JP2015175979A - optical fiber connector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical fiber connector that is hard to generate separation of a refractive index matching adhesive and damage of an optical fiber by relieving stress concentration caused at a tip end of the optical fiber.SOLUTION: An optical fiber connector 100 comprises: an optical fiber 101; an optical component 102 to which the optical fiber 101 is optically connected; a holding component 104 that retains a terminal of the optical fiber 101 and has an alignment groove 103 for aligning an optical axis of the optical fiber 101 and an optical axis of the optical component 102; and a pressing component 105 for pressing the terminal of the optical fiber 101 against the holding component 104. The optical fiber 101 and the holding component 104 are formed of materials having linear expansion coefficients different from each other. A tip end 113 of the optical fiber 101 is spherically processed, and the terminal is fixed on the holding component 104 with the pressing component 105 by a refractive index matching adhesive 111.

Description

  The present invention relates to an optical fiber connector suitable for optical connection between an optical fiber and an optical device.

  When optically connecting an optical fiber to an optical device or the like, as shown in FIG. 6, the optical fiber 601, the optical component 602 to which the optical fiber 601 is optically connected, and the end of the optical fiber 601 are held. And a holding component 604 having an alignment groove 603 that aligns the optical axis of the optical fiber 601 and the optical axis of the optical component 602, and a pressing component 605 that presses the end of the optical fiber 601 against the holding component 604. An optical fiber connector 600 is widely used.

  In the optical fiber connector 600, as shown in FIGS. 7 and 8, the optical fiber 601 is firmly fixed to the holding component 604 together with the holding component 605 by the refractive index matching adhesive 606 having a Young's modulus after curing of 100 MPa or more. Yes.

JP 2008-151843 A Japanese Patent No. 4747229 Japanese Patent Laid-Open No. 6-18745

  By the way, the optical fiber 601 and the holding part 605 are made of quartz glass, and the optical part 602 and the holding part 604 are made of a material having a larger linear expansion coefficient than that of quartz glass, for example, polyetherimide resin. .

  As described above, since the optical fiber 601 and the holding component 604 are formed of materials having different linear expansion coefficients, when the optical fiber connector 600 is used in a high temperature environment, the optical fiber 601 and the holding component 604 are caused by the difference in linear expansion coefficient. As a result, a dimensional error between the optical fiber 601 and the holding component 604 increases.

  Then, stress concentration occurs in a portion where the refractive index matching adhesive 606 is slightly present, for example, a portion 607 where the optical fiber 601 and the alignment groove 603 are in contact, and the portion 607 is refracted as a starting point. The index matching adhesive 606 may peel off, or the optical fiber 601 may be damaged as the refractive index matching adhesive 606 peels off.

  In addition, when the refractive index matching adhesive 606 is injected, it is possible to visually check whether the refractive index matching adhesive 606 has sufficiently penetrated to the tip of the optical fiber 601. Reference numeral 605 presses the terminal excluding the tip of the optical fiber 601 against the holding component 604.

  Therefore, the end of the optical fiber 601 excluding the tip is firmly fixed to the holding component 604 together with the holding component 605 formed of quartz glass having a relatively small linear expansion coefficient, like the optical fiber 601, and the refractive index matching. Although peeling of the adhesive 606 is difficult to occur, the tip portion of the optical fiber 601 is not fixed to the holding component 604 together with the holding component 605, and thus is caused by a difference in linear expansion coefficient between the optical fiber 601 and the holding component 604. Stress concentration tends to occur.

  A method of absorbing the amount of elongation of the alignment groove 603 in a high temperature environment by adjusting the distance L between the end face of the optical fiber 601 and the optical component 602 is also conceivable, but the end face of the optical fiber 601 is cut. Since the burr 608 generated sometimes is included, it is difficult to accurately manage the distance L, and the end face of the optical fiber 601 is cut substantially vertically, and includes a corner portion 609 where stress concentration is likely to occur. Therefore, it is not possible to prevent the peeling of the adhesive 606 and the damage of the optical fiber 601 only by adjusting the distance L.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an optical fiber connector in which stress concentration generated at the tip of an optical fiber is alleviated and the refractive index matching adhesive is not peeled off or the optical fiber is hardly damaged.

  The present invention created to achieve this object includes an optical fiber, an optical component to which the optical fiber is optically connected, a terminal of the optical fiber, an optical axis of the optical fiber, and the optical fiber. A holding part having an alignment groove for aligning the optical axis of the part, and a holding part that presses the end of the optical fiber against the holding part, wherein the optical fiber and the holding part have a linear expansion coefficient. The optical fiber is an optical fiber connector that is formed of different materials, the tip of the optical fiber is a tip, and the terminal is fixed to the holding part together with the holding part by a refractive index matching adhesive. .

  The optical fiber is preferably in contact with the optical component at the tip.

  The holding part is formed across the tip of the alignment groove, and further includes a concave groove that exposes the tip of the optical fiber from the alignment groove. Is preferably fixed to the holding part by the refractive index matching adhesive filled in the concave groove.

  It is preferable that the concave groove has a width that exposes at least the entire tip of the optical fiber, which is formed into a tip, from the tip of the alignment groove.

  The concave groove is preferably formed deeper than the alignment groove.

  The refractive index matching adhesive preferably has a Young's modulus after curing of 100 MPa or more.

  The optical fiber and the holding part are preferably made of quartz glass, and the holding part is preferably made of a material having a larger linear expansion coefficient than quartz glass.

  ADVANTAGE OF THE INVENTION According to this invention, the stress concentration which generate | occur | produces in the front-end | tip part of an optical fiber can be eased, and the optical fiber connector with which peeling of a refractive index matching adhesive agent or damage to an optical fiber cannot occur easily can be provided.

It is a front perspective view showing an optical fiber connector concerning an embodiment of the invention. It is a back perspective view showing an optical fiber connector concerning an embodiment of the invention. It is the sectional view on the AA line of FIG. It is a back perspective view showing an optical fiber connector concerning a modification of the present invention. It is the BB sectional view taken on the line of FIG. It is a front perspective view which shows the optical fiber connector which concerns on a prior art. It is CC sectional view taken on the line of FIG. It is the DD sectional view taken on the line of FIG.

  Preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

  As shown in FIGS. 1 to 3, an optical fiber connector 100 according to the present embodiment holds an optical fiber 101, an optical component 102 to which the optical fiber 101 is optically connected, and a terminal of the optical fiber 101. And a holding component 104 having an alignment groove 103 that aligns the optical axis of the optical fiber 101 and the optical axis of the optical component 102, and a pressing component 105 that presses the end of the optical fiber 101 against the holding component 104. Yes.

  Here, the optical fiber 101 and the holding component 104 are formed of materials having different linear expansion coefficients. When the optical fiber connector 100 is used in a high temperature environment, the optical fiber 101 and the holding component 104 are caused by the difference in linear expansion coefficient. It is assumed that a dimensional error occurs between the optical fiber 101 and the holding component 104.

  The periphery of the optical fiber 101 is covered with a coating layer 106 in the longitudinal direction, and is exposed from the coating layer 106 at the terminal. The optical fiber 101 exposed from the coating layer 106 is accommodated in the alignment groove 103 and is pressed toward the bottom of the alignment groove 103 by the pressing component 105.

  The pressing component 105 may be formed so as to press not only the optical fiber 101 exposed from the coating layer 106 but also the optical fiber 101 coated with the coating layer 106 toward the holding component 104.

  In the drawing, each of the plurality of optical fibers 101 is depicted as being independent, but the plurality of optical fibers 101 and a collective coating layer that collectively coats the periphery of the plurality of optical fibers 101, It becomes possible to improve the handleability and terminal processability of the optical fiber 101 by using an optical fiber tape having.

  Furthermore, in some drawings, in order to make it easy to grasp the configuration of the holding component 104, the optical fiber 101 is drawn with a broken line, and the holding component 105 is further disassembled.

  The optical component 102 includes, for example, a lens array having a plurality of lenses 107 arranged in parallel. The optical component 102 is formed integrally with the holding component 104 using a resin molding technique, and the positional relationship between the lens 107 of the optical component 102 and the alignment groove 103 of the holding component 104 is fixed. .

  The alignment groove 103 is formed of, for example, a V-shaped V-shaped cross section, and the optical fiber 101 exposed from the coating layer 106 is accommodated in the alignment groove 103, and is held at the bottom of the alignment groove 103 by the holding member 105. It is formed so that the optical axis of the optical fiber 101 and the optical axis of the optical component 102 are automatically aligned by simply pressing toward the optical fiber.

  The alignment groove 103 can be formed by a U-shaped U-shaped cross section or a rectangular rectangular groove, or a round hole can be formed instead of the alignment groove 103. In order to accommodate the optical fiber 101, it is necessary to make the size larger than that of the optical fiber 101, and there is a risk of rattling when the optical fiber 101 is accommodated in a U groove or a round hole. It is difficult to automatically align the optical axis of the component 102.

  The holding component 104 includes the holding portion 108 in which the alignment groove 103 is formed and the optical fiber 101 exposed from the coating layer 106 is held, and the holding portion 108 and the step portion 109 using a resin molding technique. And a fixing portion 110 to which the optical fiber 101 formed integrally and covered with the coating layer 106 is fixed.

  The step 109 is exposed from the coating layer 106 when the optical fiber 101 exposed from the coating layer 106 is held by the holding unit 108 and the optical fiber 101 covered with the coating layer 106 is fixed to the fixing unit 110. The light exposed from the coating layer 106 is maintained so that the optical axis of the optical fiber 101 is maintained in a substantially straight line between the optical fiber 101 and the optical fiber 101 coated with the coating layer 106 to prevent deterioration of optical characteristics. The height is formed so as to absorb the difference in outer diameter between the fiber 101 and the optical fiber 101 covered with the coating layer 106.

  Among these components, the optical fiber 101 and the holding component 105 are made of quartz glass, and the optical component 102 and the holding component 104 are materials having a larger linear expansion coefficient than that of quartz glass, for example, polyetherimide resin. It is formed with. That is, the optical fiber 101 and the holding component 104 are formed of materials having different linear expansion coefficients.

  When the optical fiber connector 100 is manufactured, the holding component 104 is prepared in advance, the optical fiber 101 is terminated, the optical fiber 101 is exposed from the coating layer 106, and then the light exposed from the coating layer 106 is obtained. The fiber 101 is held by the holding unit 108 and the optical fiber 101 covered with the coating layer 106 is fixed to the fixing unit 110, and the end of the optical fiber 101 is accommodated in the alignment groove 103.

  Thereafter, the refractive index matching adhesive 111 for fixing the optical fiber 101 to the holding component 104 in a state where the optical fiber 101 exposed from the coating layer 106 is pressed by the pressing component 105 toward the bottom of the alignment groove 103. Is injected from the rear end 112 of the alignment groove 103, and the refractive index matching adhesive 111 is infiltrated into the tip end portion 113 of the optical fiber 101 exposed from the coating layer 106 by capillary action to hold the optical fiber 101 together with the holding part 105. Fix to the holding component 104.

  At this time, the optical fiber 101 and the pressing part 105 can be firmly fixed to the holding part 104 by using the refractive index matching adhesive 111 having a Young's modulus after curing of 100 MPa or more.

In the optical fiber connector 100 according to the present embodiment, the optical fiber 101 has the tip 113 formed into a tip by using a CO ₂ laser or the like, and the terminal is pressed by the refractive index matching adhesive 111. At the same time, it is fixed to the holding component 104.

  As a result, since there are no burrs or corners on the end face of the optical fiber 101, stress concentration generated at the tip 113 of the optical fiber 101 is alleviated to prevent peeling of the refractive index matching adhesive 111 and damage to the optical fiber 101. It becomes possible to do.

  Furthermore, since the tip portion 113 of the optical fiber 101 is made into a front ball, a larger amount of refractive index matching adhesive 111 can be filled around the tip portion 113 of the optical fiber 101 than in the prior art. In the tip portion 113 of the fiber 101, a portion where the optical fiber 101 and the alignment groove 103 are in contact can be completely eliminated.

  Therefore, the optical fiber 101 is sufficiently fixed to the holding component 104, and the refractive index matching adhesive 111 is hardly peeled off at the tip end portion 113 of the optical fiber 101, resulting in damage to the optical fiber 101. Can also be prevented.

  Further, in the optical fiber connector 600 according to the prior art, since the burr 608 is generated on the end face when the optical fiber 601 is cut, it is difficult to accurately adjust the distance L between the end face of the optical fiber 601 and the optical component 602. Thus, the end face of the optical fiber 601 could not be matched with the focal position of the optical component 602 with high accuracy.

  On the other hand, in the optical fiber connector 100 according to the present embodiment, since the tip portion 113 of the optical fiber 101 is formed into a front ball, there are no burrs and corners on the end surface of the optical fiber 101, and the optical fiber. The end face of the optical fiber 101 can always be arranged at the same position only by bringing the tip 113 of the 101 into contact with the optical part 602, and the end face of the optical fiber 601 can be easily aligned with the focal position of the optical part 602. It becomes possible.

  Even if the tip portion 113 of the optical fiber 101 is brought into contact with the optical component 602, the tip portion 113 of the optical fiber 101 is made to be a front ball, so that the stress received from the contacted optical component 602 is dispersed. Thus, damage to the end face of the optical fiber 101 can be suppressed. In particular, stress can be more effectively dispersed by making the tip 113 of the optical fiber 101 into a perfect circle.

  The present invention is not limited to the embodiment described above, and various modifications can be made without departing from the spirit of the present invention.

  For example, as shown in FIGS. 4 and 5, the holding component 104 is formed across the tip 114 of the alignment groove 103, and is a concave groove that exposes the tip 113 of the optical fiber 101 from the alignment groove 103. 115, and the optical fiber 101 may be an optical fiber connector 400 that is fixed to the holding component 104 by the refractive index matching adhesive 111 whose tip 113 is filled in the concave groove 115.

  In this case, the concave groove 115 has a width that exposes at least the entire front end portion 113 of the optical fiber 101 that is formed into the front ball from the front end 114 of the alignment groove 103, and is formed deeper than the alignment groove 103. It is preferable.

  As a result, a portion where stress concentration is likely to occur from the vicinity of the distal end portion 113 of the optical fiber 101 can be completely eliminated, and peeling of the refractive index matching adhesive 111 and damage to the optical fiber 101 can be more effectively prevented. It becomes possible.

  The concave groove 115 is formed by forming a portion corresponding to the concave groove 115 in advance in a mold for producing the holding component 104 using a resin molding technique, and using this die to fix the holding component 104. It can be easily formed by manufacturing.

DESCRIPTION OF SYMBOLS 100 Optical fiber connector 101 Optical fiber 102 Optical part 103 Alignment groove 104 Holding part 105 Holding part 106 Cover layer 107 Lens 108 Holding part 109 Step part 110 Fixing part 111 Refractive index matching adhesive 112 Rear end 113 Front end part 114 Front end 115 Concave Groove 400 optical fiber connector

Claims (7)

Optical fiber,
An optical component to which the optical fiber is optically connected;
A holding part having an alignment groove for holding the end of the optical fiber and aligning the optical axis of the optical fiber and the optical axis of the optical part;
A holding part that presses the end of the optical fiber against the holding part;
With
The optical fiber and the holding component are formed of materials having different linear expansion coefficients,
An optical fiber connector, wherein the optical fiber has a tip formed at a tip, and a terminal is fixed to the holding component together with the pressing component by a refractive index matching adhesive.   The optical fiber connector according to claim 1, wherein a tip portion of the optical fiber is in contact with the optical component. The holding component is further formed with a concave groove that is formed across the tip of the alignment groove and exposes the tip of the optical fiber from the alignment groove;
The optical fiber connector according to claim 1 or 2, wherein the optical fiber is fixed to the holding component by the refractive index matching adhesive having a tip portion filled in the concave groove.   4. The optical fiber connector according to claim 3, wherein the concave groove has a width that exposes at least the entire front end portion of the optical fiber formed into a front ball from the front end of the alignment groove. 5.   The optical fiber connector according to claim 3 or 4, wherein the concave groove is formed deeper than the alignment groove.   The optical fiber connector according to any one of claims 1 to 5, wherein the refractive index matching adhesive has a Young's modulus after curing of 100 MPa or more. The optical fiber and the holding part are made of quartz glass,
The optical fiber connector according to any one of claims 1 to 6, wherein the holding component is formed of a material having a larger linear expansion coefficient than quartz glass.

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