On-road emission measurements of reactive nitrogen compounds from heavy-duty diesel trucks in China.

Emissions of major reactive nitrogen compounds, including nitric oxide (NO), nitrogen dioxide (NO 2) and ammonia (NH 3), from heavy-duty diesel vehicles (HDDVs) place substantial pressure on air quality for many large cities in China. To control nitrogen oxide (NO X) emissions from HDDVs, selective catalytic reduction (SCR) systems have been widely used since the China IV standards. To investigate the impacts of aftertreatment technologies and driving conditions on real-world emissions of reactive nitrogen compounds, a portable emissions measurement system was employed to test eighteen heavy-duty diesel trucks in China. The results showed that the China IV and China V HDDVs with appropriate SCR functionality could reduce NO X emissions by 36% and 53%, respectively, compared to the China III results, although their real-world emissions were still higher than the corresponding emission limits for regulatory engine tests. For these HDDVs, five samples were tested with NH 3 emissions, ranging from 1.67 ppm to 51.49 ppm. The NH 3 emission rates tended to significantly increase under high-speed driving conditions. The results indicate that the current SCR technology may have certain risks in exceeding the future China VI NH 3 limit. However, five China IV/V HDDVs were found to have SCR temperature sensors that were intentionally tampered with, resulting in comparable or even higher NO X emissions and zero NH 3 emissions. Increased NO 2 emissions due to the adoption of diesel oxidation catalysts and diesel particulate filters were also found from our experiments. This study highlights the importance of enhancing in-use compliance requirements and eliminating aftertreatment tampering for China IV and China V HDDVs. Image 1 • Tampered trucks emitted twice as much NO X as normal trucks although no NH 3 detected. • Current selective catalytic reduction may emit NH 3 above the China VI limit. • Oxidation catalysts increased NO 2 by 79%, but little effect on NO X and NH 3. [ABSTRACT FROM AUTHOR]