Dynamic Tensile Characterization of Thin-Sheet Brittle Metallic Materials

Refractory metals are favorable materials in applications where high strength and ductility are needed at elevated temperatures. In some cases, operating temperatures may be near the melting point of the material. However, as temperature drops, refractory metals typically undergo a significant mecha...

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Bibliographic Details
Published in:Experimental techniques (Westport, Conn.) Conn.), 2020-10, Vol.44 (5), p.639-648
Main Authors: Sanborn, B., Hudspeth, M., Song, B.
Format: Article
Language:English
Subjects:
Ambient temperature
Brittle materials
Brittleness
Characterization and Evaluation of Materials
Chemistry and Materials Science
Ductile-brittle transition
Finite element method
high rate
High strain rate
High temperature
Material properties
MATERIALS SCIENCE
Mechanical analysis
Melting points
Operating temperature
Refractory metals
Research Paper
Room temperature
Specimen geometry
stress-strain
Stress-strain curves
Stress-strain relationships
Temperature
tensile behavior
Tungsten
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Summary:Refractory metals are favorable materials in applications where high strength and ductility are needed at elevated temperatures. In some cases, operating temperatures may be near the melting point of the material. However, as temperature drops, refractory metals typically undergo a significant mechanical response change - ductile-to-brittle transition. These materials may be subjected to high strain rate loading at an ambient temperature state, such as an impact or crash. Knowledge of the high rate material properties are essential for design as well as simulation of impact events. The high rate stress-strain behavior of brittle metallic materials at ambient temperature is rarely studied because of experimental challenges, particularly when failure is involved. Failure typically occurs within the non-gage section of the material, which invalidates any collected stress-strain information. In this study, a method to determine a specimen geometry which will produce failures in the gage section is presented. Pure tungsten in thin-sheet form was used as a trial material to select a specimen geometry for high rate Kolsky tension bar experiments. A finite element simulation was conducted to derive a strain correction for more accurate results. The room temperature stress-strain behavior of pure tungsten at a strain rate of 24 s −1 is presented. The outcome of this experimental technique can be applied to other brittle materials for dynamic tensile characterization.
ISSN:0732-8818
1747-1567
DOI:10.1007/s40799-020-00384-7