Rich burn industrial natural gas engines offer best
in class post catalyst emissions by using a non-selective catalyst reduction
aftertreatment technology. However, they operate with reduced power density
when compared to lean burn engines. Dedicated exhaust gas recirculation (EGR)
offers a possible pathway for rich burn engines to use non-selective catalyst
reduction aftertreatment technology without
sacrificing power density. In order to achieve best in class post
catalyst emissions, the precious metals and washcoat of a non-selective
catalyst must be designed according to the expected exhaust composition of an
engine. In this work, a rich burn industrial natural gas engine operating with
dedicated EGR was paired with a commercially available non-selective catalyst.
At rated brake mean effective pressure (BMEP) the air-fuel ratio was swept
between rich and lean conditions to compare the catalyst reduction efficiency
and post catalyst emissions of rich burn and dedicated EGR combustion. It was
found that due to low oxides of nitrogen (NOx) emissions across the
entire air-fuel ratio range, dedicated EGR offers a much larger range of
air-fuel ratios where low regulated emissions can be met. Low engine out NOx also points towards a possibility of using an oxidation catalyst rather than a
non-selective catalyst for dedicated EGR applications. The location of the NOx-CO
tradeoff was shifted to more rich conditions using dedicated EGR.
References
[1]
EPA CFR 40 Part 60 Subpart JJJJ. https://www.ecfr.gov/current/title-40/chapter-I/subchapter-C/part-60/subpart-JJJJ
Ivanic, Z., Ayala, F., Goldwitz, J. and Heywood, J.B. (2005) Effects of Hydrogen Enhancement on Efficiency and NOx Emissions of Lean and EGR-Diluted Mixtures in a SI Engine. SAE Paper 2005-01-0253. https://doi.org/10.4271/2005-01-0253
[4]
Jamal, Y., Wagner, T. and Wyszynski, M.L. (1996) Exhaust Gas Reforming of Gasoline at Moderate Temperatures. International Journal of Hydrogen Energy, 21, 507-519. https://doi.org/10.1016/0360-3199(95)00103-4
[5]
Gerty, M.D. and Heywood, J.B. (2006) An Investigation of Gasoline Engine Knock Limited Performance and the Effects of Hydrogen Enhancement. SAE Paper 2006-01-0228. https://doi.org/10.4271/2006-01-0228
[6]
Alger, T., Gingrich, J. and Mangold, B. (2007) The Effect of Hydrogen Enrichment on EGR Tolerance in Spark Ignited Engines. SAE Paper 2007-01-0475. https://doi.org/10.4271/2007-01-0475
[7]
Alger, T. and Mangold, B. (2009) Dedicated EGR: A New Concept in High Efficiency Engines. SAE Paper 2009-01-0694. https://doi.org/10.4271/2009-01-0694
[8]
Alger, T., Mangold, B., Roberts, C. and Gingrich, J. (2012) The Interaction of Fuel Anti-Knock Index and Cooled EGR on Engine Performance and Efficiency. SAE Paper 2012-01-1149. https://doi.org/10.4271/2012-01-1149
[9]
Liu, C., Li, F., Song, H. and Wang, Z. (2018) Effects of H2/CO Addition on Knock Tendency and Lean Limit in a Natural Gas SI Engine. Fuel, 233, 582-591. https://doi.org/10.1016/j.fuel.2018.06.102
[10]
Denton, B., Chadwell, C., Gukelberger, R. and Alger, T. (2017) Design and Implementation of a D-EGR Mixer for Improved Dilution and Reformate Distribution. SAE Paper 2017-01-0647.
[11]
EUROMOT. MWM Methane Number Calculator. https://www.euromot.eu/publication-and-events/publications
[12]
Kline, S.J. and McClinktock, F.A. (1953) Uncertainties in Single Sample Experiments. Mechanical Engineering, 75, 3-8.
[13]
Glassman, I. and Yetter, R.A. (2008) Combustion. Academic Press, Cambridge.
[14]
Methane: The Other Important Greenhouse Gas. EDF. https://www.edf.org/climate/methane-other-important-greenhouse-gas
[15]
Van Roekel, C., Montgomery, D.T., Singh, J. and Olsen, D.B. (2019) Evaluating Dedicated Exhaust Gas Recirculation on a Stoichiometric Industrial Natural Gas Engine. International Journal of Engine Research, 22, 491-502. https://doi.org/10.1177/1468087419864733
[16]
Van Roekel, C., Montgomery, D.T., Singh, J. and Olsen, D.B. (2021) Response Surface Method Optimization of a Natural Gas Engine with Dedicated Exhaust Gas Recirculation. International Journal of Engine Research, 23, 577-590.
[17]
Heywood, J.B. (1988) Internal Combustion Engine Fundamentals. McGraw-Hill, New York.
