Gaoliang Dai, Jian Zhao , Febo Menelao, Konrad Herrmann, Uwe Brand
IMPROVED METHODS FOR ACCURATELY CALIBRATING THE 3D GEOMETRIES OF ROCKWELL INDENTERS

In this paper an improved method for calibrating the 3D geometry of Rockwell indenters using a metrological stylus profilometer is reported. The measured geometry of the indenter is not only applied to determine the quality of the indenter, but also used for correcting the hardness values for improved hardness measurement accuracy. A method for such a correction has been proposed. A virtual indentation device simulated using finite element method (FEM) has been developed. By applying both the measured and the theoretically ideal indenter geometries in the virtual device, two different hardness values HRCreal and HRCideal are obtained, respectively. The difference between HRCreal and HRCideal stands for the systematic deviation due to the indenter geometry and is used to correct the measured hardness values. Some experiments are carried out on the same group of 6 reference materials with a hardness ranging from 20 HRC to 65 HRC to verify our proposal. The geometries of three Rockwell indenters used are measured and further applied to correct the hardness values. By this correction technique the mean deviation between the three indenters on 6 reference materials could be reduced from 0.11 HRC to 0.03 HRC, indicating the effectiveness of the proposed method.

Satoshi Takagi, Tatsuya Ishibashi
ANALYSIS OF INDENTER GEOMETRY VERIFICATION DATA BY MEANS OF THE REGRESSION PLANE FITTING

An analytical method of the geometrical parameters of hardness indenters from bitmap data obtained AFM, etc. is introduced. The method is based on the fitting to the analytical geometric shape by the least square method. The results of the analysis are not influenced by human factors which are usually included in the operation of analyzing software's GUI. Examples of analytical results are shown with the estimation of the uncertainty of measurement. The uncertainty is estimated considering the uncertainty of AFM itself and the misfit of plan regression, and the uncertainty of facet angles, interior angles of the square base of the pyramid and the area function are evaluated for nano-range Vickers indenters through the propagation of error. There are some suggestions that some of the geometrical requirements in ISO 14577 may not practical when the verification process is considered.

Tanja Haas, Gottfried Bosch, Hans-Peter Vollmar
CAPABILITIES OF THE LOAD AND PARTIAL UNLOAD TECHNIQUE

The load and partial unload technique adds partial unload processes to the load curve. The mechanical properties like elastic modulus can be determined for each of these unload curves. This allows for a faster depth dependent measurement of the characteristic quantities. If the elastic modulus of a material is known and not dependent of the depth, an indenter shape correction can be performed using this technique.
The results of such a correction are compared with those gained using a correction based on the Martens hardness of the material. The elastic modulus E_IT as well as the Martens hardness H_M are corrected with both methods.
The results of both approaches are comparable down to an indentation depth of 100 nm. A Fischerscope HM2000 was used to perform the measurements.

Carlo Ferrero, Adelina Leka , Luciano Bianchi
INTERLABORATORY COMPARISONS IN ITALY TO VERIFY THE ACCREDITATION ON TORQUE WRENCH CALIBRATION

In 2008 one ILC, for the calibration of torque wrenches, was organised in Italy by COPA-SIT (Sistema Italiano di Taratura). In the present paper the main results obtained during the ILC are discussed, in particular the differences on the repeatability and accuracy given by the different laboratories are compared and evaluated.

Atsuhiro Nishino, Koji Ogushi, Kazunaga Ueda
EVALUATION OF ACTUAL SENSITIVITY LIMIT IN A 10 N·m DEAD WEIGHT TORQUE STANDARD MACHINE AND STABILITY OF A NEW 1 N·m TORQUE TRANSDUCER

A 10 N·m dead weight torque standard machine (10-N·m-DWTSM) has been under development at NMIJ/AIST since 2006 to expand the range of the torque standard. Estimation of the sensitivity limit of the fulcrum is one of the most important issues to realize a precise reference torque of small capacity by using a dead weight torque standard machine. In this study, a torque transducer was installed on the 10-N·m-DWTSM in order to keep the moment-arm on the horizontal line (balancing). The sensitivity limit of the fulcrum under real calibration conditions was estimated by reading the change in the output from the torque measuring device (TMD: the torque transducer with a cable and an indicating device) when small weights were loaded or unloaded. The small weights used in the experiment were 0.5 mg, 1 mg, 10 mg, and 100 mg. Equivalent radial loads from 0.1 N·m to 10 N·m were imposed on the fulcrum during the sensitivity measurement. As a result, the sensitivity limit of the fulcrum was confirmed to be sufficient to load at least 0.5 mg. A relative sensitivity limit of the fulcrum of less than 2.5 × 10^-5 and relative reproducibility of the sensitivity limit of the fulcrum of less than 1.7 × 10^-6 could be obtained within the calibration range from 0.1 N·m to 10 N·m.
It is also important to develop small-rated-capacity torque transducers that can be used as a transfer standard. Therefore, a transducer with a rated capacity of 1 N·m was developed in parallel with the development of the 10-N·m-DWTSM. The stability of the 1 N·m TMD has been evaluated over a period of one year.