The axial hydrodynamic behavior in a liquid‐solid circulating fluidized bed

Zheng, Ying; Zhu, Jianfeng; Wen, Jianzhang; Martin, Steve A.; Bassi, Amarjeet; Margaritis, Argyrios

doi:10.1002/cjce.5450770213

Cited by 86 publications

(103 citation statements)

References 6 publications

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“…In the developing flow region, located at the lower portion of the riser, solid acceleration along with a decrease in holdup was evident. At higher total velocity, solid holdup plateaus, which indicates that the solid flow enters into the fully developed zone, and was consistent to the results reported in earlier studies (Liang et al, 1997;Zheng et al, 1999;Vidyasagar et al, 2009). …”

Section: Average Solid Holdupsupporting

confidence: 91%

“…It is noted that there exists a similar flow structure in the axial distribution of solid holdup at every section of the riser, for the given primary velocity. Vidyasagar et al, (2009), Zheng et al, (1999, Liang et al, (1997) have also reported a similar axial distribution along the riser. An increase in axial solid holdup, with increase in auxiliary velocity can also be observed, suggesting high significance of the non-mechanical valve combination, with respect to the amount of solids held up axially in the riser.…”

Section: Axial Solid Holdupmentioning

confidence: 65%

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Effect of Liquid Viscosity and Solid Inventory on Hydrodynamics in a Liquid - solid Circulating Fluidized Bed

Sundaram

Venugopal²,

Ullas

et al. 2017

JAFM

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A comprehensive hydrodynamic study of a Liquid -Solid Circulating Fluidized Bed (LSCFB) is conducted with changes in viscosity of the fluidizing medium and the inventory height of solids initially fed into the system. An LSCFB of height 2.95m and riser outer diameter 0.1m was chosen for experimentation. The three liquid media systems with varying viscosities that were chosen were water, glycerol 10% (v/v) and glycerol 20% (v/v). Effect of inventory on the hydrodynamics was also studied, by taking initial heights of inventory to be 15cm, 25cm and 35cm. The hydrodynamic studies concentrated on pressure gradients along the axial pressure tapings, axial solid holdup, average solid holdup, solid circulation rate and slip velocity. Uniformity in axial solid holdup and average solid holdup was validated for changes in viscosity and inventory. Solid flux was seen to follow an inverse relationship to holdup. The changes in slip velocity with varying viscosity and inventory were studied, and found to decrease with both variables. The distribution parameter, Co of the drift flux model was found to be in the range of 0.983-0.994, suggesting non-uniformity in radial solid distribution, with higher solid concentration by the walls compared to the core of the column.

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Section: Average Solid Holdupsupporting

confidence: 91%

Section: Axial Solid Holdupmentioning

confidence: 65%

Effect of Liquid Viscosity and Solid Inventory on Hydrodynamics in a Liquid - solid Circulating Fluidized Bed

Sundaram

Venugopal²,

Ullas

et al. 2017

JAFM

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“…Ž . ported by Liang et al 1997 andZheng et al 1999 . Figure 5 shows the influence of the superficial liquid veloc-Ž .…”

Section: Resultsmentioning

confidence: 99%

“…This mechanical valve was preferred over the hydraulic valve Ž . described by Zheng et al 1999 due to the low density of the Diaion HPA25 anion-exchange particles, which made the operation of a hydraulic valve difficult.…”

Section: Experimental Apparatusmentioning

confidence: 99%

Continuous protein recovery with a liquid–solid circulating fluidized‐bed ion exchanger

et al. 2002

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“…Recent work has demonstrated that the flow structure of LSCFBs is quite different from either conventional liquid fluidized beds (expanded beds) or gas-solids circulating fluidized beds. In the liquidsolid circulating fluidization, particles tend to distribute uniformly in the axial direction of a riser, except for heavy particles [5], while nonuniformity appears in the radial direction with more particles at the wall [6]. Zheng and Zhu [7] characterized the microflow structure of LSCFB and also compared with that of fast fluidization in the gas-solid circulating fluidized systems.…”

Section: Introductionmentioning

confidence: 99%

Radial Particle Profiles in a Liquid‐Solid CFB with Varying Viscosity

Zheng¹

2004

Chem Eng & Technol

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Flow structure was characterized in a 76 mm diameter by 2.0 m high liquid-solid circulating fluidized bed (LSCFB) with different viscous liquids ranging from 1.0 mPa´s to 4.8 mPa´s. Measurements of mean and local solids holdup were carried out in the axial and the radial direction, respectively. The results showed that a uniform axial and a nonuniform radial distribution of the time-averaged solids holdup appeared in the LSCFB. The viscosity of the liquid phase reduces the nonuniform distribution of solid particles in the radial direction. By examining the instantaneous data signals, flow behavior in a viscous system was found to be more uniform and less vigorous. To further understand the hydrodynamics in a LSCFB, Hurst's rescaled range (R/S) analysis was also adopted to analyze its stochastic characteristics and the local flow properties.

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The axial hydrodynamic behavior in a liquid‐solid circulating fluidized bed

Cited by 86 publications

References 6 publications

Effect of Liquid Viscosity and Solid Inventory on Hydrodynamics in a Liquid - solid Circulating Fluidized Bed

Effect of Liquid Viscosity and Solid Inventory on Hydrodynamics in a Liquid - solid Circulating Fluidized Bed

Continuous protein recovery with a liquid–solid circulating fluidized‐bed ion exchanger

Radial Particle Profiles in a Liquid‐Solid CFB with Varying Viscosity

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