Optical Fibres in Nuclear Radiation Environments

Berghmans, Francis; Deparis, Olivier; Coenen, S.; Décreton, M.; Jucker, P.

doi:10.1007/978-94-011-0035-9_7

Cited by 5 publications

(2 citation statements)

References 54 publications

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“…al., 2005). Radiation hardness of OFS equaled earlier to a general dose of irradiation of about 1.2 MGy with γ-radiation and 2.6•10 16 neutrons/cm 2 with a neutron fluence (Berghmans F. & Decréton M., Ed.,1994) but now reaches doses of gamma radiation up to 23 MGy and neutron flux 52 •10 16 neutrons/cm 2 (Fiedler et. al., 2005).…”

Section: Ionizing Radiation Hardness Of Ofsmentioning

confidence: 99%

Radiation-Hard and Intelligent Optical Fiber Sensors for Nuclear Power Plants

Buymistriuc¹

2011

Nuclear Power - Control, Reliability and Human Factors

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Section: Ionizing Radiation Hardness Of Ofsmentioning

confidence: 99%

Radiation-Hard and Intelligent Optical Fiber Sensors for Nuclear Power Plants

Buymistriuc¹

2011

Nuclear Power - Control, Reliability and Human Factors

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“…7,8 Under normal operations, the gamma ray dose rates are estimated to be between 10 Ϫ5 and 1 Gy/h for possible fiber or fiber optic sensor applications in a nuclear power plant. If considering the plant lifetime to be 40 years, then fibers or fiber optic sensors should withstand these dose rates and a total dose up to 1 MGy over 40 years.…”

Section: Gamma Radiation Environmentsmentioning

confidence: 99%

Gamma radiation resistant Fabry–Perot fiber optic sensors

Liu

Miller

Talnagi³

2002

Review of Scientific Instruments

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Articles you may be interested inHigh-resolution fiber optic temperature sensors using nonlinear spectral curve fitting technique Rev. Sci. Instrum. 84, 045002 (2013);A frequency division multiplexed low-finesse fiber optic Fabry-Perot sensor system for strain and displacement measurements Rev.Optical fiber temperature sensor using a gain-switched Fabry-Perot semiconductor laser self-seeded from a linearly chirped fiber Bragg gratingThe Nuclear Regulatory Commission ͑NRC͒ in 1998 completed a study of emerging technologies that could be applicable to measurement systems in nuclear power plants ͓H. M. Hashemian et al., ''Advanced Instrumentation and Maintenance Technologies for Nuclear Power Plants,'' NUREG/ CR-5501 ͑1998͔͒. This study concluded that advanced fiber optic sensing technology is an emerging technology that should be investigated. It also indicated that there had been very little research related to performance evaluation of fiber optic sensors in nuclear plant harsh environments, although substantial research has been performed on nuclear radiation effects on optical fibers in the last two decades. A type of Fabry-Perot fiber optic temperature sensor, which is manufactured by Fiso Technologies in Canada, is qualified to be a candidate for potential applications in nuclear radiation environment due to its unique signal processing technique and its resistance to power loss. The gamma irradiation effects on this type of sensors are investigated in this article. Two sensors were irradiated in a gamma irradiation field and one of them was irradiated up to a total gamma dose of 133 Mrad. The sensor on-line performance was monitored during each gamma irradiation test. Furthermore, the sensor static and dynamic performance before and after each irradiation test were evaluated according to the Standard ISA-dS67.06.. Although several abnormal phenomena were observed, analysis shows that gamma irradiation is not accredited to the abnormal behavior, which implies that this type of sensor is suitable to a gamma irradiation environment with a high gamma dose.

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