Abstract
The honeycomb (HC) core of sandwich structures undergoes flexural loading and carries the normal compression and shear. The mechanical properties and deformation response of the core need to be established for the design requirements. In this respect, this article describes the development of the smallest possible representative cell (RC) models for quantifying the deformation and failure process of the Nomex polymer-based hexagonal HC core structure under the out-of-plane quasi-static loadings. While the hexagonal single and multi-cell models are suitable for the tension and compression, a six-cell model is the simplest RC model developed for shear in the transverse and ribbon direction. Hashin’s matrix and fiber damage equations are employed in simulating the failure process of the orthotropic cell walls, using the finite element (FE) analysis. The FE-calculated load–displacement curves are validated with the comparable measured responses throughout the loading to failure. The location of the fracture plane of the critical cell wall in the out-of-plane tension case is well predicted. The wrinkling of the cell walls, leading to the structural buckling of the HC core specimen in the compression test, compares well with the observed failure mechanisms. In addition, the observed localized buckling of the cell wall by the induced compressive stress during the out-of-plane shear in both the transverse and ribbon direction is explained. The mesoscale RC models of the polymer hexagonal HC core structure have adequately demonstrated the ability to predict the mechanics of deformation and the mechanisms of failure.
Highlights
Honeycomb (HC) sandwich panels have found numerous engineering applications, such as wind turbine blades, aircraft wings, spoilers and engine cowls, yacht hulls and floor panels, and surfboards
The measured response is taken from the tests performed in accordance with the ASTM C297 standard, with the results presented in the previous research work [45]
The single-cell finite element (FE) model, with the appropriate boundary conditions, is computationally efficient to accurately represent the out-of-plane tensile behavior of the hexagonal HC core panel fabricated from the polymer fiber-reinforced paper
Summary
Honeycomb (HC) sandwich panels have found numerous engineering applications, such as wind turbine blades, aircraft wings, spoilers and engine cowls, yacht hulls and floor panels, and surfboards. The observed localized failure initiation leading to the catastrophic fracture of the sandwich structure necessitates the simulation of the complete failure process to capture the observed failure mechanisms This calls for the constitutive model of the cell wall materials with appropriate failure criteria. A damage model is needed to predict the structural strength and simulate the progressive failure of the polymeric HC core under the general loading conditions In this respect, the current work establishes a systematic methodology to identify the smallest representative cell model of the polymeric hexagonal HC core. The calculated responses of the validated representative cell models serve in providing highfidelity input property data for the equivalent homogenized HC core model of the large structures, under the general loading conditions
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