Thermal controls for NTU student satellite series-I (SCOOB-I) satellite

The development of miniature satellites for academic and scientific research is well understood due to its feasibility, cheaper manufacturing and launch costs, and capability of performing most tasks similar to larger ones. The satellites are subjected to harsh thermal load variations in orbit, affe...

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Main Author: Birthi, Sanika
Other Authors: Sunil Chandrakant Joshi
Format: Thesis-Master by Coursework
Language:English
Published: Nanyang Technological University 2020
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Online Access:https://hdl.handle.net/10356/136582
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1365822023-03-11T17:44:55Z Thermal controls for NTU student satellite series-I (SCOOB-I) satellite Birthi, Sanika Sunil Chandrakant Joshi School of Mechanical and Aerospace Engineering Satellite Research Centre MSCJoshi@ntu.edu.sg Engineering::Aeronautical engineering Engineering::Mechanical engineering The development of miniature satellites for academic and scientific research is well understood due to its feasibility, cheaper manufacturing and launch costs, and capability of performing most tasks similar to larger ones. The satellites are subjected to harsh thermal load variations in orbit, affecting the performance of subsystems and payloads. Each component has a specified upper and lower operational temperature limit within which the thermal variations experienced in the orbit should reside. This dissertation primarily focusses on the thermal controls for the first satellite in NTU’s newly launched student satellite series: SCOOB-I. A detailed finite-difference thermal model for the 3U CubeSat in the equatorial orbit is simulated for expected launch times and mission operation. Thermal analyses for worst-case hot and worst-case cold conditions are conducted using a thermal engineering tool suite called C & R Thermal Desktop. The analysis results significantly influenced the thermal control strategies employed. Passive thermal control in the form of multi-layer insulation was adopted for the imager which previously reached unacceptable cold temperatures. The SCOOB-I satellite component temperatures were successfully maintained within their required limits after adopting thermal control. This study is then extended to conduct preliminary thermal modelling and analysis of a microsatellite named ARCADE: Atmospheric Coupling and Dynamic Explorer, which is going to be launched along with SCOOB-I. The preliminary findings showed that the components CIP_PCB and cold finger display overheating. Thus, thermal control would be necessary to keep the temperatures within the acceptable range. Master of Science (Aerospace Engineering) 2020-01-02T13:00:49Z 2020-01-02T13:00:49Z 2019 Thesis-Master by Coursework https://hdl.handle.net/10356/136582 en application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering::Aeronautical engineering
Engineering::Mechanical engineering
spellingShingle Engineering::Aeronautical engineering
Engineering::Mechanical engineering
Birthi, Sanika
Thermal controls for NTU student satellite series-I (SCOOB-I) satellite
description The development of miniature satellites for academic and scientific research is well understood due to its feasibility, cheaper manufacturing and launch costs, and capability of performing most tasks similar to larger ones. The satellites are subjected to harsh thermal load variations in orbit, affecting the performance of subsystems and payloads. Each component has a specified upper and lower operational temperature limit within which the thermal variations experienced in the orbit should reside. This dissertation primarily focusses on the thermal controls for the first satellite in NTU’s newly launched student satellite series: SCOOB-I. A detailed finite-difference thermal model for the 3U CubeSat in the equatorial orbit is simulated for expected launch times and mission operation. Thermal analyses for worst-case hot and worst-case cold conditions are conducted using a thermal engineering tool suite called C & R Thermal Desktop. The analysis results significantly influenced the thermal control strategies employed. Passive thermal control in the form of multi-layer insulation was adopted for the imager which previously reached unacceptable cold temperatures. The SCOOB-I satellite component temperatures were successfully maintained within their required limits after adopting thermal control. This study is then extended to conduct preliminary thermal modelling and analysis of a microsatellite named ARCADE: Atmospheric Coupling and Dynamic Explorer, which is going to be launched along with SCOOB-I. The preliminary findings showed that the components CIP_PCB and cold finger display overheating. Thus, thermal control would be necessary to keep the temperatures within the acceptable range.
author2 Sunil Chandrakant Joshi
author_facet Sunil Chandrakant Joshi
Birthi, Sanika
format Thesis-Master by Coursework
author Birthi, Sanika
author_sort Birthi, Sanika
title Thermal controls for NTU student satellite series-I (SCOOB-I) satellite
title_short Thermal controls for NTU student satellite series-I (SCOOB-I) satellite
title_full Thermal controls for NTU student satellite series-I (SCOOB-I) satellite
title_fullStr Thermal controls for NTU student satellite series-I (SCOOB-I) satellite
title_full_unstemmed Thermal controls for NTU student satellite series-I (SCOOB-I) satellite
title_sort thermal controls for ntu student satellite series-i (scoob-i) satellite
publisher Nanyang Technological University
publishDate 2020
url https://hdl.handle.net/10356/136582
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