Title :
Generalized Model for Magnetically Insulated Transmission Line Flow
Author :
Ottinger, Paul F. ; Schumer, Joseph W. ; Hinshelwood, David D. ; Allen, Raymond J.
Author_Institution :
Plasma Phys. Div., Naval Res. Lab., Washington, DC
Abstract :
A generalized fluid model is developed for electron flow in a magnetically insulated transmission line (MITL). By including electron pressure in the fluid model and allowing nonzero values of the electric field at the cathode, the model can treat both emission and retrapping of flow electrons. For the first time, a direct derivation of the space-charge correction term in the flow equations is also obtained by identifying a new condition at the boundary of the electron layer. Also, a free parameter in the model is chosen so that previously derived MITL flow equations are recovered when the electric field at the cathode is taken to zero; consequently, recent equilibrium MITL rescaling results still apply. Generalized MITL flow equations are derived from the model and solutions presented. These new equations form the basis for a description of the dynamic MITL flow.
Keywords :
electron emission; electron traps; flow simulation; load flow; plasma boundary layers; plasma flow; plasma simulation; power transmission lines; pulsed power supplies; space charge; cathode; dynamic MITL flow; electron emission; electron flow; electron layer boundary; electron pressure; electron retrapping; equilibrium rescaling; flow equations; free parameter; generalized fluid model; magnetically insulated transmission line flow; space-charge correction; Anodes; Cathodes; Electron emission; Equations; Impedance; Insulation; Load flow; Power transmission lines; Transmission lines; Voltage; Electron emission; electron pressure; flow impedance; fluid model; magnetically insulated transmission line (MITL); power flow;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2008.2004221
