Methods of deterministic chaos applied to the flow of thin wavy films

Lacy, C.E.; Sheintuch, Moshe; Dukler, A. E.

doi:10.1002/aic.690370402

Cited by 23 publications

(8 citation statements)

References 17 publications

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“…Time signals from natural phenomena are subject to noise which can significantly increase the correlation dimension in nonlinear time-sequence analysis (Lacy et al, 1991). In this study, a low-pass filter set at 20 Hz has been used in data sampling.…”

Section: Correlation Dimensionmentioning

confidence: 99%

Chaotic behavior of fluidized beds based on pressure and voidage fluctuations

Bai

Grace

1997

AIChE Journal

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Absolute and differential fluctuations and local voidage fluctuations are commonly used in characterizing gas-fluidized beds. Pressure fluctuations can result from several different causes including bubble formation and eruption, selfexcited oscillations of fluidized particles, pressure oscillations in the plenum chamber due to piston-like motion of the bed, bubble coalescence, and bubble splitting (Bi et al., 1995). Pressure waves from these sources can be propagated through the emulsion phase, although the amplitudes of the signals are attenuated during their propagation (Bi et al., 1995). Therefore, an absolute pressure probe records phenomena on a macroscopic scale from other locations in addition to local variations. Differential pressure measurements can, to a limited extent, filter out pressure waves originating outside the interval between the two ports connected to the differential pressure transducer, that is, measurements are on a meso-scale. Voidage probes reflect local (that is, microscale) voidage variations caused by bubble passage and the particle movement of the emulsion phase. The amplitude of local voidage fluctuations is independent of bubble size, unlike pressure fluctuations whose amplitude increases with bubble size. Previous studies (Bi et al., 1995;Bi and Grace, 1995) have shown that statistical characteristics (such as standard deviation, skewness, dominant frequency, probability distribution) calculated from these three types of signals differ significantly from one another.In recent years, the application of deterministic chaos theory to fluidized beds has been pioneered by several research groups (such as Daw and Halow, 1991;van den Bleek and Schouten, 1993;Skrzycke et al., 1993;Halow and Daw, 1994;van der Stappen et al., 1995). Analysis of pressure fluctuation signals (such as the phase-space portrait, Lyapunov exponent, correlation dimension, and Kolmogorov entropy) has provided evidence that gas-solids fluidized beds are deterministic chaotic systems. The correlation dimension of the time series has been calculated based on time series from absolute (van der Stappen et al., 1993) ExperimentsThe experiments were carried out in a 102-mm-dia. column described previously (Bi and Grace, 1995). Both FCC particles of zp = 60 pm, pp = 1,580 kg/m3 and sand particles of Lip = 214 pm, pp = 2,640 kg/m3 were used in the tests with the static bed height maintained at 0.6 m for all tests. (ap is the mean particle diameter and pp is the particle density.) Three gas velocities were used, corresponding to different flow regimes. Pressure fluctuations were measured from ports on the wall of the column using Omega PX162 pressure transducers. A low-pass filter eliminates signals with frequencies above 20 Hz. Absolute pressure fluctuations and local voidages were measured 0.28 m above the distributor, while differential pressure fluctuations were measured across an interval from 0.20 to 0.41 m above the distributor. The optical probe (see Zhou et al., 1994 for details) was located with its 1.5 mm tip ...

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Section: Correlation Dimensionmentioning

confidence: 99%

Chaotic behavior of fluidized beds based on pressure and voidage fluctuations

Bai

Grace

1997

AIChE Journal

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“…Experimental studies of falling films have been done by, among others, Kapitza & Kapitza (1949), Krantz & Goren (1971), Portalski & Clegg (1972), Alekseenko, Nakoryakov & Pokusaev (1985), and Lacy, Sheintuch & Dukler (1991). As summarized by Alekseenko et al, in most of the experiments performed, twodimensional regular waves are observed only near the wave-inception line.…”

Section: Introductionmentioning

confidence: 99%

Instabilities of three-dimensional viscous falling films

1992

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A long-wave evolution equation is used to study a falling film on a vertical plate. For certain wavenumbers there exists a two-dimensional strongly nonlinear permanent wave. A new secondary instability is identified in which the three-dimensional disturbance is spatially synchronous with the two-dimensional wave. The instability grows for sufficiently small cross-stream wavenumbers and does not require a threshold amplitude; the two-dimensional wave is always unstable. In addition, the nonlinear evolution of three-dimensional layers is studied by posing various initial-value problems and numerically integrating the long-wave evolution equation.

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“…However, even when the symmetric disturbances are expected to have the largest growth rate, the other unstable modes may influence the observed pattern. The last assertion is based on experimental data, 9 where azimuthal waves are often observed. Anyway, the symmetric perturbations are investigated not only to compare their growth with that of the asymmetric modes, but also to understand the effect that Coriolis and centrifugal forces have on all the modes.…”

Section: Introductionmentioning

confidence: 99%

Azimuthal and streamwise disturbances in a fluid layer flowing down a rotating cylinder

Ruiz-Chavarría

Dávalos‐Orozco

1997

Physics of Fluids

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In this paper an extensive investigation is done of the linear stability of a film falling down a vertical rotating cylinder. Two cases are considered: flow in the outside and flow in the inside of the cylinder. To this end, a system of differential equations which describe the instability is solved numerically with the Runge–Kutta fourth and sixth order methods. We show that in different circumstances the azimuthal disturbances become the most unstable when the rotation is taken into account. Moreover, a splitting of the azimuthal modes appears due to the Coriolis force. In the case of flow in the inside there is a threshold in the centrifugal force above which the flow is linearly stable. Besides, new results for the nonrotating case are also obtained.

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Methods of deterministic chaos applied to the flow of thin wavy films

Cited by 23 publications

References 17 publications

Chaotic behavior of fluidized beds based on pressure and voidage fluctuations

Chaotic behavior of fluidized beds based on pressure and voidage fluctuations

Instabilities of three-dimensional viscous falling films

Azimuthal and streamwise disturbances in a fluid layer flowing down a rotating cylinder

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