Mechanical, thermal and flammability properties of glass fiber film/silica aerogel composites

Aerogels are the best thermal insulating materials ever known because of their extremely low thermal conductivity. However, their applications are limited because of their brittleness and low strength. For maintaining the integrity, we prepared glass fiber film reinforced silica aerogel composites h...

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Bibliographic Details
Published in:Journal of non-crystalline solids 2017-02, Vol.457, p.52-59
Main Authors: Li, Congcong, Cheng, Xudong, Li, Zhi, Pan, Yuelei, Huang, Yajun, Gong, Lunlun
Format: Article
Language:English
Subjects:
Aerogel composites
Aerogels
Cone calorimeters
Flammability
Glass fiber films
Glass fibers
Heat transfer
Insulating materials
Mechanical properties
Silica aerogels
Sol gel process
Thermal conductivity
Thermal insulation
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Summary:Aerogels are the best thermal insulating materials ever known because of their extremely low thermal conductivity. However, their applications are limited because of their brittleness and low strength. For maintaining the integrity, we prepared glass fiber film reinforced silica aerogel composites have been prepared by the sol–gel method via ambient pressure drying. The composites were characterized by scanning electron microscopy, bulk density analysis, Brunauer–Emmett–Teller method, thermal constant analysis, and compression and cone calorimeter tests. The H2O: TEOS molar ratio of the silica aerogels was found to affect the properties of the composites significantly. As the H2O: TEOS molar ratio increased from 2 to 6, the density of the composites first decreased dramatically and then increased slightly. The thermal conductivity also showed the same trend. The mechanical properties of the composites were improved greatly compared to the pure aerogels without compromising their thermal insulation properties. Moreover, the composites prepared in this work exhibited more elasticity and flexibility than the conventional thermal insulating materials. The data obtained from the cone calorimeter test showed that with an increase in the H2O: TEOS molar ratio, the fire hazard of the composites decreased. •Glass fiber films reinforced flexible aerogel composites were successfully prepared.•The effect of H2O/TEOS molar ratios on physical properties of the GF/aerogel composites was studied.•The flexibility of the GF/aerogel composites was great improved without compromising thermal insulation properties.•The fire hazard of the GF/aerogel composites decreased with increasing water content.
ISSN:0022-3093
1873-4812
DOI:10.1016/j.jnoncrysol.2016.11.017