Active thermal control system for nano-satellites
Satellites are subjected to various types of thermal loads or radiative loads while in orbit. The evolution of reduction in the size of the satellites led to few important requirements which intend to reduction in size and mass of their subsystems. As a result a device has to be designed in order...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2015
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/64879 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Satellites are subjected to various types of thermal loads or radiative loads while
in orbit. The evolution of reduction in the size of the satellites led to few important
requirements which intend to reduction in size and mass of their subsystems. As a
result a device has to be designed in order to cater the radiative thermal loads with
reduced mass and size. This can be achieved using an electrochromic device.
Electrochromic devices are capable of altering their optical properties when a
certain potential is applied. Most basic electrochromic devices consists of active
reflective electrode, ion conducting and an ion storage layers. The materials used as
active electrode are mainly metal oxides of very small thickness. The electrolyte is
the ion conducting layer which can be conducting polymers or inorganic protons or
positive ions that can intercalated and de-intercalated with the active layer which
are bonded as half cells with active layer and ion conductor.
The present work investigates all thin film electrochromic device made of
inorganic oxides. Polymeric electrolytes are not suitable for space environment that
might outgas and contaminate the substrate over which it is coated. The emissivity
variation of two different samples made of LiPC liquid electrolyte and Ta205 Solid
electrolyte with the c-W03 as active electrochromic layer are found in the MIR and
FIR region (2 - 25 11m). The substrate is Al6061 and ITO over glass acted as top
contacts. The emissivity variation achieved is between 0.7-0.82 and 0.23-0.29 at
300K using FTIR Spectrometer. Such property of modulating emissivity makes
electrochromic devices as strong contenders to other existing active thermal control
devices for small satellites. |
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