Abstract
Electric propulsion (EP) technologies offer performance advantages compared to chemical systems. The implementation of electric thrusters in small spacecraft has been prohibited by the high power demands of conventional thrusters and the complexity of the required power conditioning units and propellant supply system. Advances in micro electronics have made the use of EP on small satellites feasible. Research and development on 3 technologies: 1. Helicon Double Layer Thruster (HDLT), 2. Hollow Cathode Thruster (HCT) and 3. Pulsed Plasma Thruster (PPT) has focussed on characterisation and design optimisation for small, micro and nanosatellite missions respectively. All thrusters operate in differing regimes and display varying degrees of development. Initial characterisation of the HDLT operating with argon propellant shows a maximum measured thrust of 1.7 mN for an operating power of 500 W. The current investigation has demonstrated a thrust of 1.7 mN and specific impulse of 70s at 50W for a HCT operating with krypton propellant. The development of PPTs for the STRaND-1 nanosatellite mission demonstrates the option of utilising EP to extend the lifetime of CubeSat missions.