With an ever-increasing demand for

With an ever-increasing demand for food fish and cost saving in
production, large-scale fish culturists havemoved production into fewer
but larger culture tanks (Timmons et al., 1998). An advantage of large
culture tanks is that water quality analysis and feed distribution can be
achieved in the same time scale as smaller≤1m3 tanks, however, these
benefits do not come freely (Timmons et al., 1998). Uniform water
distribution andmixing, solids removal, grading and harvesting, and the
risk of large economic loss from tank failure are just some of the
difficulties that arise when up-scaling production.
It is generally easier to achieve good water quality in smaller
≤1m3 tank systems due to the high overall rate of water exchange.
This results in increased dissolved oxygen and removal of wastes.
Hydraulic design of larger tanks is critical due to higher hydraulic
retention times (Timmons et al., 1998).
In commercial aquaculture systems it is most common to find
rectangular and circular geometries (Masaló and Llorà, 2008). Rectangular
geometries tend to cost less to construct but are well known to
have lowmixing zones, also known as dead spots or dead volumes (Oca
and Masaló, 2007). Dead volumes lead to the accumulation of biosolids
(faecal solids and uneaten feed) at the base of the tank (Oca and Masaló,
2007). Circular geometries allow a uniform flow pattern achieving
greater mixing ability over rectangular geometries (Masaló and Llorà,
2008), thus leading to lower levels of biosolid accumulation. Diameter/
depth ratios of between 5:1 and 10:1 should be employed to prevent