Computational singular perturbation analysis of super-knock in SI engines

Pre-ignition engine cycles leading to super-knock were simulated with a 48 species skeletal iso-octane mechanism to identify the dominant reaction pathways that are present in super-knock. To mimic pre-ignition, a deflagration front was generated via a hot spot that is placed over the piston at clos...

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Bibliographic Details
Published inFuel (Guildford) Vol. 225; pp. 184 - 191
Main Authors Jaasim, Mohammed, Tingas, Efstathios-Al, Hernández Pérez, Francisco E., Im, Hong G.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.08.2018
Elsevier BV
Subjects
Analytical chemistry
Chemical reactions
Computation
Computational singular perturbation
Computer applications
Computer simulation
Cylinders
Deflagration
Engines
Fluid dynamics
Fuels
Knock
Organic chemistry
Perturbation methods
Pre-ignition
Singular perturbation
Spark ignition
Super-knock
Thermodynamics
Computational singular perturbation
Super-knock
Pre-ignition
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Summary:Pre-ignition engine cycles leading to super-knock were simulated with a 48 species skeletal iso-octane mechanism to identify the dominant reaction pathways that are present in super-knock. To mimic pre-ignition, a deflagration front was generated via a hot spot that is placed over the piston at close proximity to the end-wall. Computational singular perturbation (CSP) was used to analyze the chemical dynamics at various in-cylinder locations: a point at the center of the cylinder where the deflagration front consumes the air/fuel mixture and two points located at 3 mm from the end-wall where super-knock and mild knock occur. The CSP analysis of the point at the center of the cylinder reveals weak two-stage ignition-like dynamics with a short second stage. At the other points, a pronounced two-stage ignition is displayed with a long second stage. A distinct contribution of formaldehyde (CH2O) at the second stage of ignition that adds to fast explosive modes in the super-knock points is not observed in the point at the center. A comparison between knock and super-knock analysis indicates that a similar set of reactions is responsible for the abnormal behavior but the fast explosive time scales are comparatively slower for knock, indicating lower reactivity, which results in the reduced intensity of knock. The analyzed results decoded important reactions responsible for the occurrence of super-knock.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2018.03.128