Share Email Print
cover

Proceedings Paper

Distributed optical fibre temperature measurements in a low dose rate radiation environment based on Rayleigh backscattering
Author(s): A. Faustov; A. Gussarov; M. Wuilpart; A. A. Fotiadi; L. B. Liokumovich; O. I. Kotov; I. O. Zolotovskiy; A. L. Tomashuk; T. Deschoutheete; P. Mégret
Format Member Price Non-Member Price
PDF $17.00 $21.00

Paper Abstract

On-line monitoring of environmental conditions in nuclear facilities is becoming a more and more important problem. Standard electronic sensors are not the ideal solution due to radiation sensitivity and difficulties in installation of multiple sensors. In contrast, radiation-hard optical fibres can sustain very high radiation doses and also naturally offer multi-point or distributed monitoring of external perturbations. Multiple local electro-mechanical sensors can be replaced by just one measuring fibre. At present, there are over four hundred operational nuclear power plants (NPPs) in the world 1. Operating experience has shown that ineffective control of the ageing degradation of major NPP components can threaten plant safety and also plant life. Among those elements, cables are vital components of I&C systems in NPPs. To ensure their safe operation and predict remaining life, environmental monitoring is necessary. In particular, temperature and radiation dose are considered to be the two most important parameters. The aim of this paper is to assess experimentally the feasibility of optical fibre temperature measurements in a low doserate radiation environment, using a commercially available reflectometer based on Rayleigh backscattering. Four different fibres were installed in the Sub-Pile Room of the BR2 Material testing nuclear reactor in Mol, Belgium. This place is man-accessible during the reactor shut-down, allowing easy fibre installation. When the reactor operates, the dose-rates in the room are in a range 0.005-5 Gy/h with temperatures of 40-60 °C, depending on the location. Such a surrounding is not much different to some "hot" environments in NPPs, where I&C cables are located.

Paper Details

Date Published: 9 May 2012
PDF: 8 pages
Proc. SPIE 8439, Optical Sensing and Detection II, 84390C (9 May 2012); doi: 10.1117/12.922082
Show Author Affiliations
A. Faustov, SCK CEN (Belgium)
Univ. of Mons (Belgium)
St. Petersburg State Polytechnical Univ. (Russian Federation)
A. Gussarov, SCK CEN (Belgium)
M. Wuilpart, Univ. de Mons (Belgium)
A. A. Fotiadi, Univ. of Mons (Belgium)
Ioffe Physical-Technical Institute (Russian Federation)
Ulyanovsk State Univ. (Russian Federation)
L. B. Liokumovich, St. Petersburg State Polytechnical Univ. (Russian Federation)
O. I. Kotov, St. Petersburg State Polytechnical Univ. (Russian Federation)
I. O. Zolotovskiy, Ulyanovsk State Univ. (Russian Federation)
A. L. Tomashuk, Ulyanovsk State Univ. (Russian Federation)
Fiber Optic Research Ctr. (Russian Federation)
T. Deschoutheete, Laborelec (Belgium)
P. Mégret, Univ. of Mons (Belgium)


Published in SPIE Proceedings Vol. 8439:
Optical Sensing and Detection II
Francis Berghmans; Anna Grazia Mignani; Piet De Moor, Editor(s)

© SPIE. Terms of Use
Back to Top