Effect of pressure fluctuations on the heat transfer characteristics in a pressurized slurry bubble column

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Flow behavior of wakes has been investigated in a three-phase slurry bubble column of 0.102 m ID and 1.5 m in height. The dependence of wake characteristics such as rising velocity, frequency, holdup and equivalent size on the operating variables was examined by employing an electric resistivity probe method. The gas velocity, liquid viscosity and solid content in the slurry phase were chosen as independent parameters. The rising velocity of wake region increased with an increase in the gas velocity (4.0-12.0 cm/s), liquid viscosity (1.0-50.0 mPa·s) or solid content (0-25 wt%) in the slurry phase. The frequency and holdup of wake phase increased with increasing gas velocity, but decreased with increasing liquid viscosity or solid content in the slurry phase. The equivalent size of wake phase increased with increasing gas velocity, liquid viscosity or solid content in the slurry phase. The wake properties and holdup were well correlated with operation variables within these experimental conditions.

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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Flow behavior of wakes in a three-phase slurry bubble column with viscous liquid medium

Lím

Jang

Kang

et al. 2011

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“…The total acquisition time was 10 s having 5000 data points. This combination of sampling rate and time can detect the full spectrum of temperature fluctuation signals in a multiphase flow system [13][14][15][16].…”

Section: May 2010mentioning

confidence: 99%

Multiple effects of operating variables on heat transfer in three-phase slurry bubble columns

Shin

Son

Lím

et al. 2010

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Characteristics of heat transfer were investigated in pressurized slurry bubble column reactors whose diameter was either 0.051, 0.076, 0.102 or 0.152 m (ID) and 1.5 m in height, respectively. Effects of gas velocity (U G ), solid contents (S C ), pressure (P), liquid viscosity (µ L ) and column diameter (D) on the heat transfer coefficient (h) between the immersed vertical heater and the column were determined. Multiple effects such as U G and D, P and D, µ L and D, and S C and D on the value of heat transfer coefficient were discussed. Temperature fluctuations were also measured and analyzed by adapting chaos theory, which was used to explain the effects of operating variables on the heat transfer in the column. The heat transfer coefficient increased with increasing gas velocity, pressure or solid content in the slurry phase, but decreased with increasing liquid viscosity or column diameter. The decrease trend of h with increasing column diameter was somewhat sensitive when the gas velocity was relatively high (U G ≥12 cm/s). The effects of column diameter on the h value became almost linear when the operating pressure (P=4-10 kg f /cm 2 ), liquid viscosity (µ L =20-38 mPa·s) or solid content in the slurry phase (S C =10-20 wt%) was relatively high and gas velocity was relatively low, within these experimental conditions. The heat transfer coefficient was well correlated in terms of dimensionless groups as well as operating variables.

“…Recently, the multiresolution signal decomposition [6] has been widely applied to analyze pressure fluctuation signals with multiscale features and unsteady characteristics in fluidization and bubble columns in chemical engineering [7][8][9][10][11][12]. Another technique, the chaotic time series analysis, has also shown great advantages in studying the nonlinear dynamics of bubble columns [4,13,14]. In the present work, both the multiresolution signal decomposition and chaotic time series analysis were simultaneously employed to analyze the temporary signals of bubble passages in non-Newtonian fluids and then to characterize qualitatively and quantitatively the nonlinear dynamics of in-line bubbles rising with coalescences.…”

Section: Introductionmentioning

confidence: 99%

Chaotic behavior of in-line bubbles rising with coalescences in non-Newtonian fluids: A multiscale analysis

Jiang

Fan

et al. 2010

International audienceThe nonlinear dynamics of in-line bubbles rising with coalescence in non-Newtonian Carboxymethylcellulose sodium (CMC) fluids was studied through the techniques such as the multiresolution signal decomposition and the chaotic time series analysis. The temporary signals of bubble passages collected by an optical sensing device at different heights were investigated by a 12-level wavelet decomposition and the scalewise characteristics of bubble motion were extracted and analyzed. The chaotic time series analysis distinguished the periodicity or the deterministic chaos of bubble motion successsfully. The calculation of Kolmogorov entropy proves that in the ranges of experimental heights and gas flowrates, the bubble rising dynamics becomes more chaotic with the increase of height, and reaches the maximum chaotic extent in a certain height, while with the further increase of height, the chaotic extent decreases slowly. With the increase of gas flowrate, at the lower height, the bubble rising dynamics changes from periodicity to deterministic chaos, and at the higher heights it reaches the maximum chaotic extent in a certain gas flowrate; however, for both cases, it has little change in the higher gas flowrates. Moreover, with the increase of CMC concentration, the bubble rising dynamics becomes less chaotic when the height is beyond a certain value