Improving the Accuracy of Predicting Effectiveness Factors for mth

intrinsic mth-order rate equation in the form of where km is the kinetic coefficient in (mol C/m3)1-m s-1, and m is the intrinsic reaction order. Corr...
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Energy & Fuels 2000, 14, 663-670

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Improving the Accuracy of Predicting Effectiveness Factors for mth Order and Langmuir Rate Equations in Spherical Coordinates Jianhui Hong, William C. Hecker, and Thomas H. Fletcher* Chemical Engineering Department and Advanced Combustion Engineering Research Center, Brigham Young University, Provo, Utah 84602 Received October 25, 1999

Char oxidation is often modeled using an mth order intrinsic reaction rate in conjunction with an effectiveness factor (η) to account for intraparticle diffusion of gas species. This approach involves the use of a general modulus (MT) and using the first-order curve of η vs MT. This method was originally referred to as the general asymptotic solution. It has been suggested that a simple Langmuir rate equation is more suitable for modeling the effects of pressure on char reactivity. Therefore, several methods of developing general moduli for the Langmuir rate expression are shown. The general asymptotic solution is most accurate as MT approaches the limits of zero and infinity. However, in the intermediate range of MT (0.2 < MT < 5), the general asymptotic solution exhibits errors of up to -17% error in spherical coordinates and -24% error in Cartesian coordinates. A correction function was constructed to improve the accuracy of predictions in the intermediate range of general modulus for both the mth-order and the Langmuir rate equations. The general asymptotic solution, combined with this correction function, is able to predict the effectiveness factor for all mth-order (0