Abstract
This paper deals with the experimental and numerical study of closed-cell aluminum-based foam under compressive loading. Experimental samples were produced by the gas blowing method. Foam samples had an average cell size of around 1 mm, with sizes in the range 0.5–5 mm, and foam density of 0.6 g/cm3. Foam samples were subjected to a uniaxial compression test, at a displacement rate of 0.001 mm/s. Load and stress were monitored as the functions of extension and strain, respectively. For numerical modeling, CT scan images of experimental samples were used to create a volume model. Solid 3D quadratic tetrahedron mesh with TETRA 10-node elements was applied, with isotropic material behavior. A nonlinear static test with an elasto-plastic model was used in the numerical simulation, with von Mises criteria, and strain was kept below 10% by the software. Uniform compressive loading was set up over the top sample surface, in the y-axis direction only. Experimental tests showed that a 90 kN load produced complete failure of the sample, and three zones were exhibited: an elastic region, a rather uniform plateau region (around 23 MPa) and a densification region that started around 35 MPa. Yielding, or collapse stress, was achieved around 20 MPa. The densification region and a rapid rise in stress began at around 52% of sample deformation. The numerical model showed both compressive and tensile stresses within the complex stress field, indicating that shear also had a prominent role. Mainly compressive stresses were exhibited in the zones of the larger cells, whereas tensile stresses occurred in zones with an increased number of small cells and thin cell walls.
Highlights
Closed-cell Al-based foams belong to a group of cellular materials offering a wide choice in their design depending on the final product [1]
Experimental tests showed that a 90 kN load produced complete failure of the sample, and three zones were exhibited: an elastic region, a rather uniform plateau region and a densification region that started around 35 MPa
Aluminum foam has even been studied for use in nuclear transportation due to its energy absorption capabilities [13]
Summary
Closed-cell Al-based foams belong to a group of cellular materials offering a wide choice in their design depending on the final product [1] Their applications are versatile and significant attention has been given to the improvement of their properties, especially in structural applications such as energy absorbers in automotive and rail engineering [2]. Kovacik et al [31] showed dependence of the Poisson ratio on foam density This is important since all finite element modeling includes the value of the Poisson ratio as a basic material property and any changes to this affect the final numerical results. This paper deals with finite element modeling (FEM) of closed-cell aluminum-based foam under compressive load, based on CT scan images extracted from a real experimental sample. Numerical results were compared with experimentally obtained stress–strain curves and analyzed
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