Optimum Design of a Ceramic Tensile Creep Specimen Using a Finite Element Method |
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Authors: | Z. Wang C. K. Chiang T.-J. Chuang |
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Affiliation: | National Institute of Standards and Technology, Gaithersburg, MD 20899-0001 |
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Abstract: | An optimization procedure for designing a ceramic tensile creep specimen to minimize stress concentration is carried out using a finite element method. The effect of pin loading and the specimen geometry are considered in the stress distribution calculations. A growing contact zone between the pin and the specimen has been incorporated into the problem solution scheme as the load is increased to its full value. The optimization procedures are performed for the specimen, and all design variables including pinhole location and pinhole diameter, head width, neck radius, and gauge length are determined based on a set of constraints imposed on the problem. In addition, for the purpose of assessing the possibility of delayed failure outside the gage section, power-law creep in the tensile specimen is considered in the analysis. Using a particular grade of advanced ceramics as an example, it is found that if the specimen is not designed properly, significant creep deformation and stress redistribution may occur in the head of the specimen resulting in undesirable (delayed) head failure of the specimen during the creep test. |
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Keywords: | ceramics finite element method optimum design power-law creep specimen design stress analysis stress relaxation |
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