Epoxy - carbon nanotubes composites with improved thermal and
Transcription
Epoxy - carbon nanotubes composites with improved thermal and
« Marie Skłodowska-Curie » scientific award in the field of materials science Epoxy - carbon nanotubes composites with improved thermal and electrical conductivity for CFRP application Ewelina Ciecierska Warsaw University of Technology, Faculty of Materials Science and Engineering Woloska, 141, 02-507 Warsaw, Poland Selection of mixing method and nanotubes type 1,00E+01 1- mechanical; 2,3- mechanical +ultrasonic; 1,00E+00 s [S/m] 1,00E-01 4, 5- mechanical +ultrasonic+ surfactant; 1,00E-02 6- three roll milling 1,00E-03 1,00E-04 1,00E-05 1 1,00E+01 2 0,1-0,5 m 3 4 5 6 1,5 m 1 m 1,00E-01 1,00E-03 Conductivity [S/m] Epoxy resin is the most often used resin in aircraft industry, due to good properties such as low density, low shrinkage during curing, high mechanical properties, and low absorption of water. The biggest disadvantage of epoxy resin is low electrical and thermal conductivity. Carbon nanotubes (CNTs) exhibit very unusual properties, low density, high Young's modulus, high tensile strength. They can conduct high density current, they are resistant to high temperature, and have high thermal conductivity. They have high surface area and even small amount of CNTs can significantly change properties of the material. Development of epoxy/carbon nanotubes composites can be meaningful if we think about new application in aircraft structure for lightning strike protection, electromagnetic interference shielding. Application of conductive nanocomposites will reduce the weight of airplane and in the result will diminish the fuel consumption. Electrical conductivity of polymer fiber reinforced composites is still not enough. Increase of conductivity of polymer fiber reinforced composites can be obtain by increasing conductivity of resin. Conductivity of polymer composites can be increased by adding metal powders or metal fibers, but it leads to the increase of materials weight, which is disadvantage in aircraft industry. In my work carbon nanotubes are used as a filler. Aim of my work is to improve conductivity of commonly used epoxy resins and also to improve mechanical properties of materials. In my PhD thesis different type of carbon nanotubes, modified and non-modified were applied. For nanotubes dispersion in polymer matrix numerous mixing methods were used. Influence of application of solvents and surfactants on dispersion was also evaluated. Impact of curing parameters on conductivity was also measured. For manufactured sample electrical and thermal conductivity was measured. Microscopy observations for dispersion control were carried out. Basis on obtained results the best method of mixing and type of nanotubes was selected. Results of my PhD thesis formed the basis for the next project „„Development of manufacturing technology of aviation composite structures with carbon prepregs without autoclave process” where I was taking part. One of the aims of these project was to improve thermal conductivity of CFRP composites. To achive this goal epoxy composites with 1 wt.% of CNTs were used. Such high filler concentration does not let fiber impregantaion. For matrix dilutation styrene was used. Influence of solvent addition on thermal conductivity, rheology properties, gel time of epoxy resin was investigated. Results of my scientific work in the field of epoxy/carbon nanotubes composites are papers in reptuable journals and also on patent application (number P.411637- Composite materials and manufacturing method of composite materials). 1,00E-05 1,00E-07 1,00E-09 1,00E-11 1,00E-13 1,00E-15 Epoxy COOH 3% COOH 5% NH2 2-3% OH 4-5% COOH (Nc) NH2 (Nc) nonmodified (Nc) nonmodified (Nc) CFRP with carbon nanotubes Scanning electron microscopy images of laminates with epoxy matrix doped with carbon nanotubes fabricated: a), b) without styrene, c), d) with 15 mass % of styrene Glass transition temperature Tg /°C Sample Thermal diffusivity CFRP laminates with epoxy/carbon nanotubes matrix containing 1 mass% of CNTs diluted with different amount of styrene EP EP+1%CNT EP+1%CNT +5%styrene EP+1%CNT +10%styrene EP+1%CNT +15%styrene 157 167 155 100 100 Gel time dependently on styrene amount 1- E. Ciecierska, A. Boczkowska, M. Kubiś, P. Chabera, T. Wiśniewski, „Effect of styrene addition on thermal properties of epoxy resin doped with carbon nanotubes” – in review in Polymers for Advanced Technologies 2- E. Ciecierska, A. Boczkowska, K. J. Kurzydlowski, I.D. Rosca, S. V. Hoa, „The effect of carbon nanotubes on epoxy matrix nanocomposites”, Journal of Thermal Analysis and Calorimetry 111 (2), pp. 1019-1024 3- E. Ciecierska, A. Boczkowska, K. J. Kurzydlowski, „Characterization of polymer based nanocomposites with carbon nanotubes”, Journal of Nanoscience and Nanotechnology 14 (4), pp. 2690-2699 4- M. Wladyka-Przybylak, D. Wesolek, W. Gieparda, A. Boczkowska, E. Ciecierska, „Functionalization effect on physico-mechanical properties of multi-walled carbon nanotubes/epoxy composites”, Polymers for Advanced Technologies 22, 1,pp 48–59 5- M. Wladyka-Przybylak, D. Wesolek, W. Gieparda, A. Boczkowska, E. Ciecierska, “The effect of the surface modification of carbon nanotubes on their dispersionin the epoxy matrix”, Polish Journal of Chemical Technology, 13, 2, 62-69, 2011