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http://dx.doi.org/10.20910/JASE.2020.14.4.25

Mechanical Properties Prediction by Manufacturing Parameters for Braided Composites  

Kim, Myungjun (Department of Aviation Maintenance Engineering, Silla University)
Publication Information
Journal of Aerospace System Engineering / v.14, no.4, 2020 , pp. 25-31 More about this Journal
Abstract
The development of manufacturing technology for braided composites has led to farther extension of the applications in aerospace structures. Since the mechanical characteristics of braided composites are affected by various materials and manufacturing parameters, it is important to determine the parameters required to appropriately design the braided composite structures. In this study, we proposed a geometric model of RUC (repeating unit cell) for 2D braided composites, and predicted the mechanical properties according to the change of fiber volume fraction, fiber filament size, braiding angle, and gap between adjacent yarns by the yarn slicing technique and stress averaging method. Finally, we analyze the characteristics of mechanical properties according to each manufacturing parameter of the braided composite material.
Keywords
Braided Composites; Manufacturing Parameters; Repeating Unit Cell; Fiber Volume Fraction; Gap between Adjacent Yarns;
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  • Reference
1 Niu, M. C., Composite Airframe Structures, Conmilit Press Ltd., Hong Kong, 1992.
2 Niranjan K. Naik, Woven fabric composites, Technomic Publishing Co., Inc., 1994.
3 Brian N. Cox, "Handbook of Analytical Methods for Textile Composites," NASA Contractor Report 4750, Contract NAS1-19243, 1997.
4 Chou, T-W., Ishikawa, T., "Analysis and Modeling of Two-Dimensional Fabric Composites," Composite Materials Series 3, Textile Structural Composites, pp. 210-264, 1989.
5 Ko, F. K., Pastore, C. M., Lei, C. and Whyte, D. W., "A Fabric Geometry Model for 3-D Braid Reinforced FP/AILi Composites," International SAMPE Metals Conference: Competitive Advances in Metals/Metal Processing, Cherry Hill, NJ, 1987.
6 Pastore, C. M. and Gowayed, Y. A.: "A Self-Consistent Fabric Geometry Model: Modification and Application of a Fabric Geometry Model to Predict the Elastic Properties of Textile Composites," Journal of Composites Technology and Research, JCTRER, Vol. 16, No. 1, pp. 32-36, Jan. 1994.   DOI
7 Yang, J-M., Ma, C-L., and Chou, T-W., "Fiber Inclination Model of Three-Dimensional Textile Structural Composites," Journal of Composite Materials, Vol. 20, pp. 472-484, September 1986.   DOI
8 Foye, R. L.: "Finite Element Analysis of the Stiffness of Fabric Reinforced Composites," NASA CR-189597, National Aeronautics and Space Administration, Hampton, Virginia, Feb. 1992.
9 Lei Xu, et al., "Prediction of material properties of biaxial and triaxial braided textile composites," Journal of Composite Materials, Vol. 46, No. 18, pp.2255-2270, 2012.   DOI
10 Naik, R. A., Ifju, P. G. and Masters, J. E., "Effect of Fiber Architecture Parameters on Deformation Fields and Elastic Moduli of 2-D Braided Composites," Journal of Composite Materials, Vol.28, pp.656-681, 1994.   DOI
11 Naik, N. K. and Ganesh, V. K., "Prediction of On-Axes Elastic Properties of Plain Weave Fabric Composites," Composites Science and Technology, Vol. 45, pp. 135-152, 1992.   DOI
12 Rajiv A. Naik, "Analysis of Woven and Braided Fabric Reinforced Composites," NASA Contractor Report 194930, Contract NAS1-19399, 1994.
13 Home Made Composite, http://www.composites.ugent.be/home_made_composites/what_are_composites.html.