This study considers steady, laminar pow of two viscous, incompressible, el
ectrically-conducting and heat-generating or absorbing immiscible fluids in
art infinitely-long impermeable parallel-plate channel piled with a unifor
m porous medium. A magnetic field of uniform strength is applied normal to
the flow direction. The channel walls are assumed to be electrically noncon
ducting and are maintained at two different temperatures. When present, the
porous medium is assumed to act as an electrical insulator and that it is
in local thermal equilibrium with the fluid The transport properties of bot
h fluids are assumed to be constant. This study is expected to be useful in
understanding the influence of the presence of slag layers on the flow and
heat transfer aspects of coal-fired Magnetohydrodynamic (MHD) generators w
hen the porous medium is absent and the effects of thermal buoyancy and a m
agnetic field on enhanced oil recovery and filtration systems where the por
ous medium is present. The problem is formulated by employing the balance l
aws of mass, linear momentum, and energy for both phases. Continuous condit
ions for the velocity and temperature as well as the shear stress and heat
flux of both phases at the interface are employed. The resulting governing
ordinary differential equations are solved numerically subject to the bound
ary and interface conditions for the velocity and temperature distributions
of both fluids in the channel. Analytical solutions for a special case of
the problem where the porous medium is absent or only its inertia effect is
neglected are obtained. Comparisons with previously reported velocity prof
iles are performed and excellent agreements are obtained. A parametric stud
y illustrating the influence of the physical parameters involved in the pro
blem is conducted and the results are presented graphically and discussed [
S0098-2202(00)02101-5].