Dispersion in core–annular flow with a solid annulus

In this paper we study the steady annular flow of a viscous fluid into an annular pipe and discuss the effects of the size of the core on the flow properties.

For the nonlinearized test, the IP is about 15 dB above the 3 compression point, and for the linearized test, the IP is 30 3 dB above the amplifier's compression point, thus providing an improvement of 15 dB. ## IV. CONCLUSIONS A simple, yet effective feedforward amplifier system with frequency tu

= velocity integrals defined by Eqs. 17 and 18 = velocity function, defined by Eq. 6 = constants, defined by Eqs. 1 to 3 and 12 to 14 = jet exit radius (m) = radius of potential core (m) = radius of jet edge (m) = velocity at jet exit (m/s) = length of potential core (m) = radial distance, Figure 1

In processes with immobilized cells mass transfer across the boundary layer surrounding the support often plays an important role. Relatively little is known about external mass transfer as a function of the superÐcial gas velocity in bioreactors such as air-lift loop reactors. In this work ion-exch

A computational study is performed on two-dimensional mixed convection in an annulus between a horizontal outer cylinder and a heated, rotating, eccentric inner cylinder. The computation has been done using a non-orthogonal grid and a fully collocated finite volume procedure. Solutions are iterated