Abstract
We present basic experimental data and the theoretical background of a novel technique for fiber spinning from polymer solutions. The principal feature of the advanced process is realization of phase separation with detachment of a solvent, accompanied by the orientation of macromolecules, under the action of high extension rates. This is similar in some respects to dry spinning, though the driving force is not diffusion with subsequent evaporation of a solvent but redistribution of polymer-solvent interactions in favor of polymer-polymer and solvent-solvent ones governed by mechanical stresses. A promise of this approach has been demonstrated by experiments performed with polyacrylonitrile solutions in different solvents and solutions of the rigid-chain aromatic polyamide. We examined mechanotropic fiber spinning in model experiments with stretching jets from a drop of polymer solution in different conditions, and then demonstrated the possibility of realizing this process in the stable long-term continuous mode. During extension, phase separation happens throughout the whole section of a jet, as was confirmed by visual observation. Then a solvent diffuses on a jet surface, forming a liquid shell on the oriented fiber. Instability of this cover due to surface tension leads either to formation of separate solvent drops “seating” on the fiber or to the flow of a solvent down to the Taylor cone. The separate liquid droplets can be easily taken off a fiber. The physics underlying this process is related to the analysis of the influence of macromolecule coil-to-stretched chain transition on the intermolecular interaction.
Highlights
Extension of polymeric fluids is one of the fundamental modes of deformation in different technological processes
The rheology of extension has a long prehistory starting from the classical Trouton law, which is based on the fundamental concepts of fluid mechanics
Polyacrylonitrile (PAN), produced by Britain, trade mark sample sample was characterized by the following parameters: composition—acrylonitrile/methyl was characterizedsulfonate by the following parameters: composition—acrylonitrile/methyl acrylate/methyl acrylate/methyl ratio equal to 93.5/5.8/0.3 wt. % and average molecular weight of 8.5 × 104
Summary
Extension of polymeric fluids is one of the fundamental modes of deformation in different technological processes. The rheology of extension has a long prehistory starting from the classical Trouton law, which is based on the fundamental concepts of fluid mechanics. According to this law, the elongation viscosity of a viscous fluid is equal to 3η where η is shear viscosity determined by the classical Newton-Stokes linear hypothesis. The elongation viscosity of a viscous fluid is equal to 3η where η is shear viscosity determined by the classical Newton-Stokes linear hypothesis This law is valid only if the flow is steady and purely viscous.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
