Abstract:
The melt spinning process for artificial fibers has been studied by many research
groups throughout the world during the last four decades. However, all these works
considered the forward problem of simulating the process for a given set of parameters.
In this study we focus on the problems of parameter estimation and
optimization.
The phase-portrait of the melt spinning process is studied using simple mathematical
models. Newtonian, power-law, Maxwell-Oldroyd and non-Newtonian models are
considered. It is found that for the Maxwell-Oldroyd model, we can not set any
arbitrary value for the final take-up velocity.
An optimal control problem for a mathematical model of a melt spinning process is
considered. Newtonian, non-Newtonian, Maxwell-Oldroyd and crystallinity models
arc used to describe the rheology of the polymer, the fiber is made of. The extrusion
velocity of the polymer at the spinneret as well as the velocity and temperature of
the quench air and fiber length serve as control variables depending on the rheology
of the polymer. A constrained optimization problem is derived and the first-order
optimality system is set up to obtain the adjoint equations. Numerical solutions are
carried out using a steepest descent algorithm.
The stability of the melt spinning process with respect to parameters is investigated
using the method of linear stability analysis. Newtonian and non-Newtonian models
arc considered. The velocity and temperature of the quench air are considered
as parameters. It is found that the non-Newtonian model with the increasing air
velocity and air temperature, the critical draw ratio increases, i.e. stability improved.
