Some remarks on the effect of flow direction on steady-state multiplicity in bubble column reactors

It is concluded that the method used lo derive stability criteria for systems operated close IO incipient fluidization using porous distributors is not applicable to systems having large pressure fluctuations at distributor level, i.e. the majority of industrial systems.

An expaimental study has been aimed at Linking the extent of axial mixing m gas and liquid phas~ m tall bubble coltmm reactors with the respective bubbling regimes (homogeneous, tr~msition, hctcrogeneous) ¢ncotmtered in such reactors and with correnpondhag macro-scale flow patterns of b~h phases. Th

The effect of different values of Peclet numbers (Pee # Pe,,) on the region of multiplicity in adiabatic tubular reactors is followed. A modification of the mapping technique for this case is proposed. The results of calculation are presented in graphs. For the range of experimentally observed ratio

The effect of micromixing on steady-state multiplicity is not displayed by the universal reaction model (URM) since this URM has considered any chemical species having the same mixing time constant. The modified universal reaction model (MURM) is derived for overcoming the above limitation. The desi