Abstract
The advent of CubeSats has provided a platform for relatively low-budget programmes
to realise space missions. In South Africa, Stellenbosch University and
the Cape Peninsula University of Technology have impressive space programmes
and have been involved in numerous successful satellite launches. A number of
CubeSat projects are currently in progress and commercial-grade Attitude Determination
and Control Systems (ADCS), and communications modules, are being
developed by the respective universities. The development of a CubeSat-compatible
Electrical Power System remains absent, and would be beneficial to future satellite
activity here in South Africa.
In this thesis, some fundamental aspects of electronic design for space applications
is looked at, including but not limited to radiation e↵ects on MOSFET devices;
this poses one of the greatest challenges to space-based power systems. To this
extent, the di↵erent radiation-induced e↵ects and their implications are looked at,
and mitigation strategies are discussed.
A review of current commercial modules is performed and their design and performance
evaluated. A few shortcomings of current systems are noted and corresponding
design changes are suggested; in some instances these changes add complexity,
but they are shown to introduce appreciable system reliability.
A single Li-Ion cell configuration is proposed that uses a 3.7 V nominal bus voltage.
Individual battery charge regulation introduces minor inefficiencies, but allows
isolation of cells from the pack in the case of cell failure or degradation. A further
advantage is the possibility for multiple energy storage media on the same power
bus, allowing for EPS-related technology demonstrations, with an assurance of minimum
system capabilities.
The design of each subsystem is discussed and its respective failure modes identified.
A limited number of single points of failure are noted and the mitigation strategies
taken are discussed. An initial hardware prototype is developed that is used to
test and characterise system performance. Although a few minor modifications are
needed, the overall system is shown to function as designed and the concepts used
are proven.
de, B (2021). An Electrical Power System for CubeSats. Afribary. Retrieved from https://track.afribary.com/works/an-electrical-power-system-for-cubesats
De, Benjamin "An Electrical Power System for CubeSats" Afribary. Afribary, 15 May. 2021, https://track.afribary.com/works/an-electrical-power-system-for-cubesats. Accessed 27 Nov. 2024.
De, Benjamin . "An Electrical Power System for CubeSats". Afribary, Afribary, 15 May. 2021. Web. 27 Nov. 2024. < https://track.afribary.com/works/an-electrical-power-system-for-cubesats >.
De, Benjamin . "An Electrical Power System for CubeSats" Afribary (2021). Accessed November 27, 2024. https://track.afribary.com/works/an-electrical-power-system-for-cubesats