The surface—S—of the body consists of parts on which
boundary conditions can be prescribed——and
parts that can interact with nearby surfaces of other
bodies—.
Prescribed boundary conditions include the electrical potential,
;
temperature, ;
electrical current density, ;
heat flux, ;
and surface convection and radiation conditions. The surface interaction model
includes heat conduction and radiation effects between the interface surfaces
and electrical current flowing across the interface. Heat conduction and
radiation are modeled by
and
respectively, where
is the temperature on the surface of the body under consideration,
is the temperature on the surface of the other body,
is the value of absolute zero on the temperature scale being used,
is the gap thermal conductance,
is the average interface temperature,
is the average of any predefined field variables at A and B, and
F and
are constants.
The electrical current flowing between the interface surfaces is modeled as
where
is the electrical potential on the surface of the body under consideration,
is the electrical potential on the surface of the other body, and
is the gap electrical conductance. The electrical energy dissipated by the
current flowing across the interface,
is released as heat on the surfaces of the bodies:
where
is an energy conversion factor and f specifies how the
total heat is distributed between the interface surfaces.
is evaluated at the end of the time increment in a steady-state analysis, and
an averaged value over the time increment is used in a transient analysis. This
is described in detail in
Heat generation caused by electrical current.
Introducing the surface interaction effects and electrical energy released
as thermal energy, the governing electric and thermal equations become
and