JP2011221163A - Manufacturing method for optical fiber tape core - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a manufacturing method for an optical fiber tape core with sure adhesive connection between the optical fiber cores which can grant adhesive resin only in between adjacent cores 2 of the optical fiber core from both surfaces of the optical fiber tape core 1.SOLUTION: The manufacturing method for the optical fiber tape core: has optical fiber cores 11a to 11d which are three or more cores made parallel; intermittent adhesive connections are made only in between two adjacent optical fiber cores; and the adhesive connection portions are separated in the longitudinal direction of the optical fiber core not to be adjacent in the parallel direction of the optical fiber core. In this manufacturing method, optical fiber core of three or more cores are fed out to be closely lined up in one vertical row in the vertical direction and at the same time, the optical fiber core of three or more cores is integrated to be tape-like by making intermittent adhesive connections for a prescribed distance of both side surfaces in between the optical fiber core of two cores lined up adjacent to each other on the lower side by a plurality of adhesive means which are arranged separated in the longitudinal direction.

Description

  The present invention relates to a method for manufacturing an optical fiber ribbon, in which a plurality of optical fibers are arranged in a row and are intermittently bonded.

  Optical fiber tape cores, in which a plurality of optical fiber cores are arranged in a line and covered together with a common resin, can be fused together and are often used due to their good capacity as a multi-fiber optical cable. Yes. However, with the expansion of optical communication and the like, single-core separation, which is also called post-branching, is often performed by taking out an optical fiber ribbon from a laid optical cable and dividing it into single-core optical fibers. Moreover, the single-core separation work needs to be performed in a live state of the optical cable and in an environment such as outdoors.

As an optical fiber ribbon satisfying such a demand, for example, in Patent Document 1, three or more optical fiber cores are arranged in a line, and only adjacent optical fiber cores are intermittently connected by a connecting portion. And the thing of the structure staggered so that a connection part does not overlap in the width direction (parallel direction) (it does not adjoin) is disclosed. The optical fiber ribbon of the configuration can handle the unconnected parts as if they were a single fiber, gathered in bundles by rounding in the width direction, and then extrusion molding on the outer periphery It is easy to make a multi-core optical cable by covering with a jacket. In addition, it is said that workability is improved because the optical fiber can be easily separated into single-core wires at the time of intermediate rear branching.
Patent Document 2 discloses a manufacturing method for intermittently connecting adjacent optical fiber core wires using a syringe.

Japanese Patent No. 4143651 JP 2003-241041 A

  Patent Document 1 also shows an example in which two adjacent connecting portions of an optical fiber ribbon are formed on both sides of the ribbon, but there is no disclosure of a manufacturing method thereof. It is not clear if it is formed. On the other hand, in Patent Document 2, energy beam curable resin is intermittently discharged from a plurality of cylindrical nozzles collected at one place between two adjacent optical fiber cores of an optical fiber tape core. And then, the resin is cured and bonded and integrated.

  The method disclosed in Patent Document 2 is schematically shown in FIG. That is, it is assumed that the four optical fiber cores 1a to 1d are optical fiber tape core wires 1 arranged in close contact with each other, and two adjacent cores are intermittently connected by the adhesive resin 2 in the longitudinal direction. In this case, the adhesive resin 2 is applied from the needle 3a of the syringe 4a between the optical fiber cores 1a and 1b, and the adhesive resin 2 is applied from the needle 3b of the syringe 4b between the optical fiber cores 1b and 1c. Between the optical fiber cores 1c and 1d, the adhesive resin 2 is applied from the needle 3c of the syringe 4c and adhered to each other. The application length and application position of the adhesive resin are individually controlled by each dispenser (not shown).

  The adhesive resin 2 is applied between the optical fiber cores that are dropped from the needles 3a to 3c and are in close contact with each other. Therefore, the application of the adhesive resin 2 has a problem that the adhesive strength is not sufficient only on one side (upper surface side) of the optical fiber ribbon 1. Also, as in Patent Document 1, when only two adjacent cores are bonded and applied so that they do not overlap in the parallel direction, light of three or more cores at the same position is caused by a positional shift caused by fine vibration during manufacturing. The fiber core may be bonded.

  In addition, in the above cited references 1 and 2, there is a description that the adhesive resin is also applied to the lower surface side, but in this case, the adhesive resin is sprayed upward with a nozzle, and there is a possibility that the adhesive resin hangs down. It is difficult to reliably bond. For this reason, an operation of applying an adhesive resin to one side of the optical fiber ribbon 1 and curing it, then flipping it upside down and bonding the opposite side in the same manner is assumed, but the manufacturing process is complicated. There is a problem that the production line speed is also slow.

  The present invention has been made in view of the above-described circumstances, and an adhesive resin can be applied from both surfaces of the optical fiber ribbon 1 to only between two adjacent optical fibers. It is an object of the present invention to provide a method of manufacturing an optical fiber ribbon with a reliable adhesive connection.

  In the method for manufacturing an optical fiber ribbon according to the present invention, three or more optical fiber cores are arranged in parallel, and only two adjacent optical fiber cores are intermittently adhesively connected, and the adhesively connected parts Is a method of manufacturing an optical fiber ribbon that is separated in the longitudinal direction of the optical fiber so as not to be adjacent in the parallel direction of the optical fibers. In this manufacturing method, the optical fiber cores of three or more cores are drawn out so as to be closely arranged in a vertical line in the vertical direction, and the upper and lower optical fiber cores are extended from the upper optical fiber core to the lower optical fiber core. It is fed out so that the timing closely arranged in the direction is sequentially delayed.

  Then, by using a plurality of bonding means spaced apart in the longitudinal direction, both side surfaces between the two optical fiber cores arranged on the lower side adjacent to each other are intermittently bonded and connected by a predetermined distance, so that three or more cores are connected. Are integrated into a tape shape. In addition, it is suitable for the said adhesion | attachment means to use the dispenser which supplies an ultraviolet curable adhesive resin intermittently using a needle, and the ultraviolet irradiation device which hardens | cures immediately after apply | coating an ultraviolet curable adhesive resin.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to apply | coat adhesive resin simultaneously from the both sides between optical fiber core wires, and can make adhesive connection strong. In addition, even if the adhesive resin hangs down, it does not adhere to other optical fiber cores, and can adhere only between the two optical fiber cores. A fiber ribbon can be used.

It is a figure explaining the outline of the present invention. It is a figure explaining an example of an embodiment of the present invention. It is a figure which shows the cable mounting example of the optical fiber tape core wire produced by the manufacturing method of this invention. It is a figure explaining the subject of this invention.

  An outline and an embodiment of the present invention will be described with reference to FIGS. In the figure, 10 is an optical fiber ribbon, 11a to 11d are optical fibers, 12a to 12c are adhesive connection portions, 13a to 13b are syringe needle pairs, 14a to 14c are syringe pairs, 15 is an adhesive resin, 16a to 16c is a dispenser, 17a to 17c are ultraviolet irradiation devices, 18a to 18d are feeding bobbins, and 19 is a winding bobbin.

  An optical fiber ribbon 10 (hereinafter referred to as a tape ribbon) formed by the manufacturing method of the present invention has a plurality of optical fibers 11a to 11d (for example, 4 cores) arranged in a line and two adjacent cores. Only the optical fiber cores of the optical fiber cores are intermittently adhesively connected, and the adhesively connected portions 12a to 12c are separated in the longitudinal direction of the optical fiber core wires so as not to be adjacent to each other in the parallel direction. ing. As each optical fiber core, for example, a glass fiber having a glass diameter of 125 μm and a strand coated with a protective coating having a coating diameter of about 250 μm or a colored wire thereon is used.

  In the manufacturing of the above-described tape core wire 10, the present invention is such that when a plurality of optical fiber core wires are formed into a tape, the optical fiber core wires 11a to 11d are arranged in a vertical line in the vertical direction as shown in FIG. To. However, as shown in FIG. 1 (A), the light is arranged so that the arrangement timing is sequentially shifted so that the number of hearts arranged in a vertical row becomes two hearts, three hearts, and four hearts at a predetermined interval. The fiber core wires 11a to 11d are sequentially drawn out. In FIG. 1A, the optical fiber core wire is drawn out from the left side, sent in the right direction, adhesively connected in a tape shape, and wound up.

  First, the first optical fiber core wire 11a and the second optical fiber core wire 11b arranged above are arranged in the vertical direction so as to be in close contact with each other at the first bonding position P1. Next, the third optical fiber core 11c is arranged in the vertical direction so as to be in close contact with the second optical fiber core 11b immediately above at the second bonding position P2. Similarly, the fourth optical fiber core 11d is similarly arranged in the vertical direction so as to be in close contact with the third optical fiber core 11c immediately above at the third bonding position P3. When the number of cores of the optical fiber core is n, the nth optical fiber core is in close contact with the adjacent (n−1) th optical fiber core at the n−1th bonding position. Are arranged in the vertical direction.

  Adhesive means are disposed at each of the bonding positions P1, P2, and P3, and the two optical fire cores that are in close contact with each other in the vertical direction are bonded and connected as indicated by the bonding connection portions 12a and 12b. As the bonding means, for example, an adhesive resin supply device including a syringe pair 14a to 14c for supplying the adhesive resin 15 in a controllable manner and a needle pair 13a to 13c, and ultraviolet irradiation devices 17a to 17c for curing the adhesive resin (FIG. 2).

  The adhesive resin 15 is preferably an ultraviolet-curing type that is also used for forming a protective coating for an optical fiber, whereby the adhesive resin can be easily cured. Moreover, the adhesive resin 15 can be applied dropwise by the syringe needle pairs 13a to 13c, and it is desirable that the adhesive resin 15 adheres by surface tension between the optical fiber core wires and does not easily drip. This is related to the viscosity of the adhesive resin 15, and a viscosity of 1 to 10 Pa · S at 25 ° C. is satisfactory.

  In addition, as shown in FIG. 1 (B), the syringe needle pairs 13a to 13c to which the adhesive resin 15 is applied are arranged on both sides of two optical fiber cores arranged in the vertical direction as a pair. It arrange | positions so that adhesive resin may be provided toward the close part between. As a result, since the adhesive connection of the optical fiber cores is performed from both sides of the parallel surface, the adhesive strength can be increased and the taped state can be prevented from being varied.

  Adhesive connection between the two optical fiber cores is performed between the two lowermost fibers in the vertical direction at the bonding positions (P1, P2, P3). That is, at the first bonding position P1, the optical fiber cores 11a and 11b are at the lowest end (in this case, the uppermost end), and at the second bonding position P2, the optical fiber cores 11b and 11c are at the lowest end. It becomes the lower end. In this way, even if the adhesive resin hangs down by adhesively connecting the two lowermost cores arranged in the vertical direction, the optical fiber core wire does not exist below the adhesive resin. It is limited between two cores and is not bonded and connected across three or more cores.

  FIG. 2 is an example in which the manufacturing method described in FIG. 1 is embodied. By using the same reference numerals as those used in the description of FIG. Although this example shows a method for manufacturing a tape core made of four optical fiber cores, the present invention can also be applied to manufacture of a tape core having three or more cores.

  As shown in FIG. 2 (A), the four optical fiber core wires 11a to 11d are fed out by the feeding bobbins 18a to 18d and, as described with reference to FIG. 1, at the predetermined bonding positions P1 to P3 in advance. They are arranged in parallel closely in the vertical direction in a defined order. The optical fiber core wire 11a fed out from the feeding bobbin 18a and the optical fiber core wire 11b fed out from the feeding bobbin 18b are arranged in the vertical direction at the bonding position P1. The optical fiber core wire 11c drawn out from the pay-out bobbin 18c is arranged in the vertical direction at least at the bonding position P2 with the optical fiber core wire 11b, and the optical fiber core wire 11d drawn out from the pay-out bobbin 18d is at least the optical fiber core wire. 11c and the bonding position P3 are arranged in the vertical direction.

  Syringe pairs 14a to 14c that supply and apply an adhesive resin as bonding means are disposed at the bonding positions P1 to P3, and the dispenser 16a to 16c supplies adhesive resin (ultraviolet curable resin) and discharges from the syringe needle pair. The amount is controlled. Further, the bonding means includes ultraviolet irradiation devices 17a to 17c that immediately cure the adhesive resin provided on the optical fiber core wires by the syringe pairs 14a to 14c, and the applied adhesive resin drips down and other The optical fiber core wire is prevented from adhering to the optical fiber and the amount of adhesion is not reduced. The ultraviolet irradiation devices 17a to 17c may be cured to such an extent that the adhesive resin does not sag, and complete curing may be performed by installing a separate powerful ultraviolet curing device on the downstream side.

  The adhesive connecting portions 12a to 12c are formed by applying (discharging) adhesive resin from the syringe pairs 14a to 14c, and the ranges thereof can be individually controlled by the dispensers 16a to 16c. Since the positions P1 to P3 are set at a predetermined distance, they can be given at the same timing. Therefore, the dispensers 16a to 16c can be controlled by one dispenser without providing for each syringe. Further, the adhesive resin of the adhesive connecting portions 12a to 12c is immediately cured by the respective ultraviolet irradiation devices 17a to 17c after being applied, and is sequentially sent to the winding bobbin 19 side without being dropped on the way. It is done. Then, an adhesive resin is applied to the next newly drawn optical fiber core wires 11a to 11d to form adhesive connection portions 12a to 12c.

  FIG. 2B is an example in which the adhesive connecting portions 12a to 12c are formed in a comb shape, and can be formed by the method described in FIG. In this case, for example, the distance a between the adhesive connecting portions 12a to 12c can be about 20 mm, and the distance b to the adjacent adhesive connecting portions can be about 100 to 150 mm. Adhesive connection between adjacent optical fiber cores is intermittently bonded at such an interval, so that a fusion splicing connection can be performed as a tape core wire, and it is easy to make a single optical fiber core wire. It can also be separated.

  FIG. 2 (C) is an example in which the adhesive connecting portions 12a to 12c are formed in an intertwined manner, and the adhesive connecting portions 12a and 12c are not connected although they are at the same position in the arrangement direction of the optical fiber core wires. It is separated from the adjacent adhesive connecting portion 12b. Therefore, also in this case, since the three optical fiber core wires are not adhesively connected at the same place, they can be handled in the same manner as in the example of FIG.

  FIG. 3 is a diagram illustrating a cable mounting example of the tape core wire 10 manufactured as described above. The slot-type optical fiber cable 21 is made of a resin rod having a tension member 22 made of steel wire, steel stranded wire or the like embedded in the center and having a plurality of grooves 24 formed in an SZ shape on the outer surface side. It is formed using the slot 23. A plurality of tape cores 10 are accommodated in the groove 24 of the slot 23, and the tape core 10 is accommodated and held by winding the coarsely wound string 25 and the upper winding tape 26 around the outer periphery of the slot 23. The outer side of the upper winding tape 26 is covered with a cable jacket 27 formed by extrusion molding of a thermoplastic resin.

  The tape core 10 as shown in FIG. 2B or FIG. 2C manufactured by the manufacturing method of FIG. 1 and FIG. 2A is stored in the groove 24 of the slot 23. When the number of cores of the tape core 10 is as small as about 4, a plurality of sheets are stored, but when the number of cores is large, the number may be 1 or 2. The tape core wire 10 may be accommodated so as to be sequentially laminated outward from the bottom wall of the groove 24 as in the prior art, but may be accommodated randomly as illustrated in the figure.

  The tape core 10 is intermittently adhesively connected between two adjacent cores, but is not directly connected between adjacent cores, and when stored in the groove 24 of the slot 23, It looks as if it contains a single core. In addition, since the adhesive connection portions between the core wires are also separated and dispersed in the cable longitudinal direction so as not to overlap at the same location, the adhesive connection portions can be stored so as not to concentrate at one location. As a result, even when the tape cores 10 are accommodated in an aligned manner, even if they are accommodated in a random or bundled manner as shown in FIG. 3, the mounting density of the optical fiber cores can be increased. It is possible to reduce the diameter or increase the number of cores.

  Also, when the optical fiber cable is branched after the middle after laying, it is preferable that the slot is housed in a single core instead of a tape core, but in the case of a single core, it is fused together like a tape core. Incoming connection is difficult, and a long time is required for connection work. On the other hand, by using the tape core wire 10 described above, it is handled like a single core wire for operations such as an intermediate rear branch without impairing the storage property in the slot or the fusion splicing property. Is possible.

DESCRIPTION OF SYMBOLS 10 ... Optical fiber ribbon, 11a-11d ... Optical fiber core, 12a-12c ... Adhesion connection part, 13a-13b ... Syringe needle pair, 14a-14c ... Syringe pair, 15 ... Adhesive resin, 16a-16c ... Dispenser , 17a to 17c ... ultraviolet irradiation device, 18a to 18d ... feeding bobbin, 19 ... winding bobbin, 21 ... slot type optical fiber cable, 22 ... tension member, 23 ... slot, 24 ... groove, 25 ... coarse winding string, 26 ... top wound tape, 27 ... cable jacket.

Claims (2)

Three or more optical fiber cores are juxtaposed, and only two adjacent optical fiber cores are intermittently adhesively connected, and the adhesively connected portions are not adjacent in the parallel direction of the optical fiber cores. As described above, a method of manufacturing an optical fiber ribbon that is separated in the longitudinal direction of the optical fiber,
The three or more optical fiber cores are drawn out so as to be closely aligned in a vertical line in the vertical direction, and are closely contacted in the vertical direction from the upper optical fiber core to the lower optical fiber core. Pull out the line-up timing in order to delay sequentially,
By means of a plurality of bonding means arranged spaced apart in the longitudinal direction, both side surfaces between two optical fiber cores arranged on the lower side adjacent to each other are bonded and connected intermittently by a predetermined distance;
A method of manufacturing an optical fiber ribbon, wherein the three or more optical fibers are integrated into a tape shape.   The said adhesion | attachment means consists of a dispenser which supplies an ultraviolet curing adhesive resin intermittently using a needle, and an ultraviolet irradiation apparatus which hardens | cures immediately after apply | coating the said ultraviolet curing adhesive resin. Manufacturing method of optical fiber ribbon.

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