Abstract
Kinetic theory of dilute macromolecular solutions is applied to pressure driven flow in a small channel where wall- (and interfacial) layers have to be reckoned with. The complete rheology is studied. It turns out that for very small channels both the shear stress and the normal stress are an order of magnitude larger than corresponding quantities in simple shear. On the other hand, when the channel is so wide that the wall layers are very thin in comparison, agreement with results appropriate for simple shear is found. The volume flow rate-pressure difference relation is derived and compared to the prediction which utilizes the slip velocity concept. For very small channels, this concept is five orders of magnitude off, but reproduces asymptotically correct results for very large channels.
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References
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Brunn, P.O., Grisafi, S. Pressure driven flow of dilute polymer solutions in a channel: Analytic results for very small and for very large channels. Rheol Acta 26, 211–216 (1987). https://doi.org/10.1007/BF01329436
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DOI: https://doi.org/10.1007/BF01329436