JP2012088437A - Optical fiber splicer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical fiber splicer capable of accurately butting optical fibers together.SOLUTION: An optical fiber splicer 1 includes a mechanical splicing part 8 for butting two optical fibers together to mechanically connect them and a wedge member 14 attached to the mechanical splicing part 8. The mechanical splicing part 8 includes a base member 82 having a fiber groove 81 formed therein to position a glass fiber 5, a lid member 83 for retaining the glass fiber 5 disposed in the fiber groove 81 with respect to the base member 82, and a clamp spring 84 clipping the base member 82 and the lid member 83 so as to press and fix the glass fiber 5 by the base member 82 and the lid member 83. The clamp spring has a substantially cylindrical shape having a part opened, and a wedge part 14b of the wedge member 14 is preliminarily inserted to an open part 84a of the clamp spring 84 against pressing force of the clamp spring 84.

Description

  The present invention relates to an optical fiber connector for connecting two optical fibers.

  As a conventional optical fiber connector in the above technical field, for example, an optical fiber connector described in Patent Document 1 is known. An optical fiber connector disclosed in Patent Document 1 includes a base portion including a base formed with a V-groove for positioning the optical fiber, a lid for pressing the optical fiber disposed in the V-groove against the base, and a base And a C-type spring mounted on the main body so as to press and fix the optical fiber with the lid. Further, a wedge insertion groove for inserting a wedge member is formed at a boundary portion between the base and the lid, and the wedge member is inserted in advance into the wedge insertion groove. For this reason, in this optical fiber connector, a gap is formed in advance between the base and the lid against the pressing force of the C-type spring. In such an optical fiber connector, when two optical fibers are connected, first, the two optical fibers are inserted into the gap between the base and the lid along the V groove of the base, and abut each other. . Thereafter, by removing the wedge member from the wedge insertion groove, the gap is closed by the pressing force of the C-shaped spring, and the two optical fibers that are in contact with each other are pressed and fixed by the base and the lid.

JP-A-9-159869

  By the way, when the gap is formed by expanding the base and the lid by inserting a wedge member at the boundary between the base and the lid as in the optical fiber connector described in Patent Document 1, the gap is It may be too large compared to the diameter of the optical fiber. In such a case, when inserting an optical fiber, an optical fiber will slip | deviate from a V groove and it will become difficult to match | combine optical fibers correctly.

  This invention is made | formed in view of such a situation, and makes it a subject to provide the optical fiber connector which can face | match an optical fiber correctly.

  In order to solve the above-described problems, an optical fiber connector of the present invention includes a mechanical splice part that mechanically connects two optical fibers by abutting each other, and a wedge member attached to the mechanical splice part. The splice unit includes a base member in which a fiber groove for positioning the optical fiber is formed, a lid member for pressing the optical fiber disposed in the fiber groove against the base member, and the base member and the lid member. The clamp spring sandwiches the base member and the lid member so as to be pressed and fixed. The clamp spring has a substantially cylindrical shape with a part opened, and the wedge member resists the pressing force of the clamp spring. And inserted in advance in the open portion of the clamp spring.

  In this optical fiber connector, the wedge member is inserted in advance into the open portion of the clamp spring against the pressing force of the clamp spring. For this reason, when two optical fibers are connected, the two optical fibers are inserted between the base member and the lid member along the fiber groove and abut each other, and then the wedge member is removed from the clamp spring. By simply doing so, the optical fibers can be mechanically connected to each other. In addition, in this optical fiber connector, the wedge member is inserted into the open portion of the clamp spring to reduce the pressing force from the clamp spring to the base member and the lid member, so that the light is applied between the base member and the lid member. A fiber can be inserted. For this reason, the gap does not become too large as compared with the case where the wedge member is inserted between the base member and the lid member to widen the base member and the lid member to form the gap. Accordingly, when the optical fiber is inserted between the base member and the lid member, the optical fiber is prevented from being displaced from the fiber groove. Therefore, the optical fibers can be accurately matched.

  In the optical fiber connector of the present invention, the wedge member is made of a material that transmits visible light, and the open portion of the clamp spring extends from one end of the clamp spring to the other end so that the gap between the base member and the lid member is exposed. It is preferable that it extends. In this case, visible light leaking from the connection portion of the optical fiber when the connection between the optical fibers is insufficient can be visually recognized through the gap between the base member and the lid member, the open portion of the clamp spring, and the wedge member. it can. For this reason, the connection state of optical fibers can be confirmed by whether the said visible light is visually recognized.

  The optical fiber connector of the present invention may further include a ferrule integrally fixed to the base member, and the ferrule may incorporate one of the two optical fibers. In this case, the optical fiber connector is configured as an optical connector.

  ADVANTAGE OF THE INVENTION According to this invention, the optical fiber connector which can match | combine optical fibers correctly can be provided.

It is a perspective view of one embodiment of an optical fiber connector concerning the present invention. It is the II-II sectional view taken on the line of FIG. It is an expanded sectional view of the mechanical splice part shown by FIG. It is sectional drawing which shows the open / close state of the mechanical splice part shown by FIG. It is sectional drawing which shows the modification of the mechanical splice part shown by FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of an optical fiber connector according to the present invention will be described in detail with reference to the drawings.

  FIG. 1 is a perspective view of an embodiment of an optical fiber connector according to the present invention. 2 is a cross-sectional view taken along line II-II in FIG. As shown in FIGS. 1 and 2, the optical fiber connector 1 is attached to the end of a drop cable 2.

  The drop cable 2 is an optical cable formed by covering an optical fiber core wire 3 and a pair of tension members (not shown) with a cable jacket 4. In the drop cable 2, the optical fiber core wire 3 is tightly configured, and the optical fiber core wire 3 and the cable jacket 4 are in close contact with each other. Such a drop cable 2 has a substantially rectangular cross section with a width of about 2.4 to 3.3 mm and a thickness of about 1.8 to 2.2 mm. The optical fiber core wire 3 includes a glass fiber (optical fiber) 5 and a covering portion 6 that covers the glass fiber 5.

  As shown in FIG. 1 and FIG. 2, the optical fiber connector 1 is fixed to the jacket fixing portion 7 that fixes the cable jacket 4 in a state of covering the optical fiber core wire 3, and the jacket fixing portion 7. A mechanical splice portion 8 for fixing the glass fiber 5 and the like exposed from the covering portion 6 of the tip portion 3a of the optical fiber core wire 3 exposed from the cable jacket 4; and a glass fiber 5 fixed to the mechanical splice portion 8 A ferrule 9 containing an optical fiber F connected to the housing, a connecting portion 10 that connects the jacket fixing portion 7 and the mechanical splice portion 8, a housing 11 that houses the mechanical splice portion 8, and a part of the connecting portion 10 And a housing portion 12 for housing the jacket fixing portion 7, a knob 13 attached to the housing 11, and a mechanical splice portion 8 via the housing 11 and the knob 13. And attached wedge member 14, and a.

  The jacket fixing portion 7 has a demon (not shown) formed therein, and the cable jacket in a state of covering the optical fiber core wire 3 by biting the demon into the cable jacket 4. 4 is fixed. By this fixing, the position of the terminal portion of the drop cable 2 is fixed, and twisting of the optical fiber core wire 3 and the glass fiber 5 exposed from the cable jacket 4 is prevented.

  The connecting portion 10 is locked with respect to the mechanical splice portion 8 by the locking claw 8a formed at the rear end portion of the mechanical splice portion 8 being caught by the locking window 10a formed at the front end portion thereof. It becomes a state. Further, the connecting portion 10 is engaged with the outer cover fixing portion 7 by the hooking claw 7a formed at the front end portion of the outer jacket fixing portion 7 being caught by the locking window 10b formed at the rear end portion thereof. It will be stopped.

  As described above, the connecting portion 10 is engaged with both the mechanical splice portion 8 and the jacket fixing portion 7, thereby connecting the mechanical splice portion 8 and the jacket fixing portion 7. Further, the connecting portion 10 has a tapered portion 10 c for guiding the optical fiber core wire 3 exposed from the cable jacket 4 fixed to the jacket fixing portion 7 to the mechanical splice portion 8. Thereby, the front-end | tip part 3a of the optical fiber core wire 3 is easily guided to the mechanical splice part 8 along the inner wall of the taper part 10c.

  The accommodating part 12 has the base 12a in which the jacket fixing | fixed part 7 and the taper part 10c of the connection part 10 are arrange | positioned, and the cover part 12b attached to the base 12a so that opening and closing is possible. In the housing part 12, the cover fixing part 7 and the connecting part 10 can be closed by closing the cover part 12b with the taper part 10c of the connecting part 10 being disposed on the base part 12a. The tapered portion 10 c is accommodated in the accommodating portion 12.

  Such a housing portion 12 is locked to the housing 11 by a locking claw 12 c provided at the front end portion of the base portion 12 a being hooked on a locking window 11 a provided at the rear end portion of the housing 11. It becomes the state.

  Here, a mechanical splice portion 8 is accommodated in the housing 11. Two openings 11 d and 11 e arranged in the front-rear direction of the optical fiber connector 1 are formed on the upper surface 11 c of the housing 11. Therefore, a part of the mechanical splice portion 8 is exposed from the two openings 11 d and 11 e of the housing 11.

  The knob 13 is attached to the housing 11 so as to be slidable in the front-rear direction of the optical fiber connector 1. An opening 13 b and a notch 13 c arranged in the front-rear direction of the optical fiber connector 1 are formed on the upper surface 13 a of the knob 13. The opening 13 b is formed at a position corresponding to the opening 11 d of the housing 11, and the notch 13 c is formed at a position corresponding to the opening 11 e of the housing 11. Therefore, a part of the mechanical splice 8 is exposed from the opening 13b and the notch 13c of the knob 13 through the opening 11d and the opening 11e of the housing 11, respectively.

  The mechanical splice portion 8 partially exposed from the housing 11 and the knob 13 in this manner is for abutting and mechanically connecting two optical fibers (glass fiber 5 and optical fiber F). As shown in FIGS. 3 and 4, the mechanical splice unit 8 is disposed in the fiber groove 81 and a base member 82 in which a fiber groove 81 having a V-shaped cross section for positioning the glass fiber 5 and the optical fiber F is formed. The base member 82 is configured to press and fix the glass fiber 5 and the optical fiber F with the lid member 83 for pressing the glass fiber 5 and the optical fiber F against the base member 82, and the base member 82 and the lid member 83. And a clamp spring 84 sandwiching the lid member 83. The ferrule 9 is integrally fixed to the base member 82.

  The clamp spring 84 has a substantially rectangular cylindrical shape with a part opened. The open portion 84a of the clamp spring 84 extends from one end of the clamp spring 84 to the other end so that a gap (boundary portion) between the base member 82 and the lid member 83 is exposed. In the optical fiber connector 1, the open portion 84 a is formed by the housing 11 and the knob 13 via the opening 11 d and the opening 11 e of the housing 11 and the opening 13 b and the notch 13 c of the knob 13, respectively. Is exposed from.

  The wedge member 14 has a main body portion 14a and two wedge portions 14b formed to protrude from the main body portion 14a. In the optical fiber connector 1, each of the wedge portions 14 b passes through the opening 13 b and the notch 13 c of the knob 13, and the opening 11 d and the opening 11 e of the housing 11. The clamp spring 84 is inserted in advance in the open portion 84a.

  The wedge portion 14 b of the wedge member 14 is inserted against the pressing force of the clamp spring 84. Therefore, in the optical fiber connector 1, the base member 82 and the lid member 83 are released in advance from the pressing force from the clamp spring 84. That is, the pressing force from the clamp spring 84 to the base member 82 and the lid member 83 is reduced in advance.

  In the optical fiber connector 1 configured as described above, when the glass fiber 5 and the optical fiber F built in the ferrule 9 are connected, as shown in FIG. 3 and FIG. The glass fiber 5 is inserted along the fiber groove 81 between the reduced base member 82 and the lid member 83. And the front end surface of the glass fiber 5 and the one end surface of the optical fiber F are faced | matched through the refractive index matching agent C. FIG.

  In this state, as shown in FIG. 4B, the wedge portion 14 b of the wedge member 14 inserted in advance in the open portion 84 a of the clamp spring 84 is removed from the open portion 84 a of the clamp spring 84. Then, the base member 82 and the lid member 83 are closed by the urging force (pressing force) of the clamp spring 84, and both are fixed to the mechanical splice portion 8 in a state where the glass fiber 5 and the optical fiber F are connected. The Rukoto.

  As described above, in the optical fiber connector 1, the wedge portion 14 b of the wedge member 14 is inserted in advance into the open portion 84 a against the pressing force of the clamp spring 84. For this reason, when the glass fiber 5 and the optical fiber F are abutted and connected, the two glass fibers 5 are inserted between the base member 82 and the lid member 83 along the fiber groove 81, and the glass fiber 5 After the buttocks and the optical fiber F are butted together, the glass fiber 5 and the optical fiber F can be butted and mechanically connected simply by removing the wedge portion 14b of the wedge member 14 from the clamp spring 84. That is, when the glass fiber 5 and the optical fiber F are connected, the operation of inserting the wedge member into the open portion 84a of the clamp spring 84 becomes unnecessary.

  Moreover, in this optical fiber connector 1, the pressing force from the clamp spring 84 to the base member 82 and the lid member 83 is reduced by inserting the wedge portion 14 b of the wedge member 14 into the open portion 84 a of the clamp spring 84. The optical fiber can be inserted between the base member 82 and the lid member 83. For this reason, compared with the case where the wedge portion 14b of the wedge member 14 is directly inserted between the base member 82 and the lid member 83 and the base member 82 and the lid member 83 are spread to form a gap, the gap is smaller. It doesn't get too big. Therefore, when the glass fiber 5 is inserted between the base member 82 and the lid member 83, the glass fiber 5 is prevented from being displaced from the fiber groove 81. Therefore, the glass fiber 5 and the optical fiber F can be accurately matched.

  In this optical fiber connector 1, the wedge member 14 is made of a material that transmits visible light (for example, a resin material such as PSU (polysulfone), PC (polycarbonate), and PEI (polyetherimide)). It is preferable. In this case, visible light leaking from these end faces when the connection between the glass fiber 5 and the optical fiber F is not sufficient, the gap between the base member 82 and the lid member 83, the open portion 84 a of the clamp spring 84, and the wedge member 14. It can visually recognize from the exterior of the optical fiber connector 1 via.

  That is, by visually recognizing the visible light, it can be confirmed whether or not the glass fiber 5 and the optical fiber F are sufficiently connected. Therefore, in this case, the glass fiber 5 and the optical fiber F can be reliably connected while confirming the connection state between the glass fiber 5 and the optical fiber F. Furthermore, if the wedge member 14 is made of resin, the weight of the optical fiber connector 1 can be reduced.

  The present invention is not limited to the above embodiment. For example, in the optical fiber connector 1 of the above-described embodiment, a mechanical splice portion 8A as shown in FIG. 5 can be used instead of the mechanical splice portion 8.

  The mechanical splice portion 8A is for connecting the two glass fibers 5 to each other. Similar to the mechanical splice portion 8, the mechanical splice portion 8A has a substantially cylindrical clamp spring 84 that is partially opened, and a wedge member is inserted in advance in the open portion.

  For this reason, even in such a mechanical splice portion 8A, when the glass fibers 5 are connected to each other, the operation of inserting the wedge member into the open portion of the clamp spring 84 becomes unnecessary. And when inserting the glass fiber 5, it is suppressed that these shift | deviate from a fiber groove. Therefore, even in such a mechanical splice portion 8A, the glass fibers 5 can be accurately butted together.

  Moreover, although the optical fiber connector 1 of the said embodiment shall be attached to the terminal of the drop cable 2, it can be attached and used for another optical cable or optical fiber.

  DESCRIPTION OF SYMBOLS 1 ... Optical fiber connector, 5 ... Glass fiber, 8 ... Mechanical splice part, 9 ... Ferrule, 14 ... Wedge member, 14a ... Wedge part, 81 ... Fiber groove, 82 ... Base member, 83 ... Cover member, 84 ... Clamp Spring, 84a ... open part, F ... optical fiber.

Claims (3)

A mechanical splice unit that mechanically connects two optical fibers by matching each other;
A wedge member attached to the mechanical splice part,
The mechanical splice portion includes a base member having a fiber groove for positioning the optical fiber, a lid member for pressing the optical fiber disposed in the fiber groove against the base member, and the base member. A clamp spring that sandwiches the base member and the lid member so as to press and fix the optical fiber with the lid member;
The clamp spring has a substantially cylindrical shape with a part opened,
The wedge member is inserted in advance in the open portion of the clamp spring against the pressing force of the clamp spring,
An optical fiber connector characterized by that. The wedge member is made of a material that transmits visible light,
2. The light according to claim 1, wherein the open portion of the clamp spring extends from one end to the other end of the clamp spring such that a gap between the base member and the lid member is exposed. Fiber connector. A ferrule integrally fixed to the base member;
The optical fiber connector according to claim 1 or 2, wherein the ferrule incorporates one of the two optical fibers.

Images