Abstract
Reactive systems in a thermochemical conversion domain are modelled considering N-specie, 1-energy and 2-mass conservation equations assuming negligible pressure gradient resulting in N+3 non-linear coupled PDE system with dependency on thermodynamic and transport properties. Typically, simplistic temperature-dependent polynomials are chosen for estimating thermal conductivity and specific heat, however, the estimation of mass diffusion coefficient (Di;mix) follows a complicated procedure involving kinetic theory culminating in Chapman-Enskog equation. This renders the solution computationally intensive. The complexity is simplified by assuming a constant Lewis (Le) number, a standard practice in the analytical solution for conventional reactive systems. In fixing Le, (Di;mix) is equated to thermal diffusivity (a ratio of thermodynamic properties) resulting in the specie and energy equation yielding a similar solution and collapse of N+3 system of simultaneous equations to 3 equations. The current article explores the validity and limitation of assuming constant Le in the simulation of char conversion process in air and steam. Results of char conversion are compared for fixed Le and D estimated with Chapman{Enskog expresion. The analysis suggests that Le remains invariant only under a severely restricted set of conditions. Fixing Le influences, the conversion process either over-/under-predicting the conversion time scales and the product gas composition.
Highlights
Thermochemical conversion processes are numerically modelled by a set of non-linear coupled equations expressing the conservation of mass, specie, momentum and energy, and a thermody
A straightforward and widely practiced approach to estimate the mass/specie diffusivity coefficient is deriving it from assumed Lewis number, first proposed by M
Numerical models for thermochemical conversion of char are often simplified by invoking the Lewis number assumption to simplify the system of equations
Summary
Thermochemical conversion processes are numerically modelled by a set of non-linear coupled equations expressing the conservation of mass, specie, momentum and energy, and a thermody-. Among the thermodynamic and transport properties, estimation of the mass diffusivity coefficient (Di,mix) involves a mathematically rigorous approach requiring solution to complex kinetic theory-based equations. A straightforward and widely practiced approach to estimate the mass/specie diffusivity coefficient is deriving it from assumed Lewis number, first proposed by M. Giovangigli [1], founding on methane-air premixed and non-premixed flames. A ratio of specie thermal diffusivity of the specie mass diffusivity is expressed as, α λ λ
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