Virginia TechEberle, A. P. R.Baird, Donald G.Wapperom, PeterVelez-Garcia, G. M.2014-01-302014-01-302009-09-01Eberle, Aaron P. R.; Baird, Donald G.; Wapperom, Peter; et al., "Obtaining reliable transient rheological data on concentrated short fiber suspensions using a rotational rheometer," J. Rheol. 53, 1049 (2009); http://dx.doi.org/10.1122/1.31773480148-6055http://hdl.handle.net/10919/25228The conventional method for obtaining transient rheological data on short glass fiber-filled polymeric fluids is to use the parallel disk (PP) geometry in a rotational rheometer. Using the PP geometry large transient stress overshoot behavior was observed during the startup of flow measurements on a 30 wt% short glass fiber-filled polybutylene terephthalate. A contributing factor to this behavior is believed to be induced fiber collisions caused by the inhomogeneous velocity field (radial varying velocity gradient). A novel approach was taken in which a "donut" shaped sample was used in a cone-and-plate device (CP-D) to maintain a sufficient gap to fiber length ratio. The magnitude of the first normal stress difference was reduced by 70%, and the time to reach steady state was reduced by 100 strain units. The Lipscomb model coupled with the Folgar-Tucker model for the evolution of fiber orientation was fit to the stress growth behavior measured using both the PP geometry and CP-D resulting in different parameters. In addition, the fitted model parameters were found to depend on the initial fiber orientation. It is believed that the CP-D allows for an accurate determination of the stress growth behavior and eventually will allow one to obtain unambiguous model parameters. (C) 2009 The Society of Rheology. [DOI: 10.1122/1.3177348]application/pdfenIn CopyrightSimple shear-flowModel predictionsRodlike particlesOrientationMotionComposite materialsFluidsRodsObtaining reliable transient rheological data on concentrated short fiber suspensions using a rotational rheometerArticle - Refereedhttp://scitation.aip.org/content/sor/journal/jor2/53/5/10.1122/1.3177348Journal of Rheologyhttps://doi.org/10.1122/1.3177348