Manufacturing and characterization of aerogel-polymer cores for composites
The unique structure of aerogels has enabled it to be one of the lightest material known to the mankind. Comprising of nearly 99% volume of air, it has one of the lowest density of all known materials. Although light, aerogels has a very high strength to weight ratio. Aerogels also have excellent...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
2009
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/16140 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The unique structure of aerogels has enabled it to be one of the lightest material
known to the mankind. Comprising of nearly 99% volume of air, it has one of the
lowest density of all known materials. Although light, aerogels has a very high
strength to weight ratio. Aerogels also have excellent noise and thermal insulation
properties.
In this project, techniques of manufacturing polymer binded aerogel cores for use in
sandwich composites are examined. Polymers used are the two thermoplastics
namely, Ethylene Vinyl Acetate (EVA) 3185 and Polypropylene (PP). This project
aimed to examine how the different weight percentage of aerogel to polymer affects
the hardness and strength of the cores. In addition Scanning Electron Microscope
(SEM) was used to examine resin percolation in the cores. It was found that for
PP:Aerogel cores, the Young’s modulus increases as the weight percentage of aerogel
increases whereas for the EVA: Aerogel cores, the Young’s modulus increases till an
optimum of 60% aerogel composition before decreasing. Signs of plastic deformation
for PP: Aerogel cores appeared at 75% compressive stress while that of EVA:
Aerogel cores appeared at 85% compressive stress. SEM results showed signs of resin
percolation in the PP: Aerogel core samples but for the EVA: Aerogel cores, there
were no obvious signs of resin percolation. This also explains the deviation in density
of the PP: Aerogel cores fabricated.
This project also explored the method of using PP columns filled with aerogel
granules as sandwich composite cores. PP columns of 20mm and 40 mm filled and
unfilled are tested for Young’s modulus and observations were made. It was
discovered that Young’s modulus is lower for columns filled with aerogel as
compared to unfilled columns. Interesting observations were made with regards to the
compressive behaviour of the columnar structures and the structure of compacted
aerogels. |
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