Abstract
AbstractExhaust emissions from diesel engine powered vehicles are considerably high during cold start and warm‐up, because of the poor catalyst performance due to the insufficient catalyst temperature. The controlled heat injection allowed by electrically heated catalysts can effectively reduce the catalyst light‐off time with relatively moderate fuel penalty. This paper compares the exhaust temperature and emissions of a case study diesel vehicle in cold and warm start conditions, and proposes two electrically heated catalyst control strategies, which are evaluated in terms of emission reduction and energy consumption with different target temperature settings. In addition, a new performance indicator, that is, the specific emission reduction, is used to evaluate the after‐treatment system and associated thermal management. For the worldwide harmonized light vehicle test cycle, the results without electrically heated catalyst show that from both cold and warm start conditions a large amount of operating points of the engine is located in the region of partial catalyst light off. Moreover, emissions, especially in terms of carbon monoxide and hydrocarbon, significantly decrease with the electrically heated catalyst implementation, for example, by at least 50% from cold start; however, they still tend to be rather substantial when the fuel is re‐injected after the engine cutoff phases. The exhaust temperature is lower than the target values in the sections of the driving cycle in which the electrically heated catalyst power is saturated according to the maximum level allowed by the device. The carbon dioxide penalty brought by the electrically heated catalyst ranges from 3.93% to 6.65% and from 6.49% to 9.35% for warm and cold start conditions, respectively.
Highlights
Stringent emission regulations were put in action and became the main drive for advanced engine technologies, such as partially premixed compression ignition (PPCI),[3] partially premixed combustion (PPC),[4] high pressure fuel injection,[5] split injection,[6] advanced control,[7] diesel oxidation catalysts (DOCs),[8] diesel particulate filters (DPFs),[9,10] selective catalyst reduction (SCR),[11] nonthermal plasma (NTP)
In the low vehicle speed section of the driving cycle, a large proportion of the engine operating points is in regions characterized only by partial catalyst light off, even when the engine is already fully warmed up
The pipe‐out emissions significantly decrease after the electrically heated catalysts (EHCs) implementation, especially for cold start conditions
Summary
Strong evidence shows the connection between emissions from diesel vehicles and smog, which is believed to contribute to severe respiratory diseases, in urban environments.[1,2] Stringent emission regulations were put in action and became the main drive for advanced engine technologies, such as partially premixed compression ignition (PPCI),[3] partially premixed combustion (PPC),[4] high pressure fuel injection,[5] split injection,[6] advanced control,[7] diesel oxidation catalysts (DOCs),[8] diesel particulate filters (DPFs),[9,10] selective catalyst reduction (SCR),[11] nonthermal plasma (NTP)Energy Sci Eng. 2019;7:2383–2397. | wileyonlinelibrary.com/journal/ese3 2383| 2384 systems,[12,13] and adoption of biodiesel.[14,15] the challenge of high exhaust emissions during engine cold start and warm‐up still remains, which is caused by the low cylinder and exhaust temperatures, resulting in poor catalyst efficiency.[16].
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