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Abstract

This study compares the cycle-to-cycle dynamics in heat release between the misfire and partial burn regime in a highly lean-operated spark-ignition engine. The cyclic dynamics in these two regimes are generally deterministic as misfires and partial burns are often followed by a higher-energy cycle due to the feed-forward mechanism present in the residual gases. Both short and long-term patterns are investigated by converting the sequences into association rules. Using association rules, as opposed to symbol sequencing, allowed additional insight into the differences in the dynamics when operating in each regime. The influence of the residual amount and residual temperature on the next-cycle dynamics is also investigated using association rules. Results show there exists similar short-term dynamics between the misfire and partial burn regime. Results also indicate the residual amount impacts the next cycle more than the residual gas temperature. Understanding of the differences in the dynamics between the misfire and partial burn regime and how the residual plays a role could impact the control method used.

Keywords

Cyclic dynamics dilute spark-ignition combustion residual combustion stability misfires and partial burns

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References

Quader

. What limits lean operation in spark ignition engines-flame initiation or propagation? SAE technical paper 760760, 1976.

Heywood

. Internal combustion engine fundamentals. New York: McGraw-Hill Education, 1988.

Ozdor

Dulger

Sher

. Cyclic variability in spark ignition engines a literature survey. SAE technical paper 940987, 1994.

Martin

Plee

Remboski

. Burn modes and prior-cycle effects on cyclic variations in lean-burn spark-ignition engine combustion. SAE technical paper 880201, 1988.

Grünefeld

Beushausen

Andresen

, et al. A major origin of cyclic energy conversion variations in SI engines: cycle-by-cycle variations of the equivalence ratio and residual gas of the initial charge. SAE technical paper 941880, 1994.

Zhao

Peng

Williams

, et al. Understanding the effects of recycled burnt gases on the controlled autoignition (CAI) combustion in four-stroke gasoline engines. SAE technical paper 2001-01-3607, 2001.

Shiomoto

Sawyer

Kelly

. Characterization of the lean misfire limit. SAE technical paper 780235, 1978.

Galmiche

Halter

Foucher

, et al. Effects of dilution on laminar burning velocity of premixed methane/air flames. Energy Fuels 2011; 25(3): 948–954.

Aleiferis

Taylor

AMKP

Ishii

, et al. The relative effects of fuel concentration, residual-gas fraction, gas motion, spark energy and heat losses to the electrodes on flame-kernel development in a lean-burn spark ignition engine. Proc IMechE, Part D: J Automobile Engineering 2004; 218(4): 411–425.

10.

Xie

Wan

, et al. Investigations into the influence of internal and external exhaust gas recirculation on the combustion stability in an optical gasoline spark ignition engine. Proc IMechE, Part D: J Automobile Engineering 2015; 229(11): 1514–1528.

11.

Stiffler

Kaul

Drallmeier

. Cyclic dynamics of misfires and partial burns in a dilute spark-ignition engine. Proc IMechE, Part D: J Automobile Engineering 2021; 235(2–3): 333–345.

12.

Maldonado

Stefanopoulou

Scarcelli

, et al. Characteristics of cycle-to-cycle combustion variability at partial-burn limited and misfire limited spark timing under highly diluted conditions. In: ASME 2019 internal combustion engine division fall technical conference. American Society of Mechanical Engineers. DOI:10.1115/icef2019-7256.

13.

Daw

Finney

CEA

Tracy

. A review of symbolic analysis of experimental data. Rev Sci Instrum 2003; 74(2): 915–930.

14.

Finney

CEA

Green

Daw

. Symbolic time-series analysis of engine combustion measurements. SAE technical paper 980624, 1998.

15.

Kaul

Vance

Drallmeier

, et al. A method for predicting performance improvements with effective cycle-to-cycle control of highly dilute spark ignition engine combustion. Proc IMechE, Part D: J Automobile Engineering 2009; 223(3): 423–438.

16.

Hahsler

Grün

Hornik

. Arules- a computational environment for mining association rules and frequent item sets. J Stat Softw 2005; 14(15): 1–25.

17.

Hahsler

. A probabilistic comparison of commonly used interest measures for association rules, https://mhahsler.github. io/arules/docs/measures (2015). https://mhahsler.github.io/arules/docs/measures (accessed 2 August 2022).

18.

Ghandhi

. Pressure and heat release analysis. John Wiley & Sons, Ltd. Hoboken, New Jersey: John Wiley, 2014.

19.

Yun

Mirsky

. Schlieren-streak measurements of instantaneous exhaust gas velocities from a spark-ignition engine. SAE technical paper 741015, 1974.

Investigation of the cyclic dynamics in the misfire and partial burn regime in a dilute spark-ignition engine and the role of the residual

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