Mass transfer from a solid soluble sphere to a flowing liquid stream

Steinberger, Robert L.; Treybal, Robert E.

doi:10.1002/aic.690060213

Cited by 147 publications

(47 citation statements)

References 19 publications

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“…Although several empirical equations are available in the literature [30,31] to calculate the convective or external mass transfer coefficient (m), we have the well-known RanzMarshall [32] equation, which is expressed as follows:…”

Section: B External Mass Transfermentioning

confidence: 99%

Kinetics of chloridization of nickel oxide with gaseous hydrogen chloride

Kanungo

Mishra

1997

Metall Mater Trans B

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The kinetics of chloridization of finely divided as well as granulated nickel oxide by gaseous HCl were studied in the temperature range 150 ЊC to 400 ЊC. The rate of chloridization depended upon temperature, partial pressure of HCl, and granule size. The conversion of NiO to NiCl 2 follows the logarithmic rate law or a pore-blocking model, which is attributed to the large increase in molar volume of the product phase. The blocked pores decreased the diffusion of gaseous reactant through the product layer. This observation has been supported by the low value of activation energy, the high order of reaction with respect to the partial pressure of HCl (g), and a slope value of Ϫ2 for the log-log plot of rate constant vs grain size. The morphological characteristics of both unreacted and chloridized nickel oxide have been studied with the help of a scanning electron microscope.

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Section: B External Mass Transfermentioning

confidence: 99%

Kinetics of chloridization of nickel oxide with gaseous hydrogen chloride

Kanungo

Mishra

1997

Metall Mater Trans B

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“…Steinberger and Treybal [18] had provided a correlation for slowly moving liquids past single spheres as well as through beds of pellets. Disregarding the contribution of the dynamic part (for very low particle Reynolds numbers in the case of a marginally stirred liquid in an ARC) the Sherwood number (Sh) is correlated with the Schmidt (Sc) and the Grashoff (Gr) numbers as Sh = 2.0 + 0.569(GrSc) 0.25 , GrSc < 10 8 (12) where…”

Section: Extended Modelmentioning

confidence: 99%

A general kinetic model framework for the interpretation of adiabatic calorimeter rate data

Bhattacharya

2005

Chemical Engineering Journal

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“…(1) to (3). [5][6][7] The latter was obtained by using dimensionless correlations written in Eqs. (1) to (3).…”

Section: Evaluation Of Overall (Averaged) Gas Phase Massmentioning

confidence: 99%

“…(1) to (3). [5][6][7] The former was calculated by using decarburization rate equation given in Eq. (23): .... (23) where pct C is the average carbon concentration in the droplet obtained by the present numerical simulation, and is the partial pressure of CO2 in the bulk.…”

Section: Evaluation Of Overall (Averaged) Gas Phase Massmentioning

confidence: 99%

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Decarburization of Molten Fe–C Droplet: Numerical Simulation and Experimental Validation

et al. 2014

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Decarburization of Fe-C droplet was investigated by fluid dynamics numerical simulation based on physical properties under gas phase mass transfer controlled regime. Fluid flow and species concentration fields around the droplet implementing a reaction of carbon with oxidant gas at the interface were calculated by a commercial CFD package which solves a set of transport equations. Overall decarburization rate of the molten Fe-C droplet was obtained by the simulation, and it was additionally validated by the present authors' own experiment using gas-liquid drop reaction in a levitation melting equipment. It was observed by the simulation that decarburization rate on the surface of a droplet was not homogeneous due to inhomogeneous gas distribution around the droplet. A new concept of local mass transfer coefficient ratio was proposed in the present study as a ratio of effective local mass transfer coefficient at a specific site over average mass transfer coefficient, as a function of θ (angle between direction of gas flow and direction to reaction site on the droplet surface from the droplet center) and dimensionless numbers regarding fluid flow:Furthermore, effect of distance between two droplets was investigated by the present numerical model for decarburization of multiple droplets. The local mass transfer coefficient was found to have a significant impact on decarburization rate of a droplet when the other droplet locates very close. Relation between decarburization rate of two droplets and distance between them were analyzed.

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Mass transfer from a solid soluble sphere to a flowing liquid stream

Cited by 147 publications

References 19 publications

Kinetics of chloridization of nickel oxide with gaseous hydrogen chloride

Kinetics of chloridization of nickel oxide with gaseous hydrogen chloride

A general kinetic model framework for the interpretation of adiabatic calorimeter rate data

Decarburization of Molten Fe–C Droplet: Numerical Simulation and Experimental Validation

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