Title :
Equilibrium lengths of railgun plasma armatures
Author :
O´Donnell, Edward E O
Author_Institution :
Sci. Applications Int. Corp., Colorado Springs, CO, USA
fDate :
6/1/1989 12:00:00 AM
Abstract :
Recent data have shown that the length of railgun plasma armatures increases with bore size. The mechanisms for plasma growth and mass loss are treated analytically through a simple thermodynamic model in which mass is added through ablation of bore materials and lost through friction. It is assumed that at the bore wall, a thin boundary layer is formed in the plasma in which the velocity is sufficiently slow that the boundary layer is left behind the bulk of the plasma. Using the scaling relations of J.D. Powell and J. Batteh (1983), a functional relationship between the plasma length lp and bore height h of the form lp=khα, where α≃0.68. Using the model developed in the present work, a linear relationship between lp and h is derived, but the proportionality factor depends on temperature, plasma conductivity, velocity, and boundary-layer thickness. Predictions of the model are interpreted in the light of available data. The model is shown to predict lengths which are in reasonable agreement with the observed data
Keywords :
electromagnetic launchers; plasma boundary layers; plasma temperature; plasma transport processes; ablation; bore height; bore materials; bore size; bore wall; boundary-layer thickness; friction; functional relationship; linear relationship; mass; mass loss; plasma conductivity; plasma growth; plasma length; proportionality factor; railgun plasma armatures; scaling relations; temperature; thermodynamic model; thin boundary layer; velocity; Boring; Conductivity; Electric resistance; Plasma measurements; Plasma properties; Plasma temperature; Projectiles; Railguns; Rails; Voltage;
Journal_Title :
Plasma Science, IEEE Transactions on
