Infrared Borescopic Analysis of Ignition and Combustion Variability in a Heavy-Duty Natural-Gas Engine

Abstract: O ptical imaging diagnostics of combustion are most often performed in the visible spectral band, in part because camera technology is most mature in this region, but operating in the infrared (IR) provides a number of benefits. These benefits include access to emission lines of relevant chemical species (e.g. water, carbon dioxide, and carbon monoxide) and obviation of image intensifiers (avoiding reduced spatial resolution and increased cost). Highspeed IR in-cylinder imaging and image processing were used t… Show more

“…In this document, the effectiveness of three ignition systems is compared using standard measurements based on in-cylinder pressure and measurements made by in-cylinder infrared (IR) imaging. Additional details of the high-speed IR imaging and the quantitative metrics derived therefrom can be found elsewhere [3].…”

“…While water is present in the intake charge due to atmospheric humidity, it is found at higher temperature and concentration (both of which yield strong emission) in the volume where combustion has occurred. The significant increases in water concentration (due to a peak water production rate of ~15 × 10 −3 mol/[cm 3 -s] for a laminar, stoichiometric, methane/air premixed f lame) and temperature (~4-fold for a laminar, stoichiometric, methane/air premixed flame) across the thickness of the flame front, a distance of approximately 0.5 mm [34], allow water to serve as a proxy for the location of the flame front and burned-gas region. Since the IR emission lines are so strong, it is often possible to collect sufficient signal without using an intensifier, thus eliminating an expensive, delicate component that reduces spatial resolution.…”

“…Image processing was carried out using a combination of LaVision DaVis and MathWorks MATLAB, as illustrated briefly in Figure 5 and in detail elsewhere [3]. (Note that the processed image in Figure 5 includes labels for some of the features visible in the image.)…”

Infrared Borescopic Evaluation of High-Energy and Long-Duration Ignition Systems for Lean/Dilute Combustion in Heavy-Duty Natural-Gas Engines

“…In this document, the effectiveness of three ignition systems is compared using standard measurements based on in-cylinder pressure and measurements made by in-cylinder infrared (IR) imaging. Additional details of the high-speed IR imaging and the quantitative metrics derived therefrom can be found elsewhere [3].…”

“…While water is present in the intake charge due to atmospheric humidity, it is found at higher temperature and concentration (both of which yield strong emission) in the volume where combustion has occurred. The significant increases in water concentration (due to a peak water production rate of ~15 × 10 −3 mol/[cm 3 -s] for a laminar, stoichiometric, methane/air premixed f lame) and temperature (~4-fold for a laminar, stoichiometric, methane/air premixed flame) across the thickness of the flame front, a distance of approximately 0.5 mm [34], allow water to serve as a proxy for the location of the flame front and burned-gas region. Since the IR emission lines are so strong, it is often possible to collect sufficient signal without using an intensifier, thus eliminating an expensive, delicate component that reduces spatial resolution.…”

“…Image processing was carried out using a combination of LaVision DaVis and MathWorks MATLAB, as illustrated briefly in Figure 5 and in detail elsewhere [3]. (Note that the processed image in Figure 5 includes labels for some of the features visible in the image.)…”

Infrared Borescopic Evaluation of High-Energy and Long-Duration Ignition Systems for Lean/Dilute Combustion in Heavy-Duty Natural-Gas Engines

A Quasi-Dimensional SI Burn Rate Model for Predicting the Effects of Changing Fuel, Air-Fuel-Ratio, EGR and Water Injection

Predicting the Influence of Charge Air Temperature Reduction on Engine Efficiency, CCV and NO_x-Emissions of a Large Gas Engine Using a SI Burn Rate Model