Large displacement micro-indentation tests have been performed on various polymeric solids to measure the plastic properties. Cylindrical flat-ended indenters with diameter in the range of 1090μm are mostly used. The mechanism of large-strain indentation has been examined with optical microscopy and finite element simulations. Results show that under a flat-tipped indenter, the material can quickly reach a fully plastic state. The size (diameter) of the plastic zone is constant in large-strain regions and unaffected by the exact tip profile (flat, spherical, and conical). The indentation stress-displacement curve at large strains is linear as a result of the steady-state plastic flow, from which the mean indentation pressure, a measure of yield strength, can be readily extrapolated. The indentation stress-displacement response is independent of the indenter diameters but strongly dependent on the strain-hardening behavior of the material and the friction between a material and an indenter. Compared with other shaped indenters, the flat-ended indenter requires the least penetration depth in order to probe the plastic properties of a material or structure.

Issue Section:
Research Papers
Keywords:
finite element analysis, friction, indentation, optical microscopy, plastic flow, polymer structure, polymers, stress-strain relations, work hardening, yield strength, micro-indentation, plasticity, polymer, finite element
Topics:
Deformation, Displacement, Finite element analysis, Stress, Modeling, Solids, Friction, Work hardening, Polymers, Plasticity
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