Liquid backmixing in bubble columns and the axial dispersion coefficient

## Ahstraet -A new graphtcal method of fincbng axial dispersion coefficients m a bubble column IS developed This method requues only the area above an experimental curve, thus IS simpler than the conventional method of curve fittmg The new method IS used to find the dimensIonless chspersion number

## Abstract Liquid mixing has been studied in a 1 m diameter bubble column, with and without internals (vertical cooling tubes). The presence of internals significantly affects both large scale recirculation and local dispersion. The most common approach to model liquid mixing is the one‐dimensiona

A phenomenological model for liquid mixing, that captures the essence of the ob-Served physical phenomena in bubble columns, is presented. In this model, mixing of the liquid phase is considered to be primarily due to convective recirculation and turbulence caused by the rising gas bubbles. The mixi

Gas holdups and volumetric mass transfer coefficients k,a are studied in a bubble column of 0.095 m dia. with 50 different gas-liquid systems comprising pure and mixed organic liquids and various gases. The gas holdups measured in pure organic liquids can be represented by existing correlations but