Material Derivation and Acceleration...contd. from previous slide
The above equations tell that the operator for
total differential with respect to time, D/Dt in a convective field is related to the
partial differential as:
Explanation of equation 7.2 :
The total differential D/Dt is known as the material or
substantial derivative with respect to time.
The first term¶/¶tin the right hand side of is known as temporal or local derivative which expresses the rate of change with time, at a fixed position.
The last
three terms in the right hand side of are together
known asconvective derivative which represents the time rate of change due to change in position in the field.
Explanation of equation 7.1
(a, b, c):
The terms in the left hand sides
of Eqs (7.1a) to (7.1c) are defined as x, y and z components
of substantial or material acceleration.
The first terms in
the right hand sides of Eqs (7.1a) to (7.1c) represent the
respective local or temporal accelerations, while the other
terms are convective accelerations.
Thus we can write,
(Material or substantial acceleration) = (temporal or local acceleration) + (convective acceleration)
Important points:
In a steady flow, the temporal acceleration is zero, since the velocity at any point is invariant with time.
In a uniform flow, on the other hand, the convective acceleration is zero, since the velocity components are not the functions of space coordinates.
In a steady and uniform flow, both the temporal and convective acceleration vanish and hence there exists no material acceleration.
Existence of the components of acceleration for different types of flow is shown in the table below.