Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna

The need for large antennas in the aerospace industry has spurred research into deployable membrane antennas, due to their lightweight and compact storage capacity. One of the main problems of incorporating large antennas in small satellites is the packaging and safe deployment of structural booms a...

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Main Author: Divya Agarwal
Other Authors: Tai Kang
Format: Thesis-Master by Coursework
Language:English
Published: Nanyang Technological University 2020
Subjects:
Online Access:https://hdl.handle.net/10356/137109
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1371092023-03-11T17:33:17Z Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna Divya Agarwal Tai Kang School of Mechanical and Aerospace Engineering Satellite Research Center mktai@ntu.edu.sg Engineering::Mechanical engineering::Mechanics and dynamics Engineering::Aeronautical engineering::Materials of construction The need for large antennas in the aerospace industry has spurred research into deployable membrane antennas, due to their lightweight and compact storage capacity. One of the main problems of incorporating large antennas in small satellites is the packaging and safe deployment of structural booms and membranes. The goal of a researcher in this field would be to enhance deployable boom predictability and ground testability, develop design that are tolerant of manufacturing imperfections, and get reliable and simple deployment methods. This study aims to mechanically design, analyze and develop a deployable boom mechanism for an S-band planar membrane antenna. The design must fulfill the desired structural requirements, aiming to achieve large apertures with reduced stowage volume and low mass budget. To perform the preliminary antenna boom design, a trade off among the concepts of deployment devices available in the literature was conducted and a suitable concept was chosen, through a simplified analytical hierarchy process. A matrix of space-qualified material was created, and the right material was selected based on a criterion that gave a low density and high stiffness material. The boom length was among the principle requirements of this study. Accordingly, static, modal, and harmonic analyses necessary to assess the requirements and choose the boom secondary dimensions were executed via a finite element model. Two designs were generated: concept A (tape spring) and concept B (telescopic boom). The former, which is more innovative, met all the criteria except stiffness and rigidity. The latter approach, which is more conservative, is relatively heavier and does not fit into the small volume of satellite. However, it provides better stiffness and can be optimized to meet the specified requirements. The novelty of this study is that it uses a stacer. Instead of a belt for the deployment, which, to the best of the author’s knowledge, is unique. Master of Science (Aerospace Engineering) 2020-02-26T01:14:52Z 2020-02-26T01:14:52Z 2019 Thesis-Master by Coursework https://hdl.handle.net/10356/137109 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::Mechanical engineering::Mechanics and dynamics
Engineering::Aeronautical engineering::Materials of construction
spellingShingle Engineering::Mechanical engineering::Mechanics and dynamics
Engineering::Aeronautical engineering::Materials of construction
Divya Agarwal
Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna
description The need for large antennas in the aerospace industry has spurred research into deployable membrane antennas, due to their lightweight and compact storage capacity. One of the main problems of incorporating large antennas in small satellites is the packaging and safe deployment of structural booms and membranes. The goal of a researcher in this field would be to enhance deployable boom predictability and ground testability, develop design that are tolerant of manufacturing imperfections, and get reliable and simple deployment methods. This study aims to mechanically design, analyze and develop a deployable boom mechanism for an S-band planar membrane antenna. The design must fulfill the desired structural requirements, aiming to achieve large apertures with reduced stowage volume and low mass budget. To perform the preliminary antenna boom design, a trade off among the concepts of deployment devices available in the literature was conducted and a suitable concept was chosen, through a simplified analytical hierarchy process. A matrix of space-qualified material was created, and the right material was selected based on a criterion that gave a low density and high stiffness material. The boom length was among the principle requirements of this study. Accordingly, static, modal, and harmonic analyses necessary to assess the requirements and choose the boom secondary dimensions were executed via a finite element model. Two designs were generated: concept A (tape spring) and concept B (telescopic boom). The former, which is more innovative, met all the criteria except stiffness and rigidity. The latter approach, which is more conservative, is relatively heavier and does not fit into the small volume of satellite. However, it provides better stiffness and can be optimized to meet the specified requirements. The novelty of this study is that it uses a stacer. Instead of a belt for the deployment, which, to the best of the author’s knowledge, is unique.
author2 Tai Kang
author_facet Tai Kang
Divya Agarwal
format Thesis-Master by Coursework
author Divya Agarwal
author_sort Divya Agarwal
title Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna
title_short Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna
title_full Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna
title_fullStr Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna
title_full_unstemmed Mechanical design, analysis and development of deployment mechanism for cubesat SAR S-band membrane antenna
title_sort mechanical design, analysis and development of deployment mechanism for cubesat sar s-band membrane antenna
publisher Nanyang Technological University
publishDate 2020
url https://hdl.handle.net/10356/137109
_version_ 1761781522402115584