Exploration on the emissions and catalytic reactors interactions of a non-road diesel engine through experiment and system level simulation

[Display omitted] •The purification efficiency characteristics and interactions of each catalyst in the integrated aftertreatment system are revealed.•CO and HC basically achieve almost 0 when the DOC temperature is higher than 600 K.•The NO reaction rate is closely related to DOC temperature.•Inlet...

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Published in:Fuel (Guildford) 2023-06, Vol.342, p.127746, Article 127746
Main Authors: Feng, Renhua, Hu, Xiulin, Li, Guanghua, Sun, Zhengwei, Ye, Ming, Deng, Banglin
Format: Article
Language:English
Subjects:
Aftertreatment
Conversion efficiency, Catalytic reactors interactions
Emissions
Non-road diesel engine
System level simulation
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Summary:[Display omitted] •The purification efficiency characteristics and interactions of each catalyst in the integrated aftertreatment system are revealed.•CO and HC basically achieve almost 0 when the DOC temperature is higher than 600 K.•The NO reaction rate is closely related to DOC temperature.•Inlet pressure of DOC has almost no effect on the conversion of HC and CO.•When the temperature is higher than 500 K, the NOx conversion efficiency of SCR is very high. In this paper, the emission characteristics and catalytic reactors interactions of a non-road diesel engine are investigated under non-road transient cycle (NRTC) by experiment and system level simulation. The results showed that the overall emission conversion efficiency of hydrocarbon (HC), carbon monoxide (CO), nitrogen oxides (NOX) and particulate matter (PM) is 96.68 %, 91.45 %, 97.67 % and 93.33 %, respectively under NRTC in experiment. In addition, the interactions of each catalytic converter for emissions under NRTC have been obtained through simulation. When the diesel oxidation catalytic (DOC) temperature is higher than 600 K, CO and HC emissions basically achieve almost 0 through DOC purification. Furthermore, DOC can convert nitric oxide (NO) into nitrogen dioxide (NO2) which provides strong oxidation for the passive regeneration of diesel particulate filter (DPF). The NO reaction rate is closely related to DOC temperature. And the average conversion efficiency from NO to NO2 in DOC is 40.36 %. Moreover, the DOC inlet pressure has almost no effect on the conversion of HC and CO. When the temperature of selective catalytic reduction (SCR) is higher than 500 K, the averages NOx conversion efficiency of SCR is up to 98.74 %. And ammonia purification catalyst (ASC) can further reduce NO emissions while absorbing slip ammonia. When the inlet temperature of DPF is more than 520 K, it has almost no effect on the oxidation of PM. The PM conversion efficiency of aftertreatment system (ATS) is mainly affected by the PM collection efficiency of DPF. The average PM collection efficiency of DPF is 53.32 %, while the PM conversion efficiency of ATS is 91.54 % by simulation. Although DPF will convert PM to CO, these CO cannot be completely converted into carbon dioxide (CO2). So the CO conversion efficiency of ATS is lower than that of DOC.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2023.127746