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Weissenberg

The first finite element schemes for differential viscoelastic models that yielded numerically stable results for non-zero Weissenberg numbers appeared less than two decades ago. These schemes were later improved and shown that for some benchmark viscoelastic problems, such as flow through a two-dimensional section with an abrupt contraction (usually a width reduction of four to one), they can generate simulations that were qualitatively comparable with the experimental evidence. A notable example was the coupled scheme developed by Marchal and Crochet (1987) for the solution of Maxwell and Oldroyd constitutive equations. To achieve stability they used element subdivision for the stress approximations and applied inconsistent streamline upwinding to the stress terms in the discretized equations. In another attempt, Luo and Tanner (1989) developed a typical decoupled scheme that started with the solution of the constitutive equation for a fixed-flow field (e.g. obtained by initially assuming non-elastic fluid behaviour). The extra stress found at this step was subsequently inserted into the equation of motion as a pseudo-body force and the flow field was updated. These authors also used inconsistent streamline upwinding to maintain the stability of the scheme. [Pg.81]

The outlined scheme is shown to yield stable solutions for non-zero Weissenberg number flows in a number of benchmark problems (Swarbric and Nassehi, 1992b). However, the extension of this scheme to more complex problems may involve modifications such as increasing of elemental subdivisions for stress calculations from 3 x 3 to 9 x 9 and/or the discretization of the stress field by biquadratic rather than bi-linear sub-elements. It should also be noted that satisfaction of the BB condition in viscoelastic flow simulations that use mixed formulations is not as clear as the case of purely viscous regimes. [Pg.86]

Normal Stress (Weissenberg Effect). Many viscoelastic fluids flow in a direction normal (perpendicular) to the direction of shear stress in steady-state shear (21,90). Examples of the effect include flour dough climbing up a beater, polymer solutions climbing up the inner cylinder in a concentric cylinder viscometer, and paints forcing apart the cone and plate of a cone—plate viscometer. The normal stress effect has been put to practical use in certain screwless extmders designed in a cone—plate or plate—plate configuration, where the polymer enters at the periphery and exits at the axis. [Pg.178]

The Weissenberg Rheogoniometer (49) is a complex dynamic viscometer that can measure elastic behavior as well as viscosity. It was the first rheometer designed to measure both shear and normal stresses and can be used for complete characteri2ation of viscoelastic materials. Its capabiUties include measurement of steady-state rotational shear within a viscosity range of 10 — mPa-s at shear rates of, of normal forces (elastic... [Pg.189]

Viscoelastic Measurement. A number of methods measure the various quantities that describe viscoelastic behavior. Some requite expensive commercial rheometers, others depend on custom-made research instmments, and a few requite only simple devices. Even quaHtative observations can be useful in the case of polymer melts, paints, and resins, where elasticity may indicate an inferior batch or unusable formulation. Eor example, the extmsion sweU of a material from a syringe can be observed with a microscope. The Weissenberg effect is seen in the separation of a cone and plate during viscosity measurements or the climbing of a resin up the stirrer shaft during polymerization or mixing. [Pg.192]

Sarid, D., lams, D., Weissenberger, V. and Bell, L.S., Compact scanning-force microscope using a laser diode. Opt. Lett., 13(12), 1057-1059 (1988). [Pg.215]

A wide range of applications for hard, wear-resistant coatings of electroless nickel containing silicon carbide particles have been discussed by Weissenberger . The solution is basically for nickel-phosphorus coatings, but contains an addition of 5-15 g/1 silicon carbide. Hiibner and Ostermann have published a comparison between electroless nickel-silicon carbide, electrodeposited nickel-silicon carbide, and hard chromium engineering coatings. [Pg.541]

Many materials of practical interest (such as polymer solutions and melts, foodstuffs, and biological fluids) exhibit viscoelastic characteristics they have some ability to store and recover shear energy and therefore show some of the properties of both a solid and a liquid. Thus a solid may be subject to creep and a fluid may exhibit elastic properties. Several phenomena ascribed to fluid elasticity including die swell, rod climbing (Weissenberg effect), the tubeless siphon, bouncing of a sphere, and the development of secondary flow patterns at low Reynolds numbers, have recently been illustrated in an excellent photographic study(18). Two common and easily observable examples of viscoelastic behaviour in a liquid are ... [Pg.115]

Fig. 3 X-ray diffraction photographs of poly-2,5-DSP. (a) Rotation photograph along the c-axis (oscillation angle 42°) (b) Weissenberg photograph of hkQ zone. Fig. 3 X-ray diffraction photographs of poly-2,5-DSP. (a) Rotation photograph along the c-axis (oscillation angle 42°) (b) Weissenberg photograph of hkQ zone.
With a new software program it is possible to measure the Texture Constant" of pectins. This Texture Constant K is calculated by the ratio of the maximum force during the time interval of the measurement and the measured area below the force-time curve. The resulting constants K correlate well with the dynamic Weissenberg number of oscillating measurements carried through with the same pectin gels. [Pg.408]

The dynamic Weissenberg number W can be calculated from data obtained by the strain frequency sweep measurement. It s the ratio of the elastic to the viscous shares in the measured gel and leads to an objective description of the sensoric properties, representing the basis for the standardization of pectins. [Pg.419]

As an example of such applications, consider the dynamics of a hexible polymer under a shear how [88]. A shear how may be imposed by using Lees-Edwards boundary conditions to produce a steady shear how y = u/Ly, where Ly is the length of the system along v and u is the magnitude of the velocities of the boundary planes along the x-direction. An important parameter in these studies is the Weissenberg number, Wi = Ti y, the product of the longest... [Pg.127]

See other pages where Weissenberg is mentioned: [Pg.1379]    [Pg.10]    [Pg.80]    [Pg.82]    [Pg.83]    [Pg.1067]    [Pg.1067]    [Pg.96]    [Pg.423]    [Pg.179]    [Pg.184]    [Pg.185]    [Pg.189]    [Pg.196]    [Pg.205]    [Pg.514]    [Pg.544]    [Pg.93]    [Pg.368]    [Pg.420]    [Pg.420]    [Pg.420]    [Pg.817]    [Pg.834]    [Pg.836]    [Pg.877]    [Pg.605]    [Pg.606]    [Pg.366]    [Pg.264]    [Pg.127]    [Pg.127]    [Pg.127]    [Pg.215]    [Pg.414]    [Pg.116]   
See also in sourсe #XX -- [ Pg.12 , Pg.14 , Pg.34 , Pg.94 ]

See also in sourсe #XX -- [ Pg.745 ]



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Weissenberg Definition

Weissenberg camera

Weissenberg effect

Weissenberg effect, viscoelasticity

Weissenberg effect, viscoelasticity measurements

Weissenberg equation

Weissenberg friction

Weissenberg geometry

Weissenberg normal stress effect

Weissenberg number

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Weissenberg photographs

Weissenberg rheogoniometer

Weissenberg, Karl

Weissenberg-Rabinowitsch correction

Weissenberg-Rabinowitsch equation,

Weissenberg—Rabinowitsch

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