Sub-size tensile specimen design for in-reactor irradiation and post-irradiation testing

Maxim N. Gussev; Richard H. Howard; Kurt A. Terrani; Kevin G. Field

doi:10.1016/j.nucengdes.2017.06.008

Sub-size tensile specimen design for in-reactor irradiation and post-irradiation testing

Maxim N. Gussev, Richard H. Howard, Kurt A. Terrani, Kevin G. Field

Research output: Contribution to journal › Article › peer-review

66 Scopus citations

Abstract

The present work aims to provide a complete engineering solution, an appropriate experimental database, and a brief physical background on designing a miniature specimen geometry suitable for irradiation in materials test reactors such as the High Flux Isotope Reactor and post-irradiation out-of-hot cell testing. The physical limits of specimen miniaturization and a background of the scale factor effect are discussed, and principal limitations are defined. The advantages of modern test methods like digital image correlation, as well as some limitations connected to small specimen size, are analyzed. A sub-sized specimen geometry, “SS-Mini,” is designed; the geometry employs existing irradiation capsules leading to the reduced cost of any irradiation campaign. The new geometry performance is evaluated using a commercial 304 L stainless steel, an aluminum alloy including advanced 3D-printed material, a high nickel 718-alloy, tungsten, and an advanced fuel cladding FeCrAl alloy. Mechanical tests are conducted to compare the engineering mechanical properties (yield and ultimate tensile stress, uniform and total elongation values) and plastic behavior of the proposed miniature specimen with common specimen types for irradiation testing.

Original language	English
Pages (from-to)	298-308
Number of pages	11
Journal	Nuclear Engineering and Design
Volume	320
DOIs	https://doi.org/10.1016/j.nucengdes.2017.06.008
State	Published - Aug 15 2017

Funding

This research was primarily funded by the U.S. Department of Energy, Office of Nuclear Energy, for the Nuclear Energy Enabling Technologies (NEET) program for the Reactor Materials effort. Laboratory Directed R&D funds at ORNL were used for testing of UAM manufactured aluminum. The authors would like to thank Dr. L.M. Garrison (ORNL) for providing tungsten tensile specimens for the present work and D.P. Stevens and S. Crawford (ORNL) for help with manuscript preparation.

Keywords

Flexible design for neutron irradiation capsules
In-situ testing
Post-irradiation investigation
Scale factor
Sub-size specimen geometry

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10.1016/j.nucengdes.2017.06.008

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title = "Sub-size tensile specimen design for in-reactor irradiation and post-irradiation testing",

abstract = "The present work aims to provide a complete engineering solution, an appropriate experimental database, and a brief physical background on designing a miniature specimen geometry suitable for irradiation in materials test reactors such as the High Flux Isotope Reactor and post-irradiation out-of-hot cell testing. The physical limits of specimen miniaturization and a background of the scale factor effect are discussed, and principal limitations are defined. The advantages of modern test methods like digital image correlation, as well as some limitations connected to small specimen size, are analyzed. A sub-sized specimen geometry, “SS-Mini,” is designed; the geometry employs existing irradiation capsules leading to the reduced cost of any irradiation campaign. The new geometry performance is evaluated using a commercial 304 L stainless steel, an aluminum alloy including advanced 3D-printed material, a high nickel 718-alloy, tungsten, and an advanced fuel cladding FeCrAl alloy. Mechanical tests are conducted to compare the engineering mechanical properties (yield and ultimate tensile stress, uniform and total elongation values) and plastic behavior of the proposed miniature specimen with common specimen types for irradiation testing.",

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AB - The present work aims to provide a complete engineering solution, an appropriate experimental database, and a brief physical background on designing a miniature specimen geometry suitable for irradiation in materials test reactors such as the High Flux Isotope Reactor and post-irradiation out-of-hot cell testing. The physical limits of specimen miniaturization and a background of the scale factor effect are discussed, and principal limitations are defined. The advantages of modern test methods like digital image correlation, as well as some limitations connected to small specimen size, are analyzed. A sub-sized specimen geometry, “SS-Mini,” is designed; the geometry employs existing irradiation capsules leading to the reduced cost of any irradiation campaign. The new geometry performance is evaluated using a commercial 304 L stainless steel, an aluminum alloy including advanced 3D-printed material, a high nickel 718-alloy, tungsten, and an advanced fuel cladding FeCrAl alloy. Mechanical tests are conducted to compare the engineering mechanical properties (yield and ultimate tensile stress, uniform and total elongation values) and plastic behavior of the proposed miniature specimen with common specimen types for irradiation testing.

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KW - Sub-size specimen geometry

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Sub-size tensile specimen design for in-reactor irradiation and post-irradiation testing

Abstract

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Keywords

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