Determination of elastic-plastic properties of Alporas foam at the cell-wall level using microscale-cantilever bending tests

0444020 - ÚTAM 2016 RIV SI eng J - Journal Article
Doktor, Tomáš - Kytýř, Daniel - Koudelka_ml., Petr - Zlámal, Petr - Fíla, Tomáš - Jiroušek, Ondřej
Determination of elastic-plastic properties of Alporas foam at the cell-wall level using microscale-cantilever bending tests.
Materiali in Tehnologije. Roč. 49, č. 2 (2015), s. 203-206. ISSN 1580-2949. E-ISSN 1580-3414
R&D Projects: GA ČR(CZ) GAP105/12/0824
Institutional support: RVO:68378297
Keywords : aluminium foam * cantilever bending * micromechanics * optical strain measurement
Subject RIV: JI - Composite Materials
Impact factor: 0.439, year: 2015
http://mit.imt.si/Revija/izvodi/mit152/doktor.pdf

The presented paper is focused on determining the mechanical properties of the Alporas closed-cell aluminium foam. To utilise the favourable properties of cellular metals (e.g., high strength-weight ratio, energy absorption or insulation capabilities) a detailed description of the mechanical properties is required. Cellular metals exhibit heterogeneity at several scale levels. The contribution of the internal structure to the overall mechanical properties may not be in detail evaluated utilizing only the macroscopic testing. On the other hand, the compact material of cell walls is influenced by its composition (titanium- and calcium-rich regions are present in aluminium). Therefore, localised testing techniques with a small region of interest (e.g., indentation methods) may neglect the inhomogeneity along the cell walls. Hence, a testing of isolated cell walls was performed. A custom-developed modular loading device (based on precise linear bearing stages) was assembled to enable cantilever bending tests. The load was applied with a stepper motor and the loading force was measured with a micro-scale load cell with a loading capacity of 2.25 N. Displacements of the samples were measured optically. Several points along the longitudinal axis of a sample were tracked using the Lucas-Kanade tracking algorithm and the obtained displacements were compared to the analytically prescribed deflection curve. Based on the obtained deflections and measured forces, a stress-strain diagram was constructed and the constants of the elastic-plastic material model were evaluated.
Permanent Link: http://hdl.handle.net/11104/0246622