As the name suggests these sensors employs fiber optics technology to function. A fiber optic sensor generally guides light to and from a measurement zone where the light is modulated by the measurand of interest and returned along the same or a different optical fiber to a detector at which the optical signal is interpreted. The measurement zone in this case can be intrinsic within the fiber that transports the optical signal or can be extrinsic to the optical waveguide.
The key benefits of using fiber optics for measurement include:
The key phenomena employed in the optical techniques for temperature measurement include:
In this article, we will only focus on one phenomenon: changes in fluorescence spectra to illustrate the operation; therefore we will demonstrate the principle of operation of the fiber optic temperature sensor based on changes in fluorescence spectra.
Contents
This is one of the most utilized fiber optic temperature sensors and is extensively used in a variety of applications.
To illustrate the principle of operation of this temperature sensor, consider the following diagram:
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In reference to the above figure, phosphor is excited by an ultraviolet light source (which limits the length of the silica-based feed fiber to a few tens meters) and the return spectrum is divided into ‘red’ and ‘green’ components, the intensity ratios of which are a simple single-valued function of phosphor temperature. For accurate temperature measurement, the detectors and feed fiber require calibration, and particularly for the detectors, the calibration is a function of the surrounding temperature. Nevertheless, this can be solved through curve fitting and interrogation of a thermal reference.
This instrument is capable of accuracies of about ±0.1 °C within sub-second integration times over a temperature range extending from approximately -50 °C to ±200°C.
Fiber optic temperature sensors are used for solving specific measurement problems for example where metallic probe either distorts the electromagnetic field significantly e.g. in microwave ovens or is subject to very high levels of interference, producing spurious readings. Typical applications include monitoring temperature profiles in both domestic and industrial microwave ovens, examining temperatures in power transformer oils, motor/generator windings. Therefore fiber optic temperature sensors are primarily used as measurement probes in regions of very high electromagnetic fields, in zone zero intrinsically safe areas, and so forth.
The distributed capability of fiber optic sensors is especially relevant in structural monitoring and in other specialized areas such as measuring the temperature distribution along underground power lines, tunnels or similar structures or in experimental circumstances such as the measurement of curing processes in large volumes of concrete.
Distributed temperature alarms triggering on and locating the presence of either hot or cold spots along the fiber can achieved at significantly lower costs. A typical application is a temperature alarm on liquefied natural gas storage tanks. Here, the core and cladding indices for a plastic-clad fiber cross at a temperature in the region of 50 °C, Such temperatures can only be realized when a leak occurs. Furthermore, the system has the obvious benefit of intrinsic safety and total compatibility with use within potentially explosive atmospheres.
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