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High-performance nanoadhesive bonding of space-durable polymer and its performance under space environments

Publication Type : Journal Article

Publisher : Journal of Spacecraft and Rockets

Source : Journal of Spacecraft and Rockets, Volume 46, Number 1, p.218–224 (2009)

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Keywords : acetone, Adhesive Joints, Cohesive Properties, Electron Spectroscopy for Chemical Analysis, Elevated Temperatures, Epoxy Adhesives, Epoxy Resins, Failure analysis, Gravimetric Analysis, Joint Strengths, Low-Power, Low-Pressure Plasmas, Nanopowders, Nuclear Propulsion, Nuclear reactors, Polybenzimidazole, Polymer surfaces, Polymers, Silicates, Space Environments, Surface chemistry, Surface Energies, surface tension, Surface-Modified, Thermogravimetric analysis, Ultra-High Temperatures

Campus : Coimbatore

School : Department of Aerospace Engineering, School of Engineering

Department : Aerospace

Year : 2009

Abstract : The present investigation highlights fabrication of polybenzimidazole by high-performance nanoadhesive and its performance under space environments. High-performance nanoadhesive is prepared by dispersing silicate nanopowder into ultra-high-temperature-resistant epoxy adhesive. The surface of polybenzimidazole is ultrasonically cleaned by acetone and then modified by low-pressure plasma before bonding. Electron spectroscopy for chemical analysis reveals that the polymer surface becomes hydrophilic, resulting in an increase in surface energy. Thermogravimetric analysis studies show that the cohesive properties of nanoadhesive are more stable when heated up to 350°C. The adhesive joint strength of surface-modified polybenzimidazole increases considerably, and there is a further significant increase in joint strength when it is prepared by nanosilicate epoxy adhesive. When the nanoadhesive joint of polybenzimidazole is exposed to the safe-low-power critical-experiment nuclear reactor, there is a considerable increase in joint strength up to a dose of 444 kGy and then a decrease. When the join ts are exposed to cryogenic (-196°C) and elevated temperatures (+300° C) for 100 h and thermal-fatigue conditions, the joint could retain 95 % of the joint strength. The failure mode of the surface-modified polymer is cohesive within the adhesive.

Cite this Research Publication : Shantanu Bhowmik, Benedictus, R., Poulis, H., Bonin, H., and Bui, V. Tam, “High-performance nanoadhesive bonding of space-durable polymer and its performance under space environments”, Journal of Spacecraft and Rockets, vol. 46, pp. 218–224, 2009.

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