RU2003111760A - METHOD AND DEVICE FOR SEWAGE TREATMENT (OPTIONS), COMPOSITION FOR SEWAGE TREATMENT AND METHOD FOR PRODUCING WASTE WATER (OPTIONS) - Google Patents

Claims (69)

1. A method of treating wastewater containing dissolved metals, characterized in that the wastewater is supplied to the first wastewater treatment tank and their flow rate and redox potential are measured, the pH of the wastewater is set in the range from 8.5 to 10.2, and the first and second liquid compositions are mixed with the wastewater, and the first liquid composition is reacted with at least one metal in the wastewater either with the precipitation of the metal from the solution, or with its transformation into a form that allows precipitation it from the solution under the action of the second liquid composition, and the metal is bound to prevent its re-dissolution in the solution, the amount of the first liquid composition added to the wastewater is determined, at least in part, based on the value of the redox potential of the wastewater and, at least in part, on the basis of the wastewater flow rate, and the second liquid composition is reacted with at least one metal in the wastewater to precipitate it from the solution and bind to metal to prevent it from re-dissolving in the solution, the amount of the second liquid composition added to the wastewater being determined, at least in part, based on the amount of the first composition being added to the wastewater. 2. The method according to claim 1, characterized in that the wastewater is additionally supplied to a second wastewater treatment tank and a third liquid composition is mixed with the wastewater, whereby flocculating and / or coagulating the precipitated metals, the amount of the third liquid composition being carried out, added to the wastewater is determined, at least in part, based on the amount of the first composition added to the wastewater, and any flocculated and / or coagulated precipitated metals are separated from the clean dy. 3. The method according to claim 2, characterized in that the fourth liquid composition is additionally mixed with the wastewater, whereby the precipitated metals are flocculated and / or coagulated, and the amount of the fourth liquid composition added to the wastewater is determined at least in part based on the amount of the first liquid composition added to the wastewater. 4. The method according to claim 1, characterized in that for each one part of the added first composition add 1.5-2.2 parts of the second liquid composition. 5. The method according to claim 2, characterized in that for each one part of the added first composition, half of the third liquid composition is added. 6. The method according to claim 2, characterized in that for each one part of the added first composition add one fourth of the fourth liquid composition. 7. The method according to claim 1, characterized in that the pH level of the wastewater is set in the range from 9.3 to 9.5. 8. The method according to claim 1, characterized in that as the first liquid composition, iron (II) sulfate, aluminum sulfate, acid, aluminum salts and a cationic polyelectrolyte are selected. 9. The method according to claim 1, characterized in that as the second liquid composition, calcium hydroxide, sodium dimethyldithiocarbamate, calcium hypochlorite, sodium hydroxide, Metex EPS, calcium salts and at least two polymer coagulants are selected. 10. The method according to claim 2, characterized in that the first cationic polyelectrolyte, the second cationic polyelectrolyte, acrylamide, cationic monomer and polymer with a high molecular weight and high charge density are selected as the third liquid composition. 11. The method according to claim 2, characterized in that as the third liquid composition, a polymer with a high molecular weight and high charge density, an anionic polymer with a high molecular weight and a liquid emulsion of anionic flocculant with a high molecular weight and high charge density are selected. 12. The method according to claim 3, characterized in that the first cationic polyelectrolyte, the second cationic polyelectrolyte, acrylamide, cationic monomer and polymer with a high molecular weight and high charge density are selected as the fourth liquid composition. 13. The method according to claim 3, characterized in that as the fourth liquid composition, a polymer with a high molecular weight and high charge density, an anionic polymer with a high molecular weight and a liquid emulsion of an anionic flocculant with a high molecular weight and high charge density are selected. 14. The method according to claim 1, characterized in that the pH level is established by adding to the wastewater the appropriate amounts of an acid solution and / or alkali solution. 15. The method according to 14, characterized in that sulfuric acid is added. 16. The method according to 14, characterized in that phosphoric acid is added. 17. A method of treating wastewater containing dissolved metals, carried out inside the pipeline, characterized in that they set the pH of the wastewater in the range from 8.5 to 10.2, measure the flow rate of wastewater flowing through the pipeline, measure the redox potential wastewater, and the first and second liquid compositions are added to the wastewater inside the pipeline, and the first liquid composition is reacted with at least one metal in the wastewater or with the precipitation of the metal from the plant a thief, or by converting it into a form that will allow it to precipitate from solution under the action of a second liquid composition, and at the same time bind the metal to prevent its re-dissolution in the solution, and the amount of the first composition added to the wastewater is determined, at least in part , based on the value of the redox potential of the wastewater and, at least in part, on the basis of the value of the wastewater flow rate, and the second liquid composition is reacted with at least one metal in the wastewater x with its precipitation from the solution and binding to the metal to prevent its re-dissolution in the solution, the second composition being added downstream of the wastewater relative to the place of addition of the first composition, and the amount of the second liquid composition added to the wastewater is determined at least in part, based on the amount of the first composition added to the wastewater. 18. The method according to 17, characterized in that the third liquid composition is additionally added to the wastewater, whereby the precipitated metals are flocculated and / or coagulated, and the third composition is added downstream of the wastewater relative to the place of addition of the second composition, and the amount of the third composition added to the wastewater is determined, at least in part, based on the amount of the first composition added to the wastewater, and flocculated and / or coagulated precipitated m are separated Tully from pure water. 19. The method according to p. 18, characterized in that the fourth liquid composition is additionally added to the wastewater, whereby the precipitated metals are flocculated and / or coagulated, and the fourth composition is added downstream of the wastewater relative to the place of addition of the third composition, and the amount of the fourth composition added to the wastewater is determined, at least in part, based on the amount of the first composition added to the wastewater. 20. The method according to 17, characterized in that establish the pH of the wastewater in the range from 9.3 to 9.5. 21. A method for periodically treating wastewater containing dissolved metals, characterized in that the wastewater is supplied to the wastewater treatment tank, the oxidation-reduction potential of wastewater is measured, the pH of the wastewater is set in the range from 8.5 to 10.2 by adding the appropriate amounts of an acid solution and / or alkali solution and mixing the wastewater with the first and second liquid compositions, the reaction of the first liquid composition with at least one metal in the effluent x water either with the precipitation of the metal from the solution, or with its transformation into a form that will allow it to precipitate from the solution under the action of the second liquid composition, and at the same time bind the metal to prevent its re-dissolution in the solution, the amount of the first liquid composition being added into wastewater, determined, at least in part, on the basis of the redox potential of the wastewater and, at least in part, on the basis of the amount of wastewater, and a second liquid setting with at least one metal in the wastewater with precipitation from the solution and binding to the metal to prevent its re-dissolution in the solution, the amount of the second liquid composition added to the wastewater being determined, at least in part, on the basis of the first composition added to wastewater. 22. The method according to item 21, wherein the third liquid composition is additionally mixed with wastewater, whereby the precipitated metals are flocculated and / or coagulated, and the amount of the third liquid composition added to the wastewater is determined at least partly based on the amount of the first composition added to the wastewater, and any flocculated and / or coagulated precipitated metals are separated from pure water. 23. The method according to item 22, wherein the fourth liquid composition is additionally mixed with the wastewater, whereby the precipitated metals are flocculated and / or coagulated, and the amount of the fourth liquid composition added to the wastewater is determined at least in part based on the amount of the first liquid composition added to the wastewater. 24. A wastewater treatment device, characterized in that it comprises a first wastewater treatment tank, a first continuous mixing device located inside the first wastewater treatment tank, redox potential measuring means, pH measuring means installed with level measurement capability the pH of the wastewater inside the first wastewater treatment tank, the acid solution feed line to the first wastewater treatment tank, the first metering pump, are installed with the ability to control the flow rate of the acid solution supplied to the first wastewater treatment tank, the alkali solution supply line to the first wastewater treatment tank, a second metering pump installed to adjust the flow rate of the alkali solution supplied to the first wastewater treatment tank, the feed line the first liquid composition in the first wastewater treatment tank, the third metering pump installed with the ability to control the flow rate of the first liquid composition supplied to the first tank wastewater bottoms, a line for supplying a second liquid composition to a first wastewater treatment tank, a fourth metering pump installed to adjust the flow rate of a second liquid composition supplied to the first wastewater treatment tank, a second wastewater treatment tank, a second continuous mixing device, located inside the second wastewater treatment tank, the wastewater supply channel from the first wastewater treatment tank to the second wastewater treatment tank, the supply line t a third liquid composition to the second wastewater treatment tank and a fifth metering pump installed to control the flow rate of the third liquid composition supplied to the second wastewater treatment tank. 25. The device according to p. 24, characterized in that it further comprises a supply line of the fourth liquid composition to the second wastewater treatment tank and a sixth metering pump installed to control the flow of the fourth liquid composition supplied to the second wastewater treatment tank. 26. The device according to paragraph 24, wherein the means for measuring the redox potential is installed with the possibility of measuring the redox potential of the wastewater inside the first wastewater treatment tank. 27. The device according to p. 24, characterized in that the means for measuring the redox potential is installed with the possibility of measuring the redox potential of the wastewater supplied to the first wastewater treatment tank. 28. A device for treating wastewater inside a pipeline, characterized in that it contains at least one static mixer, means for measuring the redox potential, installed with the ability to measure the potential of wastewater inside the pipeline, a means for measuring pH, installed with the ability to measure the pH level wastewater inside the pipeline, the line for supplying the acid solution to the pipeline, the first metering pump installed with the ability to control the flow rate of the acid solution supplied about in the pipeline, the line for supplying the alkali solution to the pipeline, a second metering pump installed with the ability to control the flow rate of the alkali solution supplied to the pipeline, the line for supplying the solution of the first liquid composition in the pipeline, the third metering pump installed with the ability to control the flow rate of the first liquid the composition supplied to the pipeline, the supply line of the second liquid composition to the pipeline located downstream of the wastewater relative to the supply line of the first liquid composition, the fourth metering pump OP installed with the possibility of regulating the flow rate of the second liquid composition supplied to the pipeline, a supply line of the third liquid composition to the pipeline located downstream of the wastewater stream relative to the supply line of the second liquid composition, and a fifth metering pump installed with the ability to control the flow rate of the third liquid composition fed into the pipeline. 29. The device according to p. 28, characterized in that it further comprises a supply line of the fourth liquid composition to the pipeline located downstream of the wastewater relative to the supply line of the third liquid composition, and a sixth metering pump installed with the ability to control the flow rate of the fourth liquid composition fed into the pipeline. 30. Composition for treating wastewater, characterized in that it mainly consists of iron (II) sulfate, aluminum sulfate, an acid solution and a solution containing aluminum salts and polymer coagulant. 31. The composition according to p. 30, characterized in that for every 1 g of the used solution accounts for from 28 to 35 g of iron sulfate (II). 32. The composition according to p. 30, characterized in that for every 1 g of the used solution accounts for from 10 to 20 g of aluminum sulfate. 33. The composition according to p. 30, characterized in that for every 1 g of the solution used accounts for 10 to 16 ml of an acid solution. 34. The composition according to p. 30, characterized in that it further comprises water. 35. The composition according to p. 30, characterized in that the sulfate of iron (II) is a seven-water hydrate of sulfate of iron (II). 36. The composition according to p. 30, wherein the acid is a 75% solution of sulfuric acid. 37. The composition according to p. 30, characterized in that the solution containing aluminum salts and polymer coagulant, is a COAGULITE 200. 38. The method of preparing the composition according to p. 30, characterized in that water is supplied to the mixing tank and then iron (II) sulfate, aluminum sulfate, an acid solution, a mixture of aluminum salts and polymer coagulant are added and mixed with water. 39. Composition for treating wastewater, characterized in that it mainly consists of calcium hydroxide, sodium dimethyldithiocarbamate, calcium hypochlorite, sodium hydroxide, METEX EPS, a mixture of calcium salts and the first polymer coagulant and the second polymer coagulant. 40. The composition according to § 39, wherein the calcium hydroxide is presented in the form of dolomite hydrated lime type S. 41. The composition according to § 39, characterized in that for every 1 g of the used second polymer coagulant is from 15 to 25 g of calcium hydroxide. 42. The composition according to § 39, wherein the sodium dimethyldithiocarbamate is presented in the form of a 40% aqueous solution. 43. The composition according to § 39, characterized in that for every 1 g of the used second polymer coagulant is from 1.5 to 4.5 ml of sodium dimethyldithiocarbamate. 44. The composition according to § 39, wherein the calcium hypochlorite is presented in the form of INDUCOLOR. 45. The composition according to p. 39, characterized in that for every 1 g of the used second polymer coagulant is from 1.0 to 3.0 g of calcium hypochlorite. 46. The composition according to § 39, wherein the sodium hydroxide is presented in the form of a 50% aqueous solution. 47. The composition according to § 39, characterized in that for every 1 g of the used second polymer coagulant is from 10.0 to 16.0 ml of sodium hydroxide. 48. The composition according to p. 39, characterized in that for every 1 g of the used second polymer coagulant is from 0.01 to 2.0 ml METEX EPS. 49. The composition according to § 39, wherein the mixture of calcium salts and the first polymer coagulant is presented in the form of COAGULITE 300. 50. The composition according to § 39, characterized in that for every 1 g of the used second polymer coagulant is from 0.01 to 2.0 ml of a mixture of calcium salts and the first polymer coagulant. 51. The composition according to § 39, wherein the second polymer coagulant is presented in the form of COAGULITE EMR. 52. The composition according to § 39, characterized in that it further comprises water. 53. The method of preparing the composition according to § 39, characterized in that water is supplied to the mixing tank and then calcium hydroxide, METEX EPS, 40% aqueous solution of dimethyldithiocarbamate, calcium hypochlorite, 50% hydroxide solution are added and mixed with water. sodium, a mixture of calcium salts and the first polymer coagulant and the second polymer coagulant. 54. A composition for treating wastewater, characterized in that it mainly consists of a first cationic polyelectrolyte, a solution containing a second cationic polyelectrolyte, acrylamide and a cationic monomer, and a polymer with a high molecular weight and high charge density. 55. The composition according to item 54, wherein each 1 g of the solution used accounts for from 0.01 to 2.0 ml of the first cationic polyelectrolyte. 56. The composition according to item 54, wherein each 1 g of the solution used accounts for from 0.01 to 2.0 ml of polymer. 57. The composition according to item 54, wherein it further comprises water. 58. The composition according to item 54, wherein the first cationic polyelectrolyte is presented in the form of CLARIFLOC C310. 59. The composition according to item 54, wherein the solution includes F04498SH. 60. The composition according to item 54, wherein the polymer is presented in the form of COAGULITE 402. 61. The method of obtaining the composition according to item 54, wherein water is supplied to the mixing tank and then the first cationic polyelectrolyte, a solution containing the second cationic polyelectrolyte, acrylamide and cationic monomer, and a polymer are added and mixed with water. 62. Composition for treating wastewater, characterized in that it mainly consists of a first anionic polymer with a high molecular weight and high charge density, a second anionic polymer with a high molecular weight and high charge density, a liquid emulsion of anionic flocculant with a high molecular weight and high charge density. 63. The composition according to p. 62, characterized in that the first anionic polymer with a high molecular weight and high charge density is presented in the form of FLOCULITE 600. 64. The composition according to p. 62, characterized in that the second anionic polymer with a high molecular weight and high charge density is presented in the form of FLOCULITE 550. 65. The composition according to p. 62, characterized in that the liquid emulsion of the anionic flocculant with a high molecular weight and high charge density is presented in the form of FLOCULITE 260. 66. The composition according to p. 62, characterized in that for every one milliliter of added liquid emulsion of anionic flocculant is from 5 to 15 g of the first anionic polymer. 67. The composition according to p. 62, characterized in that for every one milliliter of added liquid emulsion of anionic flocculant is from 5 to 15 g of the second anionic polymer. 68. The composition according to p. 62, characterized in that it further comprises water. 69. The method of preparing the composition according to p. 62, characterized in that water is supplied to the mixing tank and then the first anionic polymer, the second anionic polymer and the liquid emulsion of the anionic flocculant are added and mixed with water.