Abstract
Existing temperature sensors such as thermocouples and platinum resistance thermometers suffer from calibration drift, especially in harsh environments, due to mechanical and chemical changes (and transmutation in the case of nuclear applications). A solution to the drift problem is to use temperature sensors based on fundamental thermometry (primary thermometers) where the measured property is related to absolute temperature by a fundamental physical law. A Johnson noise thermometer is such a sensor and uses the measurement of the extremely small thermal voltage noise signals generated by any resistive element to determine temperature using the Johnson-Nyquist equation. A Johnson noise thermometer never needs calibration and is insensitive to the condition of the sensor material, which makes it ideally suited to long-term temperature measurement in harsh environments. These can include reactor coolant circuits, in-pile measurements, nuclear waste management and storage, and severe accident monitoring. There have been a number of previous attempts to develop a Johnson noise thermometer for the nuclear industry, but none have achieved commercialization because of technical difficulties. We describe the results of a collaboration between the National Physical Laboratory and Metrosol Limited, which has led to a new technique for measuring Johnson noise that overcomes the previous problems that have prevented commercialization. The results from a proof-of-principle prototype that demonstrates performance commensurate with the needs of nuclear applications is presented, together with details of progress towards the commercialization of the technology. The development partners have effected a step change in the application of primary thermometry to industrial applications and seek partners for field trials and further exploitation.
Highlights
HERMOMETRY in nuclear processes generally relies onT conventional sensors such as thermocouples or resistance thermometers
We describe a collaboration between Metrosol and NPL to design, build, test for electromagnetic compability (EMC) immunity to the conditions expected in the heavy industrial environment found in nuclear power stations, and metrologically validate a practical Johnson noise thermometry (JNT)
Initial tests were conducted on JNT1 to ensure that the measured spectra were clean with no evidence of contamination from external noise sources
Summary
T conventional sensors such as thermocouples or resistance thermometers. These thermometers need to be calibrated [1], and as the sensor material changes in harsh operating environments, the calibration changes in an unknown manner [2,3]. JNT relies on the measurement of the electrical noise arising from the random thermal motion of charge carriers (electrons) in a sensor [7], and is completely independent of any material degradation. It is in a class of thermometry techniques called ‘primary’ thermometry [8], in that it can provide a direct measure of the temperature without recourse to calibration. We describe a collaboration between Metrosol and NPL to design, build, test for electromagnetic compability (EMC) immunity to the conditions expected in the heavy industrial environment found in nuclear power stations, and metrologically validate a practical JNT. In this paper we summarise the key developments since 2015
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