JP2016080751A - Optical cable terminal - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical cable terminal capable of improving a long-term reliability.SOLUTION: An optical cable terminal 1 comprises: an optical cable 2 including optical fibers F; a substrate 13 on which an optical element 18 and a lens module 11 are mounted; and an alignment member 20 attached to an end of the optical cable 2 on a lens module 11 side, and individually aligning the optical fiber F extending from the optical cable 2. The alignment member 20 maintains the optical fibers F to be aligned such that the positions of the optical fiber F in a plane intersecting with a direction in which the optical cable 2 extends is changed.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an optical cable terminal.

  Patent Document 1 describes an optical module that can be used for an active optical cable (AOC). An optical cable is connected to the optical module, and the optical cable holds a plurality of optical fibers. In the housing, the optical fiber, the lens array component, and the optical element mounted on the substrate are optically connected.

International publication 2013/099753

  In the optical cable terminal described above, the optical fiber is bent toward the surface of the substrate. This portion may come into contact with the rear end of the substrate due to vibration of the optical cable terminal.

  This invention is made | formed in view of such a situation, and it aims at providing the optical cable terminal which can prevent damage to an optical fiber.

  In order to solve the above-described problem, an optical cable terminal according to one aspect of the present invention includes an optical cable including a plurality of optical fibers, an optical element, a connection member that optically connects the optical element and each optical fiber, And an alignment member that is attached to the end of the optical cable on the connection member side and individually aligns the optical fibers extending from the optical cable, and the alignment member intersects the direction in which the optical cable extends The optical fiber is held in an aligned state so as to change the position of the optical fiber inside.

  ADVANTAGE OF THE INVENTION According to this invention, the optical cable terminal which can prevent damage to an optical fiber can be provided.

FIG. 1 is an exploded perspective view showing an optical cable terminal according to the embodiment. FIG. 2 is a cross-sectional view showing a typical example of an electro-optic composite cable. FIG. 3 is a cross-sectional view of an electro-optic composite cable according to a modification. FIG. 4 is a perspective view showing a state in which the arrangement of the optical fiber and the metal wire is converted by the alignment member. FIG. 5 is a side view showing a state where the arrangement of the optical fibers and the metal wires is converted by the alignment member. FIG. 6 is a front view showing a state in which the arrangement of the optical fibers and the metal wires is converted by the alignment member. FIG. 7 is a plan view showing a state in which the arrangement of the optical fibers and the metal wires is converted by the alignment member.

[Description of Embodiment of the Present Invention]
First, the contents of the embodiment of the present invention will be listed and described. (1) An optical cable terminal according to an aspect of the present invention includes a substrate on which an optical cable including a plurality of optical fibers, an optical element, and a connection member that optically connects the optical element and each optical fiber, An alignment member attached to an end of the optical cable on the connection member side and individually aligning the optical fibers extending from the optical cable, wherein the alignment member is positioned in a plane intersecting a direction in which the optical cable extends. The optical fiber is held in an aligned state so as to convert.

  In the optical cable terminal according to one aspect of the present invention, the alignment member holds the optical fiber so that the positions of the optical fibers in the plane intersecting the extending direction of the optical cable are different. For this reason, a portion where the optical fiber is bent is held by the alignment member, and the optical fiber can be held between the alignment member and the connecting member without being bent. Therefore, it is possible to prevent the optical fiber from being damaged by the vibration of the optical cable terminal.

(2) In the optical cable terminal, the plurality of optical fibers in the optical cable are arranged at a first pitch, and the plurality of optical fibers in the connection member are arranged at a second pitch wider than the first pitch, In the alignment member, the positions of the plurality of optical fibers in the direction intersecting the mounting surface of the substrate on which the optical element and the connection member are mounted are converted, and the distance between the optical fibers is converted from the first pitch to the second pitch. May be. In this case, in the alignment member, conversion of the position of the optical fiber in the direction intersecting the mounting surface of the substrate and conversion from the first pitch to the second pitch are performed. As a result, at the end of the alignment member on the connecting member side, the position of the optical fiber in the direction intersecting the mounting surface of the substrate and the conversion of the pitch of the optical fiber can be achieved. Therefore, the work of holding the tip of the optical fiber on the connecting member can be easily performed.

(3) In the optical cable terminal, the optical cable is an electro-optical composite cable including a metal wire, and the alignment member guides the optical fiber to the mounting surface side of the substrate and guides the metal wire to the back surface side of the mounting surface of the substrate. As described above, the optical fiber and the metal wire may be aligned. In this case, the optical fiber and the metal wire having different mounting methods are guided in different directions. Therefore, the optical fiber mounting operation and the metal wire mounting operation can be easily performed.

(4) In the optical cable terminal, the optical cable is an electro-optic composite cable including a metal wire, and the length of the optical fiber held in the alignment member is greater than the length of the metal wire held in the alignment member. May be longer. Optical fibers are more susceptible to transmission loss due to bending than metal wires. Therefore, by making the length of the portion where the optical fiber is held longer than the length of the portion where the metal wire is held, the bending applied to the optical fiber in the portion is made gentle and the arrangement of the optical fiber is changed. be able to. Therefore, the transmission loss of the optical fiber can be reduced.

(5) The optical cable terminal may further include an outer member that covers the outer periphery of the alignment member and the outer periphery of the optical cable. Thereby, it is possible to make it difficult for bending and pulling applied to the optical cable to be transmitted to the alignment member.

[Details of the embodiment of the present invention]
A specific example of the optical cable terminal according to the embodiment of the present invention will be described with reference to the drawings. In addition, this invention is not limited to these illustrations, is shown by the claim, and intends that all the changes within the range equivalent to a claim are included. In the following description, the same reference numerals are given to the same elements in the description of the drawings, and redundant descriptions are omitted.

  FIG. 1 is an exploded perspective view showing an optical cable terminal 1 according to the present embodiment. The optical cable terminal 1 is connected to an electronic device such as a personal computer. As shown in FIG. 1, the optical cable terminal 1 includes an optical cable 2 and a connector module 10 connected to an end of the optical cable 2. The connector module 10 converts an optical signal in the optical cable 2 into an electrical signal and outputs it to an electronic device, and also converts an electrical signal input from the electronic device into an optical signal and outputs the optical signal to the optical cable 2.

  Below, as shown by the arrow of FIG. 1, let the connection direction of an electronic device and the optical cable terminal 1 be a front-back direction. The electronic device side is the front direction, and the optical cable 2 side is the rear direction. The description will be made with reference to the horizontal direction (left-right direction) and the vertical direction (up-down direction) orthogonal to the front-rear direction as appropriate. These directions are merely for convenience of explanation and do not limit the scope of the present invention.

  The optical cable 2 is an electro-optical composite cable including four optical fibers F and four metal wires M. The optical cable terminal 1 is provided with an alignment member 20 for individually aligning each optical fiber F and each metal wire M extending from the optical cable 2. The alignment member 20 is disposed on the rear end side of the metal housing 14.

  FIG. 2 is a cross-sectional view of the optical cable 2. As shown in FIG. 2, the optical cable 2 includes four optical fibers F, a tape resin 21 that integrates the four optical fibers F into a tape shape, and a tensile body disposed so as to cover the tape resin 21. 22 and a tube 23 covering the strength member 22. The four optical fibers F are arranged in parallel at the first pitch P1 so as to be equidistant from each other. The first pitch P1 corresponds to, for example, the outer diameter of the optical fiber F, and is 250 μm in the present embodiment. Of the four optical fibers F, two optical fibers F function for transmission, and the remaining two optical fibers F function for reception. The direction of the optical signal transmitted through the transmission optical fiber F and the direction of the optical signal transmitted through the reception optical fiber F are opposite to each other. In the present embodiment, the optical fiber F is a multimode optical fiber. Note that the optical fiber F may be arranged in the optical cable without being integrated by the tape resin 21.

  The optical fiber F includes a core that transmits an optical signal, a clad that covers the core, and a coating resin that covers the clad. The core and the clad may be made of glass or resin. The optical fiber F is an AGF (All glass fiber) in which both the core and the clad are made of glass, a plastic optical fiber in which both the core and the clad are made of resin, or an HPCF (core is made of glass and the clad is made of resin) Hard Plastic Clad Fiber). In addition, when the optical fiber F is HPCF, since the optical fiber F can be strengthened with respect to bending, it is preferable.

  The tensile body 22 is formed by weaving a fibrous resin material such as Kevlar or aramid. The strength member 22 is configured to be difficult to extend when the optical cable 2 is pulled. The tensile body 22 has a function of reducing the impact applied to the optical fiber F in the optical cable 2.

  In the cross section of the optical cable 2, four metal wires M are arranged outside the tube 23. The four metal lines M include two ultrafine coaxial lines 24 and two power supply lines 25. The coaxial line 24 is composed of a central conductor 24a formed by twisting seven metal wires, an insulating resin 24b positioned outside the central conductor 24a, a shield 24c positioned outside the insulating resin 24b, and a jacket positioned outside the shield 24c. 24d. A high-speed differential signal is transmitted by the two coaxial lines 24. Alternatively, each coaxial line 24 may transmit a low-speed signal in both directions. The power supply line 25 includes a central conductor 25a obtained by twisting seven metal wires and an insulating resin 25b positioned outside the central conductor 25a. The power line 25 has a larger diameter than the coaxial line 24 so that a large current can be transmitted.

  A tensile body 31 is disposed around the tube 23 and the four metal wires M. A collective shield 32 surrounding the tube 23, the metal wire M, and the tensile body 31 is disposed outside the tensile body 31. An outer cover 33 is disposed outside the collective shield 32.

  The optical fiber F is disposed at the center of the optical cable 2, and the four metal wires M are disposed vertically and horizontally with respect to the optical fiber F. Note that, as shown in the optical cable 2A in FIG. 3, the four optical fibers F may be disposed above the four metal wires M.

  Refer to FIG. 1 again. The alignment member 20 is made of an insulating resin. From the front end of the alignment member 20, four optical fibers F and four metal wires M aligned by the alignment member 20 are drawn out. The optical fiber F is drawn from the upper side of the alignment member 20, and the metal wire M is drawn from the lower side of the alignment member 20.

  The optical cable terminal 1 includes an outer member 16 that covers the outer periphery of the optical cable 2 and the outer periphery of the alignment member 20. The outer member 16 is attached to the rear end sides of the metal housing 14 and the resin housing 15. The outer member 16 is covered from the outer cover 2 a of the optical cable 2 to the alignment member 20.

  The connector module 10 includes a substrate 13 having a mounting surface 13a and a back surface 13c. On the mounting surface 13a, an optical element 18 (see FIG. 5), a driving IC (not shown) for driving the optical element 18, a signal processing IC 19, and the lens module 11 are mounted. An electrical connector 12 is attached to the front end of the substrate 13. The optical element 18, the signal processing IC 19, and the electrical connector 12 are electrically connected to each other via a wiring pattern formed on the mounting surface 13a. The connector module 10 further includes a metal housing 14 that houses the substrate 13 and a resin housing 15 that surrounds the metal housing 14.

  The lens module 11 is a connection member that optically connects the optical element 18 and the optical fiber F. Each optical fiber F extending from the alignment member 20 is mounted on the lens module 11. Each optical fiber F is fixed to the lens module 11 by being pressed by a fixing piece 17. Inside the lens module 11, an optical element 18 and a reflection surface 11 a that reflects light entering and exiting the optical fiber F are provided. The reflection surface 11a converts the optical path of the light emitted from the optical fiber F in the downward direction, and converts the optical path of the light emitted from the optical element 18 in the front-rear direction. The optical fiber F and the optical element 18 are optically connected by the reflecting surface 11a.

  Examples of the optical element 18 include a PD that is a light receiving element that converts an optical signal into an electric signal, and a VCSEL that is a light emitting element that converts an electric signal into an optical signal.

  The signal processing IC 19 is a CDR (Clock Data Recovery) device. The signal processing IC 19 has an equalizer function that amplifies an electric signal to perform waveform shaping or aligns the waveforms of a plurality of electric signals.

  The electrical connector 12 functions as an electrical interface with an external electronic device. The electrical connector 12 is disposed on the front end side of the metal housing 14.

  An electrical signal input from the external electronic device to the electrical connector 12 is processed by the signal processing IC 19. The electric signal processed by the signal processing IC 19 is converted into an optical signal by the light emitting element 18. The optical signal converted by the optical element 18 is output to the optical fiber F through the lens module 11.

  On the other hand, an optical signal input from the optical fiber F to the lens module 11 is converted into an electric signal by the light receiving element 18. The converted electrical signal is subjected to signal processing by the signal processing IC 19 and then output to an external electronic device via the electrical connector 12.

  The metal housing 14 releases heat generated from each component on the substrate 13 to the outside. The metal housing 14 includes a cover 14a and a base plate 14b having a substantially U-shaped cross section. A space for accommodating the substrate 13 is formed by the cover 14a and the base plate 14b.

  The metal housing 14 is made of a metal material having a high thermal conductivity. The conductivity of the metal housing 14 is preferably 100 W / m · K or more. The metal housing 14 is made of, for example, steel (Fe-based), tin (tin-plated copper), stainless steel, copper, brass, or aluminum.

  The resin housing 15 covers the metal housing 14. The resin housing 15 is made of a resin such as polycarbonate.

  4 and 5 are a perspective view and a side view showing a state in which the optical fiber F and the metal wire M are aligned and held by the alignment member 20. As shown in FIGS. 4 and 5, the alignment member 20 aligns and holds the optical fibers F so as to change the position of the optical fibers F in a plane intersecting (for example, orthogonal to) the front-rear direction. That is, the alignment member 20 aligns and holds the optical fibers F by gently bending the four optical fibers F from the arrangement position in the optical cable 2 to the upper side (the mounting surface 13a side of the substrate 13). In the present embodiment, the tape resin 21 is removed from the optical fiber F at the front end of the optical cable 2. The arrangement positions of the optical fibers F are individually defined by the alignment member 20 so that each optical fiber F extends upward.

  Specifically, the alignment member 20 has a first surface 20a from which the optical fiber F is drawn, and a second surface 20b from which the metal wire M is drawn. The first surface 20a and the second surface 20b are flat surfaces, for example.

  The first surface 20a protrudes from the second surface 20b, and a step is formed by the first surface 20a and the second surface 20b. The alignment member 20 is positioned with respect to the substrate 13 by the second surface 20 b coming into contact with the end surface 13 b of the substrate 13.

  In a state where the second surface 20b is in contact with the end surface 13b, the first surface 20a is located on the mounting surface 13a of the substrate 13 and faces the lens module 11 in the front-rear direction. The rear end portion (end portion on the optical cable 2 side) 20 c of the alignment member 20 accommodates the front end portion 2 b of the outer cover 2 a of the optical cable 2. Thereby, the force applied to the optical cable 2 from the outside is hardly transmitted to the substrate 13.

  The optical fiber F drawn from the first surface 20a of the alignment member 20 extends linearly along the front-rear direction. The optical fiber F drawn from the first surface 20 a is fixed to the lens module 11. In the lens module 11, the four optical fibers F are arranged side by side in the horizontal direction, and the pitch of the optical fibers F is a second pitch P 2 that is wider than the first pitch P 1 in the optical cable 2. The height of the first surface 20a relative to the mounting surface 13a of the optical fiber F is preferably substantially the same as the height of the lens module 11 relative to the mounting surface 13a of the optical fiber F. That is, it is preferable that the optical fiber F extends linearly along the mounting surface 13 a between the alignment member 20 and the lens module 11.

  In the alignment member 20, the four metal wires M are aligned so as to be drawn downward opposite to the optical fiber F. The metal wire M from the second surface 20b of the alignment member 20 is drawn out to the back surface 13c. The metal wires M are electrically connected to electronic components mounted on the back surface 13c. In the present embodiment, each metal line M is fixed to the electric wiring formed on the back surface 13c by soldering.

  FIG. 6 is a view showing the arrangement of the optical fiber F and the metal wire M at the front end (end portion on the lens module 11 side) of the alignment member 20, and FIG. 7 is a plan view showing the optical fiber F in the alignment member 20. . As shown in FIG. 6, the metal wires M are arranged in a straight line in the left-right direction on the second surface 20 b of the alignment member 20. Further, on the second surface 20 b, the two coaxial lines 24 are located inside the two power supply lines 25.

  As shown in FIGS. 6 and 7, the alignment member 20 converts the position of the optical fiber F in the vertical direction (direction orthogonal to the mounting surface 13 a of the substrate 13). Further, the interval between the optical fibers F is converted from the first pitch P1 in the optical cable 2 to a second pitch P2 that is larger than the first pitch P1. Accordingly, the optical fiber F extends from the alignment member 20 to the lens module 11 in a state where the pitch of the optical fiber F is set to the second pitch P2 in advance. Therefore, the optical fiber F extending from the alignment member 20 can be easily mounted on the lens module 11.

  In the present embodiment, the first pitch P1 corresponds to the outer diameter of the optical fiber F and is, for example, 250 μm. On the other hand, it is difficult to arrange the optical elements 18 on the mounting surface 13a at a pitch of 250 μm, for example, at a pitch of 500 μm. On the other hand, if the optical fibers F are arranged in the optical cable 2 with a large pitch of about 500 μm, the diameter of the optical cable 2 is increased.

  Therefore, in this embodiment, the pitch of the optical elements 18 is set to the second pitch P2 wider than the first pitch P1, and the pitch of the optical fibers F drawn from the alignment member 20 is also set to the second pitch P2. As a result, the optical fiber F and the optical element 18 can be optically connected only by bending the optical fiber F in the vertical direction without bending the optical axis of the light entering and exiting the optical fiber F in the horizontal direction. Therefore, the configuration of the lens module 11 can be simplified.

  The alignment member 20 as described above is formed by resin molding. First, the tip portion of the optical fiber F and the tip portion of the metal wire M are gripped by a jig (not shown) so as to be in the arrangement shown in FIG. 6, and the bending state of the optical fiber F and the metal wire M is defined. In this state, a mold is disposed between the outer sheath 2a of the optical cable 2 and the middle of the optical fiber F and the metal wire M. Then, the alignment member 20 is completed by filling the mold with resin and curing it. In this way, the front end portion 2b of the jacket 2a is accommodated, and the optical fiber F and the metal wire M are individually aligned, and the optical fiber F and the metal wire M are pulled out from the first surface 20a and the second surface 20b. The alignment member 20 can be easily manufactured.

  As described above, in the optical cable terminal 1, the alignment member 20 holds the optical fiber F so that the positions of the optical fibers F in the plane intersecting the extending direction of the optical cable 2 are different. Therefore, the portion where the optical fiber F is bent is held by the alignment member 20, and the optical fiber F can be held between the alignment member 20 and the lens module 11 without bending. Therefore, the optical fiber F can be prevented from being damaged by the vibration of the optical cable terminal 1.

  In the alignment member 20, the conversion of the position of the optical fiber F in the direction intersecting the mounting surface 13a of the substrate 13 and the conversion from the first pitch P1 to the second pitch P2 are performed. Thereby, at the end portion (first surface 20a) of the alignment member 20 on the lens module 11 side, the conversion of the position of the optical fiber F in the direction intersecting the mounting surface 13a of the substrate 13 and the conversion of the pitch of the optical fiber F are performed. It can be set as the state where and were performed. Therefore, the work of holding the tip of the optical fiber F on the lens module 11 can be easily performed.

  Further, in the alignment member 20, the optical fiber F and the metal wire M, which are different in mounting method, are guided in different directions. Therefore, the mounting operation of the optical fiber F and the mounting operation of the metal wire M can be easily performed.

  Further, the length of the optical fiber F held in the alignment member 20 is longer than the length of the metal wire M held in the alignment member 20. The optical fiber F is more susceptible to transmission loss due to bending than the metal wire M. Therefore, by making the length of the portion where the optical fiber F is held longer than the length of the portion where the metal wire M is held, the bending applied to the optical fiber F in the portion is made gentle, and the optical fiber F has a length. Placement conversion can be performed. Therefore, the transmission loss of the optical fiber F can be reduced.

  Moreover, the outer member 16 which covers the outer periphery of the alignment member 20 and the outer periphery of the optical cable 2 is provided. As a result, it is possible to make it difficult for bending and pulling applied to the optical cable 2 to be transmitted to the alignment member 20.

  Although the embodiment of the present invention has been described above, the present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist of the present invention. For example, in the above embodiment, the optical cable 2 includes four optical fibers F and four metal wires M. However, the number and arrangement of the optical fibers F and the metal wires M are not limited to the above embodiment, and the number of the optical fibers F or the metal wires M may be 1 to 3 or 5 or more, for example.

DESCRIPTION OF SYMBOLS 1 ... Optical cable terminal, 2 and 2A ... Optical cable, 2a ... Outer casing, 2b ... Front end part, 10 ... Connector module, 11 ... Lens module (connection member), 11a ... Reflecting surface, 12 ... Electrical connector, 13 ... Board | substrate, 13a ... mounting surface, 13b ... end face, 13c ... back surface, 14 ... metal housing, 14a ... cover, 14b ... base plate, 15 ... resin housing, 16 ... outer member, 17 ... fixed piece, 18 ... optical element, 19 ... signal processing IC , 20 ... Alignment member, 20a ... First surface, 20b ... Second surface, 21 ... Tape resin, 22 ... Strength member, 23 ... Tube, 24 ... Coaxial line, 24a ... Center conductor, 24b ... Insulating resin, 24c ... Shield 24d ... jacket, 25 ... power line, 25a ... center conductor, 25b ... insulating resin, 31 ... tensile body, 32 ... collective shield, 33 ... jacket, F ... optical fiber M ... metal line, P1 ... the first pitch, P2 ... the second pitch.

Claims (5)

An optical cable including a plurality of optical fibers;
A substrate on which an optical element and a connection member that optically connects the optical element and each of the optical fibers are mounted;
An alignment member attached to an end of the optical cable on the side of the connecting member and individually aligning the optical fibers extending from the optical cable,
The alignment member holds the optical fiber in an aligned state so as to change the position of the optical fiber in a plane intersecting a direction in which the optical cable extends.
Optical cable terminal. The plurality of optical fibers in the optical cable are arranged at a first pitch,
The plurality of optical fibers in the connection member are arranged at a second pitch wider than the first pitch,
In the alignment member, the positions of the plurality of optical fibers in the direction intersecting the mounting surface of the substrate on which the optical element and the connection member are mounted are changed, and the distance between the optical fibers is the first distance. Converted from pitch to the second pitch,
The optical cable terminal according to claim 1. The optical cable is an electro-optical composite cable including a metal wire,
The alignment member guides the optical fiber to the mounting surface side of the substrate and aligns the optical fiber and the metal wire so as to guide the metal wire to the back surface side of the mounting surface of the substrate.
The optical cable terminal according to claim 1. The optical cable is an electro-optical composite cable including a metal wire,
A length of the optical fiber held in the alignment member is longer than a length of the metal wire held in the alignment member;
The optical cable terminal as described in any one of Claims 1-3. An outer member that covers an outer periphery of the alignment member and an outer periphery of the optical cable;
The optical cable terminal as described in any one of Claims 1-4.

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