On the mechanism of drag reduction in turbulent flow of viscoelastic liquids

Velocity profiles m turbulent pope flow of drag-reducmg hqmds have been measured by means of Pltot tubes previously cahbrated by towmg The results are compared wtth classuxl Newton-Ian velocity profiles, and differences are discussed A quahtatlve mslght mto the mechamsm of drag reduction IS thus obt

Early work in catalyst deactivation usually involved empirical methods specific for a particular reaction. HOWever, more recently, fundamental approaches, involving direct gradient search techniques or indirect variational Pommersheim. methods, have been used to model catalyst deactivation

On the basis of Kolmogoroff's theory of local turbulent isotropy, an attempt is made to describe quantitatively the mass transfer process in liquid-liquid dispersion systems. On condition that the mass transfer resistance is located in the continuous phase, equations are developed for the two extrem

and to indicate potential control difficulties. A similar analysis (Tung and Edgar, 1979) for a fluid catalytic cracker has also highlighted potential difficulties with single loop control. Therefore the dynamic RGA usefully augments the information provided by d static RGA. The analysis can be impl