Self-heated fiber Bragg grating sensors for cryogenic environments

Tong Chen; Philip R. Swinehart; Mokhtar S. Maklad; Michael P. Buric; Kevin P. Chen

doi:10.1117/12.851526

23 April 2010 Self-heated fiber Bragg grating sensors for cryogenic environments

Tong Chen, Philip R. Swinehart, Mokhtar S. Maklad, Michael P. Buric, Kevin P. Chen

Proceedings Volume 7677, Fiber Optic Sensors and Applications VII; 76770F (2010) https://doi.org/10.1117/12.851526
Event: SPIE Defense, Security, and Sensing, 2010, Orlando, Florida, United States

Abstract

Cryogenic fuels are often considered as major energy alternatives to coal and petroleum based fuels. Safe and reliable sensor networks are required for on-demand, real-time fuel management in cryogenic environments. In this paper, a new sensor design is described that enhances the low-temperature performance of fiber sensors. FBGs inscribed in high attenuation fiber (HAF) are used to absorb in-fiber power light to raise the local sensor temperature in the cryogenic environment. When in-fiber power light is turned off, FBG sensors can serve as passive sensors to gauge temperature and stress in the cryogenic system. When the in-fiber power light is turned on, the heated sensors can be used to rapidly gauge fuel level and fuel leaks. In one example, a hydrogen gas sensor is demonstrated with a palladium-coated fiber Bragg grating (FBG). The low-temperature performance of the sensor was improved by heating the gratings as much as 200 K above the ambient temperature, and hydrogen concentration well below the 4% explosion limit was measured at 123K. In a second example, an array of four aluminum coated fiber Bragg gratings was used to measure liquid level in a cryogenic environment.

Citation Download Citation

Tong Chen, Philip R. Swinehart, Mokhtar S. Maklad, Michael P. Buric, and Kevin P. Chen "Self-heated fiber Bragg grating sensors for cryogenic environments", Proc. SPIE 7677, Fiber Optic Sensors and Applications VII, 76770F (23 April 2010); https://doi.org/10.1117/12.851526

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