Applications that might benefit from low power ion propulsion systems include Earth-orbit magnetospheric mapping satellite constellations, low Earth-orbit satellites, geosynchronous Earth-orbit satellite north-south stationkeeping, and asteroid orbiters. These spacecraft are likely to have masses on the order of 50 to 500 kg with up to 0.5 kW of electrical power available. A power processing unit for a 0.2 kW-class ion thruster is currently under development for these applications. The first step in this effort is the development and testing of a 0.24 kW beam power supply. The design incorporates a 20 kHz full bridge topology with multiple secondaries connected in series to obtain outputs of up to 1200 V(sub DC). A current-mode control pulse width modulation circuit built using discrete components was selected for this application. An input voltage of 28 +/- 4 V(sub DC) was assumed, since the small spacecraft for which this system is targeted are anticipated to have unregulated low voltage busses. Efficiencies in excess of 91 percent were obtained at maximum output power. The total mass of the breadboard was less than 1.0 kg and the component mass was 0.53 kg. It is anticipated that a complete flight power processor could weigh about 2.0 kg.
[1]
Michael J. Patterson,et al.
Scaling of Ion Thrusters to Low Power
,
1998
.
[2]
Roger M. Myers,et al.
NSTAR Ion Thruster and Breadboard Power Processor Functional Integration Test Results
,
1996
.
[3]
Michael J. Patterson,et al.
Development of an Ion Thruster and Power Processor for New Millennium's Deep Space 1 Mission
,
1997
.
[4]
Luis R. Pinero,et al.
The 10 kW power electronics for hydrogen arcjets
,
1992
.
[5]
John R. Miller,et al.
Development Status of the NSTAR Ion Propulsion System Power Processor
,
1995
.
[6]
Abraham Pressman,et al.
Switching Power Supply Design
,
1997
.
[7]
Michael J. Patterson,et al.
Low-Power Ion Propulsion for Small Spacecraft
,
1997
.
[8]
Keith H. Billings,et al.
Switchmode power supply handbook
,
1999
.