M. R. Denison scite author profile

An analysis of the surface temperature, and hence mass flux, response of a solid propellant to a disturbance in gas pressure has been developed. Time lags in the gas phase are neglected while transient heat conduction in the solid is considered. The results are obtained by perturbing the conservation equations in both the gas phase and the solid phase. Stability conditions are obtained in terms of a few dimensionless parameters which depend upon the steady state conditions. T HE COUPLING of pressure disturbances with propellant combustion has been the subject of several recent investigations (1 through 5). 4 It is now generally accepted that this feature plays an important role in the mechanism of instability (6). The most elaborate of the recent analyses (2) obtains results in terms of eleven sets of parameters which can be varied independently. Many simplifications were required in order to obtain even this complex solution. The value of such an analysis is not in obtaining explicit mathematical relationships suitable for design calculations, but rather in obtaining an understanding of what physical conditions may be expected to have a large influence on the unstable burning phenomenon. Therefore, an analysis of comparable sophistication with results in a simpler form is desirable.It was indicated by Hart and McClure (2) that a characteristic time for heat conduction in the solid is at least an order of magnitude greater than the characteristic times for the gas phase transport processes and the chemical reactions. This suggests that the gas may adjust very quickly to changes in conditions when compared to the response of the. solid. In the case of periodic pressure disturbances, time lags in the solid phase may dominate, provided the period of the disturbance is large compared to the characteristic time for gas phase adjustment. Thus, there is an upper limit in the frequency of the pressure disturbance above which an analysis neglecting gas phase time lags does not apply. This limit, which would vary depending on the physical properties of the combustion gases, is on the order of 10 4 -10 5 cps for many propellants.The physical processes presumed to take place are as follows:Consider first a step function increase in pressure. The response may be thought of as occurring in two phases. After the rapid application of the disturbance, the combustion zone moves quickly to a new position nearer the surface. Later it moves slowly as the surface temperature of the solid responds to the changed condition.The mass flux leaving the surface is less than would normally occur at the new pressure because, during the first period, the surface temperature does not have time to adjust to its steady state value. When relative motion between the combustion zone and the surface becomes small, the mass Received Nov. 25, 1960.

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Solid rocket exhaust in the stratosphere - Plume diffusion and chemical reactions

Denison

Lamb

Bjorndahl

et al. 1994

Journal of Spacecraft and Rockets

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Compressible Free Shear Layer With Finite Initial Thickness

Baum

Denison

1963

AIAA Journal

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Modeling of dust entrainment by high-speed airflow

Denison

Hookham

1996

AIAA Journal

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Interacting supersonic laminar wake calculations by a finite difference method.

Baum¹,

Denison²

1967

AIAA Journal

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M. R. Denison

A Simplified Model of Unstable Burning in Solid Propellants

Solid rocket exhaust in the stratosphere - Plume diffusion and chemical reactions

Compressible Free Shear Layer With Finite Initial Thickness

Modeling of dust entrainment by high-speed airflow

Interacting supersonic laminar wake calculations by a finite difference method.

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