769 research outputs found
Development and application of optical fibre strain and pressure sensors for in-flight measurements
Fibre optic based sensors are becoming increasingly viable as replacements for traditional
flight test sensors. Here we present laboratory, wind tunnel and flight test results of fibre
Bragg gratings (FBG) used to measure surface strain and an extrinsic fibre
Fabry–Perot
interferometric (EFFPI) sensor used to measure unsteady pressure. The calibrated full
scale resolution and bandwidth of the FBG and EFFPI sensors were shown to be 0.29% at
2.5 kHz up to 600 με and 0.15% at up to 10 kHz respectively up to 400 Pa. The wind tunnel
tests, completed on a 30% scale model, allowed the EFFPI sensor to be developed before
incorporation with the FBG system into a Bulldog aerobatic light aircraft. The aircraft was
modified and certified based on Certification Standards 23 (CS-23) and flight tested with
steady and dynamic manoeuvres. Aerobatic dynamic manoeuvres were performed in flight
including a spin over a g-range −1g to +4g and demonstrated both the FBG and the EFFPI
instruments to have sufficient resolution to analyse the wing strain and fuselage unsteady
pressure characteristics. The steady manoeuvres from the EFFPI sensor matched the wind
tunnel data to within experimental error while comparisons of the flight test and wind tunnel
EFFPI results with a Kulite pressure sensor showed significant discrepancies between the two
sets of data, greater than experimental error. This issue is discussed further in the paper
NOVEL SENSOR PLATFORMS BASED ON FABRY-PEROT RESONATORS FOR APPLICATIONS IN ENVIRONMENTAL GEOPHYSICS
Fabry-Perot resonator sensors have been widely used for various physical and chemical measurements owing to their unique advantages over traditional sensors such as high measurement resolution, mechanically robust, and distributed sensing capabilities. This dissertation focuses on the development of robust fiber optic microwave sensors based on Fabry-Perot resonator mechanism for real-time applications in environmental geophysics.
Firstly, a novel Extrinsic Fabry-Perot Interferometer (EFPI)-based fiber-optic sensor for force measurement using a pre-buckled beam was demonstrated. The axial displacement is transferred and amplified to a horizontal deflection at the middle of the buckled beam, leading to a relatively significant change in the Fabry-Perot cavity length. The force measurement range and the size of the sensor can be easily reconfigured by adjusting the size of the beam, enabling force measurement for different scenarios. Secondly, a self-compensated inclinometer with a wide dynamic range and high measurement resolution based on two hollow coaxial cable Fabry-Perot resonators (HCC-FPRs) was reported. By tracking the shift of the resonance wavelength of the HCC-FPR, two HCC-FPRs are used in the inclinometer design, which enables the inclinometer to achieve self-compensation for variations in environmental factors. Thirdly, a Polyvinyl Alcohol (PVA) film-assisted open-ended hollow coaxial cable Fabry-Perot resonator was proposed for highly sensitive embeddable soil moisture measurements. The invented sensor platform could be reconfigured to detect chemical contaminants in soil by changing the functional films in the active zone of the sensor --Abstract, p. i
Sensores de fibra ótica para meios desafiantes
With the present work, the development of fiber optic sensor solutions for the
application in challenging media was intended. New sensor structures based
on the post-processing of optical fibers were addressed, taking into account
their sensitivity to variations in the external environment.
In a first stage, fiber Bragg gratings were embedded in lithium batteries, to
monitor temperature in situ and operando. Due to the harsh chemical
environment of the battery, fiber optic sensors revealed to be the most
advantageous alternative, when comparing to the electronic sensors. Fiber
sensors exhibited good sensitivities and fast responses, besides being less
invasive, thus they did not compromise the battery response. Furthermore, they
were chemically stable.
Still in the framework of this theme, and with the objective of monitoring
possible strain and pressure variations inside the batteries, new sensors based
on in-line Fabry-Perot cavities have been proposed. These sensors were
characterized in lateral load, strain, and temperature.
In a later stage, the study focused on the development of configurations that
allowed to obtain high-resolution and/or sensitivity sensors. One of such
configurations was obtained by creating a hollow microsphere at the fiber tip.
The sensor was used to detected concentration variations and refractive index
of glycerin and water mixtures. The influence of the diaphragm size in the
sensor response was also studied, as well as the temperature response.
New sensors based on multimode interference have also been characterized,
using a coreless silica fiber tip. First, the influence of different parameters, such
as length and diameters were analyzed. The sensors were tested in different
solutions of glucose and water. It was observed that the sensor diameter is a
decisive factor in obtaining devices that are more sensitive to refractive index
and, consequently, to concentration.
The determination of the thermo-optic coefficient of water/ethanol mixtures was
also addressed using a multimode fiber interferometer sensor.
Finally, a multimode interferometer sensor was functionalized by depositing
agarose throughout the structure, allowing to optimize the response of the
sensors to the external environment.Com o presente trabalho pretendeu-se explorar soluções de sensores em fibra
ótica para a aplicação em meios desafiantes. Novas estruturas sensoras
baseadas em pós-processamento de fibra ótica foram abordadas, tendo em
consideração a sua sensibilidade a variações do meio externo.
Numa primeira etapa, foram embebidas redes de Bragg no interior de baterias
de lítio, para monitorizar variações de temperatura in situ e operando. Devido
ao complexo meio químico da bateria, os sensores em fibra ótica revelaram
ser uma alternativa mais vantajosa em relação aos sensores elétricos, não só
pela sensibilidade e rápida resposta, mas também pelo fato de não afetarem o
desempenho da bateria. Além disso, os sensores usados revelaram ser pouco
invasivos e quimicamente estáveis.
Ainda no âmbito deste tema, e com o objetivo de monitorizar possíveis
deformações e variações de pressão no interior da bateria de lítio, foram
desenvolvidos novos sensores baseados em cavidades de Fabry-Perot do tipo
in-line. Esses sensores foram caraterizados em pressão lateral, deformação e
temperatura.
Numa fase posterior, o estudo centrou-se no desenvolvimento de
configurações que permitissem a obtenção de sensores com elevada
resolução e/ou sensibilidade. Uma das configurações consistiu na formação de
uma microesfera oca na ponta de uma fibra ótica. Esse sensor foi utilizado
para detetar variações de concentração e índice de refração de misturas de
glicerina e água. A influência do tamanho do diafragma na resposta do sensor
também foi estudada, assim como a resposta em temperatura.
Em seguida, desenvolveram-se novos sensores baseados em interferência
multimodo, utilizando para tal uma ponta de fibra de sílica sem núcleo. Numa
primeira abordagem analisou-se a influência de diferentes parâmetros, como o
comprimento e o diâmetro dos sensores. Os sensores foram expostos a
diferentes soluções de glucose e água. Verificou-se que o diâmetro do sensor
é um fator decisivo para a obtenção de dispositivos mais sensíveis ao índice
de refração e, consequentemente, à concentração.
Foi também desenvolvido um sensor baseado em interferência multimodo que
permitiu determinar o coeficiente termo-ótico de misturas de etanol e água.
Por fim, procedeu-se à funcionalização de um sensor baseado em interferência
multimodo através da deposição de agarose ao longo da estrutura, permitindo
assim otimizar a sua resposta a variações do meio externo.Programa Doutoral em Engenharia Físic
Optical Current Sensors for High Power Systems: A Review
The intrinsic advantages of optical sensor technology are very appealing for high voltage applications and can become a valuable asset in a new generation of smart grids. In this paper the authors present a review of optical sensors technologies for electrical current metering in high voltage applications. A brief historical overview is given together with a more detailed focus on recent developments. Technologies addressed include all fiber sensors, bulk magneto-optical sensors, piezoelectric transducers, magnetic force sensors and hybrid sensors. The physical principles and main advantages and disadvantages are discussed. Configurations and strategies to overcome common problems, such as interference from external currents and magnetic fields induced linear birefringence and others are discussed. The state-of-the-art is presented including commercial available systems.info:eu-repo/semantics/publishedVersio
Coaxial Cable Sensors Based on Fabry-Perot Interferometers and Their Applications in Distributed Sensing
Aging civic infrastructures in the world has put tremendous pressure in their maintenances because potential failure of the large size civil structures will be catastrophic. Structure health monitoring (SHM) has been proven effective to prevent these failures, and distributed sensing technologies are preferred in SHM as they are effective to provide comprehensive evaluation of the structures. Fiber optic sensors are well developed in the past two decades for distributed sensing, but the lack of robustness and the limited deformability of silica make them not suitable for heavy duty and large deformation applications, which is very common in SHM. To address the above limitation of optical fiber sensors, we change the sensing platform from optical fibers to coaxial cable. Inspired by optical FPI, we created two reflectors on a coaxial cable to form a coaxial cable Fabry-Perot interferometer (CCFPI). The reflectors are commonly made by drilling half way holes or crimp on the cable, which introduce impedance discontinuity and hence partial reflection of EM wave in the cable. The two reflectors can produce interference patterns with multiple resonant frequencies which can be tracked to indicate changes in physical parameters such as temperature and strain. To realize distributed sensing, multiple reflectors are implemented along a coaxial cable, where every two consecutive reflectors will form a low finesse CCFPI. A specific signal process technique is used to reconstruct each individual CCFPI interferogram from the complex frequency domain signal. As examples of the distributed sensing capability of the coaxial cable platform, distributed torsion sensing and 3D beam shape estimation system are demonstrated in this thesis. By modifying the cable material and structure, we can achieve other special function for CC-FPI sensors. By fabricating the cable with ceramics as dielectric material and implanting built in reflectors, a high temperature CC-FPI sensor is developed and tested. Another example is a magnetic field sensor made by filling a cavity in a semi-rigid cable with ferrofluid. When external magnetic field change, the property of the ferrofluid will also change, resulting in spectrum shift of the FPI. The coaxial cable FPI sensors have many potentials to measure different physical parameters in distributed sensing form, which makes it a very good sensing platform for long distance and distributed sensing in harsh environment and heavy duty applications
Magnetic Field Sensor Based on a Tri-Microfiber Coupler Ring in Magnetic Fluid and a Fiber Bragg Grating
In this paper we propose and investigate a novel magnetic field sensor based on a Tri-microfiber coupler combined with magnetic fluid and a fiber Bragg grating (FBG) in a ring. A sensitivity of 1306 pm/mT was experimentally demonstrated in the range of magnetic fields from 0 to 15 mT. The reflection peak in the output spectrum associated with the FBG serves as a reference point allowing to avoid ambiguity in determining the spectral shift induced by the magnetic field. Due to its high sensitivity at low magnetic fields, the proposed structure could be of high interest in low field biosensing applications that involve a magnetic field, such as magnetic manipulation or separation of biomolecules
Optical fibre-based sensors for oil and gas applications.
Oil and gas (O&G) explorations moving into deeper zones for enhanced oil and gas recovery are causing serious safety concerns across the world. The sensing of critical multiple parameters like high pressure, high temperature (HPHT), chemicals, etc., are required at longer distances in real-time. Traditional electrical sensors operate less effectively under these extreme environmental conditions and are susceptible to electromagnetic interference (EMI). Hence, there is a growing demand for improved sensors with enhanced measurement capabilities and also sensors that generates reliable data for enhanced oil and gas production. In addition to enhanced oil and gas recovery, the sensing technology should also be capable of monitoring the well bore integrity and safety. The sensing requirements of the O&G industry for improved sensing in deeper zones include increased transmission length, improved spatial coverage and integration of multiple sensors with multimodal sensing capability. This imposes problems like signal attenuation, crosstalks and cross sensitivities. Optical fibre-based sensors are expected to provide superior sensing capabilities compared to electrical sensors. This review paper covers a detailed review of different fibre-optic sensing technologies to identify a feasible sensing solution for the O&G industry
Advances in Fiber-Optic Extrinsic Fabry-Perot Interferometric Physical and Mechanical Sensors: A Review
Fabry-Perot Interferometers Have Found a Multitude of Scientific and Industrial Applications Ranging from Gravitational Wave Detection, High-Resolution Spectroscopy, and Optical Filters to Quantum Optomechanics. Integrated with Optical Fiber Waveguide Technology, the Fiber-Optic Fabry-Perot Interferometers Have Emerged as a Unique Candidate for High-Sensitivity Sensing and Have Undergone Tremendous Growth and Advancement in the Past Two Decades with their Successful Applications in an Expansive Range of Fields. the Extrinsic Cavity-Based Devices, I.e., the Fiber-Optic Extrinsic Fabry-Perot Interferometers (EFPIs), Enable Great Flexibility in the Design of the Sensitive Fabry-Perot Cavity Combined with State-Of-The-Art Micromachining and Conventional Mechanical Fabrication, Leading to the Development of a Diverse Array of EFPI Sensors Targeting at Different Physical Quantities. Here, We Summarize the Recent Progress of Fiber-Optic EFPI Sensors, Providing an overview of Different Physical and Mechanical Sensors based on the Fabry-Perot Interferometer Principle, with a Special Focus on Displacement-Related Quantities, Such as Strain, Force, Tilt, Vibration and Acceleration, Pressure, and Acoustic. the Working Principle and Signal Demodulation Methods Are Shown in Brief. Perspectives on Further Advancement of EFPI Sensing Technologies Are Also Discussed
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