Effect of Engine Operating Parameters on Hydrocarbon Oxidation in the Exhaust Port and Runner of a Spark-Ignited Engine 950159
The effect of engine operating parameters (speed, spark timing, and fuel-air equivalence ratio [Φ]) on hydrocarbon (HC) oxidation within the cylinder and exhaust system is examined using propane or isooctane fuel. Quench gas (CO2) is introduced at two locations in the exhaust system (exhaust valve or port exit) to stop the oxidation process. Increasing the speed from 1500 to 2500 RPM at MBT spark timing decreases the total, cylinder-exit HC emissions by ∼50% while oxidation in the exhaust system remains at 40% for both fuels. For propane fuel at 1500 rpm, increasing Φ from 0.9 (fuel lean) to 1.1 (fuel rich) reduces oxidation in the exhaust system from 42% to 26%; at 2500 RPM, exhaust system oxidation decreases from 40% to approximately 0% for Φ = 0.9 and 1.1, respectively. Retarded spark increases oxidation in the cylinder and exhaust system for both fuels. Decreases in total HC emissions are accompanied by increased olefinic content and atmospheric reactivity. The effect of coolant temperature on HC emissions was examined using a gasoline fuel. The decrease in HC emissions with increasing coolant temperature occurs within the engine cylinder while the percentage burn up in the exhaust system remains constant.
Citation: Kaiser, E., Siegl, W., Trinker, F., Cotton, D. et al., "Effect of Engine Operating Parameters on Hydrocarbon Oxidation in the Exhaust Port and Runner of a Spark-Ignited Engine," SAE Technical Paper 950159, 1995, https://doi.org/10.4271/950159. Download Citation
Edward W. Kaiser, Waiter O. Siegl, Frederick H. Trinker, David F. Cotton, Wai K. Cheng, Kristine Drobot
Ford Motor Co., Massachusetts Institute of Technology
International Congress & Exposition
Global Emission Experiences: Processes, Measurements, and Substrates-SP-1094