"Irradiation Testing of Piezoelectric (Aluminum Nitride, Zinc Oxide, and Bismuth Titanate) and Magnetostrictive Sensors (Remendur and Galfenol)" Joshua Daw, Brian Reinhardt, Bernhard Tittmann, IEEE Transactions on Nuclear Science Vol. 65 2018 Link | ||
"Irradiation Testing of Ultrasonic Transducers"
Joshua Daw, Gordon Kohse, Joe Palmer, Pradeep Ramuhalli, Brian Reinhardt, Joy Rempe, Bernhard Tittmann, Robert Montgomery, Jean-Francois Villard, H. T. Chien,
ANIMMA 2013 Special Edition, IEEE Transactions on Nuclear Science
Vol. 61
2013
1-7
Link
Ultrasonic technologies offer the potential for high accuracy and resolution in-pile measurement of numerous parameters, including geometry changes, temperature, crack initiation and growth, gas pressure and composition, and microstructural changes. Many Department of Energy-Office of Nuclear Energy (DOE-NE) programs are exploring the use of ultrasonic technologies to provide enhanced sensors for in-pile instrumentation during irradiation testing. For example, the ability of single, small diameter ultrasonic thermometers (UTs) to provide a temperature profile in candidate metallic and oxide fuel would provide much needed data for validating new fuel performance models. Other efforts include an ultrasonic technique to detect morphology changes (such as crack initiation and growth) and acoustic techniques to evaluate fission gas composition and pressure. These efforts are limited by the lack of existing knowledge of ultrasonic transducer material survivability under irradiation conditions. To address this need, the Pennsylvania State University (PSU) was awarded an Advanced Test Reactor National Scientific User Facility (ATR NSUF) project to evaluate promising magnetostrictive and piezoelectric transducer performance in the Massachusetts Institute of Technology Research Reactor (MITR) up to a fast fluence of at least 1021 n/cm2 (E> 0.1 MeV). This test will be an instrumented lead test; and real-time transducer performance data will be collected along with temperature and neutron and gamma flux data. By characterizing magnetostrictive and piezoelectric transducer survivability during irradiation, test results will enable the development of novel radiation tolerant ultrasonic sensors for use in Material and Test Reactors (MTRs). The current work bridges the gap between proven out-of-pile ultrasonic techniques and in-pile deployment of ultrasonic sensors by acquiring the data necessary to demonstrate the performance of ultrasonic transducers.
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"Nuclear Radiation Tolerance of Single Crystal Aluminum Nitride Ultrasonic Transducer"
Bernhard Tittmann, Brian Reinhardt, Andrew Suprock,
Physics Procedia
Vol. 70
2015
609-613
Link
Ultrasonic technologies offer the potential for high accuracy and resolution in-pile measurement of a range of parameters, including geometry changes, temperature, crack initiation and growth, gas pressure and composition, and microstructural changes. Many Department of Energy-Office of Nuclear Energy (DOE-NE) programs are exploring the use of ultrasonic technologies to provide enhanced sensors for in-pile instrumentation during irradiation testing. For example, the ability of small diameter ultrasonic thermometers (UTs) to provide a temperature profile in candidate metallic and oxide fuel would provide much needed data for validating new fuel performance models, (Rempe et al., 2011; Kazys et al., 2005). These efforts are limited by the lack of identified ultrasonic transducer materials capable of long term performance under irradiation test conditions. To address this need, the Pennsylvania State University (PSU) was awarded an Advanced Test Reactor National Scientific User Facility (ATR NSUF) project to evaluate the performance of promising magnetostrictive and piezoelectric transducers in the Massachusetts Institute of Technology Research Reactor (MITR) up to a fast fluence of at least 1021 n/cm2. The irradiation is also supported by a multi-National Laboratory collaboration funded by the Nuclear Energy Enabling Technologies Advanced Sensors and Instrumentation (NEET ASI) program. The results from this irradiation, which started in February 2014, offer the potential to enable the development of novel radiation tolerant ultrasonic sensors for use in Material Testing Reactors (MTRs). As such, this test is an instrumented lead test and real-time transducer performance data is collected along with temperature and neutron and gamma flux data. Hence, results from this irradiation offer the potential to bridge the gap between proven out-of-pile ultrasonic techniques and in-pile deployment of ultrasonic sensors by acquiring the data necessary to demonstrate the performance of ultrasonic transducers. To date, very encouraging results have been attained as several transducers have continued to operate under irradiation. The irradiation is ongoing and will continue to approximately mid-2015. |
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"Progress towards developing neutron tolerant magnetostrictive and piezoelectric transducers"
Brian Reinhardt, Bernhard Tittmann, Joy Rempe, Joshua Daw, Gordon Kohse, David Carpenter, Michael Ames, Yakov Ostrovsky, Pradeep Ramuhalli, Robert Montgomery, Hualte Chien, Bernard Wernsman,
AIP Conference Proceedings
Vol. 1650
2015
1512-1520
Link
Current generation light water reactors (LWRs), sodium cooled fast reactors (SFRs), small
modular reactors (SMRs), and next generation nuclear plants (NGNPs) produce harsh environments in and
near the reactor core that can severely tax material performance and limit component operational life. To
address this issue, several Department of Energy Office of Nuclear Energy (DOE-NE) research programs
are evaluating the long duration irradiation performance of fuel and structural materials used in existing
and new reactors. In order to maximize the amount of information obtained from Material Testing
Reactor (MTR) irradiations, DOE is also funding development of enhanced instrumentation that will be
able to obtain in-situ, real-time data on key material characteristics and properties, with unprecedented
accuracy and resolution. Such data are required to validate new multi-scale, multi-physics modeling tools
under development as part of a science-based, engineering driven approach to reactor development. It is
not feasible to obtain high resolution/microscale data with the current state of instrumentation technology.
However, ultrasound-based sensors offer the ability to obtain such data if it is demonstrated that these
sensors and their associated transducers are resistant to high neutron flux, high gamma radiation, and high
temperature. To address this need, the Advanced Test Reactor National Scientific User Facility (ATRNSUF)
is funding an irradiation, led by PSU, at the Massachusetts Institute of Technology Research
Reactor to test the survivability of ultrasound transducers. As part of this effort, PSU and collaborators
have designed, fabricated, and provided piezoelectric and magnetostrictive transducers that are optimized
to perform in harsh, high flux, environments. Four piezoelectric transducers were fabricated with either
aluminum nitride, zinc oxide, or bismuth titanate as the active element that were coupled to either Kovar
or aluminum waveguides and two magnetostrictive transducers were fabricated with Remendur or
Galfenol as the active elements. Pulse-echo ultrasonic measurements of these transducers are made insitu.
This paper will present an overview of the test design including selection criteria for candidate
materials and optimization of test assembly parameters, data obtained from both out-of-pile and in-pile
testing at elevated temperatures, and an assessment based on initial data of the expected performance of
ultrasonic devices in irradiation conditions. |
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"Testing piezoelectric sensors in a nuclear reactor environment"
Brian Reinhardt, Andy Suprock, Bernhard Tittmann,
AIP Conference Proceedings
Vol. 1806
2017
Link
Several Department of Energy Office of Nuclear Energy (DOE-NE) programs, such as the Fuel Cycle Research and Development (FCRD), Advanced Reactor Concepts (ARC), Light Water Reactor Sustainability, and Next Generation Nuclear Power Plants (NGNP), are investigating new fuels, materials, and inspection paradigms for advanced and existing reactors. A key objective of such programs is to understand the performance of these fuels and materials during irradiation. In DOE-NE’s FCRD program, ultrasonic based technology was identified as a key approach that should be pursued to obtain the high-fidelity, high-accuracy data required to characterize the behavior and performance of new candidate fuels and structural materials during irradiation testing. The radiation, high temperatures, and pressure can limit the available tools and characterization methods. In this work piezoelectric transducers capable of making these measurements are developed. Specifically, three piezoelectric sensors (Bismuth Titanate, Aluminum Nitride, and Zinc Oxide) are tested in the Massachusetts Institute of Technology Research reactor to a fast neutron fluence of 8.65×1020 nf/cm2. It is demonstrated that Bismuth Titanate is capable of transduction up to 5 × 1020 nf/cm2, Zinc Oxide is capable of transduction up to at least 6.27 × 1020 nf/cm2, and Aluminum Nitride is capable of transduction up to at least 8.65 × 1020 nf/cm2. |
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"Updated Results of Ultrasonic Transducer Irradiation Test"
Joshua Daw, Gordon Kohse, Joe Palmer, Brian Reinhardt, Joy Rempe, Pradeep Ramuhalli, Paul Keller, Robert Montgomery, Hual-Te Chien, Bernhard Tittmann, Jean-Francois Villard,
ANIMMA - Institute of Electrical and Electronics Engineers
Vol.
2015
Link
Ultrasonic technologies offer the potential for high accuracy and resolution in-pile measurement of a range of parameters, including geometry changes, temperature, crack initiation and growth, gas pressure and composition, and microstructural changes. Many Department of Energy-Office of Nuclear Energy (DOE-NE) programs are exploring the use of ultrasonic technologies to provide enhanced sensors for in-pile instrumentation during irradiation testing. For example, the ability of small diameter ultrasonic thermometers (UTs) to provide a temperature profile in candidate metallic and oxide fuel would provide much needed data for validating new fuel performance models. These efforts are limited by the lack of identified ultrasonic transducer materials capable of long term performance under irradiation test conditions. To address this need, the Pennsylvania State University (PSU) was awarded an Advanced Test Reactor National Scientific User Facility (ATR NSUF) project to evaluate the performance of promising magnetostrictive and piezoelectric transducers in the Massachusetts Institute of Technology Research Reactor (MITR) up to a fast fluence of at least 10{sup 21} n/cm{sup 2}. A multi-National Laboratory collaboration funded by the Nuclear Energy Enabling Technologies Advanced Sensors and Instrumentation (NEET-ASI) program also provided initial support for this effort. This irradiation, which started in February 2014, is an instrumented lead test and real-time transducer performance data are collected along with temperature and neutron and gamma flux data. The irradiation is ongoing and will continue to approximately mid-2015. To date, very encouraging results have been attained as several transducers continue to operate under irradiation. |
"Irradiation Testing of Ultrasonic Transducers" Joshua Daw, Gordon Kohse, Joe Palmer, Pradeep Ramuhalli, Brian Reinhardt, Joy Rempe, Bernhard Tittmann, 2013 Conference on Advancements in Nuclear Instrumentation, Measurements Methods (ANIMMA 2013) June 23-27, (2013) | |
"Progress towards Developing Neutron Tolerant Magnetostrictive and Piezoelectric Transducers" Michael Ames, David Carpenter, Joshua Daw, Gordon Kohse, Yakov Ostrovsky, Brian Reinhardt, Joy Rempe, Bernhard Tittmann, 41st Annual Review of Progress in Quantitative Nondestructive Evaluation Conference, July 20-25, (2014) | |
"Ultrasonic transducers for harsh environments" Bernhard Tittmann, Brian Reinhardt, Joshua Daw, Ultrasonics Symposium (IUS), 2016 IEEE International September 18-21, (2016) Link |
The Nuclear Science User Facilities (NSUF) is the U.S. Department of Energy Office of Nuclear Energy's only designated nuclear energy user facility. Through peer-reviewed proposal processes, the NSUF provides researchers access to neutron, ion, and gamma irradiations, post-irradiation examination and beamline capabilities at Idaho National Laboratory and a diverse mix of university, national laboratory and industry partner institutions.
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