The Basics of Phosphorus Removal
The Basics of Phosphorus Removal
Source https://www.michigan.gov
Prepared by
Michigan Department of Environmental Quality
Operator Training and Certification Unit
Usually dispatched in 2 to 3 days
Usually dispatched in 2 to 3 days
Category:
Drinking Water Treatment
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Advancing Water, Sanitation and Hygiene (WASH) in Panchayats
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Advancing Water, Sanitation and Hygiene (WASH) in Panchayats
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Appropriate Technologies For Drinking Water Treatment In Mediterranean Countries
This paper aims at analyzing the drinking water issue in the Mediterranean region, highlighting the principal problems and the appropriate technologies applicable in the different countries. The countries of this area are characterized by a huge variety from social, cultural, economic and environmental point of view. In particular, water distribution is inhomogeneous between the North, East, and South; even the type of water sources and the related quantity and quality problems differ country by country. Potable water comes from brackish and seawater, surface water, groundwater and water reservoirs with each source face different issues. The main problem of brackish and seawater for example is the high salinity and the contamination by disinfection byproducts, in addition to the microbiological and chemical contamination due to human activities that characterize also other surface water sources. Groundwater is also affected by human activity and it is not exempted from salinity because of the water intrusion. Moreover, water reservoirs are often contaminated by seasonal algal blooms. Technologies applied for drinking water treatment vary country by country. The paper presents the main treatment processes
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Biological Biofilm Processes
•Used for removal of organic pollutants from wastewaters
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–low cost
–effective in removal of a wide range of organic contaminants
–effective in removal of colloidal organics
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• Evaluate Fe-GAC media performance in rapid small scale column tests (RSSCTs) to assess arsenic removal in a more dynamic treatment system.
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• Characterize Fe-GAC media.
• Correlate performance and media characterization for possible selection of two media for a future second phase of this project.
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