Parametric study of shock-wave formation in a spatially inhomogeneous self-igniting medium for arrhenius combustion kinetics

Abstract: An approach to describing the formation and propagation of small gas-dynamic perturbations in a spatially inhomogeneous self-igniting medium for arbitrary chemical reaction kinetics was developed in a previous paper. In the present paper, the proposed approach is illustrated by studying the problem for a simple reaction with an Arrhenius reaction rate. A comparison of calculation results with the solution of the complete system of gas dynamics equations shows that the approach provides good accuracy of quantit… Show more

“…The main dimensionless parameters of the problem are the temperature at the center of the hot spot θ m , the effective activation energy ε a in the induction step, the temperature gradient g, the heat-release time τ hr , and the order of the reaction in the heat-release step n. The effect of the first three parameters on shock-wave formation for Arrhenius combustion reaction kinetics was studied in detail in [13]. It can be assumed that the results obtained for θ m , ε a and g remain qualitatively the same.…”

“…For a fixed value of g, the initial point X 0cr moves away from the center of the hot spot with increasing time τ hr . Unlike in the case of a simple reaction with an Arrhenius rate dependence [13], the Table 1 shows that the closer the values of the ratio (τ hr /τ ind )(X 0cr ) to each other [for example, (τ hr /τ ind )(X 0cr ) ≈ 0.1 for g = 0.005 and τ hr = 0.4 or for g = 0.002 and τ hr = 0.8], the smaller the differences between their corresponding values W sp (X 0cr ) and Y (τ cr , X cr ). Thus, the determining parameter of the problem is the ratio of the heat-release time to the induction time at the initial point of the critical characteristic (τ hr /τ ind )(X 0cr ) and not the absolute quantity τ hr .…”

“…The approach developed in [12] and employed to study shock-wave formation for Arrhenius combustion kinetics [13] is used. Chain-branching reaction is modeled by the two-step Korobeinikov-Levin model [14,15].…”

Theoretical description of shock-wave formation in a spatially inhomogeneous combustible medium for chain-branching combustion kinetics

“…The main dimensionless parameters of the problem are the temperature at the center of the hot spot θ m , the effective activation energy ε a in the induction step, the temperature gradient g, the heat-release time τ hr , and the order of the reaction in the heat-release step n. The effect of the first three parameters on shock-wave formation for Arrhenius combustion reaction kinetics was studied in detail in [13]. It can be assumed that the results obtained for θ m , ε a and g remain qualitatively the same.…”

“…For a fixed value of g, the initial point X 0cr moves away from the center of the hot spot with increasing time τ hr . Unlike in the case of a simple reaction with an Arrhenius rate dependence [13], the Table 1 shows that the closer the values of the ratio (τ hr /τ ind )(X 0cr ) to each other [for example, (τ hr /τ ind )(X 0cr ) ≈ 0.1 for g = 0.005 and τ hr = 0.4 or for g = 0.002 and τ hr = 0.8], the smaller the differences between their corresponding values W sp (X 0cr ) and Y (τ cr , X cr ). Thus, the determining parameter of the problem is the ratio of the heat-release time to the induction time at the initial point of the critical characteristic (τ hr /τ ind )(X 0cr ) and not the absolute quantity τ hr .…”

“…The approach developed in [12] and employed to study shock-wave formation for Arrhenius combustion kinetics [13] is used. Chain-branching reaction is modeled by the two-step Korobeinikov-Levin model [14,15].…”

Theoretical description of shock-wave formation in a spatially inhomogeneous combustible medium for chain-branching combustion kinetics