阅读说明：本技术 光纤模块 (Optical fiber module ) 是由 卢冠甫 叶俊毅 陈俊傑 郭朝辉 于 2018-09-13 设计创作，主要内容包括：本发明提供的光纤模块,本体一面有至少一凹槽组与一容置槽。本体,于凹槽组的一面形成有一反射面槽；异于反射面槽的一面有透镜凹槽；于透镜凹槽的一面有透镜组；于靠近容置槽的侧设有第三透镜。光传导组设于本体的容置槽内,光传导组有基材及至少一光传导件,基材靠近第三透镜一面有一穿透面,且穿透面对应本体的第三透镜,光传导件用于让特定波长光源穿透并反射剩余光源,光传导件形成于基材的两面。本发明的优点在于：光传导件之间的间距以空气当介质,供不同波长的光源穿透同时反射其他波长的光源。让光路来回反射进行合光,不同波长的光路汇聚后耦合至光纤导位柱内的光纤輸出,以显著增加资讯的传输量,具有波分复用的效果。(The optical fiber module provided by the invention has at least one groove group and one accommodating groove on one surface of the body. The body is provided with a reflecting surface groove on one surface of the groove group; a lens groove is arranged on the surface different from the reflecting surface groove; a lens group is arranged on one surface of the lens groove; the side close to the containing groove is provided with a third lens. The light conduction assembly is arranged in the containing groove of the body and is provided with a base material and at least one light conduction piece, one surface of the base material, which is close to the third lens, is provided with a penetrating surface, the penetrating surface corresponds to the third lens of the body, the light conduction piece is used for allowing a light source with a specific wavelength to penetrate through and reflect the rest light source, and the light conduction piece is formed on two surfaces of the base material. The invention has the advantages that: the space between the light-transmitting pieces is used as a medium by air, and light sources with different wavelengths can penetrate through the space while light sources with other wavelengths are reflected. The light paths are reflected back and forth to combine light, and the light paths with different wavelengths are converged and coupled to the optical fiber in the optical fiber guiding post to output, so as to significantly increase the transmission amount of information and have the effect of wavelength division multiplexing.)

1. A fiber optic module, comprising:

the lens comprises a body, wherein a first groove group and a containing groove are arranged on one surface of the body, a first reflecting groove and a first lens groove are arranged in the first groove group, a first reflecting surface is formed on one surface of the body, which is close to the first reflecting groove, a first lens groove is formed on one surface of the body, which is different from the first reflecting groove, a first lens group is formed on one surface of the body, which is close to the first reflecting groove, and the first lens group and the first reflecting surface are aligned with each other, and a third lens is arranged on one side of the body, which is close to the containing groove; and

the light conduction assembly is arranged in the accommodating groove of the body and comprises a base material and at least one light conduction piece, a light reflection surface and a light penetration surface are formed on one surface of the base material, a reflection layer is arranged on one surface of the base material, the reflection layer is used for reflecting light sources, the light penetration surface corresponds to the third lens of the body, the light conduction piece is arranged on one surface of the base material, which is different from the light reflection surface, at least one film layer is respectively formed at the joint of the light conduction piece and the base material, and the film layer can be used for light sources with different wavelengths to penetrate through and simultaneously reflect light sources with other wavelengths.

2. The fiber optic module of claim 1, wherein a hollow fiber guide post protrudes from the body toward a side of the third lens, and the third lens corresponds to the fiber guide post.

3. The fiber optic module of claim 1, wherein the body is injection molded in one piece.

4. The fiber optic module of claim 1, wherein the first reflective slot defines an included angle θ with respect to a horizontal direction of the body₁。

5. The fiber optic module of claim 1, wherein the first lens groove has a plurality of first lenses, such that the plurality of first lenses can respectively correspond to the light-transmitting members through the first reflective surface of the body.

6. The fiber optic module of claim 1, wherein the first lens is a collimating lens.

7. The fiber optic module of claim 1, wherein the third lens is a converging lens.

8. The fiber optic module of claim 1, wherein the body is a transparent material.

9. The fiber optic module of claim 1, wherein the light conductor is a plurality of filters.

10. A fiber optic module, comprising:

a body, one side of the body is provided with a first groove, a second groove group and a containing groove, the body is provided with a first reflecting groove and a first lens groove in the first groove group, one side of the body, which is close to the first reflecting groove, is provided with a first reflecting surface, one side of the body, which is different from the first reflecting groove, is provided with a first lens groove, one side of the body, which is close to the first reflecting groove, is provided with a first lens group, the first lens group and the first reflecting surface are aligned with each other, the second groove group is provided with a second reflecting groove and a second lens groove, one side of the body, which is close to the second reflecting groove, is provided with a second reflecting surface, one side of the body, which is different from the second reflecting groove, is provided with a second lens group, and one side of the body, which is close to the second reflecting groove, is provided with a second lens group, the second lens group and the second reflecting surface are aligned with each other, and a third lens is arranged on one side of the body adjacent to the accommodating groove; and

the light transmission assembly is arranged in the accommodating groove of the body and comprises a base material and at least two light transmission pieces, one surface of the base material is provided with a light penetration surface, the light penetration surface corresponds to the third lens of the body, the light transmission pieces are respectively arranged on the same surface and the different surface of the base material and the light penetration surface, the joint of the light transmission pieces and the base material is respectively provided with at least one film layer, and the film layers can be used for light sources with different wavelengths to penetrate and simultaneously reflect light sources with other wavelengths.

11. The fiber optic module of claim 10, wherein the body has a hollow fiber guide post protruding from a side of the third lens, and the third lens corresponds to the fiber guide post.

12. The fiber optic module of claim 10, wherein the body is injection molded in one piece.

13. The fiber optic module of claim 10, wherein the first reflective groove has a first included angle with respect to a horizontal direction of the body.

14. The fiber optic module of claim 10, wherein the second reflective groove has a second included angle with respect to the horizontal direction of the body.

15. The fiber optic module of claim 10, wherein the first reflective slot has a first included angle in the horizontal direction of the body, and the second reflective slot has a second included angle in the horizontal direction of the body, the first included angle and the second included angle being the same.

16. The fiber optic module of claim 10, wherein the first lens groove and the second lens groove each have a plurality of lenses for allowing the plurality of lenses to respectively correspond to the light-transmitting member through the first reflective surface and the second reflective surface of the body.

17. The fiber optic module of claim 10, wherein the lens is a collimating lens.

18. The fiber optic module of claim 10, wherein the third lens is a converging lens.

19. The fiber optic module of claim 10, wherein the body is a transparent material.

20. The fiber optic module of claim 10, wherein the light conductor is a plurality of filters.

21. A fiber optic module, comprising:

a body, one side of the body is provided with a first groove, a second groove group and a containing groove, the body is provided with a first reflecting groove and a first lens groove in the first groove group, one side of the body, which is close to the first reflecting groove, is provided with a first reflecting surface, one side of the body, which is different from the first reflecting groove, is provided with a first lens groove, one side of the body, which is close to the first reflecting groove, is provided with a first lens group, the first lens group and the first reflecting surface are aligned with each other, the second groove group is provided with a second reflecting groove and a second lens groove, one side of the body, which is close to the second reflecting groove, is provided with a second reflecting surface, one side of the body, which is different from the second reflecting groove, is provided with a second lens group, and one side of the body, which is close to the second reflecting groove, is provided with a second lens group, the second lens group and the second reflecting surface are substantially aligned with each other, and a third lens is arranged on one side of the body adjacent to the accommodating groove; and

the optical conduction assembly is arranged in the accommodating groove of the body and comprises two optical conduction pieces, the two optical conduction pieces are directly attached to the two sides of the accommodating groove through glue dispensing and correspond to the first reflecting surface and the second reflecting surface, a film layer is formed on one surface of the optical conduction pieces opposite to the two sides of the accommodating groove, light sources with different wavelengths penetrate through the film layer and reflect light sources with other wavelengths at the same time, light paths are reflected back and forth to combine light, and the light paths with different wavelengths are coupled to optical fibers in the optical fiber guide post after being converged and output.

Technical Field

The present invention relates to the field of optical transmission technology, and more particularly, to a wavelength division multiplexing optical fiber module suitable for surface emitting lasers.

Background

As shown in US20150110493a1, although the optical fiber module is suitable for wavelength division multiplexing optical paths, the optical elements (collimator, filter, and reflection surface) in the optical fiber module are all coplanar optical paths, and thus the module height is increased, and the optical fiber module cannot be miniaturized.

Disclosure of Invention

In view of the technical problems that it is difficult to achieve wavelength division multiplexing in multi-channel multi-wavelength for the optical fiber module in practical use, the height of the optical fiber module is reduced and the optical fiber module is miniaturized, the present invention has been developed to solve the problems.

The invention mainly aims to provide an optical fiber module with wavelength division multiplexing function and miniaturization of an optical fiber module.

In order to achieve the above-mentioned objectives, the present invention provides an optical fiber module, which includes a body and a light guide set.

One side of the body is provided with a first groove group and a containing groove, the first groove group is provided with a first reflecting groove and a first lens groove, a first reflecting surface is formed on one side of the body, which is close to the first reflecting groove, a first lens group is formed on one side of the body, which is different from the first reflecting groove, a first lens group is formed on one side of the body, which is close to the first reflecting groove, the first lens group and the first reflecting surface are substantially aligned with each other, and a third lens is arranged on one side of the body, which is close to the containing groove.

The light conduction assembly is arranged in the containing groove of the body and comprises a base material and at least one light conduction piece, a light reflection surface and a light penetration surface are formed on one surface of the base material, a reflection layer is arranged on one surface of the light reflection surface of the base material and used for reflecting light sources, the light penetration surface substantially corresponds to the third lens of the body, the light conduction piece is arranged on one surface of the base material, which is different from the light reflection surface, and has wavelength selectivity and is respectively formed with at least one film layer, and the film layers can be used for light sources with different wavelengths to penetrate through and reflect light sources with other wavelengths.

Preferably, the body is provided with a hollow fiber guide post protruding toward one side of the third lens, and the third lens corresponds to the fiber guide post.

Preferably, the body is integrally injection molded.

Preferably, the first reflective groove and the accommodating groove have a first included angle θ in the horizontal direction.

Preferably, the first lens group has a plurality of first lenses, so that the plurality of first lenses can respectively correspond to the light-transmitting member through the first reflecting surface of the body.

As a preferred aspect of the foregoing solution, the lens is defined as a converging lens or a collimating lens according to a different direction of the optical path, wherein when the optical path is in a forward direction, the first lens and the second lens are collimating lenses.

Preferably, the lens is defined as a converging or collimating lens according to the direction of the optical path, and the third lens is a converging lens when the optical path is a forward optical path.

Preferably, the light-transmitting member is a filter.

In order to achieve the above-mentioned objectives, the present invention provides an optical fiber module, which includes a body and a light guide set.

One side of the body is provided with a first groove, a second groove group and an accommodating groove, the first groove group is provided with a first reflecting groove and a first lens groove, one side of the body, close to the first reflecting groove, is provided with a first reflecting surface, one side of the body, different from the first reflecting groove, is provided with a first lens groove, one side of the body, close to the first reflecting groove, is provided with a first lens group, and the first lens group and the first reflecting surface are substantially aligned with each other; the second groove group is provided with a second reflecting groove and a second lens groove, a second reflecting surface is formed on one surface of the body, which is opposite to the second reflecting groove, a second lens groove is formed on one surface of the body, which is close to the second reflecting groove, a second lens group is formed on one surface of the body, which is opposite to the second reflecting groove, and the second lens group and the second reflecting surface are substantially aligned with each other.

The light transmission assembly is arranged in the accommodating groove of the body and comprises a base material and at least two light transmission pieces, one surface of the base material is provided with a light penetrating surface, the light penetrating surface substantially corresponds to the third lens of the body, the light transmission pieces are respectively arranged on one surface of the light penetrating surface of the base material and one surface different from the light penetrating surface, at least one film layer is respectively formed at the joint of the light transmission pieces and the base material, and the film layer can be used for light sources with different wavelengths to penetrate and simultaneously reflect light sources with other wavelengths.

Preferably, the body is provided with a hollow fiber guide post protruding toward one side of the third lens, and the third lens corresponds to the fiber guide post.

Preferably, the body is integrally injection molded.

Preferably, the first reflective groove and the accommodating groove have a first included angle θ in the horizontal direction.

Preferably, the second reflecting groove and the accommodating groove have a second included angle θ in the horizontal direction.

Preferably, the first included angle θ is substantially equal to the second included angle θ.

Preferably, the first lens group has a plurality of first lenses, so that the plurality of first lenses can respectively correspond to the light-transmitting member through the first reflecting surface of the body.

Preferably, the second lens group has a plurality of second lenses, so that the plurality of second lenses can respectively correspond to the light-transmitting member through the second reflecting surface of the body.

Preferably, the lens is defined as a converging or collimating lens according to the direction of the optical path, wherein the first lens and the second lens are collimating lenses when the optical path is in the forward direction.

Preferably, the lens is defined as a converging or collimating lens according to the direction of the optical path, and the third lens is a converging lens when the optical path is in the forward direction.

Preferably, the light-transmitting member is a filter.

The invention has the advantages that: the space between the light-transmitting pieces is used as a medium by air, and light sources with different wavelengths can penetrate through the space while light sources with other wavelengths are reflected. The light paths are reflected back and forth to combine light, and the light paths with different wavelengths are converged and coupled to the optical fiber output in the optical fiber guiding post to significantly increase the transmission amount of information, so that the light path with the substrate removed can achieve the effect of wavelength division multiplexing.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, a brief description will be given below of the drawings required for the embodiments or the technical solutions in the prior art, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is an exploded perspective view of a fiber optic module according to an embodiment of the present invention;

FIG. 2 is a perspective view of a fiber optic module body according to an embodiment of the present invention;

FIG. 3 is a top view of a light conducting group of a fiber optic module according to one embodiment of the present invention;

fig. 4 is a top view of the combination of the optical fiber module according to the embodiment of the present invention;

FIG. 5 is a schematic, partially cross-sectional view of a fiber optic module according to one embodiment of the present invention;

FIG. 6 is a forward optical path diagram of a fiber optic module according to an embodiment of the present invention;

FIG. 7 is a reverse light path diagram of a light conducting set for photo detection of a fiber optic module according to the present invention;

FIG. 8 is an exploded perspective view of a fiber optic module body and a light guide set according to another embodiment of the present invention;

FIG. 9 is a top perspective view of the body of the fiber optic module and the light conducting set in combination in accordance with one embodiment of the present invention;

FIG. 10 is a schematic, partially cross-sectional view of a fiber optic module according to one embodiment of the present invention;

FIG. 11 is an optical path diagram of a fiber optic module according to another embodiment of the present invention;

FIG. 12 is a reverse optical path diagram of a fiber optic module according to another embodiment of the present invention;

FIG. 13 is an exploded perspective view of a fiber optic module body according to another embodiment of the present invention;

FIG. 14 is a perspective view of a fiber optic module body according to another embodiment of the present invention;

1, a fiber optic module; 10, 10' body; 11, 11' a first groove set; 12, 12' accommodating groove; 14, 14' optical fiber guide posts; 20, 20' light conducting group; 21, 21' substrate; 22, 22' light-conducting element; 111, 111' first reflective trough; 1111, 1111' a first reflecting surface; 112, 112' a first lens groove; 1121, 1121' first lens group; 1122, 1122' first lens; 13, 13' third lens; 23, a total reflection surface; 231 a reflective layer; 24, 24' penetration surface; 31 a second groove set; 311 a second reflective trough; 3111 a second reflective surface; 312 second lens groove; 3121 a second lens group; 3122 a second lens; 25, 25' film layer; 40 optical fibers; theta₁，θ₂An included angle; λ a, λ b, λ c, λ d aggregate light source; lambda a 1-lambda a6, lambda b 1-lambda b6, lambda c 1-lambda c11 and lambda d 1-lambda d 11; a printed circuit board.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

As shown in fig. 1 to 5, a first embodiment of a fiber optic module 1 of the present invention includes: a body 10 and a light-conducting set 20.

The main body 10 is formed with a first groove set 11 and a containing groove 12, the first groove set 11 includes a first reflective groove 111 and a first lens groove 112, the first reflective groove 111 is formed on the same surface of the main body 10 as the containing groove 12, and a first included angle theta is formed between the first reflective groove 111 and the containing groove 12 on the horizontal plane₁(ii) a The first reflective groove 111 is a polygonal grooveIn the embodiment, the lens assembly 1121 includes a plurality of first lenses 1122, the first lenses 1122 are substantially aligned with the first reflecting surfaces 1111, each of the first lenses 1122 is a collimating lens, and the collimating lens is a convex lens. The main body 10 is integrally formed by plastic injection, but not limited to the above. The body 10 is provided with a third lens 13 at a side close to the accommodating groove 12, a hollow optical fiber guiding column 14 is disposed at a side of the body 10 facing the third lens 13 in a protruding manner, and the third lens 13 substantially corresponds to the optical fiber guiding column 14.

The light transmission set 20 is installed in the containing groove 12 of the body, the light transmission set 20 includes a substrate 21 and a plurality of light transmission members 22, the light transmission members 22 are filters, and the respective light transmission members 22 can respectively pass through a light source with a specific wavelength and reflect light sources with other wavelengths.

The substrate 21 has a total reflection surface 23 and a light transmission surface 24 formed on a surface thereof opposite to the first reflection groove 111, the surface of the total reflection surface 23 is plated with a reflection layer 231 (not shown) formed by a high refractive index material, the reflection layer 231 can perform total reflection on the light source, the transmission surface 24 corresponds to the optical fiber guide post 14 of the body 10, and the transmission surface 24 is used for the light source to pass through and enter, wherein the substrate 21 is made of a transparent material such as transparent glass, transparent plastic, and the like.

The light-transmitting member 22 is bonded to a surface of the substrate 21 different from the total reflection surface 23, the light-transmitting member 22 substantially corresponds to the first lens 1122 of the first lens groove 112 through the first reflection surface 1111 of the body 10, and the light-transmitting member 22 and the substrate 21 have a wavelength-selective film layer 25, i.e., a plated film, on the surface to be spot-bonded. The film layer 25 can respectively transmit light sources with specific wavelengths and reflect light sources with other wavelengths, wherein the light-transmitting member 22 is a filter. The light-conducting set 20 can be placed in the accommodating groove 12 by means of dispensing and attaching, wherein the length, width and height of the accommodating groove 12 are slightly larger than or equal to those of the light-conducting set 20, and the groove wall of the accommodating groove 12 can be used as an alignment reference surface during assembling. When the light guide set 20 is assembled, if the alignment tolerance needs to be adjusted, the light guide set can be finely adjusted in the receiving groove 12 to correct the optical path alignment error.

As shown in fig. 3, 4, 5, and 6, when the light sources λ a1 to λ a6 with different wavelengths are collimated by the first lens 1122 and then reflected by the first reflection surface 1111 of the main body 10, the light sources λ a1 to λ a6 with total reflection respectively pass through the light guide 22 and enter the base material 21, the light sources λ a1 to λ a6 with different wavelengths entering the base material 21 are combined into a polymeric light source λ a after multiple refractions of the film layer 25 and the total reflection surface 23, and the polymeric light source λ a passes through the light penetration surface 24 and then is converged by the third lens 13 and then coupled into the optical fiber 40 for transmission.

Wherein, the light sources λ a 1- λ a6 are collimated by the first lens 1122 and then turned by the first reflecting surface 1111, so that the total internal reflection of the light sources must satisfy sin (π/2- φ) >1/n.φ is an oblique angle, usually 45 °; n is the refractive index of the material, typically greater than 1.

As shown in fig. 7, the optical path of the fiber optic module 1 of the present invention is reversible and can be used for optical detection, and the second embodiment has a structure similar to that of the first embodiment, and the second embodiment uses the same element names and reference numerals as the first embodiment. The difference is that the light source of the present embodiment is a light source λ b with different wavelengths, and the light source λ b enters the body 21 through the light penetration surface 24 after being collimated by the second lens 13.

When the light source λ b travels in the substrate 21, the light sources λ b with different wavelengths can respectively pass through the corresponding light-transmitting member 22 through the refraction of the reflective layer 231 and the filtration of the film layer 25, the light source passing through the light-transmitting member 22 is refracted by the first reflective surface 1111 and collimated by the first lens 1122 to pass through the body 10, and finally the incident light source is separated into the light sources λ b with different wavelengths.

As shown in fig. 8 and 10, a fiber optic module 1 according to a third embodiment of the present invention includes: a body 10 'and a light-conducting set 20'.

The main body 10 ' is formed with a first groove 11 ', a second groove group 31 and a receiving groove 12 ', the first groove group 11 ' is provided with a first reflection groove 111 ' and a first lens groove 112 ', a first reflection surface 1111 ' is formed on one surface of the main body 10 ' adjacent to the first reflection groove 111 ', a first lens groove 112 ' is formed on one surface of the main body 10 ' adjacent to the first reflection groove 111 ', a first lens group 1121 ' is formed on one surface of the main body 10 ' adjacent to the first reflection groove 112 ', and the first lens group 1121 ' and the first reflection surface 1111 ' are substantially aligned with each other; the second groove set 31 has a second reflective groove 311 and a second lens groove 312, a second reflective surface 3111 is formed on one side of the second reflective groove 311, a second lens groove is formed on a side of the body 10 ' different from the second reflective groove 311, a second lens set 3121 is formed on a side of the body 10 ' close to the second reflective groove 311, the second lens set 3121 and the second reflective surface 3111 are substantially aligned with each other, and a third lens 13 ' is disposed on a side of the body 10 ' close to the accommodating groove 12 '.

The light-transmitting set 20 'is disposed in the receiving groove 12' of the body 10 ', the light-transmitting set 20' includes a substrate 21 'and at least two light-transmitting members 22', a light-transmitting surface 24 'is disposed on one surface of the substrate 21', the light-transmitting surface 24 'substantially corresponds to the third lens 13' of the body 10 ', the light-transmitting members 22' are respectively disposed on the same and different surfaces of the substrate 21 'and the light-transmitting surface 24', at least one film 25 'is respectively formed at the joint of the light-transmitting member 22' and the substrate 21 ', and the film 25' is capable of allowing light sources with different wavelengths to pass therethrough and reflecting light sources with other wavelengths.

The light-transmitting element 22 'substantially corresponds to the first lens 1122' of the first lens group 1121 'and the second lens 3122 of the second lens group 3121 through the first reflective surface 1111' and the second reflective surface 3111 of the body 10 ', a film layer 25' is formed on one surface of the light-transmitting element 22 'which is attached to the substrate 21', the film layer 25 'being capable of allowing light sources with specific wavelengths to pass therethrough and reflecting light sources with other wavelengths, wherein the light-transmitting element 22' is a filter.

The light-conducting set 20 'can be placed in the receiving cavity 12' by dispensing and attaching, wherein the length, width and height of the receiving cavity 12 'are slightly larger than or equal to those of the light-conducting set 20', and the walls of the receiving cavity 12 can be used as alignment reference surfaces during assembling. When the light-conducting set 20 'is assembled, if the alignment tolerance needs to be adjusted, the fine adjustment can be performed in the receiving groove 12' to correct the optical path alignment error.

As shown in fig. 10 and 11, when the light sources λ c 1- λ c11 with different wavelengths are collimated by the first lens 1122 'and the second lens 3122, respectively, and then reflected by the first reflecting surface 1111' and the second reflecting surface 3111 of the main body 10 ', the reflected light sources λ c 1- λ c11 respectively pass through the light-transmitting member 22' to enter the base material 21 ', and the light sources λ c 1- λ c11 with different wavelengths entering the base material 21' are combined into a polymeric light source λ c after being refracted by the film layer 25 'for multiple times, and the polymeric light source λ c passes through the light-transmitting surface 24' and then is converged by the third lens 13 'to be coupled to the optical fiber 40 in the optical fiber guide column 14' for outputting, so as to significantly increase the transmission amount of information.

The light sources λ c 1- λ c11 are collimated by the first lens 1122 'and the second lens 3122, and then are turned by the first reflecting surface 1111' and the second reflecting surface 3111, so that the total internal reflection of the light sources must satisfy the condition of sin (π/2- φ) >1/n, where φ is an oblique angle, usually 45 °; n is the refractive index of the material, typically greater than 1.

As shown in fig. 12, the optical path design of the optical fiber module 1 of the present invention is reversible and can be used for optical detection, and the fourth embodiment has a structure similar to that of the third embodiment, and the fourth embodiment uses the same component names and reference numerals as the third embodiment. The difference is that the light source of the present embodiment is a light source λ d with different wavelengths, and the light source λ d is collimated by the second lens 16 and then enters the body 21' through the light penetration surface 24.

When the polymeric light source λ d travels in the substrate 21 ', the light sources λ d 1- λ d11 with different wavelengths respectively pass through the corresponding light-transmitting member 22 ' through refraction and filtration of the light-transmitting member 22 '. The light source passing through the light guide 22 ' passes through the body 10 ' after being refracted by the first reflecting surface 1111 ' and the second reflecting surface 3111 and collimated by the first lens 1122 ' and the second lens 3122 ', and finally the incident converged light source λ d is separated into light sources with different wavelengths for detection by the light detecting elements of the printed circuit board.

As shown in fig. 13 and 14, the fifth embodiment of the fiber optic module 1 of the present invention, which is the fifth embodiment of the present invention, is mostly similar to the third embodiment (fig. 8), and the same names and reference numerals of the elements of the third embodiment are used for the fifth embodiment. The difference is that in the fifth embodiment, the base material 21 of the light guide set 20' can be omitted. In other words,

two light-transmitting members 22 'can be directly attached to two side surfaces of the receiving groove 122' by dispensing, and correspond to the first reflecting surface 1111 'and the second reflecting surface 3111, and a film 25' is formed on one side of the light-transmitting member 22 'opposite to the two sides of the receiving groove 122', and the light-transmitting member 22 'has a film 25' with wavelength selectivity, and the transmittance spectrum thereof is transmitted by the corresponding wavelength and reflected by other wavelengths. The pattern of the film 25 'is not a film, and the film 25' is a coating film. The space between the light-transmitting members 22' opposite to each other on two sides is used as a medium for air to penetrate through light sources with different wavelengths and reflect light sources with other wavelengths. The light paths are reflected back and forth to combine light, and the light paths of different wavelengths are converged and coupled out of the optical fiber 40 in the optical fiber guide post 14' to significantly increase the amount of information transmitted, so that the light path in the form of the removed substrate 21 can also achieve the effect of wavelength division multiplexing.

The optical fiber module can be bonded to the printed circuit board a by a Chip On Board (COB) method.

The present invention has been described in terms of the above embodiments and variations, and all embodiments and variations of the present invention are exemplary only, and all variations of the invention that include the above features are intended to be covered by the present invention based on the spirit and scope of the invention.