Multiscale modeling of textile composite: A Requisite

• Post by: Rohit Madke
• March 10, 2019
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Composite materials have been rapidly developed and adopted since World War II accompanied by the emergence of new matrix materials and high-performance fibers. Modern aircraft and space structures comprise 50 to 70 percent of this unique blend of composite materials due to their ultra-low weight and high toughness. Robust predictions of the thermo-mechanical response of anisotropic composite materials across the different length scales are of the utmost importance to improve the efficiency of composite structures and to develop an in-depth understanding of microstructure-property relations.

Our activities were focused on

• Development of a generic and efficient framework for multiscale modeling and failure prediction of fabric-reinforced composites under static and impact loadings

• The real phenomenon that occurs at the micro level of the composite is simulated via representative volume element

• Various techniques used for the analysis are
  • Modified classical laminate theory
  • Semi-analytical homogenization schemes
  • Mechanics of structure genome
  • Finite element analysis with embedded cohesive zone modeling

• The characteristics obtained at lower scales are then implemented within macroscopic models for optimization of the large-scale composite structures