Three-stage heat release in n-heptane auto-ignition

Sarathy, S. Mani; Tingas, Efstathios-Al.; Nasir, Ehson F.; Detogni, Alberta; Wang, Zhandong; Farooq, Aamir; Im, Hong G.

doi:10.1016/j.proci.2018.07.075

Cited by 50 publications

(60 citation statements)

References 37 publications

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“…On the other hand, when the temperature is pointed strongly, then the system undergoes the thermal runaway, which usually develops in the last part of the explosive stage [22,29,42]. In previous studies relating to the autoignition of H 2 /air, CH 4 /air, n-hexane/air, n-heptane/air, DME/air, and ethanol/air mixtures, it was shown that chemical runaway regime practically occupies all the explosive stage, while the thermal runaway regime only appears at the very final portion of the explosive stage [22,34,37,38,41,43,44,46,[52][53][54][55][56]. The results diaplayed in Table 2 suggest that autoignition of ammonia is qualitatively different than this of hydrocarbons in that the chemical runaway process is very short and the process develops as a thermal explosion.…”

Section: Autoignition Of Ammoniamentioning

confidence: 99%

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Algorithmic Analysis of Chemical Dynamics of the Autoignition of NH3–H2O2/Air Mixtures

et al. 2019

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The dynamics of a homogeneous adiabatic autoignition of an ammonia/air mixture at constant volume was studied, using the algorithmic tools of Computational Singular Perturbation. Since ammonia combustion is characterized by both unrealistically long ignition delays and elevated NO x emissions, the time frame of action of the modes that are responsible for ignition was analyzed by calculating the developing time scales throughout the process and by studying their possible relation to NO x emissions. The reactions that support or oppose the explosive time scale were identified, along with the variables that are related the most to the dynamics that drive the system to an explosion. It is shown that reaction H 2 O 2 (+M) → OH + OH (+M) is the one contributing the most to the time scale that characterizes ignition and that its reactant H 2 O 2 is the species related the most to this time scale. These findings suggested that addition of H 2 O 2 in the initial mixture will influence strongly the evolution of the process. It was shown that ignition of pure ammonia advanced as a slow thermal explosion with very limited chemical runaway. The ignition delay could be reduced by more than two orders of magnitude through H 2 O 2 addition, which causes only a minor increase in NO x emissions.

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Section: Autoignition Of Ammoniamentioning

confidence: 99%

“…Note that the point where the two time scales meet is right before the point where the temperature completes its steep increase. This feature appears also in the autoignition of H 2 /air, CH 4 /air, n-hexane/air, n-heptane/air, DME/air, and ethanol/air mixtures [22,34,37,38,41,43,44,46,[52][53][54][55][56].…”

Section: Autoignition Of Ammoniamentioning

confidence: 99%

Algorithmic Analysis of Chemical Dynamics of the Autoignition of NH3–H2O2/Air Mixtures

et al. 2019

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“…As indicated in the figure, almost all timescales at any given instance are dissipative (indicated by solid curves) and very few are explosive (indicated in dotted curves). This is a common feature of the homogeneous autoignition process that has been demonstrated extensively; e.g., [41,42,46,47,[59][60][61][62][63][64][65][66][67][68]. The few explosive timescales appear from the start of the process until the point where the temperature undergoes a steep increase.…”

Section: Csp Analysis On Auto-ignition Systemsmentioning

confidence: 83%

Computational Singular Perturbation Method and Tangential Stretching Rate Analysis of Large Scale Simulations of Reactive Flows: Feature Tracking, Time Scale Characterization, and Cause/Effect Identification. Part 2, Analyses of Ignition Systems, Laminar and Turbulent Flames

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Ciottoli

et al. 2020

Data Analysis for Direct Numerical Simulations of Turbulent Combustion

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“…The system of the M algebraic equations ( f m ≈ 0) defines a low dimensional surface, known as slow invariant manifold (SIM), on which the solution evolves, while the system of ordinary differential equations (ODEs) governs the slow evolution of the solution on the SIM and its dynamics is characterized by the fastest of the slow time scales (M + 1), when the solution evolves sufficiently far from the boundaries of the SIM [29]. The identification of the slow characteristic CSP mode (i.e., the M + 1 mode) can be achieved only in the context of a reduced model, where the fast and slow modes can be well-defined [30][31][32][33][34]. The sign of the real part of the eigenvalue associated with each mode determines the mode's nature: a positive or negative real part indicates an explosive or dissipative mode, respectively.…”

Section: Computational Singular Perturbation (Csp) Algorithmic Tmentioning

confidence: 99%

Computational investigation of rod-stabilized laminar premixed hydrogen–methane–air flames

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Tingas

2020

AIAA Scitech 2020 Forum

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A computational study of steady, rod-stabilized, inverted, lean, CH 4-air and H 2-CH 4-air flames is conducted. For the CH 4-air flames, either decreasing the inlet equivalence ratio or increasing the mean inflow velocity leads to a larger standoff distance, and below a critical value of the inlet equivalence ratio or above a critical value of the inflow velocity, the flame blows off. For the H 2-CH 4-air flames, decreasing the inlet equivalence ratio has similar effects as those on the CH 4-air flames; however, increasing the inflow velocity reduces the standoff distance. Though counter-intuitive, the predicted behaviour of the flames is consistent with the experimental observations. Both the CH 4-air and H 2-CH 4-air flames exhibit preferential diffusion effects such as superadiabatic temperatures and local equivalence ratio variations, which are more pronounced for the H 2-CH 4-air flames, displaying non-uniform and localized consumption rates of the fuel components. The strong diffusion of H 2 plays an important role to maintain and even strengthen the reaction processes in the anchoring region and the counter-intuitive stabilization/blow-off of the H 2-CH 4-air flames.

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Three-stage heat release in n-heptane auto-ignition

Cited by 50 publications

References 37 publications

Algorithmic Analysis of Chemical Dynamics of the Autoignition of NH3–H2O2/Air Mixtures

Algorithmic Analysis of Chemical Dynamics of the Autoignition of NH3–H2O2/Air Mixtures

Computational Singular Perturbation Method and Tangential Stretching Rate Analysis of Large Scale Simulations of Reactive Flows: Feature Tracking, Time Scale Characterization, and Cause/Effect Identification. Part 2, Analyses of Ignition Systems, Laminar and Turbulent Flames

Computational investigation of rod-stabilized laminar premixed hydrogen–methane–air flames

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