JPH08179151A - Optical fiber device - Google Patents

Abstract

PURPOSE: To provide an optical fiber device which is small in optical transmission loss and facilitates assembling operation as to an optical fiber device for optically coupling both a light emitting element and a light receiving element, arranged nearby each other, with an optical fiber. CONSTITUTION: This optical fiber device is equipped with a ferrule 2 formed by inserting the optical fiber 1 into the axial hole in a slanting end surface 2A slanting to the optical axis, a ferrule external cylinder 3 which has a ferrule 2 inserted into the axial hole so that the tip of the ferrule 2 projects from the end surface, a prism 20-1 in a parallelepiped or rectangular parallelepiped shape, a total reflecting film 21 which is formed on one half surface of the base 20A of the prism 20-1 rectangularly except the center part, a half-mirror film 22 which is formed on a half surface of the top surface 20B of the prism 20-1 rectangularly including the center part, and a holder 30-1 having a round hole 31 which is formed below the axial part and where the tip part of the ferrule 2 is loosely inserted and a square hole 32 which is so formed above the round hole 31 as to communicate with it and where the prism 20-1 is loosely inserted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber device for optically coupling an optical fiber with a light emitting element and a light receiving element which are arranged close to each other.

In recent years, with the demand for downsizing of bidirectional transmission communication systems, a light emitting element and a light receiving element are arranged close to each other, and one optical fiber is arranged opposite to these light emitting element and light receiving element to form a light emitting element. And the light-receiving element are alternately operated to use one optical fiber for both the transmission transmission line and the reception transmission line.

In such a bidirectional transmission communication system,
An optical fiber device that optically couples to both the light emitting element and the light receiving element is required.

[0004]

2. Description of the Related Art A conventional optical fiber device is shown in FIGS. In the figure, 51 is a light emitting element such as a semiconductor laser mounted on the end surface of the heat sink 50 at a position away from the axis. Reference numeral 52 is a light-receiving element mounted on the end surface of the heat sink 50 at a symmetrical position with the light-emitting element 51 sandwiching the axis.

Reference numeral 55 is a lens system provided with a condensing function, which is arranged so as to face the light emitting element 51 and the light receiving element 52 so that the optical axis coincides with the extension line of the axis of the heat sink 50. 2 is
This is a cylindrical ferrule made of, for example, ceramics, in which the end of the optical fiber 1 is inserted and fixed in the axial hole.

The end face of the ferrule 2 is an inclined end face 2A which is inclined at a predetermined angle (angle at which light can be transmitted to and received from the light emitting element and the light receiving element) with respect to the optical axis. Reference numeral 3 is a cylindrical ferrule outer cylinder made of metal such as stainless steel, in which the ferrule 2 is inserted and fixed in the axial center hole. The tip of the ferrule 2 is projected from the end surface of the ferrule outer cylinder 3 by several mm.

Reference numeral 10 denotes a prism having a rectangular parallelepiped shape whose one side length is substantially equal to the diameter of the ferrule 2. The refractive index of the prism 10 is equal to the refractive index of the core of the optical fiber 1. 11 is
It is a total reflection film provided on one half surface of the bottom surface 10A of the prism 10 in a rectangular shape excluding the central portion by vapor deposition or the like.

Reference numeral 12 is a rectangular half mirror film provided by vapor deposition or the like in a rectangular shape including a central portion on a half surface in a direction diagonal to the total reflection film 11 on the ceiling surface 10B. The bottom surface 10A of the above-mentioned prism 10 is brought into close contact with the inclined end surface 2A of the ferrule 2 and adhered by using a transparent adhesive (for example, a two-component epoxy resin adhesive) 15 and mounted on the ferrule 2 to replace the conventional The optical fiber device 200 is configured.

Specifically, the prism 10 is adhered to the ferrule 2 so that the total reflection film 11 is in close contact with the surface of the ferrule 2 on the side where the inclined end surface 2A of the ferrule 2 expands. In addition, transparent adhesive
The refractive index of 15 is approximately equal to the refractive index of the prism 10.

The optical path of the optical fiber device 200 configured as described above will be described below with reference to FIG. The light emitted from the light emitting element 51 (a light beam that expands) becomes a beam that converges by passing through the lens system 55, as shown by the solid line, and the ceiling surface 10B of the prism 10 (the half mirror film 12 is not formed). It is projected on the ceiling surface part, refracted at the boundary surface, travels through the prism 10, and reaches the bottom surface 10A (total reflection film).
Reach the bottom surface where 11 is formed). Then, the light is reflected by the total reflection film 11 and reaches the portion of the half mirror film 12 provided on the ceiling surface 10B (the portion on the extension line of the optical axis of the optical fiber 1).

Almost half the optical power of the light reaching the half mirror film 12 is reflected by the half mirror film 12 in a direction coinciding with the optical axis of the optical fiber 1, and the prism 10 and the transparent adhesive 15 are reflected.
The optical fiber 1 to collect light at the end face of the optical fiber 1.
To proceed.

The remaining half of the light power reaching the half mirror film 12 is transmitted through the half mirror film 12 and travels out of the prism 10. On the other hand, the light emitted from the optical fiber 1 (a light beam that spreads) advances straight through the transparent adhesive 15 and the prism 10 as shown by the dotted line, and reaches the ceiling surface 10B. Almost half the optical power of the light reaching the ceiling surface 10B is transmitted through the half mirror film 12 and is displaced from the optical axis of the optical fiber 1 by an angle corresponding to the refractive index of the prism 10 (light receiving element).
52 direction parallel to the optical axis). And lens system
The light beam is converged by 55 and is condensed on the light receiving surface of the light receiving element 52.

The remaining half of the optical power of the light emitted from the optical fiber 1 and reaching the half mirror film 12 is reflected by the half mirror film 12 and traces the optical path of the light emitted from the light emitting element 51 to emit light. The light is condensed on the emission surface of the element 51. However, when the light-receiving element 52 is operating, the light-emitting element 51 is in a non-operating state, so that even if a part of the light emitted from the optical fiber 1 reaches the light-emitting element 51, the transmission / reception function is not hindered.

[0014]

In the conventional optical fiber device in which the ferrule and the prism using the above-mentioned transparent adhesive are fixed, as shown in FIG. 9, a paste-like transparent adhesive is applied. When doing so, bubbles K in the transparent adhesive
₁ or impurities K ₂ are easily mixed. If air bubbles K ₁ or impurities K ₂ are scattered on the optical path of the transparent adhesive, the light transmitted through the transparent adhesive may be scattered by the air bubbles or reflected by the impurities, resulting in optical transmission loss. To increase.

The paste-like transparent adhesive has a long curing time of several hours. Therefore, the conventional optical fiber device has a problem in that it requires a degassing step of the transparent adhesive, a means for preventing impurities from entering, and the like in the assembling process, which requires much time for assembling.

The present invention was created in view of the above points, and it is an object of the present invention to provide an optical fiber device which has a small optical transmission loss and is easy to assemble.

[0017]

In order to achieve the above object, the present invention, as illustrated in FIG. 1, has an end face which is an inclined end face inclined with respect to the optical axis, and an optical fiber 1 is provided in an axial hole. The ferrule 2 inserted and the cylindrical ferrule outer tube 3 inserted in the axial hole so that the tip of the ferrule 2 projects from the end surface, and the refraction index equal to or almost equal to the refractive index of the core of the optical fiber 1. Parallelepiped or rectangular prism 20-1
And a total reflection film 21 formed in a rectangular shape excluding the central portion on one half surface of the bottom surface 20A of the prism 20-1, and the total reflection film 21 is a rectangular shape including the central portion on the half surface of the ceiling surface 20B in the diagonal direction. A half mirror film 22 formed in a shape, and a round hole 31 in which the tip of the ferrule 2 is loosely inserted in the lower part of the axial center, and a prism 20-1 is inserted and fixed above the round hole 31 to fix the prism 20-1. And a cylindrical holder 30-1 having 32.

In the prism 20-1, the outer peripheral portion is fixed to the upper end surface portion of the holder 30-1 with the surface of the total reflection film 21 provided on the bottom surface 20A being in close contact with the inclined end surface 2A of the ferrule 2. The holder 30-1 is configured to be fixed to the ferrule outer cylinder 3 with its lower end surface abutting on the upper end surface of the ferrule outer cylinder 3.

The ferrule outer cylinder is made of a metal material,
The holder and the ferrule outer cylinder are laser-welded. Furthermore, the outer peripheral portion of the prism is fixed to the end face portion of the holder with an ultraviolet curable adhesive 35.

Alternatively, a rectangular dummy total reflection film 23 except the central portion is provided on the bottom surface 20A of the prism 20-1 so as to face the total reflection film 21. As illustrated in FIG. 5, the holder
30-2 is made of a glass material, and the lower end surface of the holder 30-2 is fixed to the upper end surface of the ferrule outer cylinder 3 with an ultraviolet curable adhesive 35.

As illustrated in FIG. 6, a circular half mirror film 22-2 is formed in the center of the ceiling surface of the prism 20-2 instead of the rectangular half mirror film, and the bottom surface of the prism 20-2 is formed. In place of the rectangular total reflection film, a total reflection film 21-2 is formed on the entire surface except the central portion.

Alternatively, the prism is a slanted cylinder having a slanted bottom surface and a slanted ceiling surface that are parallel to each other, and the holder is
The ferrule has a round hole into which the tip portion is loosely inserted, and a round hole into which a prism having an oblique column shape is inserted and fixed is provided above the round hole.

[0023]

According to the present invention, when the prism is fitted in the square hole (or round hole) of the holder and the lower surface of the total reflection film formed on a part of the bottom surface is in close contact with the inclined end surface of the ferrule, the prism is held by the holder. The holder is further fixed to the ferrule outer cylinder.

There is a gap having a thickness equal to the thickness of the total reflection film between the end face of the optical fiber and the bottom face of the prism, but there is no possibility that dust or the like will enter this gap. Therefore, since the light passing through this gap is not scattered, the optical transmission loss does not increase.

By providing a dummy total reflection film on the bottom surface of the prism, or by providing a total reflection film on the entire bottom surface except the central portion, the prism comes into stable contact with the inclined end surface of the ferrule.

On the other hand, the ultraviolet curable adhesive has the property of being cured in a short time by irradiating with ultraviolet rays.
Therefore, since the prism and the holder are fixed to each other by the ultraviolet curable adhesive, the time required for the assembling work is short.

Further, when the holder is made of a glass material, since ultraviolet rays pass through the holder, the ultraviolet curable adhesive can be applied to the fixing of the holder and the ferrule outer cylinder, and the working time is further shortened.

Further, when the prism having the oblique column shape is used, it suffices to provide a circular hole at the axial center of the holder, and the processing man-hour is shortened as compared with the holder having the square hole.

[0029]

The present invention will be described in detail with reference to the drawings. The same reference numerals indicate the same objects throughout the drawings.

FIG. 1 is a sectional view of an embodiment of the present invention, FIG. 2 is a perspective view showing the present invention in a separated form, FIG. 3 is a view showing an assembling process of the present invention, and FIG. 4 is a manufacturing process of a prism. It is a figure. 5 is a cross-sectional view of another embodiment of the present invention, FIG. 6 is a view of yet another embodiment of the present invention, (A) is a cross-sectional view, (B)
[Fig. 3] is a perspective view of a prism.

As shown in FIG. 1, a light emitting element 51 such as a semiconductor laser is mounted on the end surface of the heat sink 50 at a position distant from the axis, and the light receiving element is placed at a position symmetrical with the axis of the light emitting element 51. 52 is implemented.

A lens system 55 having a condensing function is arranged facing the heat sink 50 so that the optical axis coincides with the extension of the axis of the heat sink 50. Optical fiber 1 in the shaft hole
The end face of the cylindrical ferrule 2 made of, for example, ceramics, into which the end of is inserted and fixed, is an inclined end face 2A inclined at a predetermined angle (angle at which light can be transmitted to and received from the light emitting element and the light receiving element) with respect to the optical axis. .

Reference numeral 3 denotes a cylindrical ferrule outer cylinder made of a metal such as stainless steel in which the ferrule 2 is fixedly inserted in the axial hole, and the tip of the ferrule 2 is several mm from the end surface of the ferrule outer cylinder 3. It is protruding.

In FIGS. 1 and 2, 20-1 is an optical fiber 1.
Is a parallelepiped prism having a refractive index equal to or almost equal to the refractive index of the core of, and a rectangular total reflection film 21 excluding the central portion is provided on one half surface of the bottom surface 20A of the prism 20-1 for total reflection. A rectangular dummy total reflection film 23 excluding the central portion is provided on the opposite side of the film 21.

The prism 20-1 is provided with a rectangular half mirror film 22 including a central portion on a half surface of a ceiling surface 20B which is diagonal to the total reflection film 21 on the bottom surface 20A. 30-1 is a cylindrical holder made of a metal material such as stainless steel, and its outer diameter is made equal to the outer diameter of the ferrule outer cylinder 3.

The holder 30-1 is not limited to the cylindrical shape, but as will be described later, the V-groove block can be used for the assembling work, which facilitates the assembling. Therefore, the cylindrical shape is preferable.

A round hole 31 into which the tip of the ferrule 2 is loosely inserted is provided below the axial center of the holder 30-1, and a square hole 32 into which the prism 20-1 is fitted is provided above the round hole 31. There is. A round hole
The diameter of 31 is slightly larger than the diagonal length of square hole 32.

The holder 30-1 made of a metal material is laser-welded (with the welding point at the welding point) with the round hole 31 fitted in the tip of the ferrule 2 and the lower end surface abutting the upper end surface of the ferrule outer cylinder 3. (Shown by a point P) and is fixed to the ferrule outer cylinder 3.

The prism 20-1 is fitted into the square hole 32 of the holder 30-1, and the bottom surface 20A abuts the inclined end surface 2A of the ferrule 2 (specifically, the lower surfaces of the total reflection film 21 and the dummy total reflection film 23 are While being in close contact with the inclined end surface 2A), the ultraviolet curable adhesive 35 filled in the edge groove 33 above the square hole 32 is fixed to the holder 30-1.

As described above, the optical fiber device 100 is constructed by assembling the ferrule 2, the ferrule outer cylinder 3, the metal material holder 30-1 and the prism 20-1. Light emitting element 5
1, by tilting the optical axis of the optical fiber 1 with respect to the optical axis of the light receiving element 52 by a predetermined angle (a predetermined angle set from the refractive index of the prism and the angle of the inclined end face of the ferrule), the optical fiber device 100 is mounted. Deploy.

When the optical fiber device 100 is arranged in this way, the light emitted from the light emitting element 51 (a light beam that expands) is
As shown by the solid line, when it passes through the lens system 55, it becomes a convergent beam that is projected onto the ceiling surface 20B of the prism 20-1 (the ceiling surface portion where the half mirror film 22 is not formed) and is refracted at the boundary surface. Prism 20-1 and proceed to bottom 20A
(Bottom part where the total reflection film 21 is formed).

The light is reflected by the total reflection film 21 and reaches the portion of the half mirror film 22 provided on the ceiling surface 10B (the portion on the extension line of the optical axis of the optical fiber 1). Almost half the optical power of the light reaching the half mirror film 22 is reflected by the half mirror film 22 in the direction coinciding with the optical axis of the optical fiber 1, travels through the prism 20-1, and is reflected by the end face of the optical fiber 1. The light is collected and travels through the optical fiber 1.

The remaining half of the light power reaching the half mirror film 22 passes through the half mirror film 22 and travels out of the prism 20-1. On the other hand, the light emitted from the optical fiber 1 (a light beam that expands) goes straight through the prism 20-1 as shown by the dotted line and reaches the ceiling surface 20B. Ceiling surface 20B
Almost half the optical power of the light that reaches the optical axis passes through the half mirror film 22 and is displaced from the optical axis of the optical fiber 1 by an angle corresponding to the refractive index of the prism 20-1 (parallel to the optical axis of the light receiving element 52). Direction). Then, it becomes a light beam that is converged by the lens system 55 and is condensed on the light receiving surface of the light receiving element 52.

The remaining half of the power of the light emitted from the optical fiber 1 and reaching the half mirror film 22 is reflected by the half mirror film 22 and traces the optical path of the light emitted from the light emitting element 51 to emit light. The light is condensed on the emission surface of the element 51. However, when the light-receiving element 52 is operating, the light-emitting element 51 is in a non-operating state, so that even if a part of the light emitted from the optical fiber 1 reaches the light-emitting element 51, the transmission / reception function is not hindered.

The optical fiber device 100 includes the prism 20-1.
Film 21 between the bottom surface 20A of the ferrule 2 and the inclined end surface 2A of the ferrule 2
Although there is a small void equal to the film thickness of, the outer periphery of this void is blocked by the holder 30-1. Therefore,
Since dust or the like does not enter the gap, the light passing through the gap is not scattered and the optical transmission loss does not increase.

Further, since the prism and the holder are fixed to each other by the ultraviolet curable adhesive, the time required for the assembling work is short. The ferrule 2 including the end face of the optical fiber 1
Anti-reflection film on the inclined end face 2A of the prism 20-1 and the bottom face 20A of the prism 20-1.
Antireflection film in the center of the
The optical coupling loss is reduced by providing the antireflection films on the inner portions of 22.

Assembly of the optical fiber device 100 will be described below. After the prism 20-1 is inserted into the square hole 32 of the holder 30-1, the round hole 31 of the holder 30-1 is inserted into the tip of the ferrule 2 and the lower end surface of the holder 30-1 is attached to the ferrule outer cylinder 3. Abut the upper end surface of. At this time, it is preferable to insert the holder 30-1 into the front end of the ferrule 2 at a relative position so that the bottom surface 20A of the prism 20-1 is substantially parallel to the inclined end surface 2A of the ferrule 2.

Next, a finger or the like presses the ceiling surface 20B of the prism 20-1. As a result, the holder 30-1 rotates and the bottom surface 20A
Closely contacts the inclined end face 2A of the ferrule 2. Then the holder 30
The paste-like ultraviolet curable adhesive 35 is poured into the edge groove 33 of -1 and irradiated with ultraviolet rays to cure the ultraviolet curable adhesive 35.

Next, as shown in FIG. 3, a pair of V-groove blocks 45 and 46 are used, and the V-grooves 45A and 46 facing each other are provided.
Insert the ferrule outer cylinder 3 and the holder 30-1 together at A.
As described above, since the outer diameter of the holder 30-1 and the outer diameter of the ferrule outer cylinder 3 are equal, a pair of V groove blocks 45, 4 are provided.
When sandwiched by 6, the axis of the holder 30-1 and the axis of the ferrule outer cylinder 3 are aligned. Therefore, the optical axis of the optical fiber 1 coincides with the center of the bottom surface 20A of the prism 20-1.

While sandwiched between the pair of V-groove blocks 45 and 46, the contact portion between the ferrule outer cylinder 3 and the holder 30-1 is laser-welded and fixed. The prism is manufactured as shown in FIG.

As shown in FIG. 4A, a plurality of strip-shaped half mirror films 22 are formed on the upper surface of the prism base material 40 at equal pitches.
Is provided by vapor deposition or the like. Also, on the lower surface of the prism base material 40,
A plurality of strip-shaped total reflection films 21 are provided by vapor deposition or the like, with a shift of approximately half a pitch from the half mirror film 22.

As shown in FIG. 4B, the prism base material 40 is placed on the base 42 whose upper surface is inclined at a predetermined angle with respect to the bottom surface, and one side of each half mirror film 22 is placed. Cut along the edge (indicated by dotted lines A ₁ , A ₂ , ...) To make a parallelepiped elongated rod-shaped body.

When cut as described above, the total reflection film 21 formed on the lower surface is divided into a total reflection film and a dummy total reflection film. Next, the rod-shaped body is cut into a predetermined length (dotted line B
There is a half mirror film 22 on the ceiling surface 20B and the bottom surface 20B.
A parallelepiped prism 20-1 having a total reflection film 21 facing the A and a dummy total reflection film 23 is provided.

The optical fiber device 110 shown in FIG. 5 is a combination of an oblique column prism 20-3 and a holder 30-2 made of a glass material. The inclined ceiling surface 20B-3 and the inclined bottom surface 20A-3 of the oblique column prism 20-3 are parallel to each other, and the outer diameter of the oblique column prism 20-3 is equal to or larger than the outer diameter of the ferrule 2. Slightly small.

Inclined ceiling surface 20B- of the oblique column prism 20-3
A half-mirror-shaped half mirror film 22 having a size including the central part is provided on the half surface of 3, and a half-moon-shaped total reflection film 21 having a size not including the central part is provided on both sides of the inclined bottom surface 20A-3. A dummy total reflection film 23 is provided.

The holder 30-2 made of a cylindrical glass material is
A round hole 31-3 into which the tip of the ferrule 2 is loosely inserted is provided in the axial center. The upper portion of the round hole 31-3 is a portion into which the oblique column prism 20-3 is fitted.

The holder 30-2 made of glass material has a round hole 31-3.
Is inserted into the tip of the ferrule 2 and the lower end surface of the ferrule outer tube 3 is in close contact with the upper end surface of the ferrule outer tube 3.
Are bonded by an ultraviolet curable adhesive 35 interposed between the upper end surface of the above and the lower end surface of the oblique columnar prism 20-3.

The oblique column prism 20-3 is provided in the holder 30.
-2 fitted in the round hole 31-3 and the bottom surface 20A-3 abutting the inclined end surface 2A of the ferrule 2, the edge groove 33 above the round hole 31-3.
Holder 30-2 with UV curable adhesive 35 filled inside
It is stuck to.

As described above, since the holder 30-2 is made of the glass material, there is an advantage that the holder and the ferrule outer cylinder can be fixed to each other with the ultraviolet curable adhesive. Further, since the prism is formed in the oblique column shape, it is only necessary to provide a circular hole in the axial center of the holder, and the number of processing steps can be shortened as compared with the holder having the square hole.

The optical fiber device shown in FIG. 6 comprises a prism 20-2 having a rectangular parallelepiped shape and a holder 30 made of a cylindrical metal material.
It is a combination of -1 and. The holder 30-1 is provided with a round hole 31 at the lower part of the axial center, which is fitted into the tip of the ferrule 2.
A square hole 32A into which the prism 20-2 is fitted is provided above the round hole 31. The axis of the square hole 32A is inclined with respect to the axis of the round hole 31 by an angle equal to the inclination angle of the inclined end surface 2A of the ferrule 2.

A circular half mirror film 22-2 is provided at the center of the ceiling surface of the prism 20-2, and a total reflection film 21-2 is provided on the entire surface of the prism 20-2 except for the center thereof. Holder 30-1
Is laser-welded and fixed to the ferrule outer cylinder 3 in a state where the round hole 31 is fitted into the front end portion of the ferrule 2 and the lower end surface is in contact with the upper end surface of the ferrule outer cylinder 3.

The prism 20-2 is fitted into the square hole 32A of the holder 30-1, and the bottom of the prism 20-2 is in contact with the inclined end face of the ferrule 2. It is stuck to 30-1.

As described above, the prism has a rectangular parallelepiped shape, the circular half mirror film is provided on the ceiling surface, and the total reflection film is provided on the entire bottom surface except the central portion. However, there is an advantage that the manufacturing work of the prism is simple.

[0064]

Since the optical fiber device of the present invention is constructed as described above, it has the following effects.

Since there is no possibility that dust or the like will enter between the end faces of the prism and the ferrule, the optical transmission loss does not increase. Since the prism is inserted into the hole of the holder and the prism is fixed to the holder using the ultraviolet curable adhesive, the work of aligning and fixing the prism and the ferrule is easy and the work time is short.

When the holder is made of a glass material, the holder can be fixed to the ferrule outer cylinder by using an ultraviolet curable adhesive, and the assembling work is further shortened. By adopting the prism of the oblique cylinder shape, the man-hours for processing the holder are reduced.

[Brief description of drawings]

FIG. 1 is a sectional view of an embodiment of the present invention.

FIG. 2 is a perspective view showing the present invention in a separated form.

FIG. 3 is a diagram showing an assembly process of the present invention.

FIG. 4 is a diagram showing a manufacturing process of the prism.

FIG. 5 is a sectional view of another embodiment of the present invention.

6A and 6B are views of still another embodiment of the present invention, in which FIG. 6A is a sectional view and FIG. 6B is a perspective view of a prism.

FIG. 7 is a configuration diagram of a conventional example.

FIG. 8 is a perspective view of a conventional prism.

FIG. 9 is a diagram showing a main part of a conventional example.

[Explanation of symbols]

 1 Optical fiber 2 Ferrule 3 Ferrule Outer cylinder 10, 20-1, 20-2 Prism 11, 21, 21-2 Total reflection film 12, 22, 22-2 Half mirror film 15 Transparent adhesive 20-3 Oblique cylinder type Prism 23 Dummy total reflection film 30-1, 30-2 Holder 31, 31-3 Round hole 32, 32A Square hole 35 UV curable adhesive 40 Prism base material 45, 46 V groove block 50 Heat sink 51 Light emitting element 52 Light receiving element 55 Lens system 100,110,200 Optical fiber device

 ─────────────────────────────────────────────────── ─── Continuation of front page (72) Kazuhiko Kobayashi, Kazuhiko Kobayashi, 2-chome, Kitaichijo Nishi, Chuo-ku, Sapporo City, Hokkaido Fujitsu Hokkaido Digital Technology Co., Ltd. Address 1015 within Fujitsu Limited

Claims (7)

[Claims] 1. A ferrule in which an end face is an inclined end face inclined with respect to an optical axis, and an optical fiber is inserted in an axial center hole, and a tip end of the ferrule is inserted in the axial center hole so as to protrude from the end face. A cylindrical ferrule outer cylinder, a parallelepiped or rectangular parallelepiped prism having a refractive index equal to or substantially equal to that of the core of the optical fiber, and a rectangular shape excluding the central portion on one half surface of the bottom surface of the prism. A total reflection film formed in a shape, a half mirror film formed in a rectangular shape including a central portion on a half surface of a ceiling surface of the prism in a diagonal direction, and a total reflection film formed on a lower portion of an axial center portion. A cylindrical holder having a round hole into which the tip of the ferrule is loosely inserted, and a square hole into which the prism is fitted and fixed is provided above the round hole. With the surface of the reflective film in close contact with the inclined end face of the ferrule, The outer peripheral portion is fixed to the end surface portion of the holder, and the holder is fixed to the ferrule outer cylinder with the lower end surface abutting the upper end surface of the ferrule outer cylinder. Characteristic optical fiber device. 2. The ferrule outer cylinder is made of a metal material,
An optical fiber device, wherein the holder and the ferrule outer cylinder are laser-welded. 3. An optical fiber device, wherein an outer peripheral portion of the prism is fixed to an end surface portion of the holder by an ultraviolet curable adhesive. 4. The optical fiber device according to claim 1, wherein a rectangular dummy total reflection film excluding the central portion is formed on the bottom surface of the prism so as to face the total reflection film. 5. An optical fiber device, wherein the holder according to claim 1 or 2 is made of a glass material, and a lower end surface of the holder is fixed to an upper end surface of a ferrule outer cylinder by an ultraviolet curable adhesive. 6. A circular half mirror film is formed in the center of the ceiling surface of the prism instead of the rectangular half mirror film, and the bottom surface of the prism is totally reflected on the entire surface except the center. The optical fiber device according to claim 1, 2, or 5, wherein a film is formed. 7. The prism is an oblique cylinder having an inclined bottom surface and an inclined ceiling surface which are parallel to each other, and the holder has a round hole into which a tip portion of a ferrule is loosely inserted, and the holder is provided above the round hole. 7. The optical fiber device according to claim 1, wherein the optical fiber device has a round hole into which the prism having an oblique columnar shape is inserted and fixed.