Hj. Odenthal et al., Physical and mathematical modelling of tundish flows using digital particle image velocimetry and CFD-methods, STEEL RES, 71(6-7), 2000, pp. 210-219
The flow in continuous casting tundishes is considerably responsible for th
e flotation of non-metallic inclusions and the quality of steel. Because te
sts in liquid steel can hardly be performed, water model testing considerin
g the geometric and dynamic similarity laws is often used. Here, quantitati
ve investigations with time and cost expensive laser measurement techniques
are possible. The digital particle image velocimetry (DPIV) can be seen as
a completion and is an effective method to obtain reliable results.
DPIV measurements on a 1:4 scaled model of a single strand tundish are carr
ied out which lead to a good interpretation of the dynamic flow phenomena.
The flow separates at the bottom of the tundish and a recirculating region
develops. Simultaneously, the jet out of the shroud induces a contra-rotati
ng double vortex and a short circuit flow along the side walls. Furthermore
, a decreasing water level in the physical model is investigated to simulat
e the ladle change. The experimental results are used to validate numerical
simulations on the basis of the Reynolds equations. In order to describe t
he turbulence, a two-equation model (realizable k-epsilon model) is used. T
he results obtained with this model correspond well with the DPIV data. The
basic intention of the present investigations is to transfer the numerical
simulation of the water flow to the melt flow in the next step. Thus, a hi
gh accuracy of the theoretical results can be guaranteed.