WO2021123968A1 - Système de fibre optique - Google Patents

Système de fibre optique Download PDF

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Publication number
WO2021123968A1
WO2021123968A1 PCT/IB2020/060984 IB2020060984W WO2021123968A1 WO 2021123968 A1 WO2021123968 A1 WO 2021123968A1 IB 2020060984 W IB2020060984 W IB 2020060984W WO 2021123968 A1 WO2021123968 A1 WO 2021123968A1
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Prior art keywords
segment
mmf
fiber optic
optical fiber
multimode
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PCT/IB2020/060984
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English (en)
Spanish (es)
Inventor
Victor Hugo Aristizábal Tique
Jorge Alberto GÓMEZ LÓPEZ
Jairo Camilo QUIJANO PÉREZ
Francisco Javier VÉLEZ HOYOS
Original Assignee
Politécnico Colombiano Jaime Isaza Cadavid
Universidad Cooperativa De Colombia
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Application filed by Politécnico Colombiano Jaime Isaza Cadavid, Universidad Cooperativa De Colombia filed Critical Politécnico Colombiano Jaime Isaza Cadavid
Publication of WO2021123968A1 publication Critical patent/WO2021123968A1/fr

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01DMEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
    • G01D5/00Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
    • G01D5/26Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01DMEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
    • G01D5/00Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable
    • G01D5/26Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light
    • G01D5/32Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light
    • G01D5/34Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light the beams of light being detected by photocells
    • G01D5/353Mechanical means for transferring the output of a sensing member; Means for converting the output of a sensing member to another variable where the form or nature of the sensing member does not constrain the means for converting; Transducers not specially adapted for a specific variable characterised by optical transfer means, i.e. using infrared, visible, or ultraviolet light with attenuation or whole or partial obturation of beams of light the beams of light being detected by photocells influencing the transmission properties of an optical fibre
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01HMEASUREMENT OF MECHANICAL VIBRATIONS OR ULTRASONIC, SONIC OR INFRASONIC WAVES
    • G01H9/00Measuring mechanical vibrations or ultrasonic, sonic or infrasonic waves by using radiation-sensitive means, e.g. optical means
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01LMEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
    • G01L1/00Measuring force or stress, in general
    • G01L1/24Measuring force or stress, in general by measuring variations of optical properties of material when it is stressed, e.g. by photoelastic stress analysis using infrared, visible light, ultraviolet
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B6/00Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
    • GPHYSICS
    • G02OPTICS
    • G02BOPTICAL ELEMENTS, SYSTEMS OR APPARATUS
    • G02B6/00Light guides; Structural details of arrangements comprising light guides and other optical elements, e.g. couplings
    • G02B6/24Coupling light guides
    • G02B6/26Optical coupling means

Definitions

  • the present invention relates to fiber optic structures related to fiber optic sensors, fiber optic modulators, but is not limited to these applications and uses.
  • optical fibers and fiber optic structures have received a lot of interest, for example, as sensors for a large number of mechanical, electrical and chemical parameters, among others. This has led to the development of many new types of fiber and applications for use as fiber optic sensors.
  • fiber optic sensors are disclosed, such as those disclosed by documents US6144790 A, US4843233 A or the article “Specklegram in a grapefruit fiber and its response to external mechanical disturbance in a single-multiple-single mode fiber structure ”available online at https://www.ncbi.nlm.nih.gov/pubrned/180r7969 ⁇
  • Document US6144790 A discloses a fiber optic sensor comprising an optical source useful for detecting impact, vibration, temperature, pressure or other forces.
  • the sensor comprises an optical fiber with one terminal connected to a light source and with the other terminal connected to a detector.
  • the sensor has a measuring section, a particular embodiment of the invention comprises a light generated by an optical source that propagates through an optical fiber system such that a portion of the optical fiber is sensitive to external forces or disturbances that They affect the intensity of the light that propagates through the fiber optic system and the intensity of the light is received by a detector.
  • US6144790 A discloses that the speckle pattern changes according to disturbances of the sense fiber. Under the influence of an applied field, be it thermal, direct force or pressure, or other physical origin, the entire sensitive fiber, or parts thereof, or just a section of sensitive fiber, may undergo a deformation of an axial symmetry.
  • Document US6144790 A discloses that it solves a sensitivity problem of fiber optic sensors used to measure variables such as pressure and force in which long lengths of sensitive fiber coupled to mechanical devices are required, the solution is made using a single-mode optical fiber that maintains polarization.
  • the senor disclosed in document US6144790 A is not manufactured taking into account parameters of the fiber core diameter in relation to a speckle pattern, therefore, the sensor does not take into account physical alterations on the fiber segment that allow metrological parameters of the sensor to be varied, such as the sensitivity, dynamic range and operating threshold of the sensor, so the sensor's operation is limited to static values of said metrological parameters and its sensitivity is limited.
  • the article "Specklegram in a grapefruit fiber and its response to external mechanical disturbance in a single -multiple -single mode fiber structrance" discloses a fiber sensor to measure mechanical disturbances in a structure SMS (for the acronym in English of Single Mode Fiber - Multi Mode Fiber - Single Mode Fiber) of fiber optic, which has an optical fiber MMF (Multi-Mode Optical Fiber) of stepped index from which is spliced an SMF fiber (for the acronym in English of Single -Mode Optical Fiber) at each of its ends that correspond to an input fiber and an output fiber, an irradiator (Faser He-Ne) connected to the other end of the input fiber and a photodetector connected to the other end of the output fiber.
  • SMS for the acronym in English of Single Mode Fiber - Multi Mode Fiber - Single Mode Fiber
  • MMF Multi-Mode Optical Fiber
  • SMF fiber for the acronym in English of Single -Mode Optical Fiber
  • the sensitivity of the sensor could be improved by optimizing the diameter of the core of the output fiber by making it coincide with the size of the optical speckle pattern, since it functions as an aperture through which part of the fiber is captured. optical speckled pattern.
  • it does not disclose information on a relationship of the parameters of the fibers that allow varying the sensitivity, dynamic range and operating threshold of the sensor.
  • the present invention refers to an optical fiber structure, which comprises a first segment of Optical Fiber (2) with two ends; a second segment of MMF Multimode Fiber Optic (3) with two ends; where one end of the second segment Multimode Fiber Optic MMF (3) is connected to one of the ends of the first Fiber Optic segment (2); wherein said second segment has a disturbance region (8) in the cladding (3a) of the MMF Multimode Optical Fiber (3); and where the disturbance region (8) of the MMF Multimode Fiber Optic segment (3) is exposed to a physical or chemical disturbance.
  • one of the ends of the first Optical Fiber segment (2) is connected to a photodetector (5) and at one end of the second MMF Multimode Optical Fiber segment (3) a coherent light emitter is connected (1).
  • one end of the first Fiber Optic segment (2) is connected to the second port of a three-port optical circulator (10); a coherent light emitter (1) is connected to the first port of the optical circulator (10); a photodetector (5) is connected to the third port of the optical circulator (10); and a reflective film (9) is arranged at the end of the second MMF Multimode Fiber Optic segment (3), which is not connected to the first Optical Fiber segment (2).
  • the first Optical Fiber segment (2) is Single-mode (SMF).
  • the second segment of MMF Multimode Fiber Optic (3) there is a perturbation region (8) that is obtained by means of different methods as will be explained in detail later.
  • a perturbation region (8) that is obtained by means of different methods as will be explained in detail later.
  • the coating (3a) can generate the disturbance region (8) by wearing away a part of the coating (3a).
  • Another way of generating the region of disturbance (8) is by means of a narrowing (also known as tapering technique) by fusion and stretching of a part or all of the cladding (3a) of the second segment of MMF Multimode Optical Fiber.
  • the region of disturbance (8) must not necessarily consist of the modification of the cladding (3a) of the second segment of MMF Multimode Optical Fiber (3) (cladding), but that it may simply correspond to the exposure to a physical disturbance or chemistry directly from a zone or area of a part of the cladding (3a) of the second segment of MMF Multimode Optical Fiber (3).
  • FIG. 1 illustrates a longitudinal section of the fiber optic structure of an embodiment of the invention.
  • FIG. 2 illustrates a longitudinal section of an embodiment of the fiber optic structure of the invention to which a reflective film (9) is added.
  • FIG. 3 illustrates a longitudinal section of an embodiment of the invention, the optical fiber structure of the invention to which is added a reflective film (9) and an encapsulation (7) with an opening (A) of length L.
  • FIG. 3A illustrates a reflective modality that implements the fiber optic structure of the invention to which is added a reflective film and an encapsulation (7) with an aperture (A) of length L.
  • FIG. 4 illustrates a longitudinal section of the fiber optic structure of the invention indicating the contact plane (B-B) between a first segment of Optical Fiber (2) and a second segment of MMF Multimode Optical Fiber (3).
  • FIG. 4A illustrates a modality that implements the fiber optic structure of the invention where a photodetector (5) is connected at one of the ends of the first Optical Fiber segment (2) and where at the end of the second MMF Multimode Fiber Optic segment ( 3) is connected to a coherent light emitter (1).
  • FIG. 4B illustrates an example of a grain (11) of a Speckle Pattern (12) also called an optical speckled pattern that is observed in a front view of the contact plane (BB) between the first Optical Fiber segment (2) and the second MMF Multimode Fiber Optic segment (3).
  • FIG. 5 illustrates a cross section of the fiber optic structure of the invention indicating the contact plane (BB) between a first segment of Optical Fiber (2) and a second segment of MMF Multimode Optical Fiber (3) where the second segment of Fiber MMF Multimode Optics (3) is covered with an encapsulation (7) with an opening (A) forming a disturbance region (8).
  • FIG. 5A illustrates an embodiment that implements the fiber optic structure of the invention where the second segment of MMF Multimode Optical Fiber (3) is covered with an encapsulation (7) with an opening (A) forming a region of disturbance (8).
  • FIG. 5B illustrates an isometric section of the fiber optic structure of the invention indicating the contact plane (BB) between a first segment of Optical Fiber (2) and a second segment of MMF Multimode Optical Fiber (3) where the second segment of MMF Multimode Optical Fiber (3) is covered with an encapsulation (7) with an opening (A) forming a disturbance region (8).
  • FIG. 6 illustrates a cross section of the fiber optic structure of the invention where the region of disturbance is formed by melting and stretching tapering of part or all of the second fiber optic segment.
  • FIG. 7A illustrates a cross section of the second segment of MMF Multimode Optical Fiber (3), where the region of disturbance (8) obtained by coating with an encapsulation (7) with an opening (A).
  • FIG. 7B illustrates a cross section of the second segment of MMF Multimode Optical Fiber (3), with a region of disturbance (8) formed by wear, which is obtained by wear of a part of the cladding (3a) (cladding) and the cladding an encapsulation (7) with an opening (A).
  • FIG. 7C illustrates a cross section of the second segment of MMF Multimode Optical Fiber (3) with a region of disturbance (8), which is obtained by wear of a part of the cladding (3a) (cladding).
  • FIG. 8 illustrates an example of voltage versus temperature response of a particular application of the invention implemented as a temperature sensor and with a 3 centimeter MMF fiber disturbance length.
  • FIG. 9 illustrates an example of voltage versus temperature response of a particular application of the invention used as a temperature sensor and with MMF fiber disturbance length of 4.5 centimeters.
  • FIG. 10 illustrates an example of voltage versus temperature response of a particular application of the invention used as a temperature sensor and with MMF fiber disturbance length of 8 centimeters.
  • FIG. 11 illustrates an example of voltage versus temperature response of a particular application of the invention used as a temperature sensor and with MMF fiber disturbance length of 12 centimeters.
  • the present invention corresponds to an optical fiber structure, comprising:
  • the disturbance region (8) of the MMF Multimode Fiber Optic segment (3) corresponds to an area of the second MMF Multimode Fiber Optic segment (3) which is exposed to a physical disturbance or chemistry.
  • all optical fiber segments have a core and a cladding (3a), which is also called cladding.
  • Fas physical disturbances can be mechanical disturbances such as forces, pressures, temperature, among others, and chemical disturbances are considered any material or chemical substance that interacts with the disturbance region (8) in the coating (3a) of the second segment of MMF Multimode Fiber Optic (3).
  • the first segment of Optical Fiber (2) has a core (2b) and a cladding (2a) and the second segment of MMF Multimode Optical Fiber (3), has a core (3b) and a cladding (3a).
  • the first segment of Optical Fiber (2) and second segment of MMF Multimode Optical Fiber (3) are connected for example by mechanical splices that for example is selected from the group formed by FC (for the acronym in English of Ferrule Connector), PC ( Physical Contact), APC UPC (Ultra Physical Contact), ST (Straight Tip), SC (Standard Connector), FC ( Lucent Connector), SMA (Sub Miniature A), MU (Miniature Unit), MTRJ (Mechanical Transfer-Registered Jack), MPO ( Multi-fiber Push-on), E2000 and combinations thereof or by means of splices that are selected for example from the group consisting of fusion splicing, mechanical splices such as splints with different polishes such as PC (for the acronym in English for Physical Contact), UPC n English for Ultra Physical Contact), APC (for the acronym in English of Angled Physical Contact).
  • FC for the acronym in English of Ferrule Connector
  • PC Physical Contact
  • APC UPC User Physical Contact
  • FIG. 4 and FIG. 4A shows an embodiment of the invention in which there is a first Optical Fiber segment (2) with two ends; a second segment of MMF Multimode Optical Fiber (3) with two ends, in which a disturbance region (8) is generated in the cladding (3a) of the Multimode Optical Fiber MMF (3).
  • the disturbance region (8) can be generated in different ways in such a way as to facilitate the exposure of the MMF fiber (3) to physical or chemical disturbances.
  • the first end of the MMF Multimode Optical Fiber (3) is connected to one of the ends of the first Optical Fiber segment (2), where the first Optical Fiber segment (2) connects a photodetector (5) and where at the end of the second MMF Multimode Fiber Optic segment (3) a coherent light emitter (1) is connected.
  • the second segment of MMF Multimode Fiber Optic (3) is connected to a coherent light emitter (1), such as a laser source, so that when the light propagates through the second segment of MMF Multimode Fiber Optic (3) it is generates a modal interference pattern, in this case a Speckle Pattern (12) in the contact plane (B-B), which is the contact plane where the first Fiber Optic segment (2) and the second segment are connected Multimode Fiber Optic MMF (3).
  • Speckle Pattern (12) also called optical speckle pattern
  • the first Fiber Optic segment (2) generates a Speckle Pattern (12) in the contact plane (B-B).
  • the first segment of Optical Fiber (2) functions as a modal filter, where it takes part of the modes or the intensity of the coherent light that propagates through the Optical Fiber (2), which is in the plane where the grain (11) of the Speckle Pattern (12) is formed and is taken to a photodetector (5) which will respond to the power of the Speckle Pattern (12).
  • a modal filter will be understood as that system or device that is capable of taking at least one mode or a group of modes that come from an optical fiber, capturing a part of the power of the Speckle Pattern (12).
  • the value of the metrological parameters of the fiber optic structure By changing the size of the area of the disturbance region (8), for example defined by the segment (L) along the axis of the second segment of MMF Multimode Optical Fiber (3), the value of the metrological parameters of the fiber optic structure. These metrological parameters are for example the sensitivity, the dynamic range or operating range and the detection threshold.
  • sensitivity will be understood as the level of variation of the output variable of the fiber optic structure, in this case measured as the voltage, before changes in the variable to be measured, for example, temperature; that is, in how many millivolts the output signal changes for every 0 C that the temperature of the system to be measured varies.
  • the detection threshold is understood to be the minimum value of the variable to be measured from which the optical fiber structure begins to show variations above the noise level of its output signal.
  • dynamic range also called operating range
  • This response may or may not be linear.
  • Each of these metrological parameters are affected by the region of disturbance (8), which in one embodiment of the invention is determined by the width of the aperture (A) and the length (L) of the region.
  • the perturbation region (8) has an area less than or equal to the area of the cladding (3a) of the second segment of the MMF Multimode Optical Fiber (3).
  • the region of disturbance (8) can be obtained in different ways, for example by referring to FIGS. 5, FIG. 5B and FIG, 7A in a particular example the perturbation region (8) can be obtained by coating with an encapsulation (7) with an opening (A) of the second segment of MMF Multimode Optical Fiber (3), said opening A can have various shapes for example circular shapes, regular or irregular shapes, or for example referring to FIG. 5B, the perturbation region (8) has a rectangular shape defined by the segment L along the axis of the fiber and a thickness A, which can be, for example, of the order of one to two millimeters of thickness A and length L it can for example reach up to 15 cm. In embodiments of the invention, the length L is in the range of 1 cm to 15 cm.
  • the MMF Multimode Optical Fiber (3) has a length less than or equal to 15 cm.
  • the encapsulation coating (7) with an opening (A) isolates the coating (3a) of the MMF Multimode Optical Fiber segment (3) from a physical or chemical disturbance and allows only the MMF Multimode Optical Fiber segment (3) to be disturbed exposed at opening (A).
  • the encapsulated coating (7) can be made with different materials such as plastics, epoxy resin, polyuria, ceramic, glass, among other materials.
  • the coating of the encapsulation (7) has among other functions, that of isolating the cladding (3a) (cladding) of the MMF Multimode Optical Fiber (3) from physical or chemical disturbances of the coated part of the second segment of MMF Multimode Optical Fiber ( 3).
  • the encapsulation (7) with an opening (A) functions as a thermal insulator allowing only the area exposed by the opening to be thermally disturbed ( TO).
  • the region of disturbance (8) can be obtained by coating with an encapsulation (7) around the coating (3a), where said encapsulation (7) has an opening (A).
  • Said opening can be covered with a material that allows, among other effects, to change the refractive index of the region of disturbance (8).
  • materials are polyvinyl alcohol; tetraethyl orthosilicate doped porous silica matrix membranes; Eriochromocyanin R, among other materials.
  • the materials lining the aperture (A) can also be magnetostrictive, or piezoelectric so that a magnetic or electrical disturbance becomes a mechanical disturbance in the disturbance region (8).
  • the disturbance region (8) can be obtained by wear of a part of the cladding (3a) (cladding) of the second segment of MMF Multimode Optical Fiber (3), covering it with an encapsulation (7).
  • the region of disturbance (8) can be obtained by wear of a part of the cladding (3a) (cladding) of the second segment of MMF Multimode Optical Fiber (3).
  • the region of disturbance (8) is obtained as the area of exposure to a physical or chemical disturbance directly from an area of the cladding (3a) (cladding) of the second segment of MMF Multimode Optical Fiber
  • the perturbation region (8) is formed by a narrowing (tapering) by fusion and stretching of a part or all of the second segment of MMF Multimode Optical Fiber (3).
  • Fa region of disturbance (8) can generate an evanescent field and the change in the Speckle Pattern (12) can be related to said evanescent field, which occurs at the external border of the region of disturbance (8) in the coating. (3a).
  • the material that is around the worn fiber produces a modification of the Speckle Pattern (12) that will be registered by the first Optical Fiber segment (2) and that corresponds to a change in the optical power that reaches the photodetector ( 5) and on the photodetector output voltage.
  • the intensity of the change in power will depend on how strong the change is in the optical properties associated with the presence of the external environment.
  • the fiber optic structure comprises: a first segment of Optical Fiber (2), with two ends, a second segment of MMF Multimode Optical Fiber (3), with a disturbance region (8) in the cladding (3a), and with two ends, one end of the second MMF Multimode Fiber Optic segment (3) is connected to one of the ends of the first Optical Fiber segment (2) and where a reflective film (9) is added that is arranged in the second extreme, of the second segment of MMF Multimode Fiber Optic (3) said reflective film (9) is a reflective element such as a mirror, first surface, a polished surface such as a fine polishing type PC (for its acronym in English Phisical contact): where the level of return is around -40dB, UPC also called UltraPC Polishing , where the pickup level is further reduced than the PC by around -55dB.
  • a reflective film (9) is a reflective element such as a mirror, first surface, a polished surface such as a fine polishing type PC (for its acronym in English Phisical contact): where the level of return
  • APC APC Angled Physical Contact: where the reflection is reduced to around -70dB or a shiny layer, such as silver deposited by sputtering (sputtering) or dip-coating (dip coating) ) deposited on the end of the second segment of MMF Multimode Optical Fiber (3).
  • the fiber optic structure and the reflective film (9) and referring to FIG. 3A a second embodiment of the invention is made where the first segment of Optical Fiber (2) at its end is connected to the second port of the optical circulator (10); a coherent light emitter (1) is connected to the first port of the optical circulator (10); a photodetector (5) is connected to the third port of the optical circulator (10).
  • the reflective film (9) is not in contact with the second segment of MMF Multimode Optical Fiber (3) but is approached by means of an optical line of sight of the light that leaves the second segment of MMF Multimode Fiber Optic (3) and returns the light to the same second segment of MMF Multimode Fiber Optic (3) through reflection.
  • the fiber optic structure comprising: a first segment of Optical Fiber (2), with two ends, a second segment of MMF Multimode Optical Fiber (3), with a disturbance region (8) in the cladding (3a) , and with two ends, in which the first end is connected to the second end of the first Optical Fiber segment (2); and where a reflective film (9) arranged at the second end of the second segment of MMF Multimode Optical Fiber (3) is added, said reflective film (9) is a reflective element such as a mirror, a polished surface or a glossy layer deposited on the end of the second segment of MMF Multimode Optical Fiber (3) and the perturbation region (8) can be obtained by coating with an encapsulation (7) with an opening (A) of the second MMF Multimode Optical Fiber segment ( 3), and an embodiment of the invention is made where one end of the first Fiber segment Optics (2) is connected to the second port of the optical circulator (10); a coherent light emitter (1) is connected to the first port of the optical circul
  • the second embodiment of the invention works by reflection, where the light from the coherent light emitter (1) enters through the second MMF Multimode Fiber Optic segment (3), propagating through the second MMF Multimode Optical Fiber segment (3), and then a reflection is generated in the reflective film (9). The reflected light is returned and re-enters again through the contact plane (BB), where the Speckle Pattern (12) is generated between the first Optical Fiber segment (2) and the second MMF Multimode Fiber Optic segment ( 3), which reaches the photodetector (5) through an optical circulator (10). The first Fiber Optic segment (2) takes part of the power from the Speckle Pattern (12) formed in the contact plane (B-B).
  • the power capture of the Speckle Pattern (12) formed in the contact plane (BB) is associated with the diameter of the core (2b) of the first Optical Fiber segment (2) and of the core (3b ) of the second MMF Multimode Fiber Optic segment (3).
  • the light that comes from the second MMF Multimode Fiber Optic segment (3) will be coupled to a greater or lesser extent in the first Fiber Optic segment (2) depending on the dimensions of the first Fiber Optic segment (2) and the second segment of MMF Multimode Fiber Optic (3).
  • each grain (11) of the Speckle Pattern (12) carries an amount of optical power. If the size of the core (2b) of the first Fiber Optic segment (2) is very similar to the average grain size (11) of the Speckle Pattern (12), it is equivalent to capturing the power of the grain (11) of the Speckle Pattern Speckle (12) and bring said power to the photodetector (5).
  • the grains (11) of the Pattern of Speckle (12), also called spots have a statistical size and correspond to a statistical distribution, with an average grain size (11) of the Speckle Pattern (12).
  • the first Fiber Optic segment (2) functions as a power filter, so that as the size of the core (2b) of the first Fiber Optic segment (2) changes compared to the average grain size (11 ) of the Speckle Pattern (12) the following situations may occur:
  • the diameter of the core (2b) of the first Optical Fiber segment (2) is very small compared to the statistical average grain size (11) of the Speckle Pattern (12), in this case if disturbances occur on the Speckle Pattern , the first Fiber Optic segment (2), when behaving as a power filter, it would not adequately capture the power of the Speckle Pattern disturbances (12).
  • the optical power of many grains (11) of the Speckle Pattern (12) would pass through the first segment of Optical Fiber (2), for example, in proportion 5 or 6 times the order of magnitude of the size of the grain (11), so that when there is a disturbance of the Speckle Pattern (12), the photodetector (5) would not adequately capture the changes in power associated with the Speckle Pattern disturbances (12).
  • the first Optical Fiber segment (2) has a core diameter (2b) approximately equal to the statistical average grain size (11) of the Speckle Pattern (12), then when there is a disturbance on that Speckle Pattern (12) the power of one of the grains (11) of the Speckle Pattern (12) passes through the first Optical Fiber segment (2) as well as the power of the Speckle Pattern (12) disturbances that will be recorded by the photodetector (5).
  • the second segment of MMF Multimode Fiber Optic (3) is irradiated by its second end with light from the coherent light emitter (1), comply with the following condition: 0.5 1.8 where L
  • (D s ) - -jy: is the average grain size (11) of the Speckle Pattern (12); d. is the diameter of the core (2b) of the first Optical Fiber segment (2); AN: the numerical aperture of the second MMF fiber optic segment (3); yl: the wavelength of the coherent light source (1).
  • the ratio of: the core diameters (2b) of the first Fiber Optic segment (2), the numerical aperture (3b) of the second MMF Multimode Fiber Optic segment (3); and the wavelength of the coherent light source (1), the average grain size (11) of the Speckle Pattern (12) allows calibrating the assemblies and modalities of the invention by organizing the relationships of the elements and metrological parameters such as previously described by means of test disturbances and corresponding voltage or power measurements in a photodetector (5) obtaining a direct response that correlates, for example, the change of a variable of interest with the voltage or power in the photodetector (5) corresponding to the optical power of a grain (11) of average size of the Speckle Pattern (12).
  • the invention is also possible to perform spectral analysis at the output of the photodetector (5), and at the end of the fiber segment (3) opposite the first end of the second MMF Multimode Fiber Optic segment (3) that is connected to the second end of the first Fiber Optic segment (2), an electronic image acquisition system with CCD devices (Charge - Coupled Device), CMOS (Complementary Metal-Oxide-Semiconductor), or equivalent.
  • CCD devices Charge - Coupled Device
  • CMOS Complementary Metal-Oxide-Semiconductor
  • the photodetector (5) is selected from the group consisting of: light detector, photodiode, PIN photodiode, avalanche photodiode, phototransistor, photoresistor, photocathode, phototube, photovalve, photomultiplier, CCD, CMOS sensor, cell photoelectric, photoelectrochemical cell, photocell, connectorized photodetector, connectorized photodiode and combinations thereof.
  • a connectorized element is one that includes at one end a connector for mechanical splicing to optical fiber.
  • the optical fiber structure comprising: A first segment of Optical Fiber (2) of 1 m in length, with a core diameter (2b) of 9 pm and a numerical aperture (AN) of 0.13, the first segment of Optical Fiber (2) with two ends, a second segment of MMF Multimode Optical Fiber (3) of 15 cm in length, with a core diameter (3b) of 50 pm and an aperture numerical value of 0.22, where the second MMF Multimode Fiber Optic segment (3) includes a disturbance region (8), and with two ends, where one end of the second MMF Multimode Fiber Optic segment (3) is connected to one of the ends of the first Fiber Optic segment (2) by fusion splicing and where a reflective silver film (9) deposited by sputtering (sputtering) is added and arranged at the second end of the second segment of MMF Multimode Optical Fiber (3.
  • the second segment of MMF Multimode Fiber Optic (3) has a region of disturbance (8) obtained by coating the MMF Multimode Optical Fiber (3) with
  • An embodiment of the invention is made where one end of the first Fiber Optic segment (2) is connected to the second port of the optical circulator (10) by means of a mechanical connection type FC / PC (Ferrule Connector / Physical Contact) - other alternatives of mechanical connection is through connectors type ST (Straight Tip), SC (Standard Connector), LC (Lucent Connector), MU (Miniature Unit), MTRJ (Mechanical Transfer Registered Jack), E2000 connector or any type of mechanical fiber optic connector- .
  • a coherent light emitter (1) is connected, which is a fiber-connectorized laser source, with emission wavelengths at 1310, 1490 and 1550 nm, and using the wavelength of 1550 nm.
  • a photodetector (5) connectorized to fiber is connected, which is a photodetector of point optical power (5) type photodiode with response in the range of wavelengths from 800 to 1700nm.
  • the laser source ensures that the second segment of MMF Multimode Fiber Optic (3) works in a multimodal regime.
  • the second segment of MMF Multimode Fiber Optic (3) has a disturbance region (8) obtained by coating with an encapsulation (7) with an aperture (A), MMF Multimode Optical Fiber (3), where the aperture (A) It is rectangular and runs along the length of the second MMF Multimode Fiber Optic segment (3) exposing the opening (A) in the second MMF Multimode Fiber Optic segment (3).
  • the longitudinal dimension L of the opening (A) is selected from 1 cm, 3 cm, 4.5 cm, 8 cm and 12 cm and the transverse dimension of this area is between 1 mm and 3 mm.
  • the region of disturbance (8) is brought into contact or approaches a body whose temperature is to be measured.
  • the output of the photodetector (5) which is a punctual optical power photodetector (5) type photodiode connectorized to fiber with response in the wavelength range of 800 to 1700nm, is connected to a voltage meter that allows characterization of the response of the assembly of this example when a certain temperature is applied; On the other hand, said temperature is also measured with a standard temperature sensor such as a thermocouple, an RTD sensor (Resistance Temperature Detector), a thermistor or a combination of the above, and in this way obtain the calibration curve of the assembly of this example.
  • a sensitivity, dynamic range and threshold analysis of the present invention can be carried out, in the same way as illustrated in Example 2.
  • the way to obtain the calibration curves is known to a person who is moderately versed in matter and the way to obtain said curves will be described in Example 2.
  • the first segment of Optical Fiber (2) Singlemode at its first end is connected by mechanical connection type FC / PC to a photodetector (5) which is a point photodetector (5) connectorized to fiber with response in the 800 wavelength range at 1700nm, additionally a coherent light emitter (1) which for this example is a fiber optic connectorized laser source with 1550 nm emission wavelengths
  • Said emitter is a coherent light emitter (1) that is connected by means of a mechanical connection type SC / APC (Square connector or standard connector / Angled phisical contact) to the second end of the second segment of MMF Multimode Fiber Optic (3 ).
  • SC / APC Square connector or standard connector / Angled phisical contact
  • the fiber optic connectorized laser source with emission wavelengths 1550 nm ensures that the second segment of MMF Multimode Fiber Optic (3) works in multimodal regimen.
  • the relationship is 0.8 between the core diameter (2b) of the first Optical Fiber segment (2) and the average grain diameter (11) of the Speckle Pattern (12) that is generated in the contact plane (BB) between the first segment of Optical Fiber (2) and second segment of MMF Multimode Optical Fiber (3) when it is irradiated with coherent light from the coherent light emitter (1).
  • the second segment of MMF Multimode Optical Fiber (3) has a disturbance region (8) obtained by coating the cladding (3a) of the MMF Multimode Optical Fiber (3) with an encapsulation (7) with an opening (A), where the aperture (A) is rectangular along the length of the second MMF Multimode Fiber Optic segment (3) exposing the second MMF Multimode Optical Fiber segment (3) in the aperture (A).
  • the longitudinal dimension L of the opening (A) is selected from 1cm, 3cm, 4.5cm, 8cm and 12cm and the transverse dimension of this area is between 1mm and 3mm.
  • the region of disturbance (8) is brought into contact or approaches a body whose temperature is to be measured.
  • the output of the photodetector (5) which is a point optical power photodetector (5) type photodiode connectorized to fiber with response in the range of wavelengths from 800 to 1700 nm is connected to a voltage meter that allows the characterization of the Response of the assembly of this example when the disturbance region (8) is brought into contact or approaches a body whose temperature is to be measured, on the other hand said temperature is also measured with a standard temperature sensor such as a thermocouple, an RTD (Resistance Temperature Detector) sensor, a thermistor or a combination of the above, in order to obtain the mounting calibration curve of this example.
  • a sensitivity, dynamic range and threshold analysis of the present invention can be performed as presented below.
  • the first Fiber Optic segment (2) has two ends; a second segment of MMF Multimode Fiber Optic (3) 15 cm long, with a diameter of 50 um and a numerical aperture of 0.22, with a perturbation region (8), and with two ends, where one end of the second segment Fiber Optic Multimode MMF
  • the third segment of Optical Fiber (2) Singlemode at its first end is connected by means of a mechanical connection type FC / PC to a photodetector (5) which is a point photodetector connectorized to fiber with response in the range of wavelengths from 800 to 1700nm, additionally a coherent light emitter
  • Said emitter is a coherent light emitter (1) that is connected by means of a mechanical connection type SC / APC (for its acronym in English Square connector or standard connector / Angled phisical contact) to the end of the second segment of MMF Multimode Fiber Optic (3) .
  • SC / APC for its acronym in English Square connector or standard connector / Angled phisical contact
  • the fiber optic connectorized laser source with emission wavelengths 1550 nm ensures that the second segment of MMF Multimode Fiber Optic (3) operates in a multimodal regime.
  • the relationship is 0.8 between the core diameter (2b) of the first Optical Fiber segment (2) and the average diameter of grains (11) of the Speckle Pattern (12) that is generated in the contact plane (BB) between the first Fiber Optic segment
  • the (3) has a disturbance region (8) that is obtained by wear of a part of the cladding (3a) (cladding) where for the worn area the longitudinal dimension of is selected between 1 cm, 3 cm, 4.5 cm, 8 cm and 12 cm and the transverse dimension is select between 1mm and 3mm.
  • the region of disturbance (8) is brought into contact with substances that are changing their chemical composition, such as, for example, a percentage by volume of propyl alcohol in distilled water.
  • the output of the optical power photodetector (5) is connected to a voltage meter that allows the characterization of the response of the assembly of example 3 when the percentage by volume of propyl alcohol in distilled water is changed, to obtain the calibration curve of the system proposed in this invention.

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  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Optics & Photonics (AREA)
  • Optical Couplings Of Light Guides (AREA)

Abstract

La présente invention concerne un système de fibre optique, qui comprend: une structure qui comprend un premier segment de fibre optique (2) avec deux extrémités; un second segment de fibre optique multimode MMF (3) avec deux extrémités; la première extrémité du second segment de fibre optique multimode MMF (3) est reliée à la première extrémité du premier segment de fibre optique (2); le second segment de fibre optique multimode MMF (3) comprend une zone de perturbation (8) qui s'expose à une perturbation physique ou chimique.
PCT/IB2020/060984 2019-12-20 2020-11-20 Système de fibre optique WO2021123968A1 (fr)

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CONC2019/0014494A CO2019014494A1 (es) 2019-12-20 2019-12-20 Estructura de fibra óptica

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WO2006071642A1 (fr) * 2004-12-23 2006-07-06 Trustees Of Princeton University Détection “ cavity ring-down ” de résonance de plasmon de surface dans un résonateur à fibre optique
WO2008003071A2 (fr) * 2006-06-29 2008-01-03 The Board Of Trustees Of The Leland Stanford Junior University Capteur à fibre optique utilisant une fibre de bragg
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Publication number Priority date Publication date Assignee Title
WO2006071642A1 (fr) * 2004-12-23 2006-07-06 Trustees Of Princeton University Détection “ cavity ring-down ” de résonance de plasmon de surface dans un résonateur à fibre optique
WO2008003071A2 (fr) * 2006-06-29 2008-01-03 The Board Of Trustees Of The Leland Stanford Junior University Capteur à fibre optique utilisant une fibre de bragg
US8351029B2 (en) * 2007-12-06 2013-01-08 Mitsubishi Electric Corporation Optical fiber sensor

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