Hydrodynamic methods velocity profile

The rotating disc electrode (RDE) is the classical hydrodynamic electroanalytical technique used to limit the diffusion layer thickness. However, readers should also consider alternative controlled flow methods including the channel flow cell (38), the wall pipe and wall jet configurations (39). Forced convection has several advantages which include (1) the rapid establishment of a high rate of steady-state mass transport and (2) easily and reproducibly controlled convection over a wide range of mass transfer coefficients. There are also drawbacks (1) in many instances, the construction of electrodes and cells is not easy and (2) the theoretical treatment requires the determination of the solution flow velocity profiles (as functions of rotation rate, viscosities and densities) and of the electrochemical problem very few cases yield exact solutions. 

In this chapter, emphasis will be given to heat transfer in fast fluidized beds between suspension and immersed surfaces to demonstrate how heat transfer depends on gas velocity, solids circulation rate, gas/solid properties, and temperature, as well as on the geometry and size of the heat transfer surfaces. Both radial and axial profiles of heat transfer coefficients are presented to reveal the relations between hydrodynamic features and heat transfer behavior. For the design of commercial equipment, the influence of the length of heat transfer surface and the variation of heat transfer coefficient along the surface will be discussed. These will be followed by a description of current mechanistic models and methods for enhancing heat transfer on large heat transfer surfaces in fast fluidized beds. Heat and mass transfer between gas and solids in fast fluidized beds will then be briefly discussed. 

The velocity and concentration profiles are developed along the HFs by means of the mass conservation equation and the associated boundary conditions for the solute in the inner fluid. This analysis separates the effects of the operation variables, such as hydrodynamic conditions and the geometry of the system, from the mass transfer properties of the system, described by diffusion coefficients in the aqueous and organic phases and by membrane permeability. The solution of such equations usually involves numerical methods. Different applications can be found in the literature, for example, separation and concentration of phenol, Cr(VI), etc. [48-51]. 

It should be noted that all investigations of flow stability of polymerizing liquids are few in number and have been carried out up till now only for unidimensional problems. The problem of stability of steady rheokinetic two-dimensional flows to local hydrodynamic perturbations has not been discussed in the literature yet. Obviously the problem can be solved (the solution is difficult from the technical point of view), for example, by numerical methods solving the problem on unsteady development of the flow of polymerizing mass directly after a forced local change of the profile of the flow velocity. 

The ions in the same direction as the EOF are moved faster, while the movement against the EOF is slowed down. Neutral species move at the same rate as EOF. The important feature of EOF is that fluid is electrically driven and there is no pressure drop across the overall capillary. This is in contrast to the hydrodynamic flow using pressure-driven methods such as HPLC, which is shown in Fig. 2. The advantage is the occurrence of a flat profile plug with the same velocity driven by EOF regardless of their cross-sectional position in the capillary. This can give rise to a narrow zone and higher separation efficiency for CE method. 

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