Second‐order chemical reactions in a nonhomogeneous turbulent fluid

Vassilatos, G.; Toor, H. L.

doi:10.1002/aic.690110419

Cited by 106 publications

(91 citation statements)

References 12 publications

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“…By arguments similar to those used for nonpremixed irreversible reaction (Vassilatos and Toor, 1965;Bourne and Toor, 1977) we expect uin to be negative, and because XL = X b , u:D must be positive.…”

Section: Covariance Termsmentioning

confidence: 96%

Turbulent reactive mixing of reversible reactions

Toor

1997

AIChE Journal

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The convective dimusion equations were used to obtain mean concentrations and concentration fluctuation covariances during turbulent reactive mixing of fast reversible reactions. The mean concentrations are directly applicable to reactions that are much faster than the mixing, while the covariances can serve as a first approximatim closure for slower reactions. The covariances should also be useful for testing more general closure models. Numerical examples are presented for the simple mass-actwn rate law with stoichiometric coefsicients of unity.

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Section: Covariance Termsmentioning

confidence: 96%

Turbulent reactive mixing of reversible reactions

Toor

1997

AIChE Journal

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“…Modeling using this closure was tested by direct experimentation on acid-base reactions in one idealized reactor design. The experimental conversion measurements were made by a heat balance using the heat of reaction (Ma0 and Toor, 197.0, 1971;Vassilatos and Toor, 1965). The velocity field was measured by conventional anemometer methods and the conversion accurately predicted from these results by McKelvey et.…”

Section: Introductionmentioning

confidence: 99%

Turbulent mixing with multiple second‐order chemical reactions

Heeb

Brodkey

1990

AIChE Journal

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A molecular-based statistical simulation program was developed to study the covariance terms involved in the mass balance equations for complex chemical reactions during mixing. Several closure theories were compared to the simulations and available experimental data. The simple closure by Brodkey and Lewalle was found to be an extension of Toor's analysis applied to two reactions. This closure does not satisfy the molar fluctuation balance equation and was found only to represent the high Reynolds number data of Li and Toor. This result led to examining other possible closures which were based on Damkoehler numbers, reaction rate constant ratios, and limiting forms of the covariance term. These closures also were inadequate. The second reaction's covariance term varied from the product of the average values for each component to the Brodkey and Lewalle value for the range of Reynolds numbers considered. Thomas G. Heeb Robert S. Brodkey Department of Chemical EngineeringOhio State University Columbus, OH 43210 IntroductionChemical reactor design is a major area of research. The design is relatively simple for laminar flow, but difficult for turbulent flow. Unfortunately, the majority of reactors operate in the turbulent flow regime. Turbulent flow occurs because of either the necessity of high heat and mass transfer rates to control temperature or high throughputs for economic reasons. In spite of the need for turbulent design methods, they are only available for the simple single step reactions of the type:

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“…Keeler,et al ((et 5), and Vassilatos and Toor (ref. 6) have utilized very fast, acid-base neutra i ization reactions for the study of turbulent-chemica' interactions in one dimensional flow experi•-mP r tts.…”

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confidence: 99%