Litcius/Paper detail

Semi-analytical model for flat indentation of metal materials and its applications

Xiaokun Liu, Lixun Cai, Hui Chen, Shuqian SI

2020Chinese Journal of Aeronautics26 citationsDOIOpen Access PDF

Abstract

The increasing use of small material components in a wide range of industrial fields necessitates the development of an accurate and robust indentation testing method. To this end, this paper proposes an Energy-density-equivalence for a Flat Indentation (E-FI) model based on the energy density equivalent principle. The proposed model describes the relationships among the material parameters of Hollomon’s power law (H-law), flat indenter diameter, energy, and indentation displacement. An E-FI Method (E-FIM) that determines the H-law parameters of materials through the indentation test is also developed. The energy-displacement curves forward-predicted by the E-FI model (based on known H-law parameters of materials) and the H-law parameters of materials given by the E-FIM (based on known energy-displacement curves) are consistent with the results of Finite Element Analysis (FEA) and the H-law parameters of materials used as the input for FEA, respectively. Using E-FIM, the goodness of fit for both stress–strain curves with H-law, predicted based on the displacement with 2% signal interference, and that for stress–strain curves without interference is more than 0.98. The stress–strain relations predicted by E-FIM were consistent with the results obtained via uniaxial tensile tests of ten ductile materials.

Topics & Concepts

IndentationMaterials scienceFinite element methodPower lawDisplacement (psychology)Stress (linguistics)Strain energy density functionStructural engineeringStress–strain curveStrain energyMechanicsComposite materialPhysicsMathematicsEngineeringPsychologyLinguisticsPhilosophyStatisticsPsychotherapistMetal and Thin Film MechanicsAdvanced Surface Polishing TechniquesForce Microscopy Techniques and Applications