65

Under equilibrium, these forces balance each other, i.e. equal and

opposite,

-

=

-2m17-

(3.3.6)

The velocity gradient for the particular laminar layer of fluid is therefore,

(3.3.7)

Substituting for the pressure gradient from equation (3.3.3), we have the

relation between the velocity gradient and pressure gradient,

-

-

-

(3.3.8)

Notice that the velocity gradient is in the radial direction, i.e. across the

vessel, whereas the pressure gradient is in the longitudinal direction, i.e.

along the vessel axis. Velocity at radius r across the vessel can be

readily obtained by integration of (3.3.7)

(3.3.9)

where

k

is the constant

integration, obtainable by applying the

boundary condition that the velocity of fluid at the vessel wall (r=ri) is

zero, i.e. v(r=ri)

=

We have,

Thus, velocity is maximum, or vmax, when

r=O,

or along the axis,

(3.3.1

(3.3.1