English

Traceable thermal imaging in harsh environments

Instrumentation and Detectors 2023-02-13 v1

Abstract

Despite being regarded as a well-established field, temperature measurement continues to pose significant challenges for many professionals in the metrology industry. Thermal imagers enable fast, non-contact and a full field measurement, however there is a lack of metrological development to support their use. Here, thermal imagers have been examined for the monitoring of special nuclear material containers; the surface temperature is an important parameter for store management decisions. Throughout this research: a selection of thermal imagers were calibrated and made traceable to the International Temperature Scale of 1990; laboratory observations of a proxy steel plate were made; initial measurement of nuclear material storage containers were made; then a deployment to an inactive store was demonstrated. For this technique to be feasible, uncertainties less than 10^\circC would be required. During the laboratory calibration of an uncooled and cooled thermal imager against blackbody reference sources, across the measured temperature range of 10^\circC to 100^\circC the uncertainties were less than 3.20^\circC (k=2k=2) and 0.50^\circC (k=2k=2) respectively. Here kk is the uncertainty coverage factor. When these calibrations were applied to the plate, regions of steel and higher emissivity coating were evaluated. These uncoated regions were measured with a thermal imager to demonstrate temperature differences compared to surface mounted thermocouples of 8.3^\circC and uncertainties up to 30.1^\circC (k=2k=2). For the coated regions this temperature difference was reduced to 1.8^\circC with uncertainties up to 6.8^\circC (k=2k=2).

Keywords

Cite

@article{arxiv.2302.05198,
  title  = {Traceable thermal imaging in harsh environments},
  author = {Jamie Luke McMillan},
  journal= {arXiv preprint arXiv:2302.05198},
  year   = {2023}
}

Comments

PhD thesis

R2 v1 2026-06-28T08:36:57.197Z