Treatment of textile wastes utilizing a lime-polyelectrolyte system
The feasibility of the excess lime process for color removal from textile dye wastes was evaluated. The lime dosages were optimized by using anionic, cationic, and nonionic polyelectrolytes as coagulant aids. The effect of the process on the removal of organic pollutants was determined. The time int...
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ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-710662020-09-29T05:48:29Z Treatment of textile wastes utilizing a lime-polyelectrolyte system Wilbourn, Edward Gray Sanitary Engineering LD5655.V855 1970.W52 Textile industry -- Waste disposal Textile waste The feasibility of the excess lime process for color removal from textile dye wastes was evaluated. The lime dosages were optimized by using anionic, cationic, and nonionic polyelectrolytes as coagulant aids. The effect of the process on the removal of organic pollutants was determined. The time interval between coagulant additions was analyzed. Color reductions of at least 94 per cent were obtained by the lime and lime-polyelectrolyte processes. The lime dosage of 980 to 1,060 ppm was decreased by at least 30 per cent using 5 ppm polyelectrolyte dosages. The processes reduced the Total Organic Carbon concentration by 73 per cent approximately, the Chemical Oxygen Demand by 50 per cent, and suspended solids by about 85 to 90 per cent. The excess lime process was more efficient in removing organic matter than the lime-polyelectrolyte processes, and also incurred the least chemical coagulant cost. The excess lime process was most effective at 30 minutes flocculation and 30 minutes settling. The lime-polyelectrolyte processes were more effective when the polyelectrolyte was added after about 30 minutes lime flocculation and settled for 5 minutes. The lime-polyelectrolyte processes produced a floe which settled rapidly. The volume of sludge produced was about 8.1 to 12.8 per cent, resulting in a sludge to supernatant ratio range of 1:7 to 1:11. The lime-polyelectrolyte sludge volumes were usually higher than the lime sludge volumes. Master of Science 2016-05-23T14:57:39Z 2016-05-23T14:57:39Z 1970 Thesis Text http://hdl.handle.net/10919/71066 en_US OCLC# 20498434 In Copyright http://rightsstatements.org/vocab/InC/1.0/ xi, 188 leaves application/pdf application/pdf Virginia Polytechnic Institute and State University |
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LD5655.V855 1970.W52 Textile industry -- Waste disposal Textile waste |
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LD5655.V855 1970.W52 Textile industry -- Waste disposal Textile waste Wilbourn, Edward Gray Treatment of textile wastes utilizing a lime-polyelectrolyte system |
description |
The feasibility of the excess lime process for color removal from textile dye wastes was evaluated. The lime dosages were optimized by using anionic, cationic, and nonionic polyelectrolytes as coagulant aids. The effect of the process on the removal of organic pollutants was determined. The time interval between coagulant additions was analyzed.
Color reductions of at least 94 per cent were obtained by the lime and lime-polyelectrolyte processes. The lime dosage of 980 to 1,060 ppm was decreased by at least 30 per cent using 5 ppm polyelectrolyte dosages. The processes reduced the Total Organic Carbon concentration by 73 per cent approximately, the Chemical Oxygen Demand by 50 per cent, and suspended solids by about 85 to 90 per cent. The excess lime process was more efficient in removing organic matter than the lime-polyelectrolyte processes, and also incurred the least chemical coagulant cost. The excess lime process was most effective at 30 minutes flocculation and 30 minutes settling. The lime-polyelectrolyte processes were more effective when the polyelectrolyte was added after about 30 minutes lime flocculation and settled for 5 minutes. The lime-polyelectrolyte processes produced a floe which settled rapidly.
The volume of sludge produced was about 8.1 to 12.8 per cent, resulting in a sludge to supernatant ratio range of 1:7 to 1:11. The lime-polyelectrolyte sludge volumes were usually higher than the lime sludge volumes. === Master of Science |
author2 |
Sanitary Engineering |
author_facet |
Sanitary Engineering Wilbourn, Edward Gray |
author |
Wilbourn, Edward Gray |
author_sort |
Wilbourn, Edward Gray |
title |
Treatment of textile wastes utilizing a lime-polyelectrolyte system |
title_short |
Treatment of textile wastes utilizing a lime-polyelectrolyte system |
title_full |
Treatment of textile wastes utilizing a lime-polyelectrolyte system |
title_fullStr |
Treatment of textile wastes utilizing a lime-polyelectrolyte system |
title_full_unstemmed |
Treatment of textile wastes utilizing a lime-polyelectrolyte system |
title_sort |
treatment of textile wastes utilizing a lime-polyelectrolyte system |
publisher |
Virginia Polytechnic Institute and State University |
publishDate |
2016 |
url |
http://hdl.handle.net/10919/71066 |
work_keys_str_mv |
AT wilbournedwardgray treatmentoftextilewastesutilizingalimepolyelectrolytesystem |
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1719347010831646720 |