stoichiometric compression ignition (sci) engine concept · • operate compression ignition engine...
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Stoichiometric Compression Ignition (SCI) Engine Concept
DOE Contract DE-FC26-05NT42416
Rich Winsor and Kirby Baumgard John Deere Power Systems
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Outline
History Objectives Overall Concept Major Issues Comparison to Other Concepts Status of Development Further Work Acknowledgements
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Operation of Diesel Engines at Stoichiometric
Starting
Full load at low speeds
Military Investigations in 1989 – 1991 for increased power
Full time Stoichiometric Compression Ignition for emission control on DDC Series 60 prototype engine in November, 1981
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Program Objectives
• Heavy-duty vehicle engine of reasonable size and cost
• Engine meeting 2010 on-highway emission standards
• Superior fuel economy and life cycle cost • Applicability to off-highway vehicles
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SCI Concept
• Operate compression ignition engine atstoichiometric and use three-way catalyst forcontrol of NOx, HC, and CO
• Use continuously-regenerating diesel particulatefilter for PM control
• Obtain superior fuel efficiency because of rapidcombustion near TDC and efficient air system withreduced exhaust aftertreatment losses
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Major SCI Issues
• Smoke and PM at φ = 1.00 • NOx level and three-way catalyst efficiency • High exhaust temperature • Control to maintain stoichiometry, especially
during rapid load changes • Transient response
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Comparison of Alternative Combustion Concepts
• Massive EGR – high percentages of EGR at relatively rich A/F ratio to reduce NOx
• Extreme EGR – very high EGR to give true Low Temperature Combustion (LTC) with low NOx andPM
• HCCI – homogeneous charge ignites and produces very little NOx and PM (requires EGR for higherloads)
• PPCI – some homogeneous charge ignites near TDC, while remainder of fuel is injected relativelylate to minimize NOx
• SCI – conventional diesel combustion at near optimum timing with φ = 1
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Full Load Estimates of Low Emission Concepts
Combustion System % EGR φ Major Issues
Massive EGR 40 - 50 0.8 power & PM
Extreme EGR 60 - 70 0.9 power & efficiency
HCCI 45 - 55 0.9 power & control
PPCI 40 - 50 0.8 control and PM
SCI 0 - 20 1.0 control, NOx & PM
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Advantages of SCI Concept
• Little or no EGR • High power capability with moderate cylinder
pressure • Low air and exhaust flows • Low turbocharger boost requirements • Rapid combustion near TDC for good fuel economy• Easy starting and reliable combustion • Relatively simple and reliable exhaust aftertreatment
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Base Engine – John Deere 6090
9L six-cylinder 242 kW @ 2100 rpm 1530 N-m @ 1575 rpm 118.4 x 136 mm bore x stroke Four-valve head with pushrods Vertical central common rail injector Single-piece steel piston Variable geometry turbocharger Air-to-air intercooled HPL cooled EGR John Deere ECU Off-highway Tier 3 compliant
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Development Status
• Operated at stoichiometric at half and full load
• Smoke and PM – need improvement
• NOx – unclear
• BSFC - promising
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Promising Early Results at Half Load
Stoichiometric Operation with some EGR
0.0
0.1
0.2
0.3
0.4
0.5
0.6
1000 1200 1400 1600 1800 2000 2200
Engine Speed - rpm
PM -
g/kW
h
0
1
2
3
4
5
6
NO
x - g
/kW
h
PM
NOx
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Full Load Smoke Results (~ 20% EGR)
Rated Power Peak Torque 88
77
6 6
712
716
812
712
716
812
Smok
e - F
SN
Smok
e - F
SN 5
4
3
5
4
3
2 2
1 1
0 0 0.92 0.94 0.96 0.98 1.00 1.02 0.92 0.94 0.96 0.98 1.00 1.02
CBM Equivalence Ratio CBM Equivalence Ratio
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Full Load NOx Results (~ 20% EGR)
Rated Power
0
1
2
3
4
5
6
7
8
0 1 2 3 4
NOx - g/kWh
Smok
e - F
SN
Peak Torque
0
1
2
3
4
5
6
7
8
0 1 2 3 4
NOx - g/kWh
Smok
e - F
SN
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Methods to Reduce Smoke and PM
• Combustion system optimization
• Higher injection pressure • Multiple injection strategy • Less EGR – no EGR • Higher H/C ratio in fuel • Oxygenated fuel
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BSFC Estimates from Simulation
• Simulation was baselined using production engine• Heat release changed to curve calculated from
cylinder pressure data at stoichiometric conditions • With exhaust aftertreatment and using standard
restrictions and efficiencies calculated 41% brake thermal efficiency at rated power and 42% at peaktorque
• Air system restrictions and efficiencies are beingreviewed for improvement based on the reducedflows and pressure ratios
• Camshaft is being optimized for the operatingconditions
• Combustion is being improved by better mixing
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CFD to Improve Combustion System
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Studying Injection, Piston Bowl, and Mixing
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Likely SCI Engine Configuration
ge 1
Variable Valve Actuation - for load control
High Injection Pressure – for PM control
No EGR – for simplicity, cost, low heat rejection
Low Boost Variable Geometry Turbocharger
Three-way Catalyst – for NOx control
Diesel Particulate Filter with air injection – for PM control
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Next Development Activities
• Demonstrate acceptable engine-out smoke and PM
• Refine fuel consumption estimates • Develop F/A ratio control for three-way catalyst • Install VVA system for load control in conjunction
with VTG • Consider higher power for better brake efficiency
(thermal loading issues)
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Acknowledgements
• John Fairbanks - DOE Technology Development Manager
• Ralph Nine - DOE Project Manager • Ricardo Inc. for air system simulations using WAVE • Prof. John Abraham (Purdue University) for CFD of
combustion system • Sturman Industries for advanced injection system
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