Methods Aeration of liquids (usually water) is achieved by: • passing air through the liquid by means of the
Venturi tube,
aeration turbines or
compressed air which can be combined with diffuser(s) air stone(s), as well as
fine bubble diffusers,
coarse bubble diffusers or linear aeration tubing. Ceramics are suitable for this purpose, often involving dispersion of fine air or gas bubbles through the porous ceramic into a liquid. The smaller the bubbles, the more gas is exposed to the liquid increasing the gas transfer efficiency. Diffusers or
spargers can also be designed into the system to cause turbulence or mixing if desired. Porous ceramic diffusers are made by fusing aluminum oxide grains using porcelain bonds to form a strong, uniformly porous and homogeneous structure. The naturally hydrophilic material is easily wetted resulting in the production of fine, uniform bubbles. On a given volume of air or liquid, the
surface area changes proportionally with drop or bubble size, the very surface area where exchange can occur. Utilizing extremely small bubbles or drops increases the rate of
gas transfer (aeration) due to the higher contact surface area. The pores which these bubbles pass through are generally micrometre-size.
Uses of aeration of liquids • To smooth (
laminate) the flow of tap water at the faucet. • Production of
aerated water or
cola for drinking purposes. • Secondary treatment of
sewage or
industrial wastewater through use of aerating mixers/
diffusers. • To increase the
oxygen content of water used to house animals, such as
aquarium fish or
fish farm • To increase oxygen content of
wort (unfermented beer) or
must (unfermented wine) to allow yeast to propagate and begin
fermentation. • To dispel other dissolved gases such as
carbon dioxide or
chlorine. • In chemistry, to oxidise a compound dissolved or suspended in water. • To induce mixing of a body of otherwise still water. •
Pond aeration. == Aeration of liquid solids ==