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微纳光纤Fabry-Perot超低温压力传感器研究 被引量:3

Research on the Micro Optical Fiber Fabry-Perot Ultra-low Temperature Pressure Sensor
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摘要 提出了一种用于超低温环境的微纳光纤非本征法布里-珀罗干涉仪压力传感器。单模光纤端面通过飞秒激光刻蚀出微孔,与无芯光纤熔接形成密闭的法珀腔。通过将无芯光纤切割、研磨等步骤,制作出微纳光纤压力传感器。利用飞秒激光微加工,可以加工出不同孔径的微孔及不同厚度的膜片,得到不同灵敏度及测量压力范围的压力传感器。实验结果表明,提出的传感器在-196℃、0~5 MPa的压力范围内表现出良好的线性度,压力升高和降低过程中腔长-压力灵敏度分别为110.33 nm/MPa和110.68 nm/MPa。该传感器能够满足超低温环境下的压力测量需求。 Ultra-low temperature pressure sensors refer to the pressure sensor that can work normally in the temperature range of 4~110 K.Nowadays,liquid hydrogen and liquid oxygen are widely used as fuels in space vehicles,which puts forward requirements of pressure parameter measurement in ultra-low temperature environment.At present,electronical sensors have been reported to measure pressure in ultralow temperature environment.However,electrical sensors contain electromagnetic interference and potential safety hazards,making them unable to work in a harsh environment.Due to advantages of intrinsic safety,high sensitivity,immunity to electromagnetic interference,small volume,light weight,fiber optic sensors have been widely used in various fields of physical quantity measurement.The structure of the extrinsic Fabry-Perot interferometer is naturally suitable for pressure measurement.Optical fiber extrinsic Fabry-Perot interferometer pressure sensors are mainly divided into two types:diaphragm-based type and diaphragm-free type.Diaphragm-free fiber pressure sensors can be only used to measure gas pressure and the sensitivity is greatly affected by temperature.For the diaphragm-based type,to measure pressure in ultra-low temperature environment,a pressure sensor must have a robust structure at ultra-low temperature and the material of the diaphragm needs to be resistant to ultra-low temperature.Since no other materials are introduced,the all-silica diaphragm-based pressure sensor has advantages of high mechanical strength and small size.One method is selective etching of the fiber core to form a micro-hole.Compared with chemical etching method,fs laser micromachining is a safe method to fabricate the air cavity and the thin diaphragm due to high precision material processing capability.Optical fiber sensors have been used for temperature measurement at ultra-low temperature,which proves that pure quartz is resistant to ultra-low temperature.In this paper,for the measurement of pressure at ultra-low temperature,a micro optical fiber extrinsic Fabry-Perot interferometer sensor is proposed and experimentally demonstrated.The end face of a single mode fiber is inscribed by a femtosecond laser to form a micro-hole.Then the single mode fiber is spliced to a non-core fiber to form a sealed Fabry-Perot cavity.The micro optical fiber pressure sensor is fabricated by cleaving and grinding the non-core fiber.By femtosecond laser micromachining,micro-holes with different apertures and diaphragms with different thicknesses can be processed to obtain pressure sensors with different sensitivities and pressure measurement ranges.The test system is shown in the figure below.Experiment results show the sensor proposed in this paper exhibits good linearity within a pressure range from 0 to 5 MPa at-196℃,and the cavity length-pressure sensitivities during the process of pressure increasing and decreasing are 110.33 nm/MPa and 110.68 nm/MPa,respectively.The proposed sensor can meet the pressure measurement requirements in an ultra-low temperature environment.
作者 张雨彤 江毅(指导) 崔洋 冯新星 ZHANG Yutong;JIANG Yi;CUI Yang;FENG Xinxing(Key Laboratory of Photonic Information Technology,Ministry of Industry and Information Technology,School of Optics and Photonics,Beijing Institute of Technology,Beijing 100081,China;School of Physical Science and Technology,Baotou Teachers’College,Baotou,Inner Mongolia 014030,China)
出处 《光子学报》 EI CAS CSCD 北大核心 2022年第5期221-227,共7页 Acta Photonica Sinica
基金 国家自然科学基金(Nos.61775020,U20B2057)。
关键词 非本征法布里-珀罗干涉仪 光纤传感器 飞秒激光微加工 超低温 压力测量 Extrinsic Fabry-Perot interferometers Optical fiber sensors Femtosecond laser micromachining Ultra-low temperature Pressure measurement
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