Simulation of Non-Crimp 3D Orthogonal Carbon Fabric Composite for Aerospace Applications Using Finite Element Method
Non-crimp 3D orthogonal fabric composite is one of
the textile-based composite materials that are rapidly developing
light-weight engineering materials. The present paper focuses on
geometric and micromechanical modeling of non-crimp 3D
orthogonal carbon fabric and composites reinforced with it for
aerospace applications. In this research meso-finite element (FE)
modeling employs for stress analysis in different load conditions.
Since mechanical testing of expensive textile carbon composites with
specific application isn't affordable, simulation composite in a virtual
environment is a helpful way to investigate its mechanical properties
in different conditions.
[1] A. C. Long, Design and Manufacture of Textile Composites,
Woodhead Publishing, 2005, p. 405.
[2] A. P. Mouritz, M. K. Bannisterb, P. J. Falzonb, K. H. Leongb, “Review
of Applications for Advanced Three-Dimensional Fibre Textile
Composites”, Composites: Part A, Vol.30, pp.1445–1461, 1999.
[3] A. Miravete, 3-D Textile Reinforcements in Composite Materials,
Woodhead Publishing, 2000, P. 16.
[4] B. Sun, Y. Liu, B. Gu, “A unit cell approach of finite element
calculation of ballistic impact damage of 3-D orthogonal woven
composite”, Composites: Part B, Vol. 40, pp. 552-560, 2009.
[5] A.E., Bogdanovich, “Advancements in Manufacturing and Applications
of 3-D Woven Preforms and Composites”, Sixteenth International
Conference on Composite Materials (ICCM-16), Kyoto, Japan, July 8-
13, 2007.
[6] P.G., Unal, “3D Woven Fabrics”, In: Woven Fabrics, Jeon, H.Y., (Ed.),
ISBN: 978-953-51-0607-4, InTech-Open Access Publisher, DOI:
10.5772/37492, 2012, p.106.
[7] F., Stig, 3D-woven reinforcement in composites, PhD thesis, KTH
School of Engineering Sciences, Stockholm, Sweden, 2012.
[8] L., Tong, A.P., Mouritz, M.K., Bannister, “3D Fibre Reinforced
Polymer Composites”, Elsevier, ISBN 0-08-043938-1, Netherlands,
2002, p.19-21.
[9] W., Shi, H., Hu, B., Sun, B., Gu, “Energy absorption of 3D orthogonal
woven fabric under ballistic penetration of hemispherical‐cylindrical
projectile”, Journal of The Textile Institute, Vol. 102, No. 10, pp. 875-
889, 2011.
[10] V., Carvelli, J., Pazmino, S.V., Lomov, I., Verpoest, “Deformability of a
non-crimp 3D orthogonal weave E-glass composite reinforcement”,
Composites Science and Technology, Vol. 73, pp. 9-18, 2012.
[11] X., Jia, B., Sun, B., Gu, “A numerical simulation on ballistic penetraton
damage of 3D orthogonal woven fabric at microstructure level”,
International Journal of Damage Mechanics, Vol. 21, pp. 237-266,
2012.
[12] R., Mishra, J., Militky, B.K., Behera, V., Banthia, “Modelling and
simulation of 3D orthogonal fabrics for composite applications”, Journal
of the Textile Institute, Vol. 103, No. 11, pp. 1151-1266, 2012.
[13] M., Karahan, S.V., Lomov, A.E., Bogdanovich, I., Verpoest, “Fatigue
tensile behavior of carbon/epoxy composite reinforced with non-crimp
3D orthogonal woven fabric”, Composites Science and Technology, Vol.
71, pp. 1961-1972, 2011.
[14] S.V., Lomove, A.E., Bogdanovich, D.S., Ivanov, K., Hamada, T.,
Kurashiki, M., Zako, M., Karahan, I., Verpoest, “Finite element
modeling of progressive damage in non-crimp 3D orthogonal weave and plain weave E-glass composites”, 2nd World Conference on 3D Fabrics,
Greenville, South Carolina, USA, 2009.
[15] Ch.,El Hage, R., Younes, Z., Aboura, M.L., Benzeggagh, M., Zoaeter,
“Analytical and numerical modeling of mechanical properties of
orthogonal 3D CFRP”, Composites Science and Technology, Vol. 69,
pp. 111-116, 2009.
[16] K.J., Bathe, Finite Element Procedures in engineering Analysis, Prentice
hall, Englewood Cliff, 1996, p. 3-10.
[17] F. L., Stasa, Applied Finite Element Analysis for Engineers, Holt,
Rinehart and Winston, 1985, p. 11-15.
[18] ww.toraycfa.com/pdfs/T300DataSheet.pdf
[19] J. P., Holman, Heat Transfer, 9th Ed, McGraw Hill, 2002.
[20] C. W., Ohlhorst, L., Wallace, O., Philip, thermal conductivity database
of various structural carbon-carbon composite material , Nasa technical
memorandum, 1997.
[1] A. C. Long, Design and Manufacture of Textile Composites,
Woodhead Publishing, 2005, p. 405.
[2] A. P. Mouritz, M. K. Bannisterb, P. J. Falzonb, K. H. Leongb, “Review
of Applications for Advanced Three-Dimensional Fibre Textile
Composites”, Composites: Part A, Vol.30, pp.1445–1461, 1999.
[3] A. Miravete, 3-D Textile Reinforcements in Composite Materials,
Woodhead Publishing, 2000, P. 16.
[4] B. Sun, Y. Liu, B. Gu, “A unit cell approach of finite element
calculation of ballistic impact damage of 3-D orthogonal woven
composite”, Composites: Part B, Vol. 40, pp. 552-560, 2009.
[5] A.E., Bogdanovich, “Advancements in Manufacturing and Applications
of 3-D Woven Preforms and Composites”, Sixteenth International
Conference on Composite Materials (ICCM-16), Kyoto, Japan, July 8-
13, 2007.
[6] P.G., Unal, “3D Woven Fabrics”, In: Woven Fabrics, Jeon, H.Y., (Ed.),
ISBN: 978-953-51-0607-4, InTech-Open Access Publisher, DOI:
10.5772/37492, 2012, p.106.
[7] F., Stig, 3D-woven reinforcement in composites, PhD thesis, KTH
School of Engineering Sciences, Stockholm, Sweden, 2012.
[8] L., Tong, A.P., Mouritz, M.K., Bannister, “3D Fibre Reinforced
Polymer Composites”, Elsevier, ISBN 0-08-043938-1, Netherlands,
2002, p.19-21.
[9] W., Shi, H., Hu, B., Sun, B., Gu, “Energy absorption of 3D orthogonal
woven fabric under ballistic penetration of hemispherical‐cylindrical
projectile”, Journal of The Textile Institute, Vol. 102, No. 10, pp. 875-
889, 2011.
[10] V., Carvelli, J., Pazmino, S.V., Lomov, I., Verpoest, “Deformability of a
non-crimp 3D orthogonal weave E-glass composite reinforcement”,
Composites Science and Technology, Vol. 73, pp. 9-18, 2012.
[11] X., Jia, B., Sun, B., Gu, “A numerical simulation on ballistic penetraton
damage of 3D orthogonal woven fabric at microstructure level”,
International Journal of Damage Mechanics, Vol. 21, pp. 237-266,
2012.
[12] R., Mishra, J., Militky, B.K., Behera, V., Banthia, “Modelling and
simulation of 3D orthogonal fabrics for composite applications”, Journal
of the Textile Institute, Vol. 103, No. 11, pp. 1151-1266, 2012.
[13] M., Karahan, S.V., Lomov, A.E., Bogdanovich, I., Verpoest, “Fatigue
tensile behavior of carbon/epoxy composite reinforced with non-crimp
3D orthogonal woven fabric”, Composites Science and Technology, Vol.
71, pp. 1961-1972, 2011.
[14] S.V., Lomove, A.E., Bogdanovich, D.S., Ivanov, K., Hamada, T.,
Kurashiki, M., Zako, M., Karahan, I., Verpoest, “Finite element
modeling of progressive damage in non-crimp 3D orthogonal weave and plain weave E-glass composites”, 2nd World Conference on 3D Fabrics,
Greenville, South Carolina, USA, 2009.
[15] Ch.,El Hage, R., Younes, Z., Aboura, M.L., Benzeggagh, M., Zoaeter,
“Analytical and numerical modeling of mechanical properties of
orthogonal 3D CFRP”, Composites Science and Technology, Vol. 69,
pp. 111-116, 2009.
[16] K.J., Bathe, Finite Element Procedures in engineering Analysis, Prentice
hall, Englewood Cliff, 1996, p. 3-10.
[17] F. L., Stasa, Applied Finite Element Analysis for Engineers, Holt,
Rinehart and Winston, 1985, p. 11-15.
[18] ww.toraycfa.com/pdfs/T300DataSheet.pdf
[19] J. P., Holman, Heat Transfer, 9th Ed, McGraw Hill, 2002.
[20] C. W., Ohlhorst, L., Wallace, O., Philip, thermal conductivity database
of various structural carbon-carbon composite material , Nasa technical
memorandum, 1997.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:70080", author = "Sh. Minapoor and S. Ajeli and M. Javadi Toghchi", title = "Simulation of Non-Crimp 3D Orthogonal Carbon Fabric Composite for Aerospace Applications Using Finite Element Method", abstract = "Non-crimp 3D orthogonal fabric composite is one of
the textile-based composite materials that are rapidly developing
light-weight engineering materials. The present paper focuses on
geometric and micromechanical modeling of non-crimp 3D
orthogonal carbon fabric and composites reinforced with it for
aerospace applications. In this research meso-finite element (FE)
modeling employs for stress analysis in different load conditions.
Since mechanical testing of expensive textile carbon composites with
specific application isn't affordable, simulation composite in a virtual
environment is a helpful way to investigate its mechanical properties
in different conditions.", keywords = "3D orthogonal woven composite, Aerospace
applications, Finite element method, Mechanical properties.", volume = "9", number = "6", pages = "982-9", }
