Realization of in Situ Fiber-Core Temperature Measurement in a Kilowatt-Level Fiber Laser Oscillator: Design and Optimization of the Method Based on OFDR

High-power fiber lasers have been widely used in various industrial manufacturing and military defense applications. During the development of fiber lasers in the past decades, the thermal effect has always been one of the biggest obstacles. It is crucial to study the temperature characteristics and...

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Veröffentlicht in:Journal of lightwave technology 2021-04, Vol.39 (8), p.2573-2582
Hauptverfasser: Lou, Zhaokai, Han, Kai, Yang, Baolai, Zhang, Hanwei, Xi, Xiaoming, Wang, Xiaolin, Xu, Xiaojun, Liu, Zejin
Format: Artikel
Sprache:eng
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Zusammenfassung:High-power fiber lasers have been widely used in various industrial manufacturing and military defense applications. During the development of fiber lasers in the past decades, the thermal effect has always been one of the biggest obstacles. It is crucial to study the temperature characteristics and overcome the thermal restrictions for a better output performance. With the systematic design and optimization in this article, optical frequency domain reflectometry (OFDR) can achieve in situ distributed temperature measurement of the fiber core in high-power fiber lasers. This allows a better study of the temperature characteristics and thermal effects. The fiber-core distributed temperature of a kilowatt-level fiber oscillator is first demonstrated based on this method here. The splicing point between the high reflectivity fiber Bragg grating (HR-FBG) and gain fiber withstands the highest temperature, reaching 101.6 °C at a 1.47 kW output. In addition, the temperature of the gain fiber gradually decreases from 92 °C to 30 °C along the pumping direction. The internal temperatures of the combiner and HR-FBG are also measured to evaluate their performances in the high-power regime. The temperature distributions in the experiment agree well with the theoretical simulation.
ISSN:0733-8724
1558-2213
DOI:10.1109/JLT.2020.3048747