Thermal analysis of the 6U CubeSat Velox-II
Development and experimentation of small satellites have become feasible with the advancements in technologies in aerospace industries. The satellites are subjected to various types of thermal loads or radiative loads while in orbit. Every component of the spacecraft has its own temperature...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2015
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/64807 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Development and experimentation of small satellites have become feasible
with the advancements in technologies in aerospace industries. The satellites are
subjected to various types of thermal loads or radiative loads while in orbit. Every
component of the spacecraft has its own temperature limitations and the
temperature of the each component has to be within these limits to avoid reduced
efficiency or permanent damage while in orbit. Thus extensive modelling and
simulation of satellite's behaviour in space environment helps to reduce the risk and
reliability concern.
Velox-II is a 6U Nano-Satellite designed for carrying the communication
payload and it also has an advanced navigation system. In the present work the
thermal . analysis of Velox-II is carried out by ESATAN-TMS software. The
simplified thermal model is built using ESATAN-TMS Workbench, in which a
geometric mathematical model is built to calculate the radiative coupling between
the model nodes followed by thermal mathematical model to calculate the
temperature at specific points. A near equatorial orbit and sub-systems design (i.e.
the power output) parameters are used as the inputs to determine the temperature
profile at concerned locations such as battery, MCU, solar panels etc. The results
obtained are post-processed using ThermNV. The internal components are all
within the acceptable temperature range except for the battery. The minimum
temperature of battery is below the qualification range. In addition, the external
components such as helical antenna, and the solar panels facing the sun suffer over
heating during sunlight phase. |
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