Abstract
The indentation properties of pure aluminum (99.9%, 3N aluminum) and high purity aluminum (99.999%, 5N aluminum) with respect to the strain rate dependence of strength are experimentally investigated in order to clarify the effect of strain rate on the micro-indentation test. A micro-indentation test using a Berkovich indenter was performed at loading rates of 0.7, 7, and 70 mN/s. In all of the specimens, the indenter was loaded to a maximum value of 1200 mN, and then was maintained for 30 s. In the 3N specimen, the dependence of the loading rate on the load was slight at loading rates of 0.7 and 7 mN/s, whereas the load at the loading rate of 70 mN/s was higher than the loads at loading rates of 0.7 and 7 mN/s. On the other hand, the load for the 5N specimen increased with the increasing loading rate. Thus, the effect of the loading rate on the load-displacement curve for the 3N and 5N specimens was similar to the strain rate dependence of strength for theses metals. In addition, the micro-indentation test was demonstrated to be strongly affected by high strain rate at a loading rate of 70 mN/s.
Highlights
Instrumented indentation tests are widely used to investigate the elastic and plastic properties of mechanical materials [1,2,3]
The authors [6] have investigated the effect of high strain rate on indentation properties by comparing the results of a microindentation test at a loading rate of 70 mN/s and the results obtained by the finite element method (FEM) analysis using the pure copper having strain rate dependence of strength
The indentation properties of the pure aluminum with the strain rate dependence of strength (99.9 mass% and 99.999 mass% pure aluminum) were experimentally investigated in order to clarify in greater detail the effect of high strain rate on the micro-indentation test
Summary
Instrumented indentation tests are widely used to investigate the elastic and plastic properties (indentation properties) of mechanical materials [1,2,3]. The authors [6] have investigated the effect of high strain rate (dynamic strain rate) on indentation properties by comparing the results of a microindentation test at a loading rate of 70 mN/s and the results obtained by the finite element method (FEM) analysis using the pure copper (rolled copper and annealed copper) having strain rate dependence of strength. The load-displacement curves obtained through the static-FEM analysis were inconsistent with those obtained through the micro-indentation test for both rolled copper and annealed copper. The indentation properties of the pure aluminum with the strain rate dependence of strength (99.9 mass% and 99.999 mass% pure aluminum) were experimentally investigated in order to clarify in greater detail the effect of high strain rate on the micro-indentation test
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
