Two dimensional numerical modelling and analysis of a novel electromagnetic inductive valve.

A novel type of electromagnetic inductive valve has been developed for the gas injector of the planar pulsed inductive plasma thruster. However, due to the complex operation process of the valve, the design work and the performance prediction can only be accomplished by experimentation. This paper explains a two dimensional model applied to predict the valve performance. The electromagnetic and mechanical aspects which dominate the valve operation process are treated as two weakly coupled problems. The equivalent circuit method is applied to analyze the electromagnetic problem where the valve is represented by a series of sub-conductors. The Lorentz force is calculated and introduced into the mechanical problem as an analytical load. Simulation and experimental validations are implemented in a prototype valve. Compared results from experiments convince that the present model can be used to predict the valve dynamic performances with satisfying accuracy. Moreover, the detailed insight with respect to the development of magnetic flux density, induced current, Lorentz force and velocity of the diaphragm is presented to better understand the valve operation process. The results indicate that the effective acceleration of the diaphragm occurs in the initial phase of valve opening. Only the diaphragm obtains enough kinetic energy during the first half cycle of the coil current, can the valve be fully opened. [ABSTRACT FROM AUTHOR]