Department of Engineering Science University of Oxford Felix Leach, Richard Stone University of Oxford Dave Richardson Jaguar Land Rover Andrew Lewis, Sam Akehurst, James Turner University of Bath Roger Cracknell, Sarah Remmert, Steven Campbell - Shell felix.leach@eng.ox.ac.uk a Highly Boosted GDI engine June 23 2017
Outline Introduction Boosted engines PN from boosted engines Ultraboost Engine DMS PN measurement Results Load Fuel injection pressure EGR Inlet air temperature Exhaust back pressure Lambda Fuel injection timing Conclusions Slide 2
Boosted engines Stone, Introduction to Internal Combustion Engines, 4 th Ed. 2012 Boosted 1.6L NA 2.5L Highly boosted engines move road load operating points to a more efficient part of the engine map Slide 3
Boosted engines Bugatti Chiron 8.0L engine quad-turbocharged (2x parallel sequential) Mercedes-AMG A45 Mercedes M133 AMG 2.0 L Single turbocharger Slide 4
Boosted engines Bugatti Chiron 8.0L engine quad-turbocharged (2x parallel sequential) 25.1 bar BMEP Mercedes-AMG A45 Mercedes M133 AMG 2.0 L Single turbocharger 28.3 bar BMEP Slide 5
PN from boosted engines Higher cylinder Ts & Ps Greater post-flame oxidation? Higher exhaust backpressures Higher residuals? Better mixture formation Higher exhaust temperatures Greater post-flame oxidation? Slide 6
Highly-boosted, heavilydownsized engine torque curve and power output of the NA Jaguar Land Rover AJ133 5.0 L V8 engine 35% improvement in fuel economy / CO 2 target 60% downsizing (2.0 litre i4) Driveability of the original V8 to be maintained Operation on 95 RON pump gasoline Type Inline 4 cylinder Bore Stroke 83 92 mm Displacement 1991 cm 3 Valves per cylinder 2 intake, 2 exhaust Compression ratio 9:1 Maximum fuel pressure 200 bar Peak BMEP 35 bar Peak cylinder pressure 150 bar Slide 7
Particulate Matter measurements Cambustion DMS500 Reavell et al. SAE 2002-01-2714 Slide 8
DMS mode fitting Slide 9
Digital filtering of low diameter PN To replicate PMP measurement protocol 50% count efficiency: D50 = 23 nm >90% count efficiency: D90 = 41 nm Wiebe function: d p > 14 f 1 exp 3.54 d p 14 40 1.09 Slide 10
Wiebe (#/cc) Effect of Wiebe filtering 8.0E+08 6.0E+08 4.0E+08 2.0E+08 0.0E+00 0.0E+00 2.0E+08 4.0E+08 6.0E+08 8.0E+08 Logfit (#/cc) Slide 11
Sampling location Approx 3m downstream of exhaust manifold Water cooled exhaust manifold Downstream of backpressure throttle and one silencer No catalyst Sampling location Slide 12
Results load ramp PN measured from ~50 500 Nm load (~3-32 bar BMEP) Fixed engine speed (2000 rpm) 9 steps 3 injection pressures Naturally aspirated and turbocharged regions Change in calibration between two regions All tests conducted on a baseline gasoline (97 RON, EN228) Slide 13
PN emission (#/cm3) Results load ramp Particle Number 6E+7 5E+7 4E+7 BMEP / bar 0 5 10 15 20 25 30 35 Naturally Aspirated region 60 bar injection pressure 80 bar injection pressure 100 bar injection pressure 160 bar injection pressure 180 bar injection pressure 200 bar injection pressure 60/160 bar injection pressure 3E+7 Turbocharged region 2E+7 1E+7 0E+0 0 100 200 300 400 500 Torque / Nm Slide 14
Accumulation mode diameter / nm Results load ramp Particle size 250 200 150 100 BMEP / bar 0 5 10 15 20 25 30 35 Turbocharged region 60 bar injection pressure 80 bar injection pressure 100 bar injection pressure 160 bar injection pressure 180 bar injection pressure 200 bar injection pressure 50 Naturally Aspirated region 0 0 100 200 300 400 500 Torque / Nm Slide 15
Test points Slide 16
Results - EGR 2000rpm full load Slide 17
Results Inlet air T 1250rpm / 3.77 bar BMEP Slide 18
Results Exhaust Back Pressure 3000rpm full load Slide 19
Results Lambda 4000rpm full load Slide 20
PN emission (#/cm 3 ) Results Fuel injection timing 1250rpm / 3.77 bar BMEP 3.5E+07 3.0E+07 2.5E+07 2.0E+07 1.5E+07 20 C Inlet air 40 C Inlet air 1.0E+07 5.0E+06 0.0E+00 340 btdc 330 btdc 320 btdc Slide 21
Conclusions Variable Engine load Fuel injection pressure EGR Inlet air temperature Exhaust back pressure λ (AFR) Spark timing Fuel injection timing Effect on PN emissions Load Particulates P Particulates EGR Particulates T Particulates Back pressure Particulates λ Particulates Ignition Particulates Injection Particulates Reference: Leach et al. Particulate emissions from a highly boosted GDI engine International Journal of Engine Research 2017 Slide 22
ULTRABOOST consortium Slide 23
Any questions? Slide 24