Abstract
Determining tensile properties from small punch test is being pursued actively in the nuclear industry due to the limited volume of material such tests use compared with standard tests which can be critical when considering active or development samples. One of the crucial challenges in harnessing the full potential of this technique is formulating methodologies which correlate the small punch specimen’s deflection to equivalent uniaxial tensile properties. Existing approaches for correlation rely on deflection obtained from a single point on the small punch test specimen, used with empirical equations to make the correlation. However, the deflection and strain accumulation in a small punch specimen is highly heterogeneous and data from a single point does not represent the gross deformation evolving in the specimen. This data when used in conjunction with the empirical formulations for deriving equivalent uniaxial tensile properties, would not result in accurate identification of material properties. In this work we offer an alternative approach which uses the full field deflection of the specimen mapped through in-situ digital image correlation. The use of digital image correlation combined with inverse finite element analysis augments the existing method of material properties identification from single point deflection data thereby significantly improving the reliability of the measurements.
Highlights
Over the last few decades there has been a considerable impetus for developing small scale specimen testing techniques for evaluating mechanical properties of materials
The loaddeflection data in these two regimes were subsequently used for estimating the mechanical properties incorporating inverse finite element modelling (iFEM)
The Digital Image Correlation (DIC) estimated deflection contours were almost concentric to the central point
Summary
Over the last few decades there has been a considerable impetus for developing small scale specimen testing techniques for evaluating mechanical properties of materials. It is the multiple advantages these techniques offer that has propelled its sustained advancement and is being actively pursued as a reliable method in situations where estimation of mechanical properties using (V.D. Vijayanand). V.D. Vijayanand et al / Journal of Nuclear Materials 538 (2020) 152260 in force-controlled mode are used to obtain the time-displacement characteristics. The wide acceptance of the small punch test has led to the development of a pre-normative code of practice by CEN [26]. The code describes various approaches for deriving creep, tensile and fracture properties
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