Fig. 42 Variation of viscosity of PES with shear rate. The shear rate in injection molding is typically about 1 1000 s. More

Fig. 7 Viscosity and shear stress versus shear rate for PDMS (polydimethylsiloxane) from rotational rheometry More

Fig. 2 Rheological testing of bioinks using (a) shear-rate and (b) shear stress sweeps. Example plots are shown for sol gels consisting of different combinations of gelatin methacryloyl (GelMA), κ-carrageenan (κCA), and nanosilicates (nSi). Graphs on right in (a) and (b) reprinted from Ref 15 More

Fig. 2 Effect of shear rate on apparent viscosity of semisolid alloys. Source: Ref 3 More

Fig. 12 Typical shear rate characteristics of lubricants More

Fig. 5 Melt viscosity versus shear rate curves for a typical ionomer at three temperatures; rheometric data based on 0.75 mm (0.030 in.) diameter, 25 mm (1 in.) length, and length-to-diameter ratio of 840 mm (33 in.) More

Fig. 7 Melt viscosity versus shear rate curves for HP ionomer at three temperatures More

Fig. 14 Shear rate versus apparent viscosity More

Fig. 15 Viscosity, temperature, and shear rate fields for electrohydrodynamic lubrication contact with SRR = 2. Source: Ref 65 More

Fig. 34 Viscosity for a polymer material as a function of shear rate at several temperatures More

Fig. 4 Viscosity as a function of shear rate for a highly filled uncured epoxy formulation. Source: Ref 11 More

Fig. 6 Steady-state viscosity as a function of shear rate for an epoxy resin with various levels of silica filler. Source: Ref 12 More

Fig. 8 Viscosity versus shear rate for a commercial polymer with varying molecular weights. Mw, molecular weight More

Fig. 11 Schematic plots showing the shear stress vs. shear strain rate behavior of different materials More

Fig. 6 Shear strain rate versus shear stress (logarithmic scale) for commercial purity Zn-22Al having a grain size of 3.5 μm at various temperatures from 433 to 493 K. Source: Ref 14 More

Fig. 8 Shear strain rate versus shear stress (logarithmic scale) for high purity Zn-22Al for various grain sizes at 493 K. Source: Ref 14 More

Fig. 14 Shear strain rate versus shear stress (logarithmic scale). (a) For high-purity Zn-22Al having a grain size of 3.5 μm at various temperatures from 433 to 493 K. Source: Ref 14 . (b) For high-purity Pb-62Sn having a grain size of 8 μm at various temperatures from 392 to 422 K. Source More

Fig. 16 Graphical determination of shear stress from torque-twist records for rate-insensitive materials. Source: Ref 56 More

Fig. 6 Shear stress versus rate rheology curves for a typical ionomer; rheometric data based on 0.75 mm (0.030 in.) diameter, 25 mm (1 in.) length, and length-to-diameter ratio of 840 mm (33 in.) More