Neutron Radiography of Irradiated Nuclear Fuel at Idaho National Laboratory

2020

Standard neutron imaging is usually performed with a thermal or cold spectrum, but sometimes, penetration of thermal or cold neutrons is not sufficient for thick samples, so higher energies should be tried e.g. on technical machine parts or on rock samples containing crystal water. A 1-2 mm cadmium filter effectively absorbs all neutrons with energies lower than 0.4 eV, but is relatively transparent for higher energies, including epithermal neutrons. Radiography and computed tomography measurements were recorded at Idaho Nation Laboratory in the USA and Heinz Maier-Leibnitz Institut (MLZ) at the FRM II reactor in Germany. Image quality was improved by better penetration and by filtering out scattered and thermalized neutrons.

Section: Measurements At the Nrad Reactor Of Idaho National Labmentioning

confidence: 99%

Epithermal Neutron Radiography and Tomography on Large and Strongly Scattering Samples

2020

“…The TREAT radiography system is used to perform neutron radiography of fuels, experiments, and other specimens before and after irradiation at the TREAT reactor [2]. Neutron radiographs are acquired using transfer method with dysprosium conversion foils and image plates [3], similar to the process used at INL's Neutron Radiography (NRAD) Reactor [4]. The system includes the radiography facility where radiography cassettes are exposed to the neutron beam and a Radiography Room where radiographs are subsequently processed.…”

Section: Treat Neutron Radiography Program and Facility Descriptionmentioning

confidence: 99%

Reactivation of the Transient Reactor Test (TREAT) Facility Neutron Radiography Program

Jensen

Papaioannou

et al. 2020

The TREAT radiography system is used to perform neutron radiography of fuels, experiments, and other specimens before and after irradiation within the TREAT reactor. The TREAT neutron radiography facility performed approximately 5,000 radiographs by the spring of 1977. Originally built in 1958, the TREAT Facility was in operation until it was placed in a shutdown status in 1994. Following the Fukushima incident and seeing a need for enhanced accident tolerant fuels, the United Stated Department of Energy decided to restart the TREAT facility and resume transient operations. In November 2017, the TREAT reactor was successfully restarted and is currently performing operational testing in preparation for initial experiment irradiations and transient testing. This paper discusses efforts to reactivate the TREAT neutron radiography facility. To characterize the neutron beam, gold foil activation measurements were made to determine an average neutron flux and flux profile. An open beam image provides the information about variations in the beam profile. A series of system qualification radiographs have been acquired to determine the effective image acquisition parameters, resulting image quality, and the relationships between the two.

“…Phase One of this project investigated the ability of a gadolinium-based infiltrant to enhance the contrast of indirect neutron radiography images at the Neutron RADiography (NRAD) reactor at the Idaho National Laboratory. This reactor is a 250 kW TRIGA (Training, Research, Isotopes, General Atomics) reactor, and provides neutrons for two beamlines [3]. Two radiography stations at the NRAD allow for indirect neutron imaging using a cassette containing activation foils.…”

Section: Introductionmentioning

confidence: 99%

Quantitative Crack Analysis using Indirect Neutron Radiography and Neutron Activation Analysis with Contrast Enhancement Agents

Jarmer

King

et al. 2020

This paper presents an analysis of infiltration and washing methods to develop a quantitative metric for crack features using indirect neutron radiography and neutron activation analysis. A gadolinium contrast agent enhances the visibility of crack features in digitally processed neutron radiographs. Neutron activation analysis of crack infiltrants using dysprosium as a surrogate for gadolinium directly measures the amount of infiltrant in crack features.