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http://dx.doi.org/10.12989/aas.2018.5.6.633

Numerical simulation of the thermoelectric behavior of CNTs/CFRP aircraft composite laminates  

Lin, Yueguo (Department of Design and Manufacture of Aircrafts, Civil Aviation University of China, CAUC)
Lafarie-Frenot, Marie Christine (Institut Pprime, CNRS - ENSMA - Universite de Poitiers, Departement Physique et Mecanique de Materiaux)
Bai, Jinbo (CentraleSupelec, Universite Paris-Saclay 3 rue Joliot-Curie)
Gigliotti, Marco (Institut Pprime, CNRS - ENSMA - Universite de Poitiers, Departement Physique et Mecanique de Materiaux)
Publication Information
Advances in aircraft and spacecraft science / v.5, no.6, 2018 , pp. 633-652 More about this Journal
Abstract
The present paper focuses on the development of a model for simulating the thermoelectric behavior of CNTs/CFRP Organic Matrix Composite (OMC) laminates for aeronautical applications. The model is developed within the framework of the thermodynamics of irreversible processes and implemented into commercial ABAQUS Finite Element software and validated by comparison with experimental thermoelectric tests on two types of composites materials, namely Type A with Carbon Nanotubes (CNT) and Type B without CNT. A simplified model, neglecting heat conduction, is also developed for simplifying the identification process. The model is then applied for FEM numerical simulation of the thermoelectric response of aircraft panel structures subjected to electrical loads, in order to discuss the potential danger coming from electrical solicitations. The structural simulations are performed on quasi-isotropic stacking sequences (QI) $[45/-45/90/0]_s$ using composite materials of type A and type B and compared with those obtained on plates made of metallic material (aluminum). For both tested cases-transit of electric current of intermediate intensity (9A) and electrical loading on panels made of composite material-higher heating intensity is observed in composites materials with respect to the corresponding metallic ones.
Keywords
CNTs/CFRP laminates; thermoelectric behavior; numerical simulations; temperature field;
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1 Sierakowski, R.L., Telitchev, I.Y. and Zhupanska, O.I. (2008), "On the impact response of electrified carbon fiber polymer matrix composites: Effects of electric current intensity and duration", Comp. Sci. Tech., 68(3-4), 639-649.   DOI
2 Toray Carbon Fibers America, Inc. (2013), Title of website link; Toray Industries, AL, U.S.A. http://www.toraycfa.com/pdfs/T700SDataSheet.pdf.
3 Villiere, M., Lecointe, D., Sobotka, V., Boyard, N. and Delaunay, D. (2013), "Experimental determination and modeling of thermal conductivity tensor of carbon/epoxy composite", Compos. Part A Appl. Sci. Manuf., 46, 60-68.
4 Xia, Z.H., Okabe, T., Park, J.B., Curtin, W.A. and Takeda, N. (2003), "Quantitative damage detection in CFRP composites: Coupled mechanical and electrical models", Comp. Sci. Tech., 63(10), 1411-1422.   DOI
5 Dassault Systemes Simulia Corp. (2009), ABAQUS Ver. 6.9., Providence, RI, U.S.A.
6 De Groot, S.R. and Mazur, P. (1969), Non-equilibrium thermodynamics, North Holland Publishing Company, Amsterdam, The Netherlands.
7 Zhao, Z.G., Ci, L.J., Cheng, H.M. and Bai, J.B. (2004), "Growth of multi-walled carbon nanotube of different morphologies on carbon fibres by floating catalyst method", Carbon, 43, 663-665.
8 Gigliotti, M., Lafarie, M.C. and Grandidier, J.C. (2011), "Development of experimental and modeling tools for the characterization of the thermo-electro-mechanical behavior of composite materials for aircraft applications", Mech. Industry, 12(2), 87-101.
9 Gigliotti, M., Lafarie-Frenot, M.C., Lin, Y. and Pugliese, A. (2015), "Electro-mechanical fatigue of CFRP laminates for aircraft applications", Compos. Struct., 127, 436-449.
10 Hexcel Corporation (2015), $180^{\circ}C$ curing epoxy matrix; Hexcel Corporation, CT, U.S.A. https://www.hexcel.com/user_area/content_media/raw/HexPly_M21_global_DataSheet.pdf
11 Kalogiannakis, G., Hemelrijck, D. and Assche, G. (2004), "Measurements of thermal properties of carbon/epoxy and glass/epoxy using modulated temperature differential scanning calorimetry", J. Compos. Mater., 38(2), 163-175.   DOI
12 Lin, Y., Gigliotti, M., Lafarie-Frenot, M.C. and Bai, J. (2015a), "Experimental study to assess the effect of carbon nanotube addition on the through-thickness electrical conductivity of CFRP laminates for aircraft applications", Compos. Part B Eng., 76, 31-37.   DOI
13 Lin, Y., Gigliotti, M., Lafarie-Frenot, M.C. and Bai, J. (2015b), "Effect of carbon nanotubes on the thermoelectric properties of CFRP laminate for aircraft applications", J. Reinf. Plast. Comp., 34(2), 173-184.   DOI
14 Muller, I. (1973), Thermodynamik, Bertelsmann, Dusseldorf, Germany.
15 Saba, J., Magga, Y., He, D., Miomandre, F. and Bai, J. (2013), "Continuous electrodeposition of polypyrrole on carbon nanotube-carbon fiber hybrids as a protective treatment against nanotube dispersion", Carbon, 51, 20-26.   DOI
16 Schulte, K. and Wittich, H. (1995), "The electrical response of strained and or damaged polymer-matrix composites", Proceedings of ICCM10 Canada, British Columbia, Canada, August.