MINIATURE DIAPHRAGM-BASED FIBER-OPTIC TIP FP PRESSURE SENSOR, AND FABRICATION METHOD AND APPLICATION THEREOF

Abstract

A miniature diaphragm-based fiber-optic tip FP pressure sensor, and fabrication method and application thereof. A miniature diaphragm-based fiber-optic tip FP pressure sensor includes an optical fiber, a hollow-core optical fiber, and a pressure sensing diaphragm, wherein the optical fiber and the hollow-core optical fiber have the same diameter, the two are spliced by arc welding; and the pressure sensing diaphragm is bonded to the endface of the hollow-core optical fiber by hydroxide catalysis bonding. The FP pressure sensor can not only realize the all-silica structure of a sensor, but also make the joint of each component free of organic polymer, and has extremely high long-term stability and thermal stability. Meanwhile, by means of a fabrication method of the miniature diaphragm-based fiber-optic tip FP pressure sensor, the application range and service life of the sensor are increased, and fabrication costs are reduced.

Claims

1. A miniature diaphragm-based fiber-optic tip FP pressure sensor, comprising an optical fiber, a hollow-core optical fiber and a pressure sensing diaphragm, wherein the optical fiber and the hollow-core optical fiber have the same diameter, the two are spliced by arc welding; and the pressure sensing diaphragm is bonded to the endface of the hollow-core optical fiber by hydroxide catalysis bonding; the hollow-core optical fiber has an inner diameter of 30-100 μm, and a length of 10-1000 μm; and the pressure sensing diaphragm has a thickness of 0.1-100 μm.

2. The miniature diaphragm-based fiber-optic tip FP pressure sensor according to claim 1, wherein the diaphragm is made of silicon dioxide, silicon, or sapphire.

3. The miniature diaphragm-based fiber-optic tip FP pressure sensor according to claim 1, wherein the hollow-core optical fiber is a hollow-core optical fiber or a multimode optical fiber with fiber core removed by corrosion.

4. A fabrication method of the miniature diaphragm-based fiber-optic tip FP pressure sensor, comprising the following steps: (1) preparing bonding solution, including the first solution obtained by mixing NaOH or KOH with a molar ratio of 1:500 with water, and second solution, i.e. sodium silicate aqueous solution with a mass percentage concentration of 1-7%: mixing and uniformly shaking, filtering using a microporous filter with an aperture less than 0.2 μm, thus obtaining the bonding solution; (2) taking an optical fiber, peeling off the cladding, wiping with alcohol, and cutting the endface of the optical fiber with a fiber cleaver; taking a hollow-core optical fiber, and cutting the endface of the hollow-core optical fiber flatly with the fiber cleaver; (3) placing the optical fiber and the hollow-core optical fiber in a fusion splicer in a mode of aligning the endface of the optical fiber with the endface of the hollow-core optical fiber, conducting discharge splicing, the discharge strength being 30-50 bit, the discharge time being 1000-1500 ms, obtaining an optical fiber-hollow-core optical fiber structure; (4) immersing the optical fiber-hollow-core optical fiber structure in methanol and acetone in sequence, and taking out and washing the immersed structure with deionized water; (5) preparing pressure sensing diaphragms, the pressure sensing diaphragms and the optical fiber having the same diameter; sucking a single diaphragm by a negative pressure device, placing the diaphragm on a clean plastic substrate, and slightly washing with ethanol, to achieve the purpose of obtaining an absolutely clean surface to be bonded; (6) dropping the bonding solution on a hydrophilic slide to make same uniformly distributed; dipping the bonding solution on the slide with the tip of the hollow-core optical fiber of the optical fiber-hollow-core optical fiber structure treated in step (4), aligning the optical fiber-hollow-core optical fiber structure with the pressure sensing diaphragm with a clamp, bonding, discharging air bubbles, and standing at normal temperature, to preliminarily cure the bonding solution; and (7) after the bonding solution is preliminarily cured, standing the bonding solution at room temperature for tens of days, to completely cure the bonding solution.

5. An application of the miniature diaphragm-based fiber-optic tip FP pressure sensor according to claim 1, wherein the miniature diaphragm-based fiber-optic tip FP pressure sensor detects static pressure and dynamic pressure simultaneously, including air pressure, hydraulic pressure, and sound pressure.

6. The application of the miniature diaphragm-based fiber-optic tip FP pressure sensor according to claim 5, wherein the miniature diaphragm-based fiber-optic tip FP pressure sensor is used as an organism pressure sensor, an oil well pressure sensor, a bridge and dam osmotic pressure sensor, a fiber-optic microphone, a hydrophone, and various sound pressure sensors.

Description

Description of Drawings

[0035] FIG. 1 is a structural schematic diagram of a traditional DEFPI fiber-optic sensor;

[0036] FIG. 2 is a structural schematic diagram of a miniature diaphragm-based fiber-optic tip FP pressure sensor;

[0037] FIGS. 3(a) and 3(b) are schematic diagrams of the endface cutting method of the optical fiber and hollow-core optical fiber;

[0038] FIGS. 4(a) and 4(b) are schematic diagrams of the fabrication method of the optical fiber-hollow-core optical fiber structure;

[0039] FIGS. 5(a), 5(b) and 5(c) are schematic diagrams of the bonding process of the pressure sensing diaphragm;

[0040] FIG. 6 is the spectrum of a miniature diaphragm-based fiber-optic tip FP pressure sensor; and

[0041] FIG. 7 is a schematic diagram of an air pressure sensor detection device.

[0042] In the figures: 1. optical fiber; 2. collimation capillary tube matching optical fiber in outer diameter; 3. pressure sensing diaphragm; 4. hollow-core optical fiber; 5. fiber core of optical fiber; 6. cladding of optical fiber; 7. bonding solution; 8. broadband light source; 9. circulator; 10. spectrometer; 11. computer; 12. sensor; 13. pressure device.

DETAILED DESCRIPTION

[0043] Specific embodiments of the present invention are described below in detail in combination with the technical solution and accompanying drawings.

Embodiment 1

[0044] In the present invention, a dual-beam interferometric structure is formed by a single-mode optical fiber, a hollow-core optical fiber, and a silicon dioxide diaphragm, and the all-silica structure of a sensor is realized by only using arc welding and hydroxide catalysis bonding, and the structure of the sensor is shown in FIG. 2. The single-mode optical fiber has a diameter of 125 μm, and a fiber core diameter of 9 μm; the hollow-core optical fiber has an outer diameter of 125 μm, and an inner diameter of 80 μm; and the silicon dioxide diaphragm has a diameter of 125 μm, and a thickness of 1 μm. The end surface of the optical fiber and the inner surface of the silicon dioxide diaphragm form two reflecting surfaces, and two beams of reflected light form dual-beam interference on the two surfaces, thereby forming a low-finesse FP interferometer. When the external pressure acts on the silicon dioxide diaphragm, the silicon dioxide diaphragm is elastically deformed, which leads to the changes in the cavity length of the FP interference. At this time, the pressure can be obtained by measuring the changes in the effective cavity length.

[0045] (1) Preparing bonding solution: taking 1 part of commercial sodium silicate aqueous solution which consists of 14 wt. % sodium hydroxide and 27wt. % silicon dioxide, diluting the sodium silicate aqueous solution with 6 parts of deionized water according to the volume ratio, mixing and uniformly shaking, and then filtering using a microporous filter with an aperture less than 0.2 μm, thus obtaining the bonding solution.

[0046] (2) Taking an optical fiber 1, and cutting an endface of the optical fiber 1 with a fiber cleaver, as shown in FIG. 3(a); and taking a hollow-core optical fiber 4, and cutting the endface of the hollow-core optical fiber 4 with the fiber cleaver, as shown in FIG. 3(b).

[0047] (3) Placing the optical fiber 1 and the hollow-core optical fiber 4 in a fusion splicer in a mode of aligning the endface of the optical fiber 1 with the endface of the hollow-core optical fiber 4, conducting discharge splicing, the discharge strength being 45 bit, the discharge time being 1000 ms, obtaining an optical fiber-hollow-core optical fiber structure, as shown in FIG. 4(a).

[0048] (4) Under a microscope, cutting another endface of the spliced hollow-core optical fiber 4 flatly, wherein the length of the cut hollow-core optical fiber 4 is about 150 μm, which is the sensing cavity length, as shown in FIG. 4(b).

[0049] (5) Immersing the optical fiber-hollow-core optical fiber structure in methanol and acetone in sequence, and taking out and washing the immersed structure with deionized water.

[0050] (6) Taking silicon dioxide diaphragms prepared by the micro-electro-mechanical system (MEMS) technology as pressure sensing diaphragms 3, the pressure sensing diaphragms 3 having the same diameter as the optical fiber 1; sucking a single diaphragm by a negative pressure device, placing the diaphragm on a clean plastic substrate, and slightly washing with ethanol, to achieve the purpose of obtaining an absolutely clean surface to be bonded;

[0051] (7) Dropping the bonding solution on a hydrophilic slide to make same uniformly distributed; dipping the bonding solution on the slide with the endface of the optical fiber-hollow-core optical fiber structure treated in step (5), as shown in FIG. 5(a); aligning the optical fiber-hollow-core optical fiber structure with the pressure sensing diaphragm 3 with a clamp, bonding, discharging air bubbles, and standing at normal temperature, to preliminarily cure the bonding solution, as shown in FIG. 5(b).

[0052] (8) After the bonding solution is preliminarily cured, standing the bonding solution at room temperature for tens of days, to completely cure the bonding solution, as shown in FIG. 5(c); or placing the bonding solution in a vacuum oven for tens of hours for performing heat treatment and accelerating curing.

[0053] (9) Connecting the sensor 12 with the broadband light source 8 and the spectrometer 10 through the circulator 9, so the reflection spectrum of the sensor can be detected, then placing the sensor 12 in the pressure device 13, changing the air pressure inside the device, observing the change in the spectrum and demodulating change in cavity length by using the algorithm in the computer 11, so that a linear curve of cavity length changing with air pressure can be obtained; and measuring the absolute pressure value through the cavity length change curve, as shown in FIGS. 6 and 7.

[0054] The sensor can detect static air pressure, hydraulic pressure, and dynamic sound pressure signals, and can be used as an altitude airspeed sensor, an organism pressure sensor, a fiber-optic microphone, and a hydrophone.