Transcript Slide 1

Measurements and Characterization of Gasoline HCCI Combustion
Angelo P. Chialva, Randy E. Herold, David E. Foster, Jaal B. Ghandhi
Lab Objective
Engine Intake Charge: Imposed Unmixedness
Combustion and Emissions Results
Temperature Stratification: Baseline cases vs. Temperature Stratification (T_strat_e1) cases.
• To quantify the effects fuel/air, thermal,
and residual gas unmixedness have on
gasoline HCCI combustion
Investigating in-cylinder mixture
charge bulk unmixedness:
-Using dual intake surge tank, split
runner setup, investigate the incylinder flow field evolution from 330
°bTDC (intake) through 30 °bTDC
(compression) using PLIF.
GM HCCI Lab Experiments Chart
Engine Load IMEP
An increase in engine IMEP is observed as delta
temperature between runners mixture increases.
COV of IMEP
Improvement of COV of IMEP is found at
stages with high cycle to cycle variations.
Emissions Index CO
Effects of intake charge temperature stratification
provide trends with higher combustion burning efficiencies.
Emissions Index HC
Effects of intake charge temperature stratification
provide trends with higher combustion burning efficiencies.
Increasing delta temperature at a fixed “mass averaged temperature.” Maximum temperature delta ~ 80 degrees Celsius.
Approach to Unmixedness Experiments
EGR Stratification: Baseline cases vs. EGR Stratification (EGR_unmixedness) cases.
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Combustion Efficiency
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Baseline_2
Baseline_3
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Unmixedness Experiments: Lab setup
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Engine intake port / intake manifold design:
- Dual and independent intake charge runners.
- Extended intake port septum.
- Two independently heat controlled dual intake
charge mixtures (air, fuel and external EGR)
- Homogeneous EGR and
intake charge temperature.
Temperature Stratification
Case#1 – T_strat_d
Intake Charge Temperature
Sweeps
-Imposed intake charge thermal
unmixedness by:
Split runner / split
port setup
- Varying intake charge
temperature at each runner.
- Targeting in-cylinder mass
averaged temperatures within
HCCI window.
- Maximum temperature delta
up 80 degrees Celsius.
Case#2 – T_strat_e
Intake valves lift profile target:
“minimization of charge mixing in
intake port due to back-flow.”
stock
profile
EGR Stratification
Case#1
Case#2
Pressure Balanced Intake
System: EGR + Air + Fuel
-Imposed intake charge EGR
unmixedness by:
current
profile
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330
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Air Intake Temperature (C)
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Combustion Efficiency
Similar burning efficiencies are achieved at
lower intake charge temperatures.
- Varying EGR distribution
between split intake charges.
University of Wisconsin Engine Research Center
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Air Intake Temperature (C)
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Baseline_1
Baseline_2
Baseline_3
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EGR_unmixedness_2
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EINO (g/kg)
CA 50 (deg aTDC)
window shift
Emissions Index HC
High combustion efficiency at lower intake charge
temperatures results in lower HC emissions.
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Baseline_2
Baseline_3
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EGR_unmixedness_2
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- Low Temperature End: COV
of IMEP (1).
- High Temperature End:
Knock index (2).
- Engine IMEP through out
temperature window (3).
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-Definition of HCCI combustion
temperature window:
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HCCI Combustion
Performance Baseline
Baseline_1
Baseline_2
Baseline_3
EGR_unmixedness_1
EGR_unmixedness_2
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window shift
EIHC (g/kg)
- Bulk stratification is created by
feeding each port independently.
However, that initially stratified charge
is mixed throughout the induction and
compression processes, resulting in a
uniform unmixedness at 30 °bTDC.
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Air Intake Temperature (C)
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Combustion Phasing CA50
Combustion phasing approaching TDC occurs
at lower intake charge temperatures.
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Air Intake Temperature (C)
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Emissions Index NO
Levels of NO emissions increases as intake charge
temperature increases with an offset of 20 degrees
respect to baseline data points.
Future Work
Temperature offset on engine data between cases with homogeneous and unmixed EGR ~ 20 degrees Celsius.
• Conduct experiments in optical engine to test different
intake port/ intake manifold setups for the purpose of
maintaining charge bulk unmixedness.
• Run HCCI combustion tests in metal engine to characterize
the effects of thermal and EGR unmixedness as different
levels of uniform unmixedness are obtained in the mixture
charge.
• Analyze combustion and emissions performance in HCCI
engine tests while introducing thermal and EGR
unmixedness at lighter engine loads and leaner air-fuel
mixture conditions.
• Study the combined effects of thermal and EGR
unmixedness in engine combustion and emissions while
implementing rebreathing cams and varying effective CRs.