Chaitanya S. Sampara scite author profile

Global oxidation kinetics for propylene (C 3 H 6 ), CO, H 2 , and NO were determined over a platinum (Pt) catalyst with simulated diesel exhaust between 200 and 415°C over wide concentration ranges. An integral reactor with high space velocity capability (up to 2 million h -1 ) was used to generate low and moderate conversion data for the rate-generation process. First-order concentration dependency for all the reactants involved in the C 3 H 6 , CO, and H 2 oxidation reactions captured the experimental behavior very well. For the NO-NO 2 reaction, the rate was found to be first order with respect to NO and 0.5 order with respect to O 2 . An overall inhibition term including only the effects of CO and NO for all the reactions was found to be adequate over the range of conditions examined in this study. A simplified 1D reactor code was used to interpret the data and predict exit concentrations. An objective function was defined for the optimization process, which is sensitive to model predictions at all conversion levels. An optimization strategy was also developed to systematically simplify the form of rate expressions and to generate proper initial guesses for each of the intermediate steps.The final rate forms were compared with light-off curves generated on a full-scale reactor mounted on a 1.7 L Isuzu engine at University of Michigan.

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Global Kinetics for a Commercial Diesel Oxidation Catalyst with Two Exhaust Hydrocarbons

Sampara

Bissett

Chmielewski

2007

Ind. Eng. Chem. Res.

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Global kinetics for the oxidation of diesel fuel (DF), propylene (C 3 H 6 ), CO, H 2 , and NO were determined over a commercial diesel oxidation catalyst (DOC) with simulated diesel exhaust between 200 and 415 °C over a wide concentration range intended to represent engine exhaust from both conventional and premixed compression ignition (PCI) combustion. Total hydrocarbons in the exhaust were represented as a combination of propylene, to represent partially oxidized fuel species, and diesel fuel, to represent unburned fuel. An integral reactor with high space velocity capability (up to 2 million h -1 ) was used to generate low and moderate conversion data for the rate-generation process. Mass transport properties of DF were determined based on the experimental data. First-order concentration dependency for all of the reactants involved in the DF, C 3 H 6 , CO, and H 2 oxidation reactions adequately captured the experimental behavior. An overall inhibition term including only the effects of CO and NO was found to be adequate for these reactions over the range of conditions examined for this study. For the NO oxidation reaction, the rate was found to be first order with respect to NO and 0.5 with respect to O 2 . The inhibition term for this reaction was found to be a function of DF and NO. Modeling approaches and optimization strategies similar to our previous work 1 were employed for the entire rate-generation process. These rate expressions were first validated against light-off curves generated with the same laboratory reactor operating at realistic space velocities and subsequently validated against light-off curves generated on a full-size DOC mounted on a 1.7 L Isuzu diesel engine using both conventional and PCI combustion strategies.

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Kinetic study of adsorption and desorption of SO2 over γ-Al2O3 and Pt/γ-Al2O3

Hamzehlouyan

Sampara

et al. 2016

Applied Catalysis B: Environmental

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