JP5203314B2 - Optical module - Google Patents

Description

  The present invention relates to an optical module.

  An optical assembly containing a light emitting element or a light receiving element for mutually converting an electric signal and an optical signal, an optical fiber optically connected to the optical assembly, a circuit board electrically connected to the optical assembly, There is known an optical module having (Patent Document 1).

JP 2008-203427 A

  The mounting position of the optical assembly is displaced due to component tolerances or assembly errors. The wiring for electrically connecting the circuit board and the optical assembly is preferably short, but if the position of the optical assembly is shifted, the electrical connection between the two may not be achieved. However, in the conventional structure, since the position of the optical assembly is determined in advance, the position cannot be adjusted.

  An object of the present invention is to electrically connect a circuit board and an optical assembly at a short distance.

  (1) An optical module according to the present invention includes a case, a circuit board fixed to the inside of the case, and one of an electric signal and an optical signal disposed between the circuit board and the inner surface of the case. An optical assembly containing a light emitting element or a light receiving element for conversion to the other, an optical fiber optically connected to the optical assembly, wiring for electrically connecting the optical assembly and the circuit board, and the light A first sheet sandwiched between the assembly and the circuit board; and a second sheet sandwiched between the optical assembly and the inner surface of the case; and the first sheet and the optical assembly. A static friction coefficient between the second assembly and the optical assembly is greater than a static friction coefficient between the optical assembly and the circuit board. The optical assembly is sandwiched between the circuit board and the case by the elastic force of at least one of the circuit board, the first sheet, and the second sheet. And is held by the first sheet and the second sheet by the frictional force with the first sheet and the frictional force with the second sheet. According to the present invention, since the optical assembly is held by a frictional force, the optical assembly can be moved by applying a force exceeding the maximum frictional force. Thereby, since the position of the optical assembly can be adjusted, the distance between the circuit board and the optical assembly can be reduced, and the two can be electrically connected at a short distance.

  (2) In the optical module described in (1), a static friction coefficient between the first sheet and the circuit board is larger than the static friction coefficient between the optical assembly and the circuit board. The coefficient of static friction between the second sheet and the case is larger than the coefficient of static friction between the optical assembly and the case, and the first sheet is caused to generate the circuit by a frictional force with the circuit board. The second sheet may be held on the substrate, and the second sheet may be held on the case by a frictional force with the case.

  (3) In the optical module described in (2), the surfaces of the optical assembly facing the first sheet and the second sheet are flat, and the circuit board is opposed to the first sheet. The surface may be flat, and the inner surface of the case may be flat.

  (4) In the optical module described in (1) or (2), a first attachment that is interposed between the first sheet and the circuit board and is fixed to the circuit board; and the second sheet; It may be characterized by further comprising at least one of a second attachment that is interposed between the case and fixed to the case.

(5) In the optical module described in (4), a static friction coefficient _T between the first sheet and the first attachment is larger than the static friction coefficient between the optical assembly and the circuit board. A coefficient of static friction _T between the second sheet and the second attachment is greater than a coefficient of static friction between the light assembly and the case, and the first sheet is formed of the first attachment and the second attachment. It is good also as the above-mentioned 2nd sheet being held by the 2nd attachment by the frictional force with the 2nd attachment by the 1st attachment with the above-mentioned frictional force.

  (6) In the optical module described in (5), the surface facing the first sheet of the optical assembly forms a first curved surface, and the surface facing the second sheet of the optical assembly is a first surface. Forming a second curved surface, a surface of the first attachment facing the first sheet forms a third curved surface, a surface of the second attachment facing the second sheet forms a fourth curved surface, The first curved surface, the second curved surface, the third curved surface, and the fourth curved surface may be positioned so as to be drawn around the same axis.

It is sectional drawing of the optical module which concerns on 1st Embodiment to which this invention is applied. It is sectional drawing of the optical module which concerns on 1st Embodiment to which this invention is applied. It is sectional drawing of the optical module which concerns on 2nd Embodiment to which this invention is applied. It is a perspective view which shows a 1st attachment. It is sectional drawing which shows the modification 1 of the optical module which concerns on 2nd Embodiment to which this invention is applied. It is sectional drawing which shows the modification 2 of the optical module which concerns on 2nd Embodiment to which this invention is applied.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
1 and 2 are different cross-sectional views of the optical module according to the first embodiment to which the present invention is applied.

  The optical module has a case 10. The case 10 may be formed of resin, or may be formed of metal as long as electrical insulation can be ensured.

  A circuit board 12 is fixed inside the case 10. The circuit board 12 is formed of a material having elasticity such as resin. The circuit board 12 and the case 10 are fixed by screws (not shown). On the circuit board 12, wiring patterns and terminals (not shown) are formed, and electronic components (not shown) are mounted.

  An optical assembly 14 is disposed between the circuit board 12 and the inner surface of the case 10. The optical assembly 14 incorporates a light emitting element or a light receiving element for converting one of an electric signal and an optical signal into the other. An optical fiber 16 is optically connected to the optical assembly 14.

  The optical assembly 14 and the circuit board 12 are electrically connected by wiring 18. The wiring 18 may be a plate-shaped metal piece as shown in FIGS. 1 and 2, a flexible wiring board, or a lead wire. In the example shown in FIGS. 1 and 2, pins 20 provided as external terminals of the optical assembly 14 are inserted into holes of the plate-like wiring 18, and the pins 20 and the wiring 18 are joined by solder. The wiring 18 is electrically connected to a wiring pattern (not shown) of the circuit board 12, and the electrical connection is made by solder.

  A first sheet 22 is sandwiched between the optical assembly 14 and the circuit board 12. The surface of the optical assembly 14 facing the first sheet 22 is flat. The surface facing the first sheet 22 of the circuit board 12 is also flat. The first sheet 22 is formed of an elastic material such as a resin such as silicone resin or rubber. As a modification, if the circuit board 12 is formed from a material having elasticity, the first sheet 22 may be formed from a material having no elasticity (for example, glass or the like) as long as it is not plastically deformed.

The static friction coefficient μ _1A between the first sheet 22 and the optical assembly 14 is larger than the static friction coefficient μ _AB between the optical assembly 14 and the circuit board 12. The static friction coefficient μ _1B between the first sheet 22 and the circuit board 12 is also larger than the static friction coefficient μ _AB between the optical assembly 14 and the circuit board 12.

  A second sheet 24 is sandwiched between the optical assembly 14 and the inner surface of the case 10. The surface of the optical assembly 14 facing the second sheet 24 is flat. The inner surface of the case 10 is also flat. The second sheet 24 is also formed of an elastic material such as a resin such as silicone resin or rubber. As a modification, if the circuit board 12 is formed from a material having elasticity, the second sheet 24 may be formed from a material having no elasticity (for example, glass or the like) as long as it is not plastically deformed.

The static friction coefficient μ _2A between the second sheet 24 and the optical assembly 14 is larger than the static friction coefficient μ _AC between the optical assembly 14 and the inner surface of the case 10. The coefficient of static friction μ _2C between the second sheet 24 and the inner surface of the case 10 is also larger than the coefficient of static friction μ _AC between the optical assembly 14 and the inner surface of the case 10.

  The optical assembly 14 is pressed in a direction to be sandwiched between the circuit board 12 and the case 10 by at least one elastic force of the circuit board 12, the first sheet 22, and the second sheet 24. The optical assembly 14 is held by the first sheet 22 and the second sheet 24 by the frictional force with the first sheet 22 and the frictional force with the second sheet 24. The first sheet 22 is held on the circuit board 12 by frictional force with the circuit board 12. The second sheet 24 is held on the case 10 by a frictional force with the inner surface of the case 10.

  According to the present embodiment, since the optical assembly 14 is held by a frictional force, if the force exceeding the maximum frictional force is applied, the optical assembly 14 can be moved in a two-dimensional direction along the surface of the circuit board 12. it can. Thereby, since the position of the optical assembly 14 can be adjusted, the distance between the circuit board 12 and the optical assembly 14 can be reduced, and both can be electrically connected at a short distance.

  When the optical module is assembled, the outer tolerance and assembly tolerance of the optical assembly 14, the outer tolerance of the wiring 18, the tolerance of the wiring pattern (not shown) formed on the circuit board 12, the outer tolerance of the circuit board 12, and the case 10 Even if a tolerance occurs in a two-dimensional direction along the surface of the circuit board 12 with respect to the position of the optical assembly 14 with respect to the circuit board 12 due to external tolerance or the like, the position of the optical assembly 14 can be adjusted.

  The fixed strength of the optical assembly 14 can be evaluated by a mechanical test that applies acceleration to the optical module. According to the Telcordia standard, optical modules are required to have a mechanical test result of an acceleration of 4900 meters per second or more per second.

The coefficient of static friction between the first sheet 22 and the optical assembly 14 is μ _1A , the force pushing the optical assembly 14 perpendicular to the direction of the first sheet 22 is F ₁ , and the area where the first sheet 22 and the optical assembly 14 are in contact S ₁ , the coefficient of static friction between the second sheet 24 and the light assembly 14 is μ _2A , the force pushing the light assembly 14 perpendicular to the direction of the second sheet 24 is F ₂ , and the second sheet 24 and the light assembly 14 When the contact area is S ₂ and the weight of the optical assembly 14 is W,
W × 4900 ≦ F ₁ × μ _1A × S ₁ + F ₂ × μ _2A × S ₂
Then, an optical module that passes the Telcordia standard can be obtained.

  By applying this embodiment, the wiring 18 can be sufficiently shortened even when the optical assembly 14 is driven by a high-speed signal exceeding 10 Gbps and the coaxial connector cannot be used due to space limitations. Therefore, good high frequency characteristics can be obtained in the optical assembly 14, and high-speed signals can be transmitted efficiently.

(Second Embodiment)
FIG. 3 is a cross-sectional view of an optical module according to a second embodiment to which the present invention is applied.

  In the present embodiment, the optical assembly 214 has a multistage cylindrical shape, and has a first curved surface 226 and a second curved surface 228 on the outer surface. The first curved surface 226 and the second curved surface 228 are formed to be convex in opposite directions. Since the outer surface of the optical module is not flat, the optical module has a first attachment 230 and a second attachment 232 for holding the case 210 and the circuit board 212.

  FIG. 4 is a perspective view showing the first attachment 230. A third curved surface 234 corresponding to the first curved surface 226 of the optical assembly 214 is formed on the first attachment 230. The third curved surface 234 has a larger radius of curvature than the first curved surface 226. The optical assembly 214 and the first attachment 230 can be arranged such that a uniform gap is provided between the first curved surface 226 and the third curved surface 234.

  The second attachment 232 has the same configuration as the first attachment 230, and a fourth curved surface 236 corresponding to the second curved surface 228 of the light assembly 214 is formed. The fourth curved surface 236 has a larger radius of curvature than the second curved surface 228. The light assembly 214 and the second attachment 232 can be arranged such that a uniform gap is provided between the second curved surface 228 and the fourth curved surface 236.

The first attachment 230 is fixed to the circuit board 212. The light assembly 214 is held by the first attachment 230 via the first sheet 222. A first attachment 230 is interposed between the first sheet 222 and the circuit board 212. The static friction coefficient μ _1AT between the first sheet 222 and the first attachment 230 is larger than the static friction coefficient μ _AB between the light assembly 214 and the circuit board 212. The first sheet 222 is held on the first attachment 230 by a frictional force with the first attachment 230. A surface of the first attachment 230 facing the first sheet 222 is a third curved surface 234. The first curved surface 226 of the optical assembly 214 faces the first sheet 222.

The second attachment 232 is fixed to the case 210. The optical assembly 214 is held by the second attachment 232 via the second sheet 224. A second attachment 232 is interposed between the second sheet 224 and the inner surface of the case 210. The static friction coefficient μ _2AT between the second sheet 224 and the second attachment 232 is larger than the static friction coefficient μ _AC between the light assembly 214 and the inner surface of the case 210. The second sheet 224 is held on the second attachment 232 by a frictional force with the second attachment 232. A surface of the second attachment 232 facing the second sheet 224 is a fourth curved surface 236. The second curved surface 228 of the optical assembly 214 faces the second sheet 224.

  The optical assembly 214, the first attachment 230, and the second attachment 232 are positioned such that the first curved surface 226, the second curved surface 228, the third curved surface 234, and the fourth curved surface 236 are arranged around the same axis. The other configurations and effects of the present embodiment correspond to the contents described in the first embodiment.

(Modification)
FIG. 5 is a cross-sectional view showing Modification 1 of the optical module according to the second embodiment to which the present invention is applied. In the present modification, the first attachment 230 shown in FIG. 3 is omitted, and a thicker first sheet 322 is arranged instead of the first sheet 222 shown in FIG.

  FIG. 6: is sectional drawing which shows the modification 2 of the optical module which concerns on 2nd Embodiment to which this invention is applied. In the present modification, the second attachment 232 shown in FIG. 3 is omitted, and a thicker second sheet 324 is arranged instead of the second sheet 224 shown in FIG.

  In any modification, since one of the first attachment 230 and the second attachment 232 is provided, the optical assembly 214 can be held. The other configurations and effects correspond to those described in the second embodiment.

  The present invention is not limited to the above-described embodiments, and various modifications can be made. For example, the configuration described in the embodiment can be replaced with substantially the same configuration, a configuration that exhibits the same operational effects, or a configuration that can achieve the same purpose.

  10 Case, 12 Circuit board, 14 Optical assembly, 16 Optical fiber, 18 Wiring, 20 Pin, 22 First sheet, 24 Second sheet, 210 Case, 212 Circuit board, 214 Optical assembly, 222 First sheet, 224 Second Sheet, 226 1st curved surface, 228 2nd curved surface, 230 1st attachment, 232 2nd attachment, 234 3rd curved surface, 236 4th curved surface, 322 1st sheet, 324 2nd sheet.

Claims (6)

Case and
A circuit board fixed to the inside of the case;
A light assembly containing a light emitting element or a light receiving element, which is disposed between the circuit board and the inner surface of the case, for converting one of an electric signal and an optical signal into the other;
An optical fiber optically connected to the optical assembly;
Wiring for electrically connecting the optical assembly and the circuit board;
A first sheet sandwiched between the optical assembly and the circuit board;
A second sheet sandwiched between the optical assembly and the inner surface of the case;
Have
A coefficient of static friction between the first sheet and the light assembly is greater than a coefficient of static friction between the light assembly and the circuit board;
A coefficient of static friction between the second sheet and the light assembly is greater than a coefficient of static friction between the light assembly and the case;
The optical assembly is pressed in a direction sandwiched between the circuit board and the case by at least one elastic force of the circuit board, the first sheet, and the second sheet, and a frictional force with the first sheet The optical module is held by the first sheet and the second sheet by a frictional force with the second sheet. The optical module according to claim 1,
A coefficient of static friction between the first sheet and the circuit board is greater than the coefficient of static friction between the light assembly and the circuit board;
A coefficient of static friction between the second sheet and the case is greater than the coefficient of static friction between the light assembly and the case;
The first sheet is held on the circuit board by a frictional force with the circuit board,
The optical module, wherein the second sheet is held by the case by a frictional force with the case. The optical module according to claim 2,
Opposite surfaces of the optical assembly facing the first sheet and the second sheet are flat,
The surface of the circuit board facing the first sheet is flat,
The optical module according to claim 1, wherein the inner surface of the case is flat. The optical module according to claim 1 or 2,
A first attachment fixed between the first sheet and the circuit board and fixed to the circuit board;
A second attachment interposed between the second sheet and the case and fixed to the case;
An optical module further comprising at least one of the above. The optical module according to claim 4,
A coefficient of static friction _T between the first sheet and the first attachment is greater than the coefficient of static friction between the optical assembly and the circuit board;
A coefficient of static friction _T between the second sheet and the second attachment is greater than the coefficient of static friction between the light assembly and the case;
The first sheet is held on the first attachment by a frictional force with the first attachment;
The optical module, wherein the second sheet is held by the second attachment by a frictional force with the second attachment. The optical module according to claim 5,
The surface facing the first sheet of the optical assembly forms a first curved surface,
The surface facing the second sheet of the optical assembly forms a second curved surface,
The surface of the first attachment facing the first sheet forms a third curved surface,
A surface of the second attachment facing the second sheet forms a fourth curved surface,
The optical module, wherein the first curved surface, the second curved surface, the third curved surface, and the fourth curved surface are positioned so as to be drawn around the same axis.

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