Numerical Simulation and Flame Analysis of Combustion and Knock in a DISI Optically Accessible Research Engine

Iaccarino, Salvatore; Breda, Sebastiano; D'Adamo, Alessandro; Fontanesi, Stefano; Irimescu, Adrian; Merola, Simona Silvia

doi:10.4271/2017-01-0555

Cited by 15 publications

(5 citation statements)

References 23 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…On the other hand, this type of test bed provides valuable information in terms of in-cylinder phenomena. Therefore, it has been used by many researchers and companies in recent years [1,32,33]. One other issue is that the optical window is flat, while the setup found in the commercial engine from which the cylinder head was taken featured a profile designed for wall guided stratification (i.e.…”

Section: Mfb Mfbmentioning

confidence: 99%

Flame Front and Burned Gas Characteristics for Different Split Injection Ratios and Phasing in an Optical GDI Engine

2019

Self Cite

View full text Add to dashboard Cite

Direct-injection in spark-ignition engines has long been recognized as a valid option for improving fuel economy, reducing CO2 emissions and avoiding knock occurrence due to higher flexibility in control strategies. However, problems associated with mixture formation are responsible for soot emissions, one of the most limiting factors of this technology. Therefore, the combustion process and soot formation were investigated with different injection strategies on a gasoline direct injection (GDI) engine. The experimental analysis was realized on an optically accessible single cylinder engine when applying single, double and triple injection strategies. Moreover, the effect of fuel delivery phasing was also scrutinized by changing the start of the injection during late intake- and early compression-strokes. The duration of injection was split in different percentages between two or three pulses, so as to obtain close to stoichiometric operation in all conditions. The engine was operated at fixed rotational speed and spark timing, with wide-open throttle. Optical diagnostics based on cycle resolved digital imaging was applied during the early and late stages of the combustion process. Detailed information on the flame front morphology and soot formation were obtained. The optical data were correlated to in-cylinder pressure traces and exhaust gas emission measurements. The results suggest that the split injection of the fuel has advantages in terms of reduction of soot formation and NOx emissions and a similar combustion performance with respect to the single injection timing. Moreover, an early injection resulted in higher rates of heat release and in-cylinder pressure, together with a reduction of soot formation and flame distortion. The double injection strategy with higher percentage of fuel injected in the first pulse and early second injection pulse showed the best results in terms of combustion evolution and pollutant emissions. For the operative condition studied, a higher time for mixture homogenization and split of fuel injected in the intake stroke shows the best results.

show abstract

Section: Mfb Mfbmentioning

confidence: 99%

Flame Front and Burned Gas Characteristics for Different Split Injection Ratios and Phasing in an Optical GDI Engine

2019

Self Cite

View full text Add to dashboard Cite

show abstract

“…Vancoillie et al [42] used a fuel-specific Arrhenius formulation for the reaction rate of methanol and ethanol and the average ignition delay was used to integrate a knock precursor species. A similar approach based on the calculation of fuel specific AI delays from chemical kinetics simulations with validated mechanism was developed and used in the past by d'Adamo et al in a research unit in [43]. Chen and co-authors investigated the influence of turbulence intensity on the knock propensity of a highly downsized SI engine in [44].…”

Section: The Knock Modelmentioning

confidence: 99%

CFD Analysis and Knock Prediction into Crevices of Piston to Liner Fireland of an High Performance ICE

Rosetti

Iotti

Bedogni

et al. 2019

SAE Technical Paper Series

Self Cite

View full text Add to dashboard Cite

show abstract

“…The experimental results also showed that several knock events occurred on the exhaust side. Iaccarino et al 18 observed on a single-cylinder optical engine that the auto-ignition combustion occurred on both sides of the cylinder. The statistical results showed that the knock probability on the intake side was relatively high and that on the exhaust side was relatively low.…”

Section: Introductionmentioning

confidence: 99%

Experimental study of spatial distribution of knock events in a turbocharged spark-ignition engine

Meng,

Han,

Fan

et al. 2024

International Journal of Engine Research

View full text Add to dashboard Cite

An experimental investigation on the spatial distribution of knock events in a turbocharged spark-ignition engine for hybrid vehicle applications was conducted by using a multichannel fiber optic method. The knock positions were detected under different conditions to investigate the influence of crucial engine design and operating parameters on the knock characteristics including the spatial distribution in the combustion chamber and its relationship to knock intensity. The measured data reveal that the spatial distribution in the engine with a port fuel injection (PFI) system is mainly located on the exhaust side with insignificant influence of engine speed and load, which is attributed to the elevated thermal load around the exhaust valves. However, the knock events under gasoline direct-injection (DI) conditions were found to occur in more scattered locations with more occurring on the engine front-end and rear-end sides. These results indicate that the in-cylinder fuel-air mixing process may have a significant impact on the knock occurrence spots under DI conditions. The knock positions of the engine with different excessive air ratios, injection timings, and intake-valve timings were also detected, indicating that engine operating parameters have complex influences on the knock-region distribution in a DI engine. In addition, experiments were also carried out in two different cylinders to verify the cylinder-to-cylinder variations in knock regions which may be caused by the engine cooling design. Furthermore, no apparent correlations were observed between the knock position and the knock intensity by analysis of the experimental data.

show abstract

Numerical Simulation and Flame Analysis of Combustion and Knock in a DISI Optically Accessible Research Engine

Cited by 15 publications

References 23 publications

Flame Front and Burned Gas Characteristics for Different Split Injection Ratios and Phasing in an Optical GDI Engine

Flame Front and Burned Gas Characteristics for Different Split Injection Ratios and Phasing in an Optical GDI Engine

CFD Analysis and Knock Prediction into Crevices of Piston to Liner Fireland of an High Performance ICE

Experimental study of spatial distribution of knock events in a turbocharged spark-ignition engine

Contact Info

Product

Resources

About