A transparent flow cell apparatus has been used to obtain quantitative information on the morphology evolution of a model polymer blend flowing in complex flow fields. A dilute emulsion of poly-dimethylsiloxane droplets immersed in a poly-isobutene matrix, both Newtonianliquids at room temperature, has been chosen as a model system. Optical microscopy coupled with image acquisition analysis allowed tomonitor the behavior of droplets flowing through a sudden contraction and through a gradual converging channel followed by a sudden expansion. The experimental results indicate that drop deformation and breakup are sensitive to both shear and extensional components. A simple criterion, based on the evaluation of a local critical capillary number, is proposed to predict the morphological evolution of the flowing blend. By using computer simulations to estimate the velocity gradients in the flow field, it is shown that the proposed criterion is able tosuccessfully predict the observed morphology
Morphology evolution of immiscible polymer blends in complex flow fields / Testa, C.; Sigillo, I.; Grizzuti, Nino. - In: POLYMER. - ISSN 0032-3861. - STAMPA. - 42:13(2001), pp. 5659-5667. [10.1016/S0032-3861(01)00078-7]
Morphology evolution of immiscible polymer blends in complex flow fields
GRIZZUTI, NINO
2001
Abstract
A transparent flow cell apparatus has been used to obtain quantitative information on the morphology evolution of a model polymer blend flowing in complex flow fields. A dilute emulsion of poly-dimethylsiloxane droplets immersed in a poly-isobutene matrix, both Newtonianliquids at room temperature, has been chosen as a model system. Optical microscopy coupled with image acquisition analysis allowed tomonitor the behavior of droplets flowing through a sudden contraction and through a gradual converging channel followed by a sudden expansion. The experimental results indicate that drop deformation and breakup are sensitive to both shear and extensional components. A simple criterion, based on the evaluation of a local critical capillary number, is proposed to predict the morphological evolution of the flowing blend. By using computer simulations to estimate the velocity gradients in the flow field, it is shown that the proposed criterion is able tosuccessfully predict the observed morphologyI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.