Investigation and simulation by a metaheuristic algorithm of the effect of carbon nanotubes fibers on the improvement of the properties of nanocomposite material

• Autorzy: Oukkas M. , Mokaddem A. , Doumi B. , Boutaleb M. , Temimi L. , Boutaous A.
• Języki publikacji: EN

Abstrakty

EN

In this article, we investigated and studied the effect of carbon Nanotubes fibers on the improvement of the mechanical and thermal properties of our epoxy matrix composite material. Our calculations were based on a heuristic optimization algorithm. The results show that the level of the damage is related to the concentration of the mechanical and thermal stresses, for the three materials studied carbon/epoxy, Graphite-epoxy and carbon nanotubes/epoxy, the calculations also show that carbon nanotubes have greatly improved the mechanical and physical properties of our material, and that this material is more resistant than the other carbon/epoxy composite materials and graphite-epoxy nanocomposite. The numerical simulation shows a good agreement with the real behavior of the three materials studied. This means that the mechanical and physical properties have been greatly improved after the use of carbon nanotubes fibers. Finally, we can say that our model has worked well in relation to the phenomenon of damage of composites and nanocomposites materials. It would be interesting to see, thereafter, the effect of carbon nanotubes fibers on the damage of the fiber-matrix interface of a bio-nanocomposite.

Słowa kluczowe

EN

carbon nanotube; damage; interface; nanocomposite; epoxy; graphite-epoxy

PL

nanorurki węglowe; uszkodzenie; powierzchnia przylegania; nanokompozyty; kompozyty epoksydowe; kompozyty grafitowo-epoksydowe

• Wydawca: Wydawnictwo Politechniki Łódzkiej
• Czasopismo: Mechanics and Mechanical Engineering
• Rocznik: 2017
• Tom: Vol. 21, nr 4
• Strony: 1009--1020
• Opis fizyczny: Bibliogr. 30 poz., il. kolor., rys., wykr.

Twórcy

autor

Oukkas M.

• Centre Universitaire Nour Bachir El Bayadh, 32000, Algérie

autor

Mokaddem A.

• Centre Universitaire Nour Bachir El Bayadh, 32000, Algérie

autor

Doumi B.

• Faculty of Sciences, Department of Physics, Dr Tahar Moulay University of Saïda

autor

Boutaleb M.

• Faculty of Sciences, Department of Physics, Dr Tahar Moulay University of Saïda

autor

Temimi L.

• Faculté de Physique, Université des Sciences et de la Technologie, Mohamed-Boudiaf el Mnaouar, BP 1505, Bir El Djir 31000, Oran, Algérie

autor

Boutaous A.

• Faculté de Physique, Université des Sciences et de la Technologie, Mohamed-Boudiaf el Mnaouar, BP 1505, Bir El Djir 31000, Oran, Algérie

Bibliografia

• [1] Monthioux, M., Kuznetsov, V. L.: Who should be given the credit for the discovery of carbon nanotubes, Carbon, 44, 2006.
• [2] Iijima, S.: Helical microtubules of graphitic carbon, Nature, 354, 56-58, 1991.
• [3] Waldner, J-B.: Nano-informatique et Intelligence Ambiante - Inventer l’Ordinateur du XXIème Siècle, Paris, Hermes Science, ISBN 978-2-7462-1516-0, LCCN 2007474110, 2007.
• [4] Radushkevich, L. V., Lukyanovich, V. M.: O strukture ugleroda, obrazujucegosja pri termiceskom razlozenii okisi ugleroda na zeleznom kontakte, Zurn. Fisic. Chim., 26, 88-95, 1952.
• [5] Boehm, H.P.: Carbon from carbon monoxide disproportionation on nickel and iron catalysts: morphological studies and possible growth mechanisms, Carbon, 11, 583-90, 1973.
• [6] Oberlin, A., Endo, M., Koyama, T.: Filamentous growth of carbon through benzene decomposition, Journal of Crystal Growth, 32, 3, 335-349, DOI 10.1016/0022-0248(76-90115-9), 1976.
• [7] Endo, M., Saito, R., Dresselhaus, M. S.: InCarbon Nanotubes: Preparation and properties, T. Ebbeson, CRC Press, 35-110, Chapter II, 1997.
• [8] Abrahamson, J., Wiles, P. G., Rhoades, B. L.: Structure of Carbon Fibers Found on Carbon Arc Anodes, Carbon, 11, 37, 1999.
• [9] Kolesnik, N. F., Akhmatov, Y. S., Suhomlin, V. I., Prilutskii, O. V.: Metals, Izvestiya Akademii Nauk SSSR, 3, 12-17, 1982.
• [10] Iijima, S., Ichihashi, T.: Single-shell carbon nanotubes of 1-nm diameter, Nature, 363, 603-605, 1993.
• [11] Bethune, D. S., Klang, C. H., De Vries, M. S., Gorman, G., Savoy, R., Vasquez, J., Beyers, R.: Cobalt catalysed growth of carbon nanotubes with single-atomic-layer walls, Nature, 363, 605-607, 1993.
• [12] Thostenson, E. T., Ren, Z., Chou, T.-W.: Advances in the science and technology of carbon nanotubes and their composites: a review, Composites Science And Technology, 61, 13, 1899-1912, 2001.
• [13] Rodney, S., Ruoff, R. S., Lorents, D. C.: Mechanical and Thermal Properties of Carbon Nanotubes, Carbon, 33, 7, 925-930, 1995.
• [14] Yu, M. F., Lourie, O., Dyer, M. J., Moloni, K., Kelly, T. F., Ruoff, R. S.: Strength and breaking mechanism of multiwalled carbon nanotubes under tensile load, Science, 287, 5453, 637-640, 2000.
• [15] Zakri, C., Pénicaud, A., Poulin, P.: Les nanotubes, des fibres d’avenir, Dossier Pour la Science, 79, 2013.
• [16] Launois, P.: Les nanotubes de carbone, LAL (Bat 200), Campus d’Orsay, Université Paris, 2007.
• [17] Lebrun, G. A.: Comportement thermomécanique et durée de vie de composites à matrice céramique : théorie et expérience, PhD thesis, Université de Bordeaux, 1996.
• [18] Tadjedit, S., Mokaddem, A., Temimi, L., Doumi, B., Boutaous, A., Beldjoudi, N.: Comparative study by a genetic algorithm on the mechanical properties of PLA and Epoxy Bio-composite Materials reinforced with natural fiber, Journal of Mechanics and Mechanical Engineering, 20, 3, 333-347, 2016.
• [19] Cox, H. L.: The elasticity and strength of paper and other fibrous materials, British journal of applied physics, 12, 72-79, 1952.
• [20] Weibull, W.: Theory of the strength of materials, Royal Swedish Academy of Eng. Sci. Proc., 151, 1-45, 1939.
• [21] P. Bonniau, P., Bunsell, A. R.: A comparative study of water absorption theories applied to glass epoxy composites, J. Comp. Mater., 15, 272-293, 1981.
• [22] Pham Hong, T.: Caractérisation et modélisation du comportement diélectrique d’un matériau composite soumis à un vieillissement hydrothermique Thèse de doctorat, Université Joseph Fourier - Grenoble, 2005.
• [23] Nogueira, P., Ramirez, C., Torres, A., Abad, M. J., Cano, J., Lopez, J., Lopezbueno, I., Barral, L.: Influence of the curing cycle selection on the thermal degradation of an epoxy-diamide system, J. Polym. Sci., 80, 71880, 2001.
• [24] Diamant, Y., Marom, G., Broutman, L. J.: The effect of network structure on moisture absorption of epoxy resins, J. Polym. Sci., 26, 30158-3025, 1981.
• [25] Adamson, M. J.: Thermal expansion and swelling of cured epoxy resin used in graphite/epoxy composite material, J. Mater. Sci., 15, 17368-1745, 1980.
• [26] Apicella, A., Egiziano, L., Nicolais, L., Tucci, V.: Environmental degradation of electrical and thermal properties of organic insulating materials, J. Mater. Sci., 23, 1988.
• [27] Temimi, H. L., Mokaddem, A., Belkaid, N., Boutaous, A., Bouamrane, R.: Study of the effect of water intake by the matrix on the optimization of the fiber matrix interface damage for a composite material by genetic algorithms, Strength of Materials, Springer, 45, 6, 739-747, 2013.
• [28] Collins and Avouris,: Les nanotubes en électronique , Dossier Pour la science, 2001.
• [29] Asma, Y., Luo, J-J. Isaac, M. D.: Processing of expanded graphite reinforced polymer nanocomposites, Compos. Sci. Technol. 66, 1179-86, 2006.
• [30] Mokaddem, A., Alami, M., Doumi, B. and Boutaous, A.: Prediction by a genetic algorithm of the fiber matrix interface damage for composite material. Part1: study of shear damage to two composites T300/914 and Peek/APC2, Strength Mate., Springer, 46, 4, 543-7, 2014.