Mass‐ and momentum transfer in hydrogen/air and methane/air mixtures

Abstract: In this article we present results for the viscosity and the mass transfer rates of hydrogen/ air, hydrogen/oxygen, methane/air and methane/oxygen mixtures in the temperature range from 1000 to 7000 K and a pressure range from lo3 to lo6 Pa. In addition, the combustion ratio is varied from 0 to 03. The transport properties are calculated from the first order solution of the Chapman Enskog approach to the Boltzmann equation, assuming chemical equilibrium composition. An extensive literature study was performed … Show more

“…[l I]) lead to the formulation of the inelastic collision terms as functions of the relaxation times ~i J n~,~ and ~i j n~*~~~, as well as the partition functions Qint,i. The type of the resulting equation is identical to that of the integral of the elastic collision as given in [9]. The complete method and the resulting integral equations are described in detail by Pascal [7].…”

“…The dynamic viscosity of a mixture, the binary diffusion, and the multi-component diffusion in a mixture are only weakly affected by the thermal nonequilibrium. They do not differ from known solutions and are, therefore, discussed in the first part of this article [9]. All terms contributing to the molecular heat conductivity are affected strongly by the thermal nonequilibrium.…”

“…This value corresponds to a chemically frozen mixture condition. The second term describes the transport of enthalpy concerning the mass flow, also called conductivity due to reaction [9]. The third and fourth terms describe thermal diffusion effects, the third summand describes the Soret effect and the fourth one the Dufour effect.…”

“…The heat conductivity due to translation in a gas mixture with v components can be described by a v-dimensional linear equation system as already applied for the viscosity q and the diffusive mass flux j in [9].…”

“…The vector j t corresponds to the solution vector of the diffusion matrix for concentration and pressure diffusion given in [9]. As constant pressure is assumed for chemical equilibrium, pressure diffusion can be neglected for all following considerations.…”

Energy transfer in hydrogen/air and methane/air mixtures

“…[l I]) lead to the formulation of the inelastic collision terms as functions of the relaxation times ~i J n~,~ and ~i j n~*~~~, as well as the partition functions Qint,i. The type of the resulting equation is identical to that of the integral of the elastic collision as given in [9]. The complete method and the resulting integral equations are described in detail by Pascal [7].…”

“…The dynamic viscosity of a mixture, the binary diffusion, and the multi-component diffusion in a mixture are only weakly affected by the thermal nonequilibrium. They do not differ from known solutions and are, therefore, discussed in the first part of this article [9]. All terms contributing to the molecular heat conductivity are affected strongly by the thermal nonequilibrium.…”

“…This value corresponds to a chemically frozen mixture condition. The second term describes the transport of enthalpy concerning the mass flow, also called conductivity due to reaction [9]. The third and fourth terms describe thermal diffusion effects, the third summand describes the Soret effect and the fourth one the Dufour effect.…”

“…The heat conductivity due to translation in a gas mixture with v components can be described by a v-dimensional linear equation system as already applied for the viscosity q and the diffusive mass flux j in [9].…”

“…The vector j t corresponds to the solution vector of the diffusion matrix for concentration and pressure diffusion given in [9]. As constant pressure is assumed for chemical equilibrium, pressure diffusion can be neglected for all following considerations.…”

Energy transfer in hydrogen/air and methane/air mixtures