Fiber-based distributed bolometry.

Regina Magalhães,Sonia Martin-Lopez,Walter Margulis,Hugo F Martins,João Pereira,Andres Garcia-Ruiz,Miguel Gonzalez-Herraez

doi:10.1364/oe.27.004317

Abstract

Optical fibers are inherently designed to allow no interaction between the guided light and the surrounding optical radiation. Thus, very few optical fiber-based technologies exist in the field of optical radiation sensing. Accomplishing fully-distributed optical radiation sensing appears then as even more challenging since, on top of the lack of sensitivity explained above, we should add the need of addressing thousands of measurement points in a single, continuous optical cable. Nevertheless, it is clear that there exists a number of applications which could benefit from such a distributed sensing scheme, particularly if the sensitivity was sufficiently high to be able to measure correctly variations in optical radiation levels compatible with the earth surface. Distributed optical radiation sensing over large distances could be employed in applications such as Dynamic Line Rating (DLR), where it is known that solar radiation can be an important limiting factor in energy transmission through overhead power cables, and also in other applications such as thermo-solar energy. In this work, we present the proof-of-concept of the first distributed bolometer based on optical fiber technology and capable of detecting absolute changes of irradiance. The core idea of the system is the use of a special fiber coating with high emissivity (e.g., carbon coating or black paint). The high absorption of these coatings translates into a temperature change that can be read with sufficiently high sensitivity using phase-sensitive reflectometry. To demonstrate the concept, we interrogate distinct black-coated optical fibers using a chirped-pulse ΦOTDR, and we readily demonstrate the detection of light with resolutions in the order of 1% of the reference solar irradiance, offering a high-potential technology for integration in the aforementioned applications.

Highlights

Several engineering applications are currently seeking for measurement methods providing continuous distributed measurements of optical radiation over large distances, typically around a few tens of kilometers
In Dynamic Line Rating (DLR), temperature acquisition over the cable is often combined with meteorological measurements, which allow for precise models of behavior of the line conductor and optimal values of transmission line limits [3]
It consists of a block responsible for generating linearly-chirped pulses and sending them towards the Fibers Under Test (FUTs); and a second block responsible for the detection of the Rayleigh backscattered light generated during the process

Summary

Introduction

Several engineering applications are currently seeking for measurement methods providing continuous distributed measurements of optical radiation over large distances, typically around a few tens of kilometers. One of the most interesting and promising applications for large-scale spatially-resolved optical radiation detection is the optimization of power transmission along overhead power lines [1]. A possible option to optimize the grid and improve efficiency is based on the concept of Dynamic Line Rating (DLR) [2]. DLR replaces the traditional static ratings by updating the ampacity values in real time based on weather conditions and cable temperature. In DLR, temperature acquisition over the cable is often combined with meteorological measurements, which allow for precise models of behavior of the line conductor and optimal values of transmission line limits [3]. Very few dedicated technologies exist to enable this measurement in the power cable itself, and a single-point measurement of effective incident radiation is not Corrected: 11 April 2019

Methods

Results

Conclusion