JPH0611629A - Optical element/optical fiber assembly and its assembling and adjusting method - Google Patents

Abstract

PURPOSE:To enhance the optical coupling efficiency and to facilitate the adjusting operation of the optical element/optical fiber assembly which optically couples the optical element, such as light emitting element, light receiving element and optical waveguide and the optical fiber via two lenses and its assembling and adjusting method. CONSTITUTION:This assembly has an optical element/lens assembly 1 which is constituted by optically coupling the optical element and the lens 15 housed and fixed into an assembly case 10 in such a manner that an emitted or received light beam passes the hole on the side wall, the lens/optical fiber assembly 20 which is constituted by optically coupling the lens 25 and the optical fiber 5 inserted into the axial central hole of a holder 21, a first wedge-shaped glass plate 31 which is housed and fixed into the axial central hole of a first holder 35 and a second wedge-shaped glass plate 32 which is housed and fixed into the axial central hole of a second holder 37. The optical element/lens assembly 1 and the lens/optical fiber assembly 20 are optically coupled via the first and second wedge-shaped glass plates 31, 32.

Description

Detailed Description of the Invention

[0001]

The present invention relates to a light emitting element, a light receiving element,
The present invention relates to an optical element / optical fiber assembly in which an optical element such as an optical waveguide and an optical fiber are optically coupled via two lenses, and an assembly and adjustment method thereof.

[0002]

2. Description of the Related Art FIG. 5 is a view of a conventional example, (A) is a plan sectional view, and (B) is a side sectional view of an optical element / lens assembly.

In FIG. 5, reference numeral 2 is an optical waveguide provided on the surface of the waveguide substrate 2A. 11 is an angle-shaped base made of stainless steel or the like. The vertical plate member of the base 11 is provided with a hole into which a lens holder 13 described later is inserted and fixed.

Reference numeral 15 denotes a lens which is inserted into the shaft center hole of a cylindrical lens holder 13 with a collar made of stainless steel or the like. Reference numeral 1 is an optical element / lens assembly in which an optical waveguide 2 and a lens 15 are combined so as to be optically coupled.

Although the optical waveguide 2 is exemplified as the optical element, this optical element may be a light emitting element or a light receiving element.
The optical waveguide substrate 2A is arranged so that the end surface of the optical waveguide 2 faces the vertical plate member of the base 11 and is located at a predetermined distance (a position where the end surface of the optical waveguide is located at the focal position of the lens 15).
The bottom surface of is fixed to the bottom plate member of the base 11.

Then, the lens holder 13 is inserted into the hole of the vertical plate member of the base 11, and the lens holder 13 is finely moved and adjusted in the XY plane in a state where the flange is in contact with the vertical surface. The optical axis of the optical waveguide 2 and the optical axis of the lens 15 are aligned with each other, and in this state, the lens holder 13 is fixed to the vertical plate member by laser welding or the like.

Therefore, the light emitted from the optical waveguide 2 becomes a parallel beam by the lens 15. Further, the parallel beam projected on the lens 15 from the side opposite to the optical waveguide 2 is condensed on the end face of the optical waveguide 2 and travels through the optical waveguide 2.

Reference numeral 10 denotes a box-shaped assembly case made of stainless steel or the like, and a side wall 10B is provided with a stepped hole 14 whose step end surface is slightly inclined with respect to the axis. 16 is
It is a window glass made of sapphire or the like through which a light beam passes. The window glass 16 is attached to the step end surface of the stepped hole 14.

The optical element / lens assembly 1 is housed in the assembly case 10 so that the optical axis of the lens 15 and the center of the window glass 16 are aligned, and the base 11 is the bottom plate of the assembly case 10.
Optical element by screwing or soldering to 10A
The lens assembly 1 is fixed to the assembly case 10.

On the other hand, 6 is a ferrule in which the optical fiber 5 is inserted into the fine axial hole. The end surface of the ferrule 6 is finished by polishing or the like so as to match the end surface of the optical fiber 5.

The ferrule 6 is inserted and fixed in the shaft center hole of the cylindrical holder 7 made of stainless steel or the like. On the other hand, the lens 25 is press-fitted into the shaft hole of the lens holder 17 made of stainless steel or the like.

The position of inserting the lens 25 into the axial center hole is such that the end face of the optical fiber 5 coincides with the focus of the lens 15 when the end face of the holder 7 is brought into contact with the end face of the lens holder 17. It is a predetermined position.

One end face of the lens holder 17 is brought into contact with the outer end face of the side wall 10B of the assembly case 10,
17 is fixed to the side wall 10B by laser welding or the like. In addition, the end surface of the holder 7 is brought into contact with the other end surface of the lens holder 17,
The holder 7 is fixed to the lens holder 17 by laser welding or the like.

As described above, the optical element / lens assembly 1
The optical element / optical fiber assembly formed by combining the optical fiber 5 and the optical fiber 5 is optically coupled as described below. The light emitted from the optical waveguide 2 is converted into a parallel beam by the lens 15, passes through the window glass 16, and is projected on the lens 25.
The light is condensed at the end face of the optical fiber 5 by. Therefore, the optical fiber 5 is advanced.

On the other hand, the light emitted from the optical fiber 5 becomes a parallel beam by the lens 25, is projected onto the lens 15 through the window glass 16, and is condensed by the lens 15 on the end face of the optical waveguide 2. Therefore, the optical waveguide 2 advances.

[0016]

By the way, the outer surface of the side wall of the assembly case (the surface to which the end surface of the lens holder is brought into close contact) is accurately aligned with the optical axis of the optical element / lens assembly, that is, the optical axis of the optical waveguide. It is extremely difficult to machine so that

Due to this, the optical axis of the optical element / lens assembly and the optical axis of the optical fiber intersect without being parallel to each other, and there is a so-called angular deviation. Conventionally, while the light is emitted from the optical waveguide and the optical power is observed at the end side of the optical fiber, the lens holder 17 is finely moved in the XY plane to set the axis of the lens 25 to the optical element. By shifting from the axis of the lens 15 of the lens assembly and making the optical axis of the light beam emitted from the lens 25 parallel to the Z axis to adjust the angular deviation, the ferrule can be finely moved in the XY plane. ,
The misalignment between the optical axis of the lens 25 and the optical axis of the optical fiber is adjusted to maximize the optical power emitted from the optical fiber.

In the conventional method for adjusting the angle deviation and the axis deviation, the lens holder 17 and the ferrule 6 are alternately moved finely as described above, and the adjustment work is difficult and takes a lot of time. was there.

The present invention was made in view of the above points, and it is an object of the present invention to provide an optical element / optical fiber assembly having a high optical coupling efficiency, and another object is to make adjustment work relatively easy. An object of the present invention is to provide a method for assembling and adjusting an optical element / optical fiber assembly.

[0020]

In order to achieve the above object, the present invention is directed to an assembly case as shown in FIG. 1 so that a light beam to be emitted or received may pass through a hole in the side wall 10B. An optical element / lens assembly 1 in which an optical element housed and fixed in 10 and a lens 15 are optically coupled, and a holder
The lens / optical fiber assembly 20 formed by optically coupling the lens 25 and the optical fiber 5 that are inserted into the axial center hole of 21 so as to face each other, and the stepped axial center hole of the first holder 35, The first wedge-shaped glass plate 31 housed and fixed, and the second wedge-shaped glass plate housed and fixed in the stepped shaft hole of the second holder 37.
32 is provided, and the optical element / lens assembly 1 and the lens / optical fiber assembly 20 are the first and second wedge-shaped glass plates.
It is configured to be optically coupled via 31,32.

As the adjusting means, the first holder 35 is fitted with the frustoconical convex surface 35A of the first holder 35 fitted to the frustoconical concave surface 19 provided around the hole of the side wall 10B of the assembly case 10. A frustoconical concave surface provided on the end surface on the opposite side of the frustoconical convex surface 35A of the first holder 35 while rotating as desired.
The light beam is made parallel to the Z-axis by rotating the second holder 37 as desired with the truncated cone-shaped convex surface 37A centered on the axis of the second holder 37 fitted in the 35B.

With the end face of the holder 21 of the lens / optical fiber assembly 20 in contact with the end face of the second holder 37 opposite to the frustoconical convex face 37A, the holder 21 is finely moved in the XY plane. It is assumed that the optical axis of the lens / optical fiber assembly 20 and the optical axis of the optical element / lens assembly 1 coincide with each other by moving.

Further, as illustrated in FIG. 2, the light beam to be emitted or received is passed through the hole of the side wall 10B,
Optical element and lens housed and fixed in assembly case 10
An optical element / lens assembly 1 formed by optically coupling 15 and
The lens / optical fiber assembly 20 is formed by optically coupling the lens 25 and the optical fiber 5 which are inserted into the shaft hole of the holder 21 so as to face each other, and the wedge-shaped lens and optical fiber assembly 20 of the holder 40. The first and second wedge-shaped glass containers 45 and 47 arranged so that their side end faces are orthogonal to each other, and the desired refractive index formed by housing and sealing in the first and second wedge-shaped glass containers 45 and 47, respectively. Solution of 4
6, 48, and the optical element / lens assembly 1 and the lens / optical fiber assembly 20 are
Optically coupled via the wedge-shaped glass containers 45, 47 of.

The adjusting means is the first wedge-shaped glass container 45.
Adjusting the concentration of the solution 46 in the first wedge-shaped glass container 45
Is adjusted so that the traveling direction of the light beam is parallel to the XZ plane.

Next, the solution in the second wedge-shaped glass container 47
Adjust the concentration of 48 and adjust the traveling direction of the light beam by the second wedge-shaped glass container 47 to be parallel to the YZ plane,
The light beam is made parallel to the Z axis.

The lens / optical fiber assembly 20
With the end face of the holder 21 in contact with the end face of the holder 40, the holder 21 is finely moved in the XY plane, and the optical axis of the lens / optical fiber assembly 20 and the optical element / lens assembly 1 are moved. Match the axis.

[0027]

According to the first and second aspects of the invention, as shown in FIG. 3, visible light is emitted from both the optical element / lens assembly 1 and the lens / optical fiber assembly 20, and the first wedge-shaped glass plate 31 is used. The screen S is provided between the second wedge-shaped glass plates 32.
Is inserted so as to be orthogonal to the Z axis, and the angular deviation is adjusted.

The light emitted from the optical element / lens assembly 1 and projected onto the screen S through the first wedge-shaped glass plate 31 is rotated by rotating the first wedge-shaped glass plate 31 about the Z-axis. The locus becomes a circle Q ₁ on S.

The optical axis of the light emitted from the optical element / lens assembly 1 is not always parallel to the Z axis.
In addition, the second light emitted from the lens / optical fiber assembly 20
The light projected on the screen S through the wedge-shaped glass plate 32 of No. 2 is rotated on the Z-axis of the second wedge-shaped glass plate 32, and the locus thereof is a circle Q ₂ on the screen S.

[0030] The lens / optical fiber assembly 20
The optical axis of the light emitted from is almost parallel to the Z axis. That
And yen Q₁And yen Q₂Project each emitted light at the intersection of
So that the first wedge-shaped glass plate 31 and the second wedge-shaped glass
Rotate each plate 32.

As a result, the angular displacement between the optical element / lens assembly 1 and the lens / optical fiber assembly 20 is adjusted. Next, attach the lens / optical fiber assembly 20 to the X
-The axis shift is adjusted by finely moving on the Y plane.

On the other hand, in claims 3 and 4, it is assumed that light is emitted from the optical waveguide and is adjusted while observing the optical power at the end side of the optical fiber. At this time, the refractive index of each of the solutions is changed by changing the concentration of each of the solutions housed and sealed in the first and second wedge-shaped glass containers, so that the angle deviation can be easily adjusted.

That is, after adjusting the angle deviation with respect to the XZ plane, the angle deviation with respect to the YZ plane is adjusted, and finally the axis deviation is adjusted. The procedure is simple and the adjustment work is short.

[0034]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be specifically described below with reference to FIGS. The same reference numerals denote the same objects throughout the drawings.

FIG. 1 is a sectional view of an embodiment of the present invention, FIG. 2 is a sectional view of another embodiment of the present invention, FIG. 3 is a view for explaining the operation of the present invention, and FIG. 4 is an adjusting procedure of the present invention. It is a figure explaining.
In FIG. 1, an optical element / lens assembly 1 is constructed by combining an optical waveguide 2 and a lens 15 so as to be optically coupled.

More specifically, the end face of the optical waveguide 2 is opposed to the vertical plate member of the base 11 and is located at a predetermined distance (a distance such that the end face of the optical waveguide is located at the focal position of the lens 15). Further, the bottom surface of the optical waveguide substrate 2A is fixed to the bottom plate member of the base 11.

Then, the lens holder 13 is inserted into the hole of the vertical plate member of the base 11, and the lens holder 13 is finely moved in the XY plane with the flange of the lens holder 13 being in contact with the vertical surface. After adjustment, the optical axis of the optical waveguide 2 and the optical axis of the lens 15 are aligned with each other, and in that state, the lens holder 13 is fixed to the vertical plate member by laser welding or the like.

Although the optical waveguide 2 is exemplified as the optical element, the optical element may be a light emitting element or a light receiving element. Box-shaped assembly case made of stainless steel, etc.
The side wall 10B of 10 is provided with a stepped hole 14 whose step end surface is slightly inclined with respect to the axis, and the outer side surface of the side wall 10B is provided with a truncated cone-shaped concave surface 19 whose apex coincides with the axis of the stepped hole 14. It is provided.

Numeral 16 is a window glass made of sapphire or the like through which a light beam passes, and is attached to the stepped end face of the stepped hole 14. The optical element / lens assembly 1 described above is housed in the assembly case 10, and is fixed to the assembly case 10 by screwing or soldering the base 11 to the bottom plate 10A of the assembly case 10.

Reference numeral 20 denotes a lens 25 and a ferrule 6 which are separated from each other by a predetermined distance in an axial hole of a substantially cylindrical holder 21 made of stainless steel (the end face of the optical fiber 5 is located at the focal position of the lens 25). The lens and the optical fiber assembly are inserted so as to face each other and have a predetermined distance.

Reference numeral 31 is a first wedge-shaped glass plate having the other side surface opposed to one side surface inclined as desired, and 32 is a second wedge-shaped glass plate having the same shape as the first wedge-shaped glass plate 31. is there.
Reference numeral 35 is a substantially cylindrical first holder made of stainless steel or the like.

One end surface of the first holder 35 is a frustoconical convex surface 35A that fits into the frustoconical concave surface 19 provided on the side wall 10B of the assembly case 10, and the other end surface is a frustoconical concave surface 35B.

The flat surface 31B of the first wedge-shaped glass plate 31 is orthogonal to the axis, and the axis of the stepped shaft hole 36 and the center of the flat surface 31B are aligned with each other so that the first holder 35 Stepped shaft center hole 36
A first wedge-shaped glass plate 31 is attached inside.

Reference numeral 37 is a substantially cylindrical second holder made of stainless steel or the like. One end surface of the second holder 37 is a frustoconical convex surface 37A that fits into the frustoconical concave surface 35B of the first holder 35, and the other end surface is a flat surface.

The step of the second holder 37 is arranged so that the flat surface 32B of the second wedge-shaped glass plate 32 is orthogonal to the axis and the axis of the stepped axial hole 38 is aligned with the center of the flat surface 32B. A second wedge-shaped glass plate 32 is attached in the axial center hole 38.

The truncated conical convex surface 35A of the first holder 35 is fitted to the truncated conical concave surface 19 of the assembly case 10 in a posture such that the wedge-shaped side end surface of the first wedge-shaped glass plate 31 becomes substantially vertical, and the desired shape is obtained. After the adjustment, the first holder 35 and the side wall 10B are laser-welded to fix the first holder 35 to the assembly case 10.

The frustoconical convex surface 37A of the second holder 37 is fitted into the frustoconical concave surface 35B of the first holder 35 in a posture such that the wedge-shaped side end surface of the second wedge-shaped glass plate 32 becomes substantially horizontal. After the desired adjustment, the second holder 37 and the first holder 35 are laser-welded or the like to fix the second holder 37 to the first holder 35.

The end surface of the holder 21 of the lens / optical fiber assembly 20 is brought into contact with the flat surface of the second holder 37 to adjust the axial deviation as desired, and then the holder 21 and the second holder 37 are adjusted.
Lens and optical fiber assembly 20
Is fixed to the second holder 37.

A method for assembling and adjusting the above-mentioned optical element / optical fiber assembly will be described below with reference to FIG.
First, from each of the optical element / lens assembly 1 and the lens / optical fiber assembly 20, visible light (helium /
A neon laser beam or the like) is emitted, and a screen S ₁ is placed just before the optical element / lens assembly 1 and a screen S ₂ is placed just before the lens / optical fiber assembly 20, and the position of the optical axis is drawn on the screen.

Next, as shown in FIG. 4A, the screens S ₁ and S ₂ are moved perpendicularly to the optical axis so that they are closer to each other at equal distances and overlap each other. As a result, the light emitted from the optical element / lens assembly 1 moves to point A on the screen S ₁ . The light emitted from the lens / optical fiber assembly 20 moves to point B on the screen S ₂ .

Then, the first holder 35 (that is, the first wedge-shaped glass plate 31) is attached to the optical element / lens assembly 1,
The second holder 37 (that is, the second wedge-shaped glass plate 32) is attached to the lens / optical fiber assembly 20.

As described above, the first wedge-shaped glass plate 31, the second
By attaching the wedge-shaped glass plate 32, the light emitted from the optical element / lens assembly 1 is refracted and moved to the point P ₁ shown in FIG. 4B. The light emitted from the lens / optical fiber assembly 20 is refracted and moves to the point P ₂ shown in FIG. 4B.

A circle Q _a passing through P ₁ around the point A and _a circle Q _b passing through P ₂ around the point B is drawn. Then, the first holder 35 is rotationally adjusted to refract the output optical fiber from the optical element / lens assembly 1 so that it passes through the intersection C between the circle Q _a and the circle Q _b, and the optical element / lens assembly 1 The first holder 35 and the first holder 35 are fixed by laser welding or the like.

The intersection of circle Q _a and circle Q _b is C and D
In this case, the intersection point C close to the optical axis is selected. (Because the optical coupling efficiency is improved.) Further, the second holder 37 is rotationally adjusted to refract the output optical fiber from the lens / optical fiber assembly 20, and the intersection point C between the circle Q _a and the circle Q _b. To pass through.

Remove the screens S _{1 and} S ₂
In a state where the optical fiber assembly 20 is integrated with the second holder 37, the second holder 37 is fitted to the first holder 35 and laser welding or the like is performed to make the first holder 35 and the second holder 37. Stick and. And the lens and optical fiber assembly 20
Is rotated 180 degrees about the optical axis. (That is, the direction of light is adjusted.) The angular deviation is adjusted as described above.

Then, light is emitted from the optical element / lens assembly 1 and the optical power of the optical fiber 5 is observed at the terminal side of the optical fiber 5 while the holder of the lens / optical fiber assembly 20 is being observed.
With the end surface of 21 in contact with the flat surface of the second holder 37,
The holder 21 of the lens / optical fiber assembly 20 is laser-welded and fixed to the second holder 37 when the optical power emitted from the optical fiber by moving slightly in the XY plane is maximum.

In FIG. 2, the outer surface of the side wall 10B of the assembly case 10 for housing the optical element / lens assembly 1 is a flat surface. Reference numeral 45 denotes a first wedge-shaped glass container in which the other side surface facing one side surface is inclined as desired and has a constant wall thickness, and 47 is a second wedge-shaped glass container having the same shape as the first wedge-shaped glass container 45. It is a container.

Reference numeral 40 denotes a cylindrical holder made of stainless steel or the like having a square shaft center hole 41 in the shaft center. The inclined surface of the first wedge-shaped glass container 45 is the optical element / lens assembly 1
The holder 40 so that the flat surface is perpendicular to the axis.
A first wedge-shaped glass container 45 is fixed in the axial center hole 41 of the.

The first wedge-shaped glass container 45 is provided with two entrances and exits, and the tube connected to the entrances is drawn out of the holder 40. The second wedge-shaped glass container 47 is provided behind the first wedge-shaped glass container 45 so as to face the back of the first wedge-shaped glass container 45.
It is stuck inside 41.

More specifically, the inclined surface is on the optical element / lens assembly 1 side (that is, the first wedge-shaped glass container 45 side), the flat surface is orthogonal to the axis, and the wedge-shaped side end surface is the first wedge-shaped glass. A second wedge-shaped glass container 47 is fixed in the axial center hole 41 of the holder 40 so as to be orthogonal to the wedge-shaped side end surface of the container 45.

It should be noted that the second wedge-shaped glass container 47 is also provided with two entrances and exits, and the tube connected to these entrances is attached to the holder 40.
Is pulled out of. 46 and 48 are solutions that transmit light, such as salt water.

The holder 40 is assembled by abutting the end surface of the holder 40 against the outer surface of the side wall 10B of the assembly case 10 and laser welding in a posture such that the wedge-shaped side end surface of the first wedge-shaped glass container 45 is vertical. It is stuck to the case 10.

Then, the solution 46 having a desired concentration is sealed in the first wedge-shaped glass container 45 to adjust the angular deviation in a predetermined direction. Further, a solution 48 having a desired concentration is sealed in the second wedge-shaped glass container 47 to adjust the angular deviation in a predetermined direction.

Holder for lens / optical fiber assembly 20
The end surface of 21 is brought into contact with the end surface of the holder 40, and after adjusting the axial displacement as desired, the holder 21 and the holder 40 are laser-welded to fix the lens / optical fiber assembly 20 to the holder 40.

A method for assembling and adjusting the above-mentioned optical element / optical fiber assembly will be described below. Light is emitted from the optical waveguide 2 and is adjusted while observing the optical power at the end side of the optical fiber 5. First, the holder 40 is fixed to the assembly case 10, and the lens / optical fiber assembly 20 is fixed. In such a state that the solution 46 is fed into the first wedge-shaped glass container 45 and the concentration of the solution 46 is changed, the refractive index of the first wedge-shaped glass container 45 is adjusted, and the optical power emitted from the optical fiber 5 is maximized. The concentrated solution is sealed in the first wedge-shaped glass container 45. As a result, the traveling direction of the light beam becomes parallel to the XZ plane, so that there is no angular deviation with respect to the XZ plane.

Then, the lens / optical fiber assembly 20
Is slightly moved in the X-axis direction to maximize the optical power emitted from the optical fiber. Next, the solution 48 is fed into the second wedge-shaped glass container 47, and the concentration of the solution 48 is changed to adjust the refractive index of the second wedge-shaped glass container 47 so that the optical power emitted from the optical fiber 5 has the maximum concentration. Solution in a second wedge-shaped glass container
Seal in 47. As a result, the traveling direction of the light beam becomes parallel to the YZ plane, so that there is no angular deviation with respect to the YZ plane.

Then, the lens / optical fiber assembly 20
Is slightly moved in the Y-axis direction to maximize the optical power emitted from the optical fiber and adjust the axis deviation, and the holder 21 of the lens / optical fiber assembly 20 is laser-welded to make the holder 40
Stick to.

[0068]

As described above, according to the present invention, the optical element
When assembling and adjusting the lens assembly and the lens / optical fiber assembly, the axial deviation is adjusted after adjusting the angular deviation, and the procedure is simple and the adjustment work is short.

Further, since the adjustment work is easy, the optical coupling efficiency between the optical element / lens assembly and the lens / optical fiber assembly is high.

[Brief description of drawings]

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

FIG. 2 is a sectional view of another embodiment of the present invention.

FIG. 3 is a diagram for explaining the operation of the present invention.

4A and 4B are views for explaining the adjustment procedure of the present invention.

FIG. 5 is a plan view of a conventional example (A) is a side sectional view of an optical element / lens assembly.

[Explanation of symbols]

1 Optical element / lens assembly 2 Optical waveguide 5 Optical fiber 6 Ferrule 10 Assembly case 13 Lens holder 15,25 Lens 16 Window glass 19,35B Frustroconical concave surface 35A, 37A
Conical convex surface 20 Lens / optical fiber assembly 31 First wedge-shaped glass plate 32 Second wedge-shaped glass plate 35 First holder 37 Second holder 40 Holder 45 First wedge-shaped glass container 47 Second wedge-shaped glass container 46 , 48 solution

Claims (4)

[Claims] 1. A light beam which is emitted or received is a side wall (1).
The optical element / lens assembly (1) in which the optical element and the lens (15) are optically coupled and fixed in the assembly case (10) so as to pass through the hole (0B), and the holder (21). Lens (25) inserted oppositely in the axial hole
And the optical fiber (5) are optically coupled to each other, and the lens / optical fiber assembly (20) and the first wedge-shaped glass plate (1) housed and fixed in the axial hole of the first holder (35). 31) and a second wedge-shaped glass plate (32) housed and fixed in the shaft center hole of the second holder (37), and the optical element / lens assembly (1) and the lens / light The fiber assembly (20) and the first and second wedge-shaped glass plates (3
An optical element / optical fiber assembly characterized by being optically coupled via (1,32). 2. The optical element / optical fiber assembly according to claim 1, wherein the first holder (35) is provided on the truncated conical concave surface (19) provided around the hole of the side wall (10B) of the assembly case (10). Frustoconical convex surface
While the first holder (35) is rotated as desired while the (35A) is fitted, a cone provided on the end surface of the first holder (35) opposite to the truncated conical convex surface (35A). The second holder (37) on the trapezoidal concave surface (35B)
With the frustoconical convex surface (37A) centered on the axis of the, the second holder (37) is turned as desired to make the light beam parallel to the Z-axis, Attach the holder (2) of the lens / optical fiber assembly (20) to the end face of the holder (37) opposite to the truncated cone-shaped convex surface (37A).
With the end face of 1) abutting, the holder (21) is finely moved in the XY plane, and the lens / optical fiber assembly (20) is
An optical element / optical fiber assembly assembling and adjusting method, characterized in that the optical axis of the optical element and the optical axis of the optical element / lens assembly (1) are aligned. 3. A light beam that is emitted or received is a side wall (1).
The optical element / lens assembly (1) in which the optical element and the lens (15) are optically coupled and fixed in the assembly case (10) so as to pass through the hole (0B), and the holder (21). Lens (25) inserted oppositely in the axial hole
The optical fiber (5) and the optical fiber (5) are optically coupled to each other, and the wedge-shaped side end faces of both are arranged in the axial center hole of the holder (40) so as to be orthogonal to each other. 1st, 2nd wedge-shaped glass container (45, 4
7) and a solution (46, 48) having a desired refractive index which is housed and sealed in each of the first and second wedge-shaped glass containers (45, 47), and the optical element / lens assembly (1) and the lens / optical fiber assembly (20) include the first and second wedge-shaped glass containers
An optical element / optical fiber assembly characterized in that it is optically coupled via (45, 47). 4. The optical element / optical fiber assembly according to claim 3, wherein the concentration of the solution (46) in the first wedge-shaped glass container (45) is adjusted to adjust the first wedge-shaped glass container (45). By adjusting the traveling direction of the light beam so as to be parallel to the XZ plane, and adjusting the concentration of the solution (48) in the second wedge-shaped glass container (47) to obtain the second wedge-shaped glass container (47). Adjust the traveling direction of the light beam so that it is parallel to the YZ plane by making the light beam parallel to the Z-axis, and make the end face of the holder (21) of the lens / optical fiber assembly (20) into the holder (40 ), The holder (2
Optical element / optical device characterized in that the optical axis of the lens / optical fiber assembly (20) is aligned with the optical axis of the optical element / lens assembly (1) by finely moving 1) in the XY plane. Assembling and adjusting method of fiber assembly.