Fuel-efficient exhaust thermal management using cylinder throttling via intake valve closing timing modulation
Fuel-efficient exhaust thermal management using cylinder throttling via intake valve closing timing modulation
- New search for: Akash Garg
- New search for: Akash Garg
- New search for: Mark Magee
- New search for: Chuan Ding
- New search for: Leighton Roberts
- New search for: Greg Shaver
- New search for: Edward Koeberlein
- New search for: Ray Shute
- New search for: David Koeberlein
- New search for: James McCarthy Jr
- New search for: Douglas Nielsen
Most diesel engines meet today's strict NOx and particulate matter emission regulations using after-treatment systems. A major drawback of these after-treatment systems is that they are efficient in reducing emissions only when their catalyst temperature is within a certain range (typically between 250 °C and 450 °C). At lower engine loads this is a major problem as the exhaust temperatures are usually below 250 °C. The primary objective of this study was to analyze "cylinder throttling" via both delayed and advanced intake valve closure timing. The effect of cylinder throttling on exhaust gas temperatures, fuel consumption, in-cylinder combustion and emissions is outlined. A significant increase in turbine outlet temperature accompanied by a decrease in fuel consumption, NOx, and particulate matter emissions was observed. Both delayed and advanced intake valve closure timings were equally effective. The increase in exhaust gas temperatures was attributed to a drop in air flow through the engine, which resulted from a reduction in the volumetric efficiency via cylinder throttling. The increase in fuel efficiency resulted from a decrease in the pumping work through a reduction in air flow through the engine. Reductions in NOx are attributed to the combined effect of a lower in-cylinder temperature due to a reduction in piston-motion-induced compression and a shift to a more premixed combustion mode. Particulate matter emissions were also reduced as a result of additional premixing. At the 1200 RPM and 2.5 bar brake mean effective pressure (BMEP) operating point, both delayed and advanced intake valve closure timings resulted in a turbine outlet temperature increase from 195 °C to 255 °C accompanied by an increase in brake thermal efficiency of 1.5% (absolute) and a reduction in brake-specific NOx and particulate matter emissions by 40% and 30%, respectively.
Document information
Fuel-efficient exhaust thermal management using cylinder throttling via intake valve closing timing modulation
2016
Article (Journal)
English
Similar titles
| Automotive engineering | 2016
Intake Valve Throttling (IVT) - A Sonic Throttling Intake Valve Engine
| SAE Technical Papers | 1968
| SAE Technical Papers | 1993
| Automotive engineering | 1994