By assuming an effective, rate determing "reaction layer" between the decomposition and flame zones, a new theoretical relation for burning rate of the form, BR=k（1/RT）ⁿ exp(Ea/RT)(P/Z)ⁿ, has been deduced where BR = burning rate, k, n=constants, Ea = activation energy, Z = mean compressibility factor, P=combustion chamber pressure and T=temperature of reaction zone. Inclusion of compressibility factor in the equation permitted the application of the concept to real situations prevailing in actual design and analysis of propulsion systems.
The proposed model was tested visa vis experimental data and it was concluded that the burning rates predicted by the proposes model is in excellent agreement with the measured values at high as well as low combustion chamber pressures. It was also shown that this model is indeed superior to the conventional empirical model, BR=ap^m where a, m=constants, and the semiempirical model, 1/BR=A/P+B/P^1/3 where A = chemical reaction time parameter and B = diffusion time parameter, particularly in the region where the combustion chamber pressures exceed 1,000 psia.