewater is directed into a horizontal sump 3 with corridors, where sorption and settling of wastewater is carried out at a speed of 5 mm / s for 2 hours.

Horizontal sedimentation tanks 3 are designed for sedimentation (settling) of suspended harmful impurities: metal ions, oil products, organic pollution, sludge, etc. Typically, standard horizontal sedimentation tanks 3 consist of at least two corridors separated by a partition (wall). Sedimentation of waste water at a rate of 5 mm / s for 2 hours is sufficient. During this time, sedimentation of sludge (various undissolved salts formed in technological shops) and suspended harmful impurities occurs. Settled sludge and harmful impurities are collected in the central pit, which runs along the entire plane of the bottom of the horizontal sump 3, with the help of hydraulic flushing.

The installation at the end of each corridor of a horizontal settler 3 loading blocks 5 (Fig. 1-3) of cassettes filled with a composition of adsorption-filtering materials based on plant waste, depending on the wastewater pollution class, allows to carry out in a horizontal settler 3 (Fig. 1) not only settling, but also sorption. So, blocks 5 (Fig. 1-3) of cassettes, placed in the corridors of a horizontal settler, directly meet on the path of wastewater flow, filtration and sorption take place.

Examples of specific implementation.

The studies were carried out on real polluted wastewater from a petrochemical plant. Contaminated wastewater from an industrial enterprise was fed to a mechanical treatment unit, where it passed through sand traps. Then, the waste water was fed to the homogenizer. Wastewater analysis was carried out to determine the composition and concentration of pollutants. By the composition and concentration of pollutants, the type of polluted wastewater was determined: moderately polluted wastewater, wastewater with a predominance of oil products, wastewater with a predominance of metal ions. Depending on the type of wastewater pollution, the composition and the optimal ratio of adsorption-filtering materials based on plant waste were selected.

The composition of adsorption-filtering materials was molded into cassettes and loaded into blocks. Blocks of cassettes filled with adsorption-filtering material based on plant waste were installed at the end of each corridor of the horizontal settler. After that, the contaminated waste water was fed into a horizontal settling tank. The flow rate in the settler was 5 mm / s, the settling time was 2 hours.

The results of purification of moderately contaminated wastewater, compositions and the optimal ratio of adsorption-filtering materials based on vegetable waste are presented in Table 1. The results of purification of polluted wastewater with a predominance of oil products, compositions and the optimal ratio of adsorption-filtering materials based on vegetable waste are presented in Table 2. Purification results contaminated wastewater with a predominance of metal ions, compositions and the optimal ratio of adsorption-filtering materials based on plant waste are presented in Table 3. Concentrations of pollutants (pollutants) in mg / dm ³ for each type of polluted wastewater at the entrance to the horizontal settler are presented in the columns 2, 3, 4 (Tables 1, 2, 3). Concentrations of pollutants (pollutants) in mg / dm ³ for each type of contaminated wastewater at the outlet from the horizontal settler at the used ratios of adsorption-filtering material are presented in columns 5-13 (tables 1, 2, 3).

Table 1 - Results of purification of moderately polluted wastewater

Pollutant - pollutant, Concentration of pollutants at the inlet to the settling tank, mg / dm ³ The concentration of pollutants at the outlet of the settling tank, mg / dm ³ , with the loading of adsorption filtering material KPOZP: TPOZO: SLO, ratio KPOZP: TPOZO: SLO (3: 2: 1) KPOZP: TPOZO: SLO (2: 2: 1) KPOZP: TPOZO: SLO (1: 1: 1) 1 2 3 4 five 6 7 eight nine ten eleven 12 13 Fe ²⁺ and Fe ³⁺ 2.0 3.36 3.5 0.5 2.22 2.5 0.9 2.41 2.86 1.1 2.36 2.92 Cu ²⁺ 0.5 1,311 2.0 0.008 0.098 0.109 0.01 0.14 0.26 0.26 0.48 0.67 Petroleum products 0,4 1.0 2.0 0.01 0.05 0.07 0.01 0.05 0.08 0.1 0.06 0.1 Smell (score) 4 4 4 2 2 2 2 2 2 2 2 2

Table 2 - Results of wastewater treatment with a predominance of petroleum products

Pollutant - pollutant, Concentration of pollutants at the inlet to the settling tank, mg / dm ³ The concentration of pollutants at the outlet of the settler mg / dm ³ , with the loading of adsorption-filtering material KPOZP: TPOZO: SLO, ratio KPOZP: TPOZO: SLO (3: 2: 0) KPOZP: TPOZO: SLO (2: 2: 1) KPOZP: TPOZO: SLO (1: 1: 1) 1 2 3 4 five 6 7 eight nine ten eleven 12 13 Fe ²⁺ and Fe ³⁺ 0.05 1.4 2.0 0 0.05 0.08 0 0.04 0.1 0 0.07 1.1 Cu ²⁺ 0.1 0.2 0.5 0.003 0.007 0.013 0.005 0.067 0.14 0.007 0.016 0.024 Petroleum products 2.0 3.0 4.0 0.04 0.05 0.07 0.02 0.04 0.17 0.03 0.06 0.09 Smell (score) 4 4 4 2 2 2 2 2 2 2 2 2

Table 3 Results of waste water treatment with a predominance of metal ions

Pollutant - pollutant, Concentration of pollutants at the inlet to the settling tank, mg / dm ³ Concentration of pollutants at the outlet of the settler mg / dm ³ , with the loading of adsorption filtering material KPOZYA: KPOZO: TPOZO, the ratio KPOZO: KPOZO: TPOZO (3: 2: 1) KPOZO: KPOZO: TPOZO (2: 2: 1) KPOZO: KPOZO: TPOZO (1: 1: 1) 1 2 3 4 five 6 7 eight nine ten eleven 12 13 Fe ²⁺ and Fe ³⁺ 3.5 five ten 2.5 2.34 2.46 2.5 2.75 2.97 2.36 3.85 3.48 Cu ²⁺ 2 3 five 0.109 0.75 3.52 0.95 1.23 3.98 0.65 1.48 3.64 Petroleum products 0.03 0.2 0,4 0 0 0.015 0 0 0.021 0 0 0.026 Smell (score) 4 4 4 2 2 2 2 2 2 2 2 2

As you can see from the table. 1, 2, 3, after the passage of wastewater through horizontal sedimentation tanks loaded with compositions of adsorption-filtering materials based on plant waste, the concentration of pollutants (pollutants) for each type of contaminated wastewater at the outlet from the horizontal sedimentation tanks decrease. Thus, the degree of wastewater treatment from pollution, oil products, metal ions is increased.

The proposed method of wastewater treatment increases the efficiency of wastewater treatment by increasing the degree of wastewater treatment, reduces the load on biological treatment facilities and reduces air pollution from odor through the use of sorption materials made from plant waste. The use of the proposed method will increase the stability of the technological mode of operation of treatment facilities, and will also expand the range of adsorption-filtering materials (sorbents) on a plant basis.

Claims (1)

A method of wastewater treatment, including the supply of wastewater to a mechanical treatment unit containing a sand trap, then to the homogenizer and the subsequent direction of wastewater to a horizontal sump with corridors, characterized in that after the wastewater is fed into the homogenizer, wastewater is analyzed to determine its composition and concentration pollutants, according to the composition and concentration of pollutants, wastewater is divided into moderately polluted wastewater, polluted wastewater with a predominance of petroleum products, polluted wastewater with a predominance of metal ions, depending on the wastewater pollution, a composition of adsorption-filtering materials based on plant waste is selected, Modified lignocellulose-containing materials are used as adsorption-filtering material - acid-treated fruit shells of barley grains - KPOZYa, acid-treated fruit shells of oat grains - KPOZO, acid-treated fruit husks of wheat grains - KPOZP, term ichically processed fruit shells of oat grains - TPOZO, as well as crushed mixed leaf litter - SLO, and with moderately polluted wastewater, a composition of adsorption-filtering materials from KPOZP, TPOZO and SLO is used in the ratio (3-1) :( 2-1): 1 accordingly, for polluted wastewater with a predominance of oil products, a composition of adsorption-filtering materials from KPOZP, TPOZO and SLO is used in the ratio (3-1) :( 2-1) :( 0: 1), respectively, with polluted wastewater with a predominance of metal ions use a composition of adsorptive-filtering materials from KPOZYA, KPOZO and TPOZO in the ratio (3-1) :( 2-1): 1, respectively, form the composition of adsorption-filtering materials into cassettes and load into blocks, thus formed blocks from cassettes, filled adsorption-filtering material based on plant waste, installed at the end of each corridor of the horizontal sump, then the wastewater is sent to the horizontal sump for sorb tion and settling at a speed of 5 mm / s for 2 hours.

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