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INJECTION SYSTEMS REQUIREMENTS. Outlook for electrostatic atomization in automotive applications Rodica A. Baranescu Workshop on Electrostatic Atomization, March 2-4, 2009. Traditional requirements. Accurate fuel metering per cycle for load control
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INJECTION SYSTEMS REQUIREMENTS Outlook for electrostatic atomization in automotive applications Rodica A. Baranescu Workshop on Electrostatic Atomization, March 2-4, 2009
Traditional requirements • Accurate fuel metering per cycle for load control • Provide vaporization and distribution in combustion space • Provide the mixture in correct proportion under all conditions (start/acceleration/full power) • Protect sensible components in the injector from damage by deposits in the fuel or by debris
Drivers for Fuel Injection Revolution • Stringent emission standards for NOx and particulates, requiring combustion control • Euro V; US 2007; US 2010 • Fuel consumption and GHG reduction pressure • More stringent “sociability” requirements for CI engines • driving fun: acceleration, low end torque • improved comfort: low noise, easy start • Competition with SI and hybrids (for CI engines) • Fuel injection progress seen in both SI and CI engines
Advanced Requirements for Injection • Increase of operating pressure • Injection rate control and flexibility • Multiple injections per cycle (of determined duration and quantity) • Electronic control and management of injection process
Challenges for injection systems • Reduce injector deposits • High temperature 1200C; 2000 bars; small clearances • Reduce oxidation due to heat entrainment in fuel system • Improve fuel quality worldwide to provide robustness to modern fuel systems • Develop new additive technology for increased detergency • Deal with new fuels (biodiesel) and its poor oxidation stability • Develop new materials and technology for injectors • Develop new software for injection management • Strive for global fuel specifications matched to requirements
Injection Rate Flexibility Provides: • combustion control • Rate of pressure rise • Noise • NOx formation
Development Targets for Injection Systems • Improved nozzle design (including orifices) • Enhanced metering accuracy • Increased injection pressure • Multi injection capability (for combustion control in CI engines)
Common Rail Fuel Injection Systemfrom Delphi Common Rail System with Direct Acting Injector, MTZ 10/2008, Volume 69
Common Rail Fuel Injection Systemfrom “2000 bar Diesel Common Rail by Bosch for Passenger Cars” , MTZ 10/2008, Volume 69
Common Rail System Features • High pressure - independent of injection cycle and engine speed • Constant high pressure during injection • Allows more than one injection per cycle • Square rate of discharge at full and low load • Penalty in noise and high pressure rise in combustion chamber
Multiple injections patterns 1 pre-injection; 2 main injection; 3 steep rise; 4 boot shape; 5 gradual rise; 6 gradual drop; 7 steep drop; 8 close secondary; 9 late post-injection
Common Rail Fuel Injection Systemfrom “Delphi Common Rail System with Direct Acting Injector”, MTZ 10/2008, Volume 69
Piezo Electric Injector • Needle hydraulically actuated by piezo stack • Weight reduced (two fold) • Up to 5 injections (closed coupled) per cycle • Allows precise injections of small quantities (1mm3) • Lower fuel leakage rates ( requires smaller pump)
Conclusions Fuel injection system complexity has increased substantially Design and packaging is additionally challenging Lower pressure injection systems seem more suitable to electrostatic atomization Viscous fuels and liquids and large injection systems seem also suitable to electrostatic charge Approach is interesting and improved atomization is worthwhile; potential for new hardware designs is significant