[article]
Titre : |
Predicting the multipollutant performance of utility SCR systems |
Type de document : |
texte imprimé |
Auteurs : |
Stephen Niksa, Auteur ; April Freeman Sibley, Auteur |
Année de publication : |
2010 |
Article en page(s) : |
pp. 6332–6341 |
Note générale : |
Industrial chemistry |
Langues : |
Anglais (eng) |
Mots-clés : |
Catalyst material composition |
Résumé : |
This analysis relates catalyst material composition and bimodal pore size characteristics in a direct, quantitative way to the reactivities for simultaneous NO reduction, Hg0 oxidation, and SO3 production along utility selective catalytic reduction (SCR) reactors. SCR monoliths sustain two chemically distinct regions. In the inlet region, strong NH3 adsorption minimizes the coverage of chlorinated and sulfated surface sites, so NO reduction inhibits Hg0 and SO2 oxidation. Once the NH3 has been consumed, however, the chlorinated surface coverage surges by orders of magnitude, and the Hg0 oxidation rate rapidly increases, even while the HCl concentration in the gas phase remains uniform. Ammonia inhibition also eliminates the benefit of the rapid film mass transfer at the SCR inlet from promoting Hg0 oxidation. In many cases, the Hg0 oxidation rate becomes limited by film transport soon after the Hg0 begins to oxidize, so that none of the catalyst internal surface area is utilized. Shifting the pore size distribution toward macropores in a final catalyst stage appears to be an effective means for directly enhancing Hg0 oxidation. The predictions were validated with pilot-scale data to demonstrate the crucial impact of NH3 inhibition on SCR performance and with full-scale data for catalysts from a single vendor to show quantitative consistency across broad ranges of coal Cl content, gas hourly space velocity (GHSV), NH3/NO ratio, and catalyst specifications. |
ISSN : |
0888-5885 |
En ligne : |
http://pubs.acs.org/doi/abs/10.1021/ie9020599 |
in Industrial & engineering chemistry research > Vol. 49 N° 14 (Juillet 2010) . - pp. 6332–6341
[article] Predicting the multipollutant performance of utility SCR systems [texte imprimé] / Stephen Niksa, Auteur ; April Freeman Sibley, Auteur . - 2010 . - pp. 6332–6341. Industrial chemistry Langues : Anglais ( eng) in Industrial & engineering chemistry research > Vol. 49 N° 14 (Juillet 2010) . - pp. 6332–6341
Mots-clés : |
Catalyst material composition |
Résumé : |
This analysis relates catalyst material composition and bimodal pore size characteristics in a direct, quantitative way to the reactivities for simultaneous NO reduction, Hg0 oxidation, and SO3 production along utility selective catalytic reduction (SCR) reactors. SCR monoliths sustain two chemically distinct regions. In the inlet region, strong NH3 adsorption minimizes the coverage of chlorinated and sulfated surface sites, so NO reduction inhibits Hg0 and SO2 oxidation. Once the NH3 has been consumed, however, the chlorinated surface coverage surges by orders of magnitude, and the Hg0 oxidation rate rapidly increases, even while the HCl concentration in the gas phase remains uniform. Ammonia inhibition also eliminates the benefit of the rapid film mass transfer at the SCR inlet from promoting Hg0 oxidation. In many cases, the Hg0 oxidation rate becomes limited by film transport soon after the Hg0 begins to oxidize, so that none of the catalyst internal surface area is utilized. Shifting the pore size distribution toward macropores in a final catalyst stage appears to be an effective means for directly enhancing Hg0 oxidation. The predictions were validated with pilot-scale data to demonstrate the crucial impact of NH3 inhibition on SCR performance and with full-scale data for catalysts from a single vendor to show quantitative consistency across broad ranges of coal Cl content, gas hourly space velocity (GHSV), NH3/NO ratio, and catalyst specifications. |
ISSN : |
0888-5885 |
En ligne : |
http://pubs.acs.org/doi/abs/10.1021/ie9020599 |
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