Optical diagnostics and multi-point pressure sensing on the knocking combustion with multiple spark ignition

An integrated experimental and Large-Eddy Simulation (LES) study is presented for homogeneous premixed combustion in a spark-ignition engine. The engine is a single-cylinder two-valve optical research engine with transparent liner and piston: the Transparent Combustion Chamber (TCC) engine. This is a relatively simple, open engine configuration that can be used for LES model development and validation by other research groups. Pressure-based combustion analysis, optical diagnostics and LES have been combined to generate new physical insight into the early stages of combustion. The emphasis has been on developing strategies for making quantitative comparisons between high-speed/high-resolution optical diagnostics and LES using common metrics for both the experiments and the simulations, and focusing on the important early flame development period. Results from two different LES turbulent combustion models are presented, using the same numerical methods and computational mesh. Both models yield Cycle-to-Cycle Variations (CCV) in combustion that are higher than what is observed in the experiments. The results reveal strengths and limitations of the experimental diagnostics and the LES models, and suggest directions for future diagnostic and simulation efforts. In particular, it has been observed that flame development between the times corresponding to the laminar-to-turbulent transition and 1% mass-burned fraction are especially important in establishing the subsequent combustion event for each cycle. This suggests a range of temporal and spatial scales over which future experimental and simulation efforts should focus.

Download Full-text

Investigation on spray cyclic variations under idle operation of engine using optical diagnostics and statistical methods

International Journal of Engine Research ◽

10.1177/1468087420926015 ◽

2020 ◽

pp. 146808742092601 ◽

Cited By ~ 1

Author(s):

Yifan Zhou ◽

Wenyuan Qi ◽

Yuyin Zhang ◽

Peinan Zhang

Keyword(s):

Statistical Methods ◽

Direct Injection ◽

Injection Pressure ◽

Optical Diagnostics ◽

Spark Ignition ◽

Fuel Temperature ◽

Direct Injection Engine ◽

Mass Distributions ◽

Cyclic Variations ◽

Vapor Mass

Under idle operations of a spark-ignition direct-injection engine, issues such as misfire, unstable combustion, and power imbalance between individual cylinders are often encountered, which worsen the fuel economy and tailpipe emissions. These undesired phenomena have close relations with cyclic variations of the fuel sprays in the cylinder. In this article, the spray cyclic variations under idle operations have been investigated at a constant volume chamber using ultraviolet/visible laser absorption/scattering imaging technique and Mie scattering optical diagnostics combined with different statistical methods such as probability presence image, intersection over union, and edge fluctuation length. The variations in spray morphology of liquid/vapor phases and vapor mass distributions have been characterized. It was found that the cyclic spray variation after the end of injection is too large to ignore, implying that this cyclic variation should be taken into consideration when matching the spray to a combustion chamber or numerical modeling. The effects of injection pressure and fuel temperature on spray cyclic variations have been quantitatively examined. The results show that the higher injection pressure or the higher fuel temperature is, the larger variation in spray morphology and vapor mass distributions was observed, indicating that adopting an appropriately lower injection pressure or lower fuel temperature is helpful to a stable ignition and combustion under idle conditions for a non-homogeneous spark-ignition direct-injection engine.

Download Full-text

Optical diagnostics of early flame development in a DISI (direct injection spark ignition) engine fueled with n-butanol and gasoline

Energy ◽

10.1016/j.energy.2015.10.140 ◽

2016 ◽

Vol 108 ◽

pp. 50-62 ◽

Cited By ~ 24

Author(s):

Simona Silvia Merola ◽

Cinzia Tornatore ◽

Adrian Irimescu ◽

Luca Marchitto ◽

Gerardo Valentino

Keyword(s):

Direct Injection ◽

Optical Diagnostics ◽

Spark Ignition ◽

Spark Ignition Engine ◽

Flame Development ◽

Direct Injection Spark Ignition

Download Full-text

66-4: Invited Paper : High Dielectric Capacitive Materials for High Linearity Multi-Point Pressure-Sensing Touch Controls

SID Symposium Digest of Technical Papers ◽

10.1002/sdtp.11817 ◽

2017 ◽

Vol 48 (1) ◽

pp. 976-979

Author(s):

Johnson Hou ◽

Eason Chern ◽

Victor Chou ◽

Benson Yu ◽

Raymond Tsai

Keyword(s):

Pressure Sensing ◽

High Linearity ◽

Point Pressure ◽

High Dielectric

Download Full-text

An Experimental Study on the Effects of Burst Pressure on Air Blast Development in a Blast Wave Simulator

10.1115/fedsm2021-65930 ◽

2021 ◽

Author(s):

Parker Zieg ◽

John Benson ◽

Yang Liu

Keyword(s):

Blast Wave ◽

High Speed ◽

Imaging System ◽

Blast Waves ◽

Burst Pressure ◽

Schlieren Image ◽

Membrane Thickness ◽

Pressure Sensing ◽

Point Pressure ◽

Driver Section

Abstract Due to the extensive use of explosive devices in military conflicts, there has been a dramatic increase in life-threatening injuries and resultant death toll caused by explosive blasts. In an attempt to better understand the blast waves and mitigate the damages caused by such blast waves, various devices/systems have been developed to replicate the field blast scenarios in laboratory conditions. The East Carolina University Advanced Blast Wave Simulator (i.e., ECU-ABWS) is one such facility that can reproduce blast waves of various shapes and profiles. The peak overpressure of a blast is the key factor that causes the greatest number of damages, and it is essentially determined by the burst pressure of the blast. Therefore, a better understanding of the effects of burst pressure on blast generation and development is strongly desired to develop safer and more effective blast mitigation technologies. In the present study, a series of experiments were carried out in the ECU-ABWS to characterize the blast waves generated under different burst pressure conditions. While the incident (side-on) pressures at multiple locations along the blast propagation direction were measured using a temporally-resolved multi-point pressure sensing system, the time-evolutions of blast wave profiles were also qualitatively revealed by using a high-speed Schlieren imaging system. The synchronization of pressure sensing and Schlieren image acquisition enables us to extract more physical details of the dynamic blast wave development under different burst pressure conditions by associating the incident pressures and shock wave morphologies. In this study, the different burst pressures were achieved by altering the thickness of the membrane separating the driver section of pressurized gas and the driven section of air at atmospheric pressure. It is found that there is a linear relationship between the burst pressure and the peak overpressure. As the burst pressure increases (by increasing the membrane thickness), more clearly defined shock wavefronts are also observed along with the peak overpressure increase.

Download Full-text