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Dr. Bajnóczy Gábor Tonkó Csilla

BUDAPEST UNIVERSITY OF TECHNOLOGY AND ECONOMICS. DEPARTMENT OF CHEMICAL AND ENVIRONMENTAL PROCESS ENGINEERING. FACULTY OF CHEMICAL AND BIOCHEMICAL ENGINEERING. DETERGENT CONTAINING WASTEWATERS. Dr. Bajnóczy Gábor Tonkó Csilla. SURFACE ACTIVE CHEMICAL AGENT CONTAINING WASTEWATERS.

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Dr. Bajnóczy Gábor Tonkó Csilla

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  1. BUDAPEST UNIVERSITY OF TECHNOLOGY AND ECONOMICS DEPARTMENT OF CHEMICAL AND ENVIRONMENTAL PROCESS ENGINEERING FACULTY OF CHEMICAL AND BIOCHEMICAL ENGINEERING DETERGENT CONTAINING WASTEWATERS Dr. Bajnóczy Gábor Tonkó Csilla

  2. SURFACE ACTIVE CHEMICAL AGENT CONTAINING WASTEWATERS Surface active chemical agent: dissolved or dispersed in fluid (water), tending to adsorb on the surface of fluid changing the physical-chemical properties of the fluid surface. detergent: organic synthetic cleaning agent soap: sodium and potassium salt of saturated or unsaturated long carbon-chain carboxylic acid surface-active chemical agent detergent soap

  3. SURFACE ACTIVE CHEMICAL AGENT, SOURCES DETERGENT POLLUTION NATURAL: Algae bloom: significant surfaceactive compound → foaming HUMAN: Cleaning activities

  4. COMPONENTS OF DETERGENTS AND ENVIRONMENTAL ASPECTS 1. Surface active compounds a./ Anionic detergent: on straight carbon chain R1–COO– (carboxylate), R2–SO3– (sulphonate) and R3–SO4– (sulphate) groups, used in washing machines. Carbon-chain can’t be branched, carboxylates are especially fast biodegradable. Non-toxic, but high oxygen demanding materials in natural waters. b./ Cationic detergent: end of chain kvaterner ammonium group R-NH3+, antiseptic effect, used as rinsing material. Using is forbidden in washing powders: kills the micro organisms in technology of sewage water treatment. c./ Non-ionic detergent: the straight carbon-chain molecule contains partial negative charged alcoholic group or ether bond. Fine detergents, body wash. Carbon-chain can’t be branched, due to alcoholic group fast biodegradable. Non-toxic, but high oxygen demanding materials in natural waters.

  5. 2. Addidives to reduce water hardness Water hardness: caused by water dissolved calcium and magnesium salts of water. in soft water in hard water R – SO3- Na+ R – SO3- R – SO3 Ca++ Ca the non-polar and polar part remains active R – SO3- R – SO3 the non-polar and polar part cease, no washing effect a./ Old type water hardness reduction: trisodium - phosphate 2 Na3PO4 + 3 Ca 2+ = Ca3(PO4)2 + 3 Na+ precipitate Can not be applied in washing machines.

  6. b./ water-solube, complex forming, water hardness reducing additives (phosphorus-containing) Ca 2+ Mg 2+ large stability constant, watersoluble, Ca or Mg complex Na3P3O10 + + Na + • - non-toxic • non-corrosive • non-flammable • known substance • easy biodegradable • hydrolyzing on known compounds in water P3O10 5+ + 2 H2O = 2 HPO42- + H2PO4- Significant phosphorus load in natural water

  7. b./ water-solube, complex forming, water hardness reducing additives (phosphorus free) POLYCARBOXYLATES H2C = C – C = O H Maverage = 2 000 – 10 000 CO2Na acrylic acid sodium-polyacrylate n CO2Na H2C = C – C = O H + O = C C = C – C = O H H – acrylic acid maleic acid NaO2C CO2Na n sodium (acrylic acid -maleic) copolymer Mátlag = 20 000 – 70 000 polycarboxylates with Ca++ and Mg++ ions: form stable and water-soluble complex

  8. Composition of phosphate containing and phosphate free washing powder [%] P base P free sodium-tripolyphosphate 20 – 25 0 zeolite 0 25 polycarboxylates 0 5 organic phosphonates 0 – 0,2 0,4 sodium silicate 6 4 sodium carbonate 5 15 surface active agent 12 15 sodium perborate 14 18 activator 2 2,5 sodium sulphate 1 – 24 9 enzymes 1 0,5 sedimentation inhibitor 0,2 1 optical whitener 0,2 0,2 odorant varied Ion-exchange mineral: instead of expensive polycarboxylate, makes the textile greyish, increases wastewater sludge also in P-free, because zeolite is slow and replaces only calcium ion to sodium corrosion inhibitor additive alkaline, more in P-free more in P-free, because sodium-tripolyphosphate helps better the washing effect than carboxylates disinfectant activator of desinfectant T < 60 °C due to zeolite more in P-free

  9. DEGRADABILITY OF POLYCARBOXILATES Polycarboxylates: long chain -> hardly biodegradable. Shorter carbon-chain fractions: relatively fast degradation (8 – 15%). In spite of good water-solubility and long lifetime, the bioaccumulation hasn’t risk, because the large molecular compound can’t penetrate through the cell membrane. 90 – 95% removal efficiency can be achieved by wastewater treatment which Is due to the strong adsorption tendency on sludge. No enter into the natural water, no risk of heavy metal extraction from the mud.

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