For the elimination of hazardous chemicals from the water, many
treatment procedures have been applied. The processes involved in removing the contaminants include physical processes such as
settling and
filtration,
chemical processes such as
disinfection and
coagulation, and biological processes such as
slow sand filtration. A combination selected from the following processes (depending on the season and contaminants and chemicals present in the raw water) is used for municipal drinking water treatment worldwide.
Chemical Different chemical procedures for the conversion into final products or the removal of pollutants are used for the safe disposal of contaminants. • Pre-
chlorination for algae control and arresting biological growth. •
Aeration along with pre-chlorination for removal of dissolved iron when present with relatively small amounts of manganese. • Disinfection for killing bacteria, viruses and other pathogens, using chlorine, ozone and ultra-violet light.
Physical Physical techniques of water/waste water treatment rely on physical phenomena to complete the removal process, rather than biological or chemical changes. For solids separation that is the removal of
suspended solids trapped in the floc. •
Filtration is the technique of removing pollutants based on their particle size.
Pollutant removal from waste water permits water to be reused for a variety of purposes. The types of filters used in the procedure differ depending on the contaminants present in the water. Particle filtration and
Membrane filtration are the two main forms of waste water filtration. •
Dissolved air flotation (
Degasification) is the process of removing dissolved gases from a
solution .
Henry's law states that the amount of dissolved gas in a liquid is proportionate to the partial pressure of the gas. Degasification is a low-cost method of removing
carbon dioxide gas from waste water that raises the
pH of the water by removing the gas. • Coagulant aids, also known as
polyelectrolytes – to improve coagulation and for more robust floc formation. • Polyelectrolytes or also known in the field as
polymers, usually consist of either a positive or negative charge. The nature of the polyelectrolyte used is purely based on the source water characteristics of the treatment plant. • These will usually be used in conjunction with a primary coagulant such as ferric chloride, ferric sulfate, or alum.
Chemical precipitation is a common process used to reduce
heavy metals concentrations in wastewater. The dissolved metal ions are transformed to an insoluble phase by a chemical interaction with a
precipitant agent such as lime. In industrial applications stronger alkalis may be used to effect complete precipitation. In drinking water treatment, the
common-ion effect is often used to help reduce water hardness. Flotation uses bubble attachment to separate solids or dispersed liquids from a liquid phase.
Membrane filtration Membrane filtration can remove suspended solids and organic components, and inorganic pollutants such heavy metals. For heavy metal removal, several forms of
membrane filtration, such as
ultrafiltration,
nanofiltration, and
reverse osmosis, can be used depending on the particle size that can be maintained.
Antiscalants can help maintain membrane filtration. Some small molecules can
permeate to some extent through
membranes.
Electrochemical treatment techniques • Electrodialysis (ED) • Membrane electrolysis (ME) • Electrochemical precipitation (EP)
Activated carbon Activated carbons (ACs) or biological-activated carbon (BAC) are effective adsorbents for a wide variety of contaminants. The adsorptive removal of color, aroma, taste, and other harmful organics and inorganics from drinking water and wastewater is one of their industrial applications. Both a high surface area and a large
pore size can improve the efficiency of activated carbon. Activated carbon was utilized by a number of studies to remove heavy metals and other types of contaminants from wastewater. The cost of activated carbon is rising due to a shortage of commercial activated carbon (AC). Because of its high surface area, porosity, and flexibility, activated carbon has a lot of potential in wastewater treatment. Through two distinct
biological process, such as
biological oxidation and
biosynthesis, microorganisms can degrade organic materials in wastewater. Microorganisms involved in wastewater treatment produce end products such as
minerals,
carbon dioxide, and
ammonia during the biological oxidation process. The minerals (products) remained in the wastewater and were discharged with the
effluent.
Microorganisms use organic materials in wastewater to generate new microbial cells with dense biomass that is eliminated by
sedimentation throughout the biosynthesis process. == Standards ==