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Fiber-Optic, Ultra-High Temperature Sensor to 1,000C
The spectral position of the dip in this chiral fiber changes with temperature allowing it to be used as a temperature sensor. Temperature testing was carried out in a computer-controlled high-temperature oven in which the temperature was monitored by a thermocouple. Both long-term temperature stability and temperature sensitivity were tested using a Micron Optics fiber interrogator to monitor sensors as they were cycled from room temperature to 1000°C. Use of the interrogator reduces the characterization and testing time and increases the accuracy with which the dip position can be measured. In addition, the dip position can be traced in real time. A micro-mirror may be attached to each chiral fiber so that they can be characterized in reflection, as required by the interrogator. The dip wavelength shifts to the red by approximately 1.3 nm as the temperature is raised by 100 °C. The figure shows the wavelength of transmission dip of a chiral fiber versus temperature. The temperature was cycled five times from 700 C to 1000 C in the course of 24 hours, dwelling for 3 hours at these temperatures. The inset shows the temperature variations. As seen in the figure, the chiral fiber is capable of reliably measuring temperature up to 1000 C with better than +/- 1% accuracy
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Product based on Go!Foton Helica™ grating, fabricated by twisting a fiber passing through a precision heat zone to produce a distinct dip in the transmission spectrum.
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