Characteristics of slugging regime and transition to turbulent regime for fluidized beds of large coarse particles

Satija, Sunil; Fan, Liang‐Shih

doi:10.1002/aic.690310919

Cited by 55 publications

(23 citation statements)

References 18 publications

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“…Smaller settled bed height corresponds to the lower apparent weight of the emulsion phase and requires lower energy of gas for expansion and breakage of the bubbles. Satija and Fan [11] have also reported lower values of U c for smaller settled bed heights in the fluidized beds of particles ranging 1-7 mm in diameter. Values of transition velocity U c determined from absolute pressure fluctuations data are lower then those from differential pressure fluctuations data for the same conditions (Table 3), which is in agreement with results reported by Bi and Grace [21].…”

Section: Influence Of Temperature and Settled Bed Height On Transitiomentioning

confidence: 90%

“…Also, different approaches for data analysis could be used such as time and frequency domain analysis as well as chaos analysis. Time domain approaches include: (a) observation of the time sequence of measured signal of pressure or voidage fluctuations [1,4,11]; (b) standard deviation analysis [1,2,5,7]; (c) analysis of other statistical moments like skewness and flatness [1], autocorrelation and crosscorrelation functions [11]. Standard deviation analysis is the most common method based on plotting the standard deviation of pressure or voidage fluctuations versus gas velocity where the magnitude of standard deviation is proportional to the bubble size.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, many authors have investigated hydrodynamics of circulating and non-circulating fluidized beds of moderate and fine particles [1][2][3][4][5][6][7]. However, fluidized beds of coarse particles (d p > 1 mm) were much less investigated [8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Hydrodynamics of shallow fluidized bed of coarse particles

Brzić

Ahchieva

Piskova

et al. 2005

Chemical Engineering Journal

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Section: Influence Of Temperature and Settled Bed Height On Transitiomentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Hydrodynamics of shallow fluidized bed of coarse particles

Brzić

Ahchieva

Piskova

et al. 2005

Chemical Engineering Journal

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“…In this phase, the standard deviations have different trends for different Geldart group particles. For superficial gas velocities higher than U c , the standard deviation diagrams show a leveling off for Geldart group B particles (Makkawi and Wright, 2002) and a decreasing for Geldart group D particles (Satija and Fan, 1985;Bi and Fan, 1992) until reaching the transition to the fast fluidization regime. The transition velocities u c and u k obtained by Shannon entropy analysis are equal to those obtained by standard deviation analysis.…”

mentioning

confidence: 94%

Shannon Entropy Analysis of Dynamic Behavior of Geldart Group B and Geldart Group D Particles in a Fluidized Bed

Duan

Cong

2013

Chemical Engineering Communications

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Pressure fluctuations resulting from the nonuniform flow behavior of solid particles in a fluidized bed (0.06 m ID Â 5.0 m in height) were analyzed using the Shannon entropy analysis method. Particles representing Geldart group B and group D types were employed in the experiments. Results show that with the increase of the superficial gas velocity, transitions between bubbling fluidization, turbulent fluidization, and fast fluidization were effectively detected based on the Shannon entropy of pressure fluctuations in the bed. Meanwhile, a higher static bed height resulted in a larger value of Shannon entropy due to the wall effect of smaller diameter column and the greater resistance to bubble formation affected by the increased weight of the bed. Comparison of the particle types indicated that despite the different details of their behavior, the overall trends were similar.

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“…The frequency domain analysis has been widely applied to characterize fluidization regimes [18,26] and to get knowledge on the physical phenomena that take place inside a fluidized bed [27,28].…”

Section: Frequency Domainmentioning

confidence: 99%

Detecting regime transitions in gas-solid fluidized beds from low frequency accelerometry signals

et al. 2011

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a b s t r a c tLow frequency accelerometry signals have been applied for detecting regime transitions in a gas solid fluidized bed. Three solids have been fluidized to promote bubbling, churn and slugging regime. The Kolmogorov entropy and the power spectral density have been used to determine the regime transitions as well as to analyze the dynamical features characterizing the different regimes. Pressure and external acceleration measurements have been taken simultaneously. The accelerometry signal was sampled at 10 kHz; then, the envelope was extracted and resampled at 400 Hz. Pressure signal was sampled at 10 kHz and resampled at 400 Hz. Two problems were found during the work: the colored noise present in the envelope and the lack of low frequency information for one of the tested solids. FIR, wavelet and EMD filter strategies have been applied to remove the noise present in the envelope. It is concluded that the envelope of the accelerometry signal might be used to detect regime transition in the same way as the pressure fluctuation signals. Both Kolmogorov and spectral analysis exhibit common features to those obtained from pressure signal analysis, supporting the hypothesis of using low frequency accelerometry instead of conventional pressure measurements for monitoring fluidized beds.

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Characteristics of slugging regime and transition to turbulent regime for fluidized beds of large coarse particles

Cited by 55 publications

References 18 publications

Hydrodynamics of shallow fluidized bed of coarse particles

Hydrodynamics of shallow fluidized bed of coarse particles

Shannon Entropy Analysis of Dynamic Behavior of Geldart Group B and Geldart Group D Particles in a Fluidized Bed

Detecting regime transitions in gas-solid fluidized beds from low frequency accelerometry signals

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