Gas Holdup and Heat Transfer From Immersed Surfaces in Two- And Three-Phase Systems in Bubble Columns

Saxena, S.C.; Vadivel, R.; Saxena, Aditi

doi:10.1080/00986448908940348

Cited by 32 publications

(23 citation statements)

References 16 publications

(29 reference statements)

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“…Due to the excellent mixing in the bubble column, there is a negligible radial temperature gradient [23] and essentially zero resistance to radial mixing. Though temperature gradients have been observed in the vertical direction in industrial bubble columns [24], the depth of the liquid used in this experiment is only about 1-10% of the height of a typical bubble column.…”

Section: Heat and Mass Transfer Modelmentioning

confidence: 99%

Experiments and modeling of bubble column dehumidifier performance

Tow

Lienhard

2014

International Journal of Thermal Sciences

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Humidification-dehumidification is a promising technology for decentralized, small-scale desalination, but conventional dehumidifiers are expensive due to the large surface area required. Direct-contact dehumidification in bubble columns has been shown to significantly decrease dehumidifier size and cost. In this paper, the heat flux and parallel-flow effectiveness of a bubble column dehumidifier are investigated experimentally using significantly smaller cooling coils than in previous work. In addition, a model is developed which predicts the heat transfer rate with an average error of less than 3%.It is found that heat flux rises and effectiveness decreases with decreasing coil area. Increasing air flow rate and air temperature both lead to increased heat flux but decreased effectiveness. Neither bubble-on-coil impact nor column height are found to significantly affect heat flux or effectiveness. The conflicting findings of previous research on bubble-on-coil impact are explained by the other trends identified in this work. Modeling results for salt water * Address all correspondence to lienhard@mit.edu April 24, 2014 temperature and tube diameter are presented. Additional heat transfer in the air gap above the column liquid is explored, but found to be minimal for well-designed columns with low temperature pinch. These findings will inform the design of bubble column dehumidifiers for high heat recovery and low capital cost. Keywords: condensation, direct contact heat transfer, HDH desalination

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Section: Heat and Mass Transfer Modelmentioning

confidence: 99%

Experiments and modeling of bubble column dehumidifier performance

Tow

Lienhard

2014

International Journal of Thermal Sciences

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“…For bubble columns and slurry bubble columns, gas holdup has been found to increase with increasing superficial gas velocity (Kim et al, 1972;Koide et al, 1984;Fan et ai. 1987;Saxena et al, 1989Saxena et al, , 1990a. In the dispersed bubble 80w regime, this increase has been found to be proportional to surperfïcal gas velocity (Bach and Pilhofer, 1978;Lockett and Kirkpaûick, 1975;Kara et al, 1982 Wolff et al, 1990) reported that high superficial gas velocity, higher solids concentrations and particle densities resulted in larger bubbles and consequently lower gas holdup.…”

Section: Effeets Of Gas Veloeitymentioning

confidence: 99%

“…The influence of slurry concentration on heat transfer coefficient has been investigated by Kolbel et al (1958Kolbel et al ( , 1960, Deckwer et al (1980) and Saxena et al (1989Saxena et al ( , 1990a,…”

Section: Eff't Of Liquid Viscositymentioning

confidence: 99%

“…Heat transfer in slurry bubble colurnns has been investigated by several researchen (Deckwer et al, 1980; Saxena et al, 1989Saxena et al, , 1990, 1 992a). Generally a weak dependence of the heat transfer coefficient on the sluny concentration has k e n observed.…”

Section: Hindered Settling Velocitymentioning

confidence: 99%

“…The measurements of heat transfer in particdate muftiphase systerns can be divided into object-to-bed (Deckwer et al, 1980;Saxena et al, 1989 and1990a) or wall-to-bed heat transfer (Chiu and Ziegler, 1983;Saberian-Broudjenni et al, 1985). In this study, the measurements of heat tram fer coefficients belong to object-to-bed heat tram fer.…”

Section: Hindered Settling Velocitymentioning

confidence: 99%

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Heat Transfer and Hydrodynamics in a Three-Phase Slurry Bubble Column

Prakash

1997

Ind. Eng. Chem. Res.

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The instantaneous and time-averaged heat transfer coefficients in the regions near the wall and at the center and average gas holdups were measured in a 0.28 m diameter slurry bubble column for the air−water and air−water−glass beads (35 μm) system. The effects of high gas velocities (up to 0.35 m/s) and high solids concentrations (up to 40 vol %) were investigated. Gas holdup decreased with increasing slurry concentrations; the rate of decline was rapid at high gas velocities. The instantaneous local heat transfer measurements were analyzed to study the bubble behavior in the regions near the wall and at the center for different solids concentrations. Larger bubbles were detected in the wall region in slurry systems compared to the solid-free system. The average heat transfer coefficient decreased with increasing slurry concentrations. The heat transfer coefficient was always lower at the wall than at the center.

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Slurry Reactors1A list of symbols used in the text is provided at the end of the chapter.

Nedeltchev

Schumpe

2008

Handbook of Heterogeneous Catalysis

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The sections in this article are Introduction Types of Slurry Reactor Slurry Bubble Column Reactor Other Reactor Types Hydrodynamics of Slurry Reactors Flow Regimes Minimum Suspension Conditions Average Bubble Diameter Backmixing Gas Holdup Bubble Rise Velocity Mass Transfer in Slurry Reactors Volumetric Liquid‐Side Mass‐Transfer Coefficient ( k L a ) k L a in the Slurry Bubble Column k L a in the Stirred Tank Gas–Liquid Specific Interfacial Area ( a ) Liquid‐Side Mass‐Transfer Coefficient at the Gas–Liquid Interface ( k L ) Gas‐Side Mass‐Transfer Coefficient ( k G ) Liquid‐Solid Mass‐Transfer Coefficient ( k S ) Enhancement of Gas–Liquid Mass Transfer Adsorptive Transport (“Shuttle Mechanism”) Absorption with Heterogeneous Catalytic Reaction Reactive Particles Optimum Catalyst Size Heat Transfer in Slurry Reactors Concluding Remarks Acknowledgments

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Gas Holdup and Heat Transfer From Immersed Surfaces in Two- And Three-Phase Systems in Bubble Columns

Cited by 32 publications

References 16 publications

Experiments and modeling of bubble column dehumidifier performance

Experiments and modeling of bubble column dehumidifier performance

Heat Transfer and Hydrodynamics in a Three-Phase Slurry Bubble Column

Slurry Reactors1A list of symbols used in the text is provided at the end of the chapter.

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