Logo image
Back
Numerical modeling and analysis of static and ballistic behavior of multi-layered/multiphase composite materials using detailed microstructural discretization
Dissertation   Open access

Numerical modeling and analysis of static and ballistic behavior of multi-layered/multiphase composite materials using detailed microstructural discretization

Jovan M. Jovicic
Doctor of Philosophy (Ph.D.), Drexel University
Apr 2003
DOI:
https://doi.org/10.17918/etd-156
pdf
Jovicic_Jovan_200314.71 MBDownloadView
PDF Open Access Open Access (License Unspecified)

Abstract

Microstructure Finite element method Ceramic sphere composites Textile composites Composite Materials
The goal of this work is to analyze the static and ballistic performance of multi material systems using a detailed finite element analysis. As more complex materials systems are introduced in engineering practice, the design engineer faces the dilemma of utilizing homogenization techniques or detailed numerical models. The latter offers a number of advantages, such as the ability to introduce separate constitutive laws and failure criteria for each phase, at the expense of computation cost. This is particularly important in ballistic performance of armor where the sequence of failure of each phase plays a major role in the energy absorption. An automatic geometry generation algorithm for composite materials is presented that can generate complex composite geometries spanning several unit cells. This capability is utilized to study the following phenomena: 1. Static behavior of textile composites: A comparative study of textile composites with different reinforcement architecture that shows the origins of non- linearity and the dependence of elastic parameters on the geometry of the unit cell; 2. Impact behavior of textile composites: The role of textile architecture in impact energy absorption; 3. Ballistic properties of ceramic sphere composites with textile composite ackings. A detailed study of a new multi- layered design concept is presented using a full finite element discretization method that shows that although ceramic spheres embedded in epoxy exhibit a slightly lower energy absorption than the monolithic ceramic at the same areal density, they provide the advantage of ease of complex shape conformable manufacturing. A comparison with ballistic experiments on such material demonstrates that the analysis captures several aspects of this phenomenon.

Metrics

60 File views/ downloads
12 Record Views

Details

Logo image