Impact of gas phase reactions and catalyst poisons on the NH3-SCR activity of a V2O5-WO3/TiO2 catalyst at pre-turbine position

Impact of gas phase reactions and catalyst poisons on the NH3-SCR activity of a V2O5-WO3/TiO2 catalyst at pre-turbine position

[Display omitted] •The presence of HCs and SO2 significantly affects the NH3-SCR activity of a V-based SCR catalysts at pre-turbine position.•Depending on the HC used, NOx conversion decreases differently with simultaneous formation of some hazardous byproducts like HCHO and HCN.•Elevated pressures...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Vol. 288; p. 119991
Main Authors: Zengel, Deniz, Stehle, Matthias, Deutschmann, Olaf, Casapu, Maria, Grunwaldt, Jan-Dierk
Format: Journal Article
Language:English
Published: Elsevier B.V 05-07-2021
Subjects:
Catalyst poison
Elevated pressure
Pre-turbo
Selective catalytic reduction
Vanadium
SCR
GHSV
Vanadium
TPD
XRF
Elevated pressure
Pre-turbo
FTIR
NOx
DOC
DPF
HC
Selective catalytic reduction
Catalyst poison
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Summary:[Display omitted] •The presence of HCs and SO2 significantly affects the NH3-SCR activity of a V-based SCR catalysts at pre-turbine position.•Depending on the HC used, NOx conversion decreases differently with simultaneous formation of some hazardous byproducts like HCHO and HCN.•Elevated pressures enhance the formation of S-containing deposits during prolonged SO2 exposure at low temperatures.•Homogenous gas phase reactions lead to pronounced overconsumption of NH3 but also tremendously enhance the NO oxidation to NO2. With stricter regulations and decreasing exhaust gas temperature due to more efficient engine management, NOx abatement remains a critical issue despite many technical and catalytic advances. To counterbalance these challenges the positioning of exhaust gas aftertreatment systems in front of the turbocharger has gained significant interest in recent years. In this context, we report a systematic study on the impact of propylene, n-dodecane, and o-xylene as well as of SO2 on the gas phase reactions and NH3-SCR activity of a conventional vanadium-based catalyst at increased pressure. An elevated pressure is shown to dramatically promote homogeneous reactions of hydrocarbons, which subsequently contribute to an increased NO oxidation but also to parasitic NH3 overconsumption. The hydrocarbons are also faster catalytically oxidized and affect NOx reduction at all investigated temperatures. Their presence in the exhaust gas further leads to the formation of the toxic byproducts HCHO and HCN. Upon short term exposure to 20 ppm SO2 in the feed gas, no significant catalyst poisoning was observed. However, for longer exposure times an enhanced formation of sulfur containing deposits was encountered at low temperatures for elevated pressures. Notably, their poisonous effect was reversible after heating to high temperatures.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2021.119991