RU2230042C1 - Method of removal of phosphorus from urban sewage - Google Patents

Abstract

FIELD: purification of urban and industrial sewage. SUBSTANCE: the invention presents a method of removal of phosphorus from the urban and industrial sewage. It is dealt with the field of purification of the urban sewage and also sewage of food-processing industry, cattle-breeding complexes and intended for removal of phosphorus presented in the form of ions PO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ . from the sewage. The method includes a mechanical, a biological purifications of the sewage and physicochemical treatment of the silt water with return of the compacted active silt after depletion of phosphorus from the silt concentration tank into the aeration tank. The silt water released from ions of orthophosphoric acid in the settler of the physicochemical treatment and enrichment with the volatile fatty acids produced in the acidoficator operating with the raw settling taken from the primary sedimentation tanks in the mode of the first stage of an anaerobic fermentation, is mixed up with an active silt from the secondary sedimentation tanks and is fed in the silt concentration tank. The technical result is the high quality of purification of the sewage from phosphorus and decrease of operation costs. EFFECT: the invention ensures the high quality of purification of the sewage from phosphorus and decrease of operation costs. 1 dwg

Description

The invention relates to the field of treatment of urban wastewater, as well as wastewater of the food industry and livestock complexes, and is intended to remove phosphorus from the wastewater, presented in the form of PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ .

A known method of removing phosphorus from wastewater (A.S. 784754. The method of biochemical treatment of wastewater containing phosphorus. Gilbert Victor Levin (USA), George Jiri Topol (Canada), Alexandra Gregor Tarnay (USA). M. Cl. ³ C 02 F 3/30. Publ. 30.11.80), including mechanical, biological treatment of wastewater, physico-chemical treatment of sludge water, in which the degree of release of phosphorus from the cell of microorganisms increases as the residence time of activated sludge under anaerobic conditions increases.

Wastewater passes through primary sedimentation tanks, aeration tanks, secondary sedimentation tanks, is freed from phosphorus and fed to further processing. Active sludge from the secondary settling tanks is sent to sludge compactors to separate it under anaerobic conditions into two fractions: sludge water and condensed activated sludge. In sludge compactors under anaerobic conditions, phosphorus is released from microorganisms of activated sludge and sludge is enriched with sludge water. In the same building, sludge is compacted with sludge separation. Silt water with a high phosphate content in the amount of 75-25% of the daily flow rate of wastewater is discharged from the sludge compactor to a physicochemical treatment, where reagents are introduced into it (most often Ca (OH) _{2 is used} ) in combination with flocculants. Ca (OH) ₂ serves to bind PO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ into sparingly soluble compounds of phosphoric acid. The crystals formed are trapped in the sedimentation tanks of the physicochemical treatment and then removed with the subsequent use as a low-grade mineral fertilizer. Sludge water from the sedimentation tanks of the physical and chemical treatment is returned again for re-treatment. Concentrated activated sludge depleted in phosphorus in the amount of 25-75% is returned to the aeration tank, where it actively absorbs phosphorus, thus purifying the waste fluid from the nutrient element. The effectiveness of phosphorus removal from wastewater depends on many factors, the main of which is the duration of activated sludge in anaerobic conditions.

The disadvantage of this method is the insufficiently high quality of wastewater treatment, a significant amount of sludge compactors and the high capital costs required for their construction.

The closest in essence and the achieved result to the claimed one is a method for removing phosphorus from wastewater (Zaletova N.A., Isaeva N.V. Effective processes for removing phosphorus from urban wastewater. Collection of scientific works of the AKH named after KD Pamfilov "Effective technological processes and equipment for wastewater treatment "M .: ONTI AKH, 1988, p. 36-37 - prototype), including mechanical, biological treatment of wastewater and physico-chemical treatment of sludge water, in which to increase the degree of release of phosphorus from microorgan of activated sludge sulfuric or acetic acid is introduced in front of sludge compactors.

According to this method, the wastewater passes through primary sedimentation tanks, aerotanks, secondary sedimentation tanks, is freed from phosphorus and fed for further processing. Active sludge from the secondary settling tanks is sent to sludge compactors, before which sulfuric or acetic acid is introduced. In sludge compactors under anaerobic conditions, phosphorus is released from microorganisms of activated sludge and sludge is enriched with sludge water. In the same building, sludge is compacted with sludge separation. Sludge water is diverted to physicochemical purification, involving the introduction of reagents (Ca (OH) ₂ and a flocculant) to bind PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ into sparingly soluble compounds, and then, after carbonization, is discharged before primary sedimentation tanks for re-treatment. Condensed sludge depleted in phosphorus is returned for biological treatment to aeration tanks, where it replenishes the phosphorus lost by it in sludge compactors.

According to this method, the effect of removing phosphorus from the wastewater is 90-97% with a compaction duration of 1-6.5 hours.

The disadvantages of the prototype are the insufficiently high quality of wastewater treatment due to contamination of the wastewater with sulfur compounds, the need for additional reagent facilities, operational costs for the purchase of sulfuric or acetic acid appear.

The technical problem solved in the present method is to improve the quality of wastewater treatment from phosphorus.

The technical problem is solved as follows. In the method for removing phosphorus from wastewater, including mechanical, biological wastewater treatment and physicochemical purification of sludge water with the return of compacted activated sludge depleted in phosphorus from the sludge compactor to the aeration tank, according to the invention, sludge water freed from phosphoric acid ions in a sump of a physical chemical purification and enriched with volatile fatty acids produced in the acidifier, operating on crude sludge from primary sedimentation tanks in the first stage (acidic or hydrogen) mode erobic digestion, mixed with activated sludge from secondary sumps and fed to the sludge compactor.

Wastewater passes through primary sedimentation tanks, aeration tanks, secondary sedimentation tanks, is freed from phosphorus and fed to further processing. Active sludge from the secondary sumps is sent to the mixer, where it is mixed with sludge water freed from phosphoric acid ions in the sump of physicochemical treatment and enriched with VFA, produced in the acidifier, working on crude sludge from the primary sumps in the first stage of anaerobic digestion, and fed in the sludge compactor, where sludge is compacted with sludge separation, which is then sent for physicochemical treatment, which involves the introduction of reagents for binding PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ into sparingly soluble compounds, and then, after carbonization, is discharged before primary sedimentation tanks for re-treatment. Condensed sludge depleted in phosphorus is returned for biological treatment to aeration tanks, where it replenishes the phosphorus lost by it in sludge compactors.

Due to the use of sludge water liberated from phosphoric acid ions in the sedimentation tank of physicochemical purification and enriched with VFA, produced in crude sludge from primary settlers in the first stage of anaerobic digestion, the high quality of wastewater treatment is achieved to intensify the release of phosphorus from microorganisms. fluids from phosphorus, as well as lower operating costs.

The invention is illustrated in the drawing, which depicts a process flow diagram for the removal of phosphorus from wastewater.

Designations in the drawing: 1 - primary sedimentation tank; 2 - aeration tank; 3 - secondary sump; 4 - slugger; 5 - mixer; 6 - sedimentation tank for physico-chemical treatment; 7 - carbonizer; 8 - mixer; 9 - biologically purified waste fluid; 10 - activated sludge from the secondary sump; 11 - compacted activated sludge depleted in PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ ; 12 - circulating activated sludge depleted in PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ ; 13 - excess activated sludge; 14 - silt water enriched with ions of RO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ ; 15 is a precipitate containing Ca ₅ OH (PO ₄ ) ₃ and MgNH ₄ PO ₄ · 6H ₂ O; 16 - sludge water with a residual phosphorus content (0.1-0.5 mg / l); 17 - carbonated liquid with a pH of 8-8.5; 18 - crude sediment from the primary sedimentation tanks; 19 - silt water freed from ions of PO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ in the sump of physico-chemical treatment and enriched with VFA, produced in the acidifier, working on crude sludge from primary sumps in the mode of the first stage of anaerobic digestion; 20 - sediment, past the first stage of anaerobic digestion; 21 - supply of Ca (OH) ₂ ; 22 - flocculant supply; 23 - carbon dioxide supply (purified flue gases of the local boiler house); 24 - mixer; 25 - sludge containing iron hydroxide - waste from the production of water treatment facilities in the preparation of groundwater for domestic purposes; 26 - sedimentation tank for physico-chemical treatment; 27 - sediment from the sump of physico-chemical treatment; 28 - silt water enriched with ions of RO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ and VFA, produced in an acidifier, operating on crude sediment from primary sedimentation tanks in the regime of the first stage of anaerobic digestion, 29 - acidifier.

The inventive method for removing phosphorus from the wastewater involves passing the wastewater through the primary clarifiers 1 and aeration tanks 2. The sludge mixture, passing through the secondary clarifiers 3, is divided into two components: the biologically purified wastewater 9 is supplied for further processing, and the activated sludge 10 circulating and excess, is sent to the mixer 8, and then to the sludge compactors 4. Microorganisms of activated sludge, being in anaerobic conditions, are able to release phosphorus into the environment in the form of PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ . To intensify the process of phosphorus release, and hence reduce the volume of sludge compactors, sludge water 19 from acidifier 29 enriched in VFA is introduced into mixer 8. The production of VFA in the acidifier occurs as a result of the first stage (acidic or hydrogen) of anaerobic digestion of the crude sediment 18 coming from the primary settling tanks. Partially fermented and compacted sediment 20 from the acidifier is sent for further processing - thickening, stabilization and dehydration. Compacted activated sludge depleted in phosphorus ions 11 is discharged from the sludge compactor. Most of it 12 is returned to the aeration tank, where in the presence of dissolved oxygen and a sufficient amount of nutrient substrate, it begins to actively absorb phosphorus, and excess activated sludge 13 is removed for processing - thickening, stabilization and dehydration.

Since sludge water in the acidifier is enriched not only with VFA, but also with PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ then, to increase the effect of phosphorus removal from wastewater into sludge water from acidifier 29, a precipitate containing iron hydroxide is introduced before being fed into mixer 8 — waste from the production of water treatment facilities during the preparation of groundwater for domestic purposes 25. Then this mixture is sent to a sump physico-chemical treatment 26, in which the crystals of FeFO ₄ and MgNH ₄ PO ₄ · 6H ₂ O are precipitated. The settled crystals 27 are removed from the sump. Exempted from PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ but sludge-containing VFA containing 19 from the sedimentation tank of the physicochemical treatment (26) is sent to the mixer 8.

Silt water 14 enriched with PO ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ , in the mixer 5 it is mixed with Ca (OH) ₂ 21 and flocculant 22, for example VPK-402, praestol, polyox, and is sent to a sedimentation tank for physical and chemical treatment 6, in which crystals of Ca ₅ OH (PO ₄ ) ₃ and MgNH are precipitated ₄ PO ₄ · 6H ₂ O. The settled crystals 15 are removed from the sump and can be used as low-grade fertilizer. The clarified liquid 16 from the sump of the physicochemical treatment is sent to the carbonizer 7, where carbon dioxide (purified flue gases from the local boiler house) 23 is supplied to lower the pH to 8-8.5 and to bind Ca ²⁺ to form CaCO ₃ . Carbonated liquid 17 is discharged in front of the primary sumps for re-cleaning.

According to the claimed method, the effect of removing phosphorus from the wastewater is 92-98% with a degree of activated sludge recirculation of 1.0, a compaction time of 1-5 hours and a pH of the compacted circulating activated sludge of 6-7.5. Larger values of the effect correspond to a greater degree of compaction of sludge (65% sludge water, 35% of compacted sludge) and a higher concentration of activated sludge (9-12 g / l) loaded into the sludge compactor.

Thus, using the proposed method, high quality wastewater treatment is ensured and operating costs are reduced by mixing activated sludge from secondary sumps with sludge water freed from phosphoric acid ions in the sump of physical and chemical treatment and enriched in VFA produced in the acidifier working on crude sediment from primary sedimentation tanks in the mode of the first stage of anaerobic digestion.

Claims (1)

A method for removing phosphorus from wastewater, including mechanical, biological wastewater treatment and physicochemical purification of sludge water with the return of compacted activated sludge depleted in phosphorus from the sludge compactor to the aeration tank, characterized in that the sludge freed from phosphoric acid ions in the sump is physically -chemical purification and enriched with volatile fatty acids produced in the acidifier, working on crude sludge from primary sedimentation tanks in the mode of the first stage of anaerobic digestion, ivaetsya activated sludge from the secondary settling tanks and fed into ilouplotnitel.