Flame Image Velocimetry Analysis of Flame Front Turbulence and Growth
Rate in an Optical Direct-Injection Spark-Ignition Engine 03-15-05-0036
This also appears in
SAE International Journal of Engines-V131-3EJ
High-speed flame imaging has been widely used to investigate flame propagation in
optically accessible direct-injection spark-ignition (DISI) engines. Previous
studies utilized a high-speed movie to measure the overall growth rate of the
flame and to analyze the flame shape and its correspondence with engine
performance and efficiency. This study proposes the flame image velocimetry
(FIV), a new diagnostic method enabling time-resolved, two-dimensional flame
front vector extraction and turbulence intensity calculation. The high-speed
camera is used to record the propagating petrol flame, and contrast variations
are tracked to derive flow vectors. The PIVlab, a Matlab-based open-source code,
is used for this flame front FIV analysis, and the systematic optimization of
processing parameters is performed. The raw flame images are preprocessed using
the contrast-limited adaptive histogram equalization (CLAHE) filter before a
four-step fast Fourier transform (FFT) is applied. The interrogation window size
for each step is optimized to achieve the highest flow vectors, which, for the
studied cases, return 84-84-24-24 pixels with a half overlap. A total of 100
combustion cycles are FIV processed for each test condition to tackle the
inherent cyclic variations. The Reynolds decomposition is applied to individual
cycles to derive high-frequency component magnitude, which is interpreted as
turbulence intensity. A spatial filtering method is used for the decomposition
with optimized cut-off lengths for minimal cyclic variations of the measured
turbulence intensity. The new FIV method is proven useful in a case study using
two injectors with different nozzle structures. The results show that a smaller
hole diameter and counterbore hole shape leads to a higher flame front vector
magnitude, overall higher turbulence intensity, and more uniform distribution of
turbulence than the injector with a larger hole diameter and cylindrical hole
shape. This FIV result explains the higher engine power output and lower cyclic
variations measured for the smaller hole injector.
Citation: Lu, Y., Kim, D., Yang, J., and Kook, S., "Flame Image Velocimetry Analysis of Flame Front Turbulence and Growth Rate in an Optical Direct-Injection Spark-Ignition Engine," SAE Int. J. Engines 15(5):671-687, 2022, https://doi.org/10.4271/03-15-05-0036. Download Citation
Author(s):
Yuwei Lu, Dongchan Kim, Jinxin Yang, Sanghoon Kook
Affiliated:
The University of New South Wales, Australia
Pages: 18
ISSN:
1946-3936
e-ISSN:
1946-3944
Related Topics:
Spark ignition engines
Turbulence
Combustion and combustion processes
Imaging and visualization
Optimization
Engines
Optics
Fuel injection
Research and development
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