Abstract:
Urea-based selective catalytic reduction (SCR) system coupled with a downstream ammonia oxidation catalyst (AMOX), has become a standard NOxreduction device for Diesel en...Show MoreMetadata
Abstract:
Urea-based selective catalytic reduction (SCR) system coupled with a downstream ammonia oxidation catalyst (AMOX), has become a standard NOxreduction device for Diesel engines. On-board diagnostics of tailpipe NOxand ammonia (NH3) emissions and closed-loop controls using only tailpipe NOxsensor, are critical for SCR systems to achieve high NOxconversion efficiency and low tailpipe NH3 slip. However, due to commercial NOxsensor NH3 cross-sensitivity issue, the tailpipe NH3 emissions can be misinterpreted as NOxemissions, which may lead to erratic diagnostics and unstable control systems. The purpose of this study is to develop a high-fidelity control-oriented SCR-AMOX model and a model-based estimation algorithm using extended Kalman filter (EKF) for effectively decoupling NOxand NH3 concentrations from the mixed tailpipe NOxsensor signals for an SCR-AMOX system. The proposed model and EKF-based decoupling algorithm were validated using the experimental data collected from a Diesel engine platform during both steady-state and transient driving cycles. Experimental verification results demonstrated high accuracy of the control-oriented model and proved the efficacy of the proposed decoupling algorithm in meeting the preset thresholds. The robustness of the decoupling algorithm against the uncertainty from catalyst aging was also demonstrated and verified. Such EKF-based robust decoupling algorithm can be instrumental in the diagnostics and controls of urea-based SCR systems.
Published in: 2019 American Control Conference (ACC)
Date of Conference: 10-12 July 2019
Date Added to IEEE Xplore: 29 August 2019
ISBN Information: