CN203870020U - Optical fiber hydrogen sensor - Google Patents

Abstract

The utility model provides an optical fiber hydrogen sensor which comprises an incidence optical fiber, a reflection optical fiber and a hydrogen sensitive film. One end of the incidence optical fiber is used as a light incidence end, the other end of the incidence optical fiber is connected with the reflection optical fiber, a hydrogen accommodating cavity is arranged at the other end of the incidence optical fiber, and the corresponding end surface of the reflection optical fiber covers an opening of the hydrogen accommodating cavity and is used as a reflection end surface; gas holes are respectively formed in at least two opposite side walls of a cavity body of the hydrogen accommodating cavity and are staggered from each other; the hydrogen sensitive film is arranged on the inner surface of the hydrogen accommodating cavity and is provided with a plurality of sunken portions, and the multiple sunken portions are respectively opposite to the multiple gas holes.

Description

Optical Fider Hybrogen Sensor

Technical field

The utility model relates to hydrogen detection technique, especially, relates to a kind of Optical Fider Hybrogen Sensor.

Background technology

Hydrogen is a kind of important raw material of industry, has important application at aspects such as petrochemical complex, electronics industry, metallurgical industry, food processings; Meanwhile, hydrogen is as a kind of novel energy, not only clean environment firendly, and there is abundant source, therefore hydrogen also becomes more and more important in the status of new energy field.But, hydrogen is easily revealed, and runs into naked light when above and can cause blast when airborne density of hydrogen reaches 4%, therefore, in transport, storage and the commercial production and use procedure of hydrogen, it is an extremely important and necessary job that the density of hydrogen of environment is detected.

Optical Fider Hybrogen Sensor is owing to can having advantages of safety and Real-Time Monitoring, being widely applied to density of hydrogen detects, in all eurypalynous Optical Fider Hybrogen Sensors, the application of the interference-type optical fiber hydrogen gas sensor of interfering based on Fabry-Perot (Fabry-Perot, F-P) is comparatively extensive.Traditional interference-type optical fiber hydrogen gas sensor is that incident optical and mirror based fiber optica are separately fixed to the two ends formation F-P interference cavity of glass bushing, and establishes palladium (Pd) film at the plated surface of glass bushing.Thereby described Pd film volume after absorbing hydrogen can change and change interference cavity length, therefore can realize the detection to density of hydrogen by analyzing interference spectum.

But, because the hydrogen sensitive membrane of above-mentioned interference type Optical Fider Hybrogen Sensor is directly being plated the outside that is located at glass bushing, outside contamination may reduce the quality of described hydrogen sensitive membrane, thereby affects the detection degree of accuracy of described interference-type optical fiber hydrogen gas sensor.

Utility model content

In view of this, the utility model provides a kind of Optical Fider Hybrogen Sensor that can address the above problem.

A kind of Optical Fider Hybrogen Sensor, comprises incident optical, mirror based fiber optica and hydrogen sensitive membrane; Wherein one end and the described mirror based fiber optica of described incident optical interconnect and offer hydrogen host cavity, and the end face of described mirror based fiber optica covers the opening of described hydrogen host cavity, and as reflection end face; At least two relative sidewalls of the cavity of described hydrogen host cavity are formed with respectively pore, and the pore of described at least two relative sidewalls is crisscross arranged respectively; Described hydrogen sensitive membrane is arranged on the inside surface of described hydrogen host cavity, and described hydrogen sensitive membrane has multiple depressed parts, and described multiple depressed parts are oppositely arranged with described multiple pores respectively.

The Optical Fider Hybrogen Sensor that the utility model provides forms hydrogen host cavity at the end of described incident optical, can realize described hydrogen sensitive membrane and arrange the inside of described incident optical.By the built-in mode of above-mentioned hydrogen sensitive membrane, can effectively avoid described hydrogen sensitive membrane to be subject to the impact of outside contamination and to destroy its hydrogen sensitivity characteristic, ensure the accuracy of the density of hydrogen testing result of described Optical Fider Hybrogen Sensor.And described Optical Fider Hybrogen Sensor forms pore by least two opposing sidewalls at described hydrogen host cavity, can make enough hydrogen enter described hydrogen host cavity inside, ensures the normal realization that density of hydrogen detects; In addition, the pore of described at least two relative sidewalls is crisscross arranged respectively, thereby hydrogen is carried out to certain stopping, make hydrogen can stop time enough at described hydrogen host cavity, ensure that it can fully be absorbed by the hydrogen sensitive membrane of the side wall inner surfaces of described hydrogen host cavity, further improve the accuracy of the density of hydrogen detection of described Optical Fider Hybrogen Sensor.

Brief description of the drawings

In order to be illustrated more clearly in the technical scheme in the utility model embodiment, below the accompanying drawing using during embodiment is described is briefly described, apparently, accompanying drawing in the following describes is only embodiment more of the present utility model, for those of ordinary skill in the art, do not paying under the prerequisite of creative work, can also obtain according to these accompanying drawings other accompanying drawing, wherein:

Fig. 1 is the structural representation of a kind of embodiment of Optical Fider Hybrogen Sensor of providing of the utility model;

Fig. 2 is the side structure schematic diagram of the incident optical of the Optical Fider Hybrogen Sensor shown in Fig. 1;

Fig. 3 is the schematic flow sheet for the method for making of the Optical Fider Hybrogen Sensor shown in construction drawing 1.

Embodiment

To the technical scheme in the utility model embodiment be clearly and completely described below, obviously, described embodiment is only a part of embodiment of the present utility model, instead of whole embodiment.Based on the embodiment in the utility model, those of ordinary skill in the art are not making all other embodiment that obtain under creative work prerequisite, all belong to the scope of the utility model protection.

The Optical Fider Hybrogen Sensor that the utility model provides, by hydrogen sensitive membrane is built in to incident optical inside, avoids hydrogen sensitive membrane to be subject to outside contamination gases affect, improves the accuracy of described Optical Fider Hybrogen Sensor density of hydrogen testing result.

Refer to Fig. 1, it is the structural representation of a kind of embodiment of Optical Fider Hybrogen Sensor of providing of the utility model, described Optical Fider Hybrogen Sensor 10 comprises incident optical 11, mirror based fiber optica 12 and hydrogen sensitive membrane 13, wherein, described incident optical 11 and described mirror based fiber optica 12 can be single-mode fiber or be multimode optical fiber, also can one of them for single-mode fiber, another is multimode optical fiber, and described incident optical 11 and described outgoing optical fiber are mutually aimed at and interconnect by fusion joining process.

The two ends of described incident optical 11 can be respectively as light incident side and link, wherein said light incident side can receive the test light that external light source (such as laser diode) provides, and described link can with the mutual welding of described mirror based fiber optica 12.Wherein, the link of described incident optical offers miniature cavity 111, and described miniature cavity 111 is mainly as the hydrogen host cavity that is used for accommodating hydrogen to be detected.Described miniature cavity 111 can form by laser micro-machining technology, and its fibre core 110 bearing of trends along described incident optical 11 are offered.After forming described miniature cavity 111, described incident optical 11 just can be used as the sidewall of described miniature cavity 111 at the residue fiber optic materials of described miniature cavity 11 regions.Wherein, the internal diameter of described miniature cavity 111 is greater than the diameter of the fibre core 110 of described incident optical 11, and the fibre core 110 of described miniature cavity 111 inside is removed completely.

In specific embodiment, at the bottom of the chamber of described miniature cavity 111, can form semi-penetration semi-reflective face 101.Described semi-penetration semi-reflective face 101 just can reflect the partial test light of described incident optical 11 and form the first reflected light, and is transmitted to described miniature cavity 111 inside using another part test light as transmitted light.

Described incident optical 11 can offer multiple pores 14 described miniature cavity 111 regions, described pore 14 can extend to from the surface of described incident optical 11 described miniature cavity 111 inside, and it is mainly used to provide the passage that enters described miniature cavity 111 to hydrogen.

Particularly, because described pore 14 is generally smaller, for making the hydrogen of q.s enter described miniature cavity 111, to ensure that described Optical Fider Hybrogen Sensor 10 can carry out density of hydrogen detection, in the Optical Fider Hybrogen Sensor 10 providing at the utility model, described pore 14 is at least opened in the relative both sides of described incident optical 11 ends, is formed on two relative sidewalls of described miniature cavity 111.Should be appreciated that described incident optical 11 generally has circular xsect, therefore described miniature cavity 111 is circular cylindrical cavity, and accordingly, the sidewall of described miniature cavity 111 is actually an annular sidewall; Therefore,, in present specification, two relative sidewalls of described miniature cavity 111 should be understood to wherein two relative arch sections of described annular sidewall, the first curved wall part 112 as shown in Figure 2 and the second curved wall part 113.

And, for avoiding the hydrogen that enters described miniature cavity 111 from the pore 14 of described incident optical 11 1 sides to pass from the opposite side of described incident optical 11, in the present embodiment, the pore 14 that 111 two relative sidewalls of described miniature cavity are offered is respectively crisscross arranged respectively, that is to say, the pore 14 that one of them sidewall of described miniature cavity 111 is offered does not align with the pore 14 that another sidewall is offered, as shown in Figure 1.Can be stopped by opposite side sidewall by the hydrogen that adopts said structure to enter into described miniature cavity 111 inside from the pore 14 of one of them sidewall of described miniature cavity 111, thereby make hydrogen can stop time enough at described miniature cavity 111, ensure that it can fully be absorbed by the hydrogen sensitive membrane 13 of the side wall inner surfaces of described miniature cavity 111.

On the other hand, the side wall inner surfaces of described miniature cavity 111 can be formed with hydrogen sensitive membrane 13, described hydrogen sensitive membrane 13 can be specially palladium (Pd) film or palldium alloy (Pd Alloy) film, and it has the characteristic that absorbs hydrogen and occur volume change.Particularly, described hydrogen sensitive membrane 13 can be formed on the madial wall of described miniature cavity 111 after described miniature cavity 111 forms by vacuum coating mode.

Because described miniature cavity 111 forms at described incident optical 11 ends, its size is generally less, therefore the area of the madial wall of described miniature cavity 111 is generally all smaller, and because also needing to provide space, the madial wall of described miniature cavity 111 forms described pore 14, therefore in reality realizes, it is very limited that plating is located at the surface area of hydrogen sensitive membrane 13 of interior side-wall surface of described miniature cavity 111, may affect described hydrogen sensitive membrane 13 and absorption of hydrogen and react and occur the effect of volume change, thereby cause the detection poor effect of described Optical Fider Hybrogen Sensor 10.

For the problems referred to above, in the Optical Fider Hybrogen Sensor 10 providing at the utility model, described hydrogen sensitive membrane 13 can be formed with respectively multiple depressed parts 131 with the just right region of described pore 14.Because the pore of two of described miniature cavity 111 relative sidewalls is to be crisscross arranged respectively but not directly relative, therefore just face the region at hydrogen sensitive membrane 13 places of another sidewall at any one pore 14 of one of them sidewall of described miniature cavity 111, this may for realizing that described depressed part 131 provides in technique.Particularly, after described pore 14 forms, described depressed part 131 can pass through laser micro-machining technology, laser beam is irradiated to the hydrogen sensitive membrane 13 of the side wall inner surfaces of opposite side by described pore 14, just can make described hydrogen sensitive membrane 13 form respectively multiple depressed parts 131 in the region relative with described multiple pores 14, such as circular depression, as shown in Figure 1.

The end of described mirror based fiber optica 12 is mutually aimed at and interconnects by fusion joining process with the link of described incident optical 11, and therefore its end face can cover the opening that is located at described miniature cavity 111 just.And the end face of described mirror based fiber optica 12 can be used as reflection end face 102, the transmitted light that the semi-penetration semi-reflective face 101 from described incident optical 11 is transmitted to described miniature cavity 111 reflects, thereby forms the second reflected light.

This shows, in the Optical Fider Hybrogen Sensor 10 providing at the utility model, described miniature cavity 111 is together with the semi-penetration semi-reflective face 101 of described incident optical 11 and the reflection end face 102 of described mirror based fiber optica 12, form Fabry-Perot (Fabry-Perot, a F-P) interference cavity that is used for carrying out density of hydrogen detection.

Particularly, in the time carrying out density of hydrogen detection, the wide range test light that external light source provides incides incident optical 11, thereby and form the first reflected light at the semi-penetration semi-reflective face 101 generating unit sub reflectors of described incident optical 11, in addition, also have partial test light to enter described miniature cavity 111 from described semi-penetration semi-reflective face 101, thereby and at the reflection end face 102 of described mirror based fiber optica 12, reflection formation the second reflected light occurs through described miniature cavity 111.Described the second reflected light and described the first reflected light interfere, and can collect described the first reflected light and described the second catoptrical interference spectrum by spectrometer.In the time that density of hydrogen changes, described hydrogen sensitive membrane 13 reacts with the hydrogen that enters into described miniature cavity 111 by described pore 14, and corresponding variation also occurs its volume.The volume change of described hydrogen sensitive membrane 13 can further cause described the first reflected light and described the second catoptrical optical path difference to change, thereby further causes the interference spectrum of the two to change.Therefore the interference spectrum obtaining according to described spectrometer just can calculate the situation of change of density of hydrogen.

The Optical Fider Hybrogen Sensor that the utility model provides forms miniature cavity at the end of described incident optical, can realize described hydrogen sensitive membrane and arrange the inside of described incident optical.By the built-in mode of above-mentioned hydrogen sensitive membrane, can effectively avoid described hydrogen sensitive membrane to be subject to the impact of outside contamination and to destroy its hydrogen sensitivity characteristic, ensure the accuracy of the density of hydrogen testing result of described Optical Fider Hybrogen Sensor.

Optical Fider Hybrogen Sensor 10 shown in Fig. 1 can be made by the method for making of the Optical Fider Hybrogen Sensor shown in Fig. 3.Particularly, described method for making comprises:

Step S1, provides incident optical, and forms miniature cavity at the end of described incident optical;

Particularly, in this step, a single-mode fiber can be first provided or polish fibre more and be used as described incident optical 11, and, along the bearing of trend of the fibre core 110 of described incident optical 110, process a miniature cavity 111 by femtosecond laser parallel micromachining technology or deep ultraviolet laser micro-processing technology at the end of described incident optical 11.The size of described miniature cavity 111 can be slightly larger than the fibre core 110 of described incident optical 11, that is to say, by described femtosecond laser parallel micromachining technology or deep ultraviolet laser micro-processing technology, the fibre core of the end of described incident optical 11 110 is removed completely, and, described fibre core 110 fiber optic materials around is also partly removed, thereby forms a miniature cavity 111 with sidewall.The concrete shape of described miniature cavity 111 and structure can be consulted the specific descriptions of above embodiment.

Step S2, forms hydrogen sensitive membrane in the side wall inner surfaces of described miniature cavity;

After described miniature cavity 111 forms, can adopt the thin-film technique of magnetron sputtering or vacuum coating, palladium (Pd) film or palladium alloy membrane are established in inside surface deposition or plating at the sidewall of described miniature cavity 111, are used as described hydrogen sensitive membrane 130.

Step S3, forms the first pore array at one of them sidewall of described miniature cavity;

After described hydrogen sensitive membrane 130 completes, can adopt femtosecond laser parallel micromachining technology or deep ultraviolet laser micro-processing technology, at one of them sidewall of the miniature cavity 111 of described incident optical 11 ends, along processing by multiple the first pores 14 with the perpendicular direction of the fibre core 111 of described incident optical 11, form the first pore array.

In the process of described the first pore array, swash light intensity and irradiation time and need strict control, just be removed with the fiber optic materials that makes described sidewall, do not destroy again the fiber optic materials of another sidewall of described miniature cavity 11 simultaneously, thereby form the first pore 14 that extends to described miniature cavity 111 inside from the outside surface of described incident optical 11 ends, to make hydrogen to enter described miniature cavity 111 from described sidewall.

Step S4, forms the second pore array at another sidewall of described miniature cavity, and each pore of described the second pore array is crisscross arranged with the pore of described the first pore array respectively;

Particularly, after described the first pore array completes, can adopt equally femtosecond laser parallel micromachining technology or deep ultraviolet laser micro-processing technology, at another sidewall of the miniature cavity 111 of described incident optical 11 ends, along processing by multiple the second pores 14 with the perpendicular direction of the fibre core 111 of described incident optical 11, form the second pore array.

Wherein, need to be designed to not face with the pore of described the first pore array at the machining area of described the second pore array, thereby the pore 14 of realizing described the second pore array and described the first pore array is crisscross arranged respectively.In addition, similar, in this step, the sharp light intensity that is used for carrying out pore processing with and irradiation time need strict control, avoid the fiber optic materials of the sidewall that destroys described the first pore array place.

Step S5, the region facing at the hydrogen sensitive membrane of the interior side-wall surface of described miniature cavity and described the first pore array and described the second pore array forms multiple depressed parts;

Particularly, this step can realize by laser micro-machining technology the processing of described multiple depressed parts.Particularly, can utilize laser to be irradiated to the hydrogen sensitive membrane 13 of another sidewall surfaces from the first pore array of described miniature cavity 111 one of them sidewall or the pore 14 of described the second pore array, thereby form described depressed part 131 in described hydrogen sensitive membrane 13 region relative with described pore 14.In the present embodiment, the spot size of described laser should be less than the size of described pore 14, and the accurately control of the irradiation time of described laser, in order to avoid destroying appears in described hydrogen sensitive membrane 13.

Step S6, cremasteric reflex optical fiber, and by mutual the end of described mirror based fiber optica and described incident optical welding;

In this step, can provide another single-mode fiber or multimode optical fiber to be used as described mirror based fiber optica 12, and described mirror based fiber optica 12 is aimed at mutually with described incident optical 11.Then, adopt fusion joining process that described mirror based fiber optica 12 is fused to described incident optical 11, thereby form Optical Fider Hybrogen Sensor 10 as described in Figure 1.

The foregoing is only embodiment of the present utility model; not thereby limit the scope of the claims of the present utility model; every equivalent structure or conversion of equivalent flow process that utilizes the utility model description to do; or be directly or indirectly used in other relevant technical field, within being all in like manner included in scope of patent protection of the present utility model.

Claims (9)

1. an Optical Fider Hybrogen Sensor, is characterized in that, comprises incident optical, mirror based fiber optica and hydrogen sensitive membrane; Wherein one end and the described mirror based fiber optica of described incident optical interconnect and offer hydrogen host cavity, and the end face of described mirror based fiber optica covers the opening of described hydrogen host cavity, and as reflection end face; At least two relative sidewalls of the cavity of described hydrogen host cavity are formed with respectively pore, and the pore of described at least two relative sidewalls is crisscross arranged respectively; Described hydrogen sensitive membrane is arranged on the inside surface of described hydrogen host cavity, and described hydrogen sensitive membrane has multiple depressed parts, and described multiple depressed parts are oppositely arranged with described multiple pores respectively.

2. Optical Fider Hybrogen Sensor as claimed in claim 1, is characterized in that, described hydrogen host cavity is the cavity of offering along the bearing of trend of the fibre core of described incident optical.

3. Optical Fider Hybrogen Sensor as claimed in claim 2, is characterized in that, the internal diameter of described hydrogen host cavity is greater than the diameter of the fibre core of described incident optical.

4. Optical Fider Hybrogen Sensor as claimed in claim 3, is characterized in that, described hydrogen sensitive membrane is palladium film or palladium alloy membrane.

5. Optical Fider Hybrogen Sensor as claimed in claim 1, is characterized in that, is provided with semi-penetration semi-reflective film at the bottom of the chamber of described hydrogen host cavity.

6. Optical Fider Hybrogen Sensor as claimed in claim 1, is characterized in that, the depressed part of described hydrogen sensitive membrane is circular depression.

7. Optical Fider Hybrogen Sensor as claimed in claim 1, is characterized in that, described incident optical and described mirror based fiber optica are single-mode fiber.

8. Optical Fider Hybrogen Sensor as claimed in claim 1, is characterized in that, described incident optical is single-mode fiber, and described mirror based fiber optica is multimode optical fiber.

9. Optical Fider Hybrogen Sensor as claimed in claim 1, is characterized in that, described incident optical and described mirror based fiber optica are multimode optical fiber.