Electron beam modification of space durable polymeric nano-adhesive bonding of ultra-high temperature resistant polymer
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Nitu Bhatnagar
,
Hans Poulis
Abstract
This investigation highlights fabrication of ultra-high temperature resistant polymers such as polybenzimidazole (PBI) by high-performance nano-adhesive. High-performance nano-adhesive is prepared by dispersing carbon nano-fibers into ultra-high temperature resistant epoxy adhesive. Prior to fabrication of PBI, the surface of PBI is ultrasonically cleaned by acetone and then modified by atmospheric pressure plasma with 30, 60 and 90 s of exposure and low-pressure plasma with 30, 60, 120, 240 and 480 s of exposure. Surface characterization of the unmodified and modified PBI sheets is carried out by contact angle measurements and surface energy of the polymer is estimated. It is observed that the polar component of surface energy leading to total surface energy of the polymer increases significantly when exposed to atmospheric pressure plasma. Tensile lap shear strength of adhesive bonded PBI reveals that atmospheric pressure plasma is more useful than low-pressure plasma in terms of adhesive bond strength of PBI and increases further when fabricated by nano-carbon fibers dispersed epoxy adhesive. The nano-adhesive bonded PBI sheets are post-cured by electron beam radiation under the SLOWPOKE-2 nuclear reactor. Post curing under electron beam radiation further increases the adhesive bond strength considerably.
©2011 by Walter de Gruyter Berlin Boston
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- Synthesis, modification, and characterization of organosilicone and acrylate copolymer latex
- Synthesis and properties of random polysulfone/polyethersulfone copolymers as high-performance polymers
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Articles in the same Issue
- Original Articles
- Fabrication and characterization of organic semiconductor for electromagnetic interference shielding material
- Processing and characterization of poly(ethylene oxide)/clay nanocomposites
- Organic solar cells using a multilayer structure MoO3/Ag/MoO3 as anode
- Dilute solution viscometry study on the miscibility of N,O-carboxymethyl chitosan-cellulose acetate blends
- Determination of relevant “average” properties for tubular filler materials used in composites
- Impact behaviour of thermoplastics — materials testing and simulationa
- Foam injection moulding – specific adjustment of foam structure and mechanical propertiesa
- Metal injection molding of W-Ni-Fe microcutters
- Synthesis, modification, and characterization of organosilicone and acrylate copolymer latex
- Synthesis and properties of random polysulfone/polyethersulfone copolymers as high-performance polymers
- Electron beam modification of space durable polymeric nano-adhesive bonding of ultra-high temperature resistant polymer
