JP2007304552A - Parts kit for manufacturing fiber optic distribution cable - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a parts kit for manufacturing a fiber optic distribution cable on a working site or in a factory. <P>SOLUTION: Manufacturing a fiber optic distribution cable (30) requires to present one or more optical fibers outward of the protective covering for distribution of the fiber toward a subscriber. In one embodiment, a parts kit (60) for manufacturing the fiber optic distribution cable includes at least one cap (64) and a transition tube (62). The at least one cap is preferably used for closing an opening formed at an access location. Moreover, the cap is provided with a penetrating notch or opening (64a) for fitting the transition tube in an inserted state. Therefore, the transition tube can be routed outside the protective covering. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention generally relates to an optical fiber distribution cable, a method for manufacturing an optical fiber distribution cable, and a tool and kit therefor. In particular, the present invention is directed to an optical fiber distribution cable, a method of manufacturing an optical fiber distribution cable, a tool therefor, and an optical fiber for a subscriber, such as “Fiber To The Home” or “Fiber To The Curbe” (“Fiber”). Is the meaning of “optical fiber”, “Home” is the meaning of “home”, and “Curb” is the meaning of “curb on the shoulder”.

[Reference to related applications]
The present application is a US patent application whose application is “Tools and Methods for Manufacturing Fiber Optic Distribution Cables” (application number not assigned), and a US patent application whose application is “Methods for Manufacturing Fiber Optic Distribution Cables” (application) All of the above US patent applications were filed on the same day as the present application, and are related to US patent applications with the name of the invention “Fiber Optic Distribution Cables and Structures Therefor”. US patent applications are incorporated by reference and their disclosure is hereby incorporated by reference.

  Communication networks are used to send various signals such as voice, video, data transmission content, and the like. Traditional communication networks use cable-like copper wires to send information and data. However, copper cables have the disadvantage that they are large in diameter, heavy, and can only send relatively limited data with a fairly large cable diameter. As a result, fiber optic cables replace the majority of copper cables in long distance communication network links, thereby providing large bandwidth capacity for long distance links. However, most communication networks still use copper cables for wiring and / or drop links on the central office subscriber side. In other words, the amount of bandwidth available to subscribers is limited due to copper cable constraints in the communication network. In other words, copper cables are a bottleneck that prevents subscribers from fully utilizing the relatively high bandwidth capacity of long-haul links over optical fibers.

  As optical fibers are deployed and deployed in communication networks, subscribers will enjoy increased bandwidth. However, certain obstacles exist that make it difficult and / or expensive to route optical fiber from a fiber optic cable to a subscriber. As an example, one conventional method of accessing a wiring optical fiber from an optical fiber cable requires making a relatively long incision in the cable jacket to access the appropriate length of optical fiber. FIG. 1 shows an optical fiber cable 10 in which an incision B having an incision length BL is provided in a cable jacket. The incision length BL is determined by the length of the optical fiber OF necessary for the technician or installer to perform the access procedure. As an example, if a technician requires 30 centimeters of wiring optical fiber for an access procedure, the incision length BL is to provide a 30 centimeter optical fiber OF outside the cable jacket. A slightly longer length, for example 35 centimeters. Specifically, the desired optical fiber for the wiring is selected and cut near the downstream end of the incision B, and then the optical fiber cable is routed near the upstream end of the incision B. So that the technician is given an optical fiber OF of the required length. One drawback of this method is that the incision length BL is relatively long and interferes with the protection provided by the cable jacket. In other words, incision B must be closed and / or sealed in order to provide adequate protection, including a relatively large covering that is bulky, difficult to handle and / or hard. Material is required. As a result, the optical fiber cable for wiring is too large (or) too stiff at the wiring location, so it is impossible to effectively route the optical fiber cable for wiring through the sleeve, duct, etc. If not, it is difficult.

  Another conventional method of accessing a wiring optical fiber from an optical fiber cable requires making incisions in the cable jacket at two locations as shown in FIG. FIG. 2 shows an optical fiber cable 10 'with a first cable jacket incision B1 and a second (ie, downstream) cable jacket incision B2 that are spaced apart from each other by a substantial distance D. ing. As an example, a typical distance D between the cable jacket incisions B1, B2 is about 30 centimeters. Next, the desired optical fiber OF to be routed toward the subscriber is selected and cut at the location of the second cable jacket incision B2. Thereafter, the optical fiber OF cut at the second cable jacket incision B2 is located at the cable jacket incision B1 in FIG. 1, and then the optical fiber is connected to the first cable as shown in the figure. The optical fiber is pulled toward the first cable jacket incision B1 until it protrudes from the jacket incision B1. In short, the optical fiber OF for wiring must be located twice (one at each of the jacket incisions B1 and B2), and the first cable jacket protrudes from the incision B1. The length of the optical fiber OF is determined by the distance D between the cable jacket incisions B1 and B2. Typically, the cable jacket incisions B1 and B2 are closed to protect the environment, for example, by molding or using a heat shrink tube. Thus, the conventional procedure of accessing and submitting a wiring optical fiber is time consuming and may damage the optical fiber and / or produce a relatively large protrusion after sealing the cable jacket incision. Let

  Therefore, it is desirable for an optical fiber distribution cable to have an inexpensive solution that is gentle to the technician for laying. In addition, the solution should also provide versatility with a relatively small footprint, flexible wiring locations, easy servicing / repair, and / or connectivity. In addition, the reliability and robustness of fiber optic distribution cable assemblies may have to withstand the rigors of outdoor environments. The present invention provides a technician-friendly, reliable and inexpensive solution for routing optical fibers from optical fiber cables to subscribers at relatively small and flexible wiring locations.

  One aspect of the present invention relates to a kit of parts for deriving at least one optical fiber for wiring from an optical fiber cable. The kit includes at least one cap having an opening or notch provided therethrough and a transition tube. The transition tube is sized to fit into an opening or notch in the cap. Of course, the kit of parts of the present invention may have other suitable components. In one embodiment, the transition tube is a PTFE tube that can withstand the applied heat, thereby allowing contact with a hot melt adhesive.

  Another feature of the present invention relates to a kit of parts for deriving at least one optical fiber for wiring from an optical fiber cable. The component kit includes a cap having an opening or notch provided therethrough, a transition tube, and a tether tube. The transition tube is sized to fit into an opening or notch in the cap.

  Yet another aspect of the present invention relates to a kit of parts for deriving at least one optical fiber for wiring from an optical fiber cable. The component kit includes a cap having an opening or notch provided therethrough, a transition tube, and a ferrule attached to at least one optical fiber. The transition tube is dimensioned to fit into an opening or notch in the cap, and the transition tube is provided with a passage through which at least one wiring optical fiber fits in an inserted state. Yes.

  Both the foregoing general description and the following detailed description provide embodiments of the invention and provide an overview or framework for understanding the nature and characteristics of the invention as claimed. It should be understood that The accompanying drawings are included to provide a further understanding of the invention, and the accompanying drawings are incorporated in and constitute a part of this application. The drawings illustrate various embodiments of the invention and, together with the detailed description, serve to explain the principles and operations of the invention.

  Reference will now be made in detail to the presently preferred embodiments of the invention, examples of which are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like parts. The present invention discloses an optical fiber cable for wiring and a method of manufacturing the optical fiber cable for wiring, in which one or more optical fibers of the optical fiber cable are provided with a protective coating material for wiring, For example, it is led out of the cable jacket. In addition, the present invention also discloses a tool for use in the above manufacturing method with a kit of parts useful for manufacturing fiber optic wiring cables. In one embodiment, a relatively small opening is formed at the access location of the fiber optic cable, thereby leaving a relatively small access footprint in the fiber optic cable (ie, a protective coating and / or other). Remove a small portion of the cable components). Although a relatively small opening (eg, a cable jacket incision) is made in the access location, this method advantageously protrudes from the access location and has a length of optical fiber for routing that is longer than the access location opening. I will provide a. For example, if the opening of the cable jacket is about 2 centimeters, the wiring optical fiber is cut in the wiring cable, and the wiring optical fiber has a length of about 2.5 centimeters or more. . In other words, such a technique provides a suitable length of optical fiber for wiring that can be used for wiring, while it is necessary to form one relatively small opening or incision in the protective covering per access location. Only. Unlike conventional access methods, this embodiment of the present invention (1) does not require multiple cable cuts in a single access location, or (2) is approximately the same length as the length of the wiring optical fiber. A relatively long cable jacket incision or opening is not required. As a result of conventional access methods, therefore, after reclosing or sealing the access location for protection, a rigid, bulky and relatively large wiring footprint results. On the other hand, the length and / or cross-sectional area of the access location for the optical fiber wiring of the present invention is relatively small and flexible, so that a suitable length of the optical fiber for wiring can be protected. The problems associated with conventional methods of accessing fiber optic cables to provide in front of the network are solved. However, certain features of the invention can be implemented with two or more cable incisions or other features of conventional methods.

  FIG. 3 is a perspective view of the optical fiber cable 30 (hereinafter referred to as the wiring cable 30) of the superordinate concept of the present invention. The wiring cable 30 shows a wiring optical fiber 32 protruding from a first access location 38a provided on a protective covering 38, for example, a cable jacket. As shown, the first access location 30a has an access length AL, which is the length of the opening or incision in the protective covering 38. In addition, the wiring optical fiber length DOFL of the wiring optical fiber 32 is not less than about 5/4 times the access length AL, and more preferably not less than about 3/2 times the access length AL. In other words, the wiring optical fiber 32 is cut or separated at the cutting location CL in the wiring cable 30. For example, when the access length AL (that is, the opening or incision in the protective covering 38 at the first access location 38a) is 5 centimeters, the wiring optical fiber 32 is for wiring. The optical fiber length DOFL is about 6 centimeters or more, more preferably about 7.5 centimeters or more. Briefly, the wiring optical fiber length DOFL is larger than the access length AL of the first access location 38a because the wiring optical fiber is cut from the optical fiber cable. As described above, the present invention provides a technique for obtaining an optical fiber for wiring having an appropriate length while using a relatively small opening or incision provided in the protective coating, and the selected wiring form is thereby provided. It enables the realization of a relatively small footprint. Of course, the cable 30 may have any suitable number of wiring optical fibers 32 protruding from the first access location 38a. Similarly, the fiber optic distribution cable may have any suitable number of access locations arranged along the cable as needed. The fiber optic distribution cable of the present invention also includes one or more various methods and / or components for constructing a fiber optic distribution cable depending on the type of fiber optic cable selected and the type of connectivity desired. It is good to use.

  The wiring cable 30 is a superordinate concept because it represents an optical fiber cable that enables cutting of the optical fiber for wiring in the protective covering according to the present invention. By way of example, FIGS. 3a-3g show samples of fiber optic cable form useful in accordance with the present invention. FIGS. 3a-3g are respectively a loose loose tube cable (FIG. 3a), a slotted core cable (FIG. 3b), a monotube cable (FIG. 3c), a flat ribbon cable (FIG. 3d), a local cable (FIG. 3e), Fig. 3 shows a cable having a plurality of entangled tubes (Fig. 3f) and a cable having a bundle (Fig. 3g). In brief, the distribution cable 30 may have any suitable form. In addition, the present invention is useful for optical fibers of various types of cables, such as multiple optical fiber ribbons, loose optical fibers, buffered optical fibers, optical fiber bundles, and the like.

  FIG. 4 shows a flowchart 40 of a method for manufacturing a wiring cable using the technical idea of the present invention. First, a step 41 of providing a distribution cable, for example a distribution cable 30 with a plurality of optical fibers (not visible) and a protective covering, for example a cable jacket, is required. Next, an opening 43 is made in the distribution cable at the first access location (ie, opening or breaking the protective covering) to one or more of the plurality of optical fibers in the distribution cable. Done to access. More specifically, the protective covering is opened at the first access location for an access length AL sufficient to perform the method disclosed herein. One reason that this method of the present invention is advantageous over prior art wiring methods is that such a method requires only one relatively small opening per access location. Further, depending on the selected distribution cable structure, other cable components or portions thereof may need to be cut, opened and / or removed to access the desired optical fiber in the distribution cable. It is a condition. For example, a technician may have to remove or cut off some of the water-swellable tape, exterior material, tensile members, etc. to access multiple optical fibers in a distribution cable. Thereafter, the method 40 requires a step 45 of selecting at least one of the plurality of optical fibers of the wiring cable as the optical fiber for wiring.

  Next, the technician performs step 47 of cutting (that is, disconnecting) the optical fiber 32 for wiring at a cutting location in the wiring cable at a downstream location. As used herein, the expression “cutting location in the distribution cable” means a location along the distribution cable where the protective coating is not broken. As best shown in FIGS. 6a and 6b, the cutting step positions and inserts a suitable cutting tool into the distribution cable so that the tool is one or two at the cutting location in the distribution cable. This is done by making it possible to cut the above optical fiber for wiring. Thereafter, step 49 is performed in which the wiring optical fiber is passed through the opening at the first access location so that a portion of the wiring optical fiber is located outside the protective covering. Other optional steps are also possible after the wiring optical fiber is located outside the protective coating. For example, a distribution cable may have, for example, demarcation points, transition tubes or other steps and / or components that provide suitable components to obtain optical connectivity, in this way. Whether or not is arbitrary.

  The method of flowchart 40 is useful for either factory or field applications because the method is simple, reliable and friendly to technicians. By way of example, the method of flowchart 40 requires only one access location opening per wiring location and is provided at the access location and is longer than the length of the cable incision or opening. Only the wiring optical fiber length DOFL is required. Other methods may include, for example, one or more optional steps and / or other steps that provide other components. Specifically, the method includes, for example, providing a transition tube through which a wiring optical fiber is passed (FIG. 6c), preparing a cap for closing the first access location (FIG. 6c), and a wiring optical fiber. Providing a section point around (FIG. 6i), providing a tether tube around the optical fiber for wiring (FIG. 10), preparing an index tube and / or a tether tube plug (FIG. 10A), Sealing one access location (FIG. 14), providing an index tube that creates excess fiber length or excess ribbon length in the wiring optical fiber (FIG. 15) and / or ferrule, connector body, etc. May further include one or more of the steps of attaching (FIGS. 17 and 18). Furthermore, a kit of parts as disclosed herein is useful for performing the method of the invention and / or constructing the distribution cable of the invention.

  FIG. 5 shows an illustrative (exemplary) tool 50 for cutting one or more wiring optical fibers in a distribution cable in accordance with the present invention. The tool 50 has an elongate body 52 with a first end 54 provided with an opening 56 and a cutting element 58. The cutting element 58 is flexible so that it can fit into the opening 56, and the cutting element can move through the opening 56 when pulled, thereby cutting in the distribution cable. One or two or more wiring optical fibers can be cut or cut at a place. Specifically, pulling the cutting element 58 causes the optical fibers captured by the cutting element 58 to bend beyond their ultimate bend radii so that they are cut or cut. As best shown in FIG. 6a, the cutting element 58 is looped around one or more wiring optical fibers, and both ends 58a, 58b of the cutting element 58 are Positioned toward the second end 55 of the tool 50 through the opening 56, the second end 55 is bent upwards, thereby forming a handle for the operator. Yes. Thereafter, the tool 50 may be slid into the distribution cable to the desired cutting location (i.e. the loop of the cutting element is located adjacent to the cutting location) and then both ends 58a of the cutting element 58. , 58b are pulled, and finally one or more optical fibers for wiring in the distribution cable are cut off. As a result, the wiring optical fiber length DOFL has a length larger than the cut-out portion of the protective covering material because the wiring optical fiber is cut in the wiring cable.

  The cutting element 58 requires certain characteristics to cut or disconnect one or more wiring optical fibers. For example, the cutting element 58 has the strength necessary to break the optical fiber for routing without causing breakage when pulled, and at least one of the elongated bodies moving through the at least one opening when pulled. The flexibility necessary to form a loop in the opening must be provided. The cutting element 58 may utilize any suitable structure, size, shape and / or material that meets these requirements. Examples include structures such as one or more filaments, yarns, rovings or yarns, and examples of shapes include rounds, rectangles, and the like. In one embodiment, the cutting element 58 is an aramid-based material, such as Kevlar having a denier of about 2450. However, the cutting element 58 may be made of other suitable materials such as polymer materials such as polyester or nylon, fishing lines, metal materials such as steel wires, cotton materials and the like. For example, one embodiment may use a 50 pound test passed fishing line sold under the trade name SpiderWire®.

  Similarly, any suitable material, such as a metal that has dimensions suitable to fit within a selected distribution cable, but remains somewhat flexible while providing the necessary strength or It may be made of plastic. As shown in FIG. 5a, the elongated body 52 is made of steel tape having a tool height TH of about 2 millimeters or less and a tool width TW of about 8 millimeters or less, whereby the elongated body can be unidirectional. It shows flexibility. As shown, the opening 56 has a generally rectangular shape with a length of about 5 millimeters and a width of about 2 millimeters, but the opening 56 has other suitable dimensions and / or shapes. May be. Of course, the dimensions of the elongate body can be tailored to the size and shape of the wiring cable space in which the tool must fit, for example rectangular or round. For example, an arc-shaped or rod-shaped tool may be suitable for sliding into a round buffer tube. In addition, other variations of the tool 50 are contemplated by the present invention.

  5b-5f show a variation of the exemplary tool of the present invention. FIG. 5b shows a portion of the tool 50b with a plurality of openings 56b near the first end. As shown, the tool 50b has three openings 56b, and therefore the location of the cutting element 58 may vary across the width of the tool 50b. FIG. 5c shows a part of a tool 50c with an opening 56c, which is not rounded, so that the end of the cutting element can be easily inserted and guided in pulling. wide. Similarly, the opening of the tool need not be closed by itself. For example, FIGS. 5d and 5e show portions of tools 50d and 50e, respectively, where openings 56d and 56e are in communication with the outer edge of the tool, thereby speeding insertion of cutting element 58 into the tool. . FIG. 5f shows a tool 50f having a handle 57f with a movable part 59f for pulling the cutting element 58 to cut one or more wiring optical fibers. As shown, both ends 58a, 57b of the cutting element 58 are wrapped around the protrusions (not labeled) of the movable part 59f of the handle 57f, so that when activated, the movable part 59f is pulled in the direction indicated by the arrow, thereby pulling both ends 58a, 58b of the cutting element 58 to cut the optical fiber for wiring. Of course, other tool variations can be envisaged that pull, wrap, thread, attach or otherwise modify the disclosed tool to sever the wiring optical fiber.

  6a and 6b illustrate the use of the tool 50 for the distribution cable 30 of FIG. Specifically, FIG. 6a shows the distribution cable 30 after an opening has been formed in the first access location and one or more optical fibers have been selected as the distribution optical fibers. Further, as shown, the cutting element 58 of the tool 50 is looped around the selected plurality of wiring optical fibers 32. In other words, tool 50 and its cutting element 58 are positioned to cut a plurality of optical fibers that are captured by the loop of cutting element 58. In addition, both ends 58 a, 58 b of the cutting element 58 are moved toward the second end 55 of the tool 50, causing the cutting element 58 to fit snugly around the wiring optical fiber 32. Thereafter, the tool 50 is inserted into the distribution cable 30 and is slid into a downstream location (for example, away from the head end of the distribution cable). FIG. 6b shows the tool 50 inserted into the distribution cable 30 in order to cut off a plurality of wiring optical fibers at the cutting location CL. Thereafter, the ends 58a, 58b of the cutting element 58 are pulled with a force sufficient to break the wiring optical fiber 32 located between the loop of the cutting element 58 and the elongated body 52. After the tool 50 is taken out from the distribution cable 30, the distribution optical fiber 32 cut in the distribution cable 30 is passed through the opening at the first access location 38a, and a part of the distribution optical fiber is shown in FIG. As shown, it is routed outside the protective covering 38. From this point, the wiring cable of the present invention performs other assembly of the present invention, for example, other splicing connection to the optical fiber for wiring and / or other manufacturing steps for attaching the ferrule to the optical fiber for wiring and ( Or) it may further include other components.

  For example, FIG. 6 c shows the distribution cable 30 of FIG. 3 with a kit 60 of parts for closing the first access location 38 a and routing the distribution optical fiber 32 out of the protective covering 38. Specifically, the component kit 60 closes the transition tube 62 that protects the optical fiber 32 for wiring to the outside of the protective covering material 38 and the first access place 38a, and the other in the wiring cable. And a cap 64 for shielding the optical fiber. In this embodiment, the transition tube allows for limited movement of the wiring optical fiber that enters and exits the distribution cable when the distribution cable is bent (ie, allows piston movement). Generally speaking, the transition tube allows the wiring optical fiber to have a penetration structure that allows limited movement of the transition tube using the transition tube as a penetration conduit. In other embodiments, section points are provided around the distribution optical fiber at or near the access location, thereby preventing piston movement of the distribution optical fiber that generally enters and exits the distribution cable. Whether to use a through structure or a section point structure may depend on the structure of the distribution cable and / or the characteristics of the cable, for example, the degree of coupling of optical fibers within the cable. In other words, some cable designs or configurations are suitable for free passage, while others are suitable for section points. In addition, the transition tube may be used with segment points when the wiring optical fiber is secured as a whole by the material, thereby forming segment points.

  As shown, the cap 64 has an opening 64a dimensioned to receive a transition tube 62, such as round or rectangular, in an inserted state. After the wiring optical fiber 32 extends through the first access location 38a and beyond the protective covering 38, the transition tube 62 is slid along the wiring optical fiber 32 and is shown in FIG. 6e. It is preferable to push it into a part of the wiring cable 30 as described above. In other words, the transition tubes 62 protect and route the wiring optical fibers as they transition while allowing some movement from a position in the distribution cable to a position outside the distribution cable. Next, the exposed end of the transition tube 62 is passed through the opening 64a of the cap 64 so that the transition tube 62 extends therefrom as shown by the dotted line in FIG. 6c. The transition tube 62 is made of a suitable flexible material, but may be made of a relatively rigid material. In one example, the transition tube 62 is a PTFE tube that can withstand high temperature applications (ie, a Teflon tube). In another embodiment, the PTFE transition tube is chemically etched. Similarly, the cap 64 is made of a suitable material, such as PTFE or other soft material, but the cap 64 may be made of a relatively rigid material. Furthermore, the cap closing the access location may have other forms. FIG. 6h shows a cap 64 'that uses a notch (not labeled) as an opening through which the transition tube and / or optical fiber passes out of the protective coating. In other words, the wiring optical fiber and / or the transition tube pass through a notch in the cap 64 and a portion of the access location. Of course, other parts kits include other components such as tools for cutting optical fibers for wiring, tether tubes, index tubes, shrink tubes, sealing components, plugs and / or ferrules, receptacles, connector bodies, etc. It may have a pigtail with a connector attached in advance. Similarly, other distribution cable assemblies of the present invention can include other components or steps as described herein.

  As shown in FIG. 6e, the cap 64 is larger (i.e., longer) than the diameter of the access location AL, and the cap is provided such that a portion thereof extends substantially below the dressing 38. In addition, the cap 64 should be relatively thin and soft so that the cap can be easily tucked under the protective covering 38 by a technician. By way of example, the cap 64 is sized so that a cap 64 of about 5 millimeters is located under the protective dressing 38 at the end and has a thickness of about 0.3 millimeters. After the cap 64 is in place, the step of securing the cap with material 66 may be performed as shown in FIG. 6f. In this embodiment, material 66 is a hot melt adhesive available from Loctite under the trade name Hysol 83245-232, but other suitable materials or methods for securing the cap, such as Glue, adhesive, silicone, ultrasonic welding, etc. can be used. Provided that the material used is compatible with the optical fibers, ribbons, protective coatings and / or other components with which it may come into contact. In addition, cap 64 and / or material 66 may also function to prevent optional sealing material, such as composite molded sealing material, from entering the distribution cable. In addition, a material 66 can be deposited under the cap 64.

  Of course, the cap 64 may have other suitable forms and may vary depending on the distribution cable. For example, the cap 64 can be shaped or tailored to match the profile of the portion of the protective covering 38 that is removed from the distribution cable. In other words, the cap has a length and width that matches the length and width of the opening in the first access location, with inner and outer profiles that match the protective dressing profile of the removed portion. As a result, the cap closes the first access location with the entire surface flush. As an example, a generally rounded distribution cable jacket has inner and outer radii similar to a cable jacket with an arc length, longitudinal length and width suitable to match the opening of the access location. Use a cap. Although FIG. 6d shows a cross-section of the cap 64 shaped to close the access location for the generally rounded distribution cable, other shapes, profiles and / or lengths of the cap can be used for other cables and ( Or) a cap can be tailored to fit the opening. In addition, the cap 64 can be attached to the first access location 38a using any suitable material or method, such as adhesive, glue, ultrasonic welding, or the like.

  As described above, in the method of the flowchart 40, it is necessary to select at least one optical fiber among the plurality of optical fibers of the wiring cable as the optical fiber for wiring. Any suitable arrangement and / or type of optical fiber can be provided in the distribution cable, and the technical idea of the present invention is useful for various arrangements and / or types of optical fiber. For example, the present invention provides a cable having a bare optical fiber (eg, the stranded loose tube cable of FIG. 3e) and a cable with one or more ribbons (eg, the slotted core cable of FIG. 3b, FIG. 3c). Suitable for a monotube cable or a flat ribbon cable of FIG. 3d). Still another distribution cable may include a buffered optical fiber (FIG. 3e), a bundle of optical fibers, and the like. In distribution cables with buffered optical fibers, a large force needs to be applied to the cutting element to separate the buffer layer and the optical fiber, and such techniques are within the scope of the present invention. After selecting the optical fiber for distribution, a splitting tool (not shown) for separating the selected optical fiber from the rest of the distribution cable, such as a thin metal piece or plastic piece, may be used at the access location.

  In a cable using a ribbon, it may be desirable to select less than the total number of optical fibers of the ribbon as wiring optical fibers. As an example, four wiring optical fibers may be desirable at the access location, and each ribbon of the distribution cable has 12 optical fibers. As shown in FIG. 6g, the ribbon R has a split S formed by a technician between the fourth optical fiber and the fifth optical fiber of the ribbon R over a short distance near the access location. In this way, the desired optical fiber for wiring is separated to split the ribbon R along its longitudinal length before cutting. Specifically, FIG. 6g shows that the cutting element 58 of the tool 50 is then looped around the four separate optical fibers of the split ribbon R and the tool 50 is positioned as before. Show. Thereafter, the split portion S of the ribbon is propagated along the length in the length direction by the tool in the wiring cable. In other words, when the tool 50 is slid within the distribution cable to the cutting location CL as before, the cutting element 58 is a matrix of ribbons between the desired optical fibers as the tool 50 is slid into place to the cutting location. The ribbon is split along its longitudinal length by shearing the material. Thereafter, the selected optical fiber for wiring is cut as before using a tool.

  As described above, the wiring optical fiber is generally fixed in order to prevent movement. FIG. 6 i shows a distribution cable 30 ′ with section points 80 for generally preventing movement of the distribution optical fiber 32 ′ at or near the access location. Generally speaking, the section point 80 prevents the wiring optical fiber from moving, for example, during bending, to reduce excessive stress on the wiring optical fiber, thereby maintaining optical performance. Secure the fiber near the access location. One way to provide the section point 80 is to deposit or inject a suitable material around the wiring optical fiber 32 'at the access location. For example, the section point material may be deposited and / or injected around the distribution optical fiber into the distribution cable, thereby preventing movement of the distribution optical fiber. Any suitable material for the section point, for example, a hot melt adhesive provided around the optical fiber for wiring, silicone or the like may be used. However, the material used for the section points should be compatible with the optical fibers, ribbons, protective coatings and / or other components with which they may come into contact. In addition, the section point 80 may be used with or without the cap 64 ', and if used, the section point may be located inside or outside the cap. If the cap is omitted, the section point 80 should also function to prevent optional sealing material, eg, composite molded sealing material, from entering the distribution cable.

  In addition, the technical idea of the present invention can be embodied without cutting the wiring optical fiber from the wiring cable. For example, FIG. 6 i shows a typical distribution cable 30 ′ having a first opening 38 a ′ and a second opening 38 b ′ in a protective covering 38 ′. In other words, the section point 80 is used in a conventional access method in which the cable is opened at two locations 38a 'and 38b' to obtain the desired length of the routing optical fiber. In addition, one or more of the openings 38a ', 38b' may be closed with a suitable cap 64 'as shown. Similarly, the method of providing an excess fiber length for the optical fiber for wiring by indexing as described above can be performed without cutting the optical fiber for wiring from the wiring cable.

  7 and 8 are a perspective view and an exploded view, respectively, of an exemplary specific fiber optic distribution cable assembly 100 (hereinafter referred to as cable assembly 100) of the present invention. As best shown in FIG. 8, the distribution cable 110, the distribution optical fiber pigtail 115 ', the cap 120 for the access location AL, the transition tube 130, the tether tube 140, and the index tube 150 And an index tube plug 160, a splice protector 170, a heat shrink tube 180, and a sealing portion 190. 9 to 11 are a sectional view taken along line 9-9 of the cable assembly 100, a sectional view taken along line 10-10, and a sectional view taken along line 11-11, respectively. In addition, FIGS. 10 and 10a are shown with the wiring cable cavity empty for the sake of clarity. The cable assembly 100 has an indexing tube 150 so that a predetermined amount of excess ribbon length (ERL) or excess fiber length (EFL) can enter the optical fiber for wiring as will be described below. is doing. By placing ERL or EFL in the optical fiber for wiring, for example, during bending of the cable assembly, no stress is applied to the optical fiber for wiring. In addition, the cable assembly 100 is an example of many different distribution cables of the present invention, such as having a small or large number of components, components having various configurations, and different component arrangements.

  FIG. 9 shows that both the fiber optic cable 110 for wiring and the tether tube 140 have a generally non-round cross-section, for example, a generally flat shape, thereby making the overall cross-sectional dimension of the assembly 100 relatively small. It shows that you can. In other words, the flat portions of the distribution cable 110 and the tether tube 140 are generally aligned to allow for a small footprint compared to using two round cables. As an example, the distribution cable assembly 100 and other similar assemblies may have a maximum cross-sectional dimension MD as shown in FIG. 11, which is along a diagonal. The maximum cross-sectional dimension MD may vary based on the size of the component used, but in embodiments advantageous for a particular application as a duct, the maximum cross-sectional dimension is about 30 millimeters or less, more preferably about 28 millimeters. Below, most preferably less than about 25 millimeters, thereby allowing the cable assembly to be pulled into the duct. Of course, other embodiments may have other maximum cross-sectional dimensions larger or smaller for a given application.

  The distribution cable 110 is advantageous for several reasons, but other distribution cables can be used. First, the distribution cable 110 and other similar distribution cables are advantageous because they can have a relatively high number of optical waveguide cores (counts) with a relatively small cross-sectional footprint. As an example, the distribution cable 110 has four ribbons each having 24 optical fibers for a total of 96 fibers. In the case of a 24-fiber ribbon, the distribution cable 110 has a major cable dimension W of about 15 millimeters or less and a minimum cable dimension H of about 8 millimeters or less. Second, the distribution cable 110 is easily accessible from any of the generally flat surfaces (eg, top or bottom) of the cable, so that the technician can access any optical fiber for which wiring is desired. Can be done. Third, the distribution cable 110 allows for quick and reliable access while preventing damage to the optical fiber or tensile member during the access procedure. In other words, the technician only needs to make a cut in the protective coating, thereby accessing the cable cavity containing the optical fiber. Further, in this embodiment, the distribution cable 110 has a dry structure (that is, no grease or gel for water stop is used in the cable), and thus the technician uses the grease or gel for the optical fiber. There is no need to clean or remove from ribbons, tools, etc.

  Of course, the distribution cable of the present invention can have any suitable size, structure and / or number of cores for a given application. By way of example, other distribution cables may have other components and / or structures for water stop, such as grease, gel, extruded foam, silicone or other suitable water stop components. . In addition, a suitable water stop structure may also be provided intermittently along the distribution cable. Similarly, other distribution cables may have other suitable cable components, such as sheathing, lip cords or tubes. For example, another embodiment of a distribution cable may have a tunable portion for locating the cable in buried (underground) applications.

  As shown in FIG. 9, the wiring cable 110 has a plurality of optical fibers 112 and a protective covering material 118. In this embodiment, the distribution cable 110 is of a tubeless design having a cavity 111 containing a plurality of optical fibers 112, and these optical fibers are a plurality of ribbons 113 (in a non-strand stack). (Represented by a horizontal line). The wiring cable 110 further includes a strength member (strength member) 114 and a water-swellable component 116. As shown, the tensile members 114 are provided on opposite sides of the cavity 111 to impart preferential bending characteristics to the distribution cable 110. The tensile member 114 provides tensile strength and / or buckling strength to the distribution cable, and the tensile member may be made of any suitable material, such as a dielectric, conductor, composite, or the like. As an example, the tensile member 114 is a round glass fiber reinforced plastic (grp) having a diameter of about 2.3 millimeters, which is smaller than the height of the cavity 111. As a matter of course, the tensile member 114 may have a shape other than a round shape, and may be, for example, an elliptical tensile member.

  By using the water-absorbable expandable component 116, a dry structure of the wiring cable 110 is obtained. The water absorbent expandable component 116 may have any suitable form, such as a water-stopping yarn, a thread, a tape, and the like. In this case, the wiring cable 110 uses two water-swellable components 116 configured as an elongated tape that is an unwinding reel. As shown, the major (eg, flat) surface (not labeled) of the water-swellable component 116 is the major (eg, horizontal) surface (not labeled) of the cavity 111. So that a compact and efficient configuration is achieved while generally preventing contact of optical fibers at the corners as occurs with ribbon stacks contained in round tubes. can get. In addition, the ribbon is generally aligned with the major surface (ie, the horizontal surface) at the top and bottom of the ribbon and is generally aligned with the width (ie, the major surface) of the water-swellable component 116. , Thereby forming a composite stack of ribbon / water-swellable components in the cavity 111. As a result, a rectangular (or square) ribbon stack is correspondingly fitted into a generally rectangular (or square) cavity, which is associated with placing the rectangular (or square) ribbon stack in a round buffer tube. The problem (i.e., the problem that stress is applied to the fiber at the corners of the ribbon stack in the round buffer tube that may cause the cable to compromise optical performance requirements, e.g. bending requirements) is avoided.

  Specifically, absorbent expandable components 116 are provided at the top and bottom of a ribbon stack (not numbered), such water absorbent expandable components comprising compressible layers 116a and water expandable layers 116b. have. In other words, the water-swellable component 116 sandwiches a plurality of ribbons 113 in a non-strand stack, thereby forming a cable core. As a result, the ribbon 113, the major surface of the water-swellable component 116 and the major (horizontal) surface of the cavity 111 are generally aligned with one another (ie, are generally parallel) to form a compact structure. Yes. In addition, the water-swellable component 116 contacts at least a portion of each of the top and bottom ribbons. In other embodiments, one or more elongated tapes may be wrapped around the optical fiber or provided on one or more sides thereof. As an example, the compressible layer 116a is a foam layer, such as an open cell polyurethane material, and the water-swellable layer 116b is a water-swellable tape. However, other suitable materials can be used for the compressible layer and / or the water-swellable layer or part thereof. As shown, the compressible layer 116a and the water-swellable layer 116b are attached to each other, but they may be deposited as individual components. Generally speaking, the water-swellable component 116 is multifunctional. This is because such a water-swellable component provides a degree of bonding to the ribbon 113, prevents water movement along the cavity 111, protects the ribbon / optical fiber from impact, and the ribbon (or optical fiber). This is because the bending and bending of the wiring cable 110 are allowed by allowing movement and separation. In other embodiments, the distribution cable can be used in the cavity 111 to use other cable components that couple the optical fibers, protect the optical fibers from impact and / or stop the water. For example, the wiring cable may use foam tape or extruded foam that does not have water-stopping properties.

  As shown, the cavity 111 has a generally rectangular shape with a fixed orientation to receive the non-strand ribbon stack, but other shapes and arrangements of the cavities, eg, generally square, round or oval Is possible. In one example, the cavity may be rotated or twisted in any suitable manner along its longitudinal length. The cavity may also be partially oscillated over a given angle, for example, the cavity rotates a clockwise angle that is less than one revolution and then an angle that is less than one revolution, counterclockwise Rotate around. In addition, the cavity 111 may be offset toward one of the flat surfaces of the distribution cable 110, thereby allowing easy opening and access from one side.

  The ribbon 113 used for the distribution cable 110 may have any suitable design or number of ribbon cores. For example, the ribbon 113 may have a splittable structure using one or more subunits or stress concentrators as known in the art, thereby making the ribbon into a small group of optical fibers. Can be separated. For example, ribbons can use subunits each having four optical fibers, but ribbons without subunits can be used, and subunits have a different number of cores. You may have. The subunit allows the fiber optic ribbon to be pre-divided into small predictable core number units before the fiber optic ribbon is split along its length with the tool 50. In one embodiment, each of the illustrated ribbons 113 has 64 fiber subunits for a total of 24 optical fibers. Of course, depending on the requirements of the other cores of the optical fiber per ribbon, the number of ribbons and / or other suitable subunit configurations, e.g. It is possible to use a unit consisting of fibers, a unit consisting of three eight fibers or a unit consisting of six four fibers. Examples of suitable optical fiber arrangements include ribbons with or without subunits, rigid ribbons with tight buffer layers, tight buffer or colored optical fibers, loose light contained in tubes A fiber, an optical fiber housed in a module, or an optical fiber provided in a bundle.

  In addition, the ribbon 113 of the exemplary embodiment of the distribution cable 110 is about 0.5% or more, such as about 0.6% to about 0.00, to accommodate bending and / or wrapping of the distribution cable 110. Although having an 8% excess ribbon length (ERL), the amount of ERL used may vary based on the particular cable design. The ERL of the ribbon 110 is related to the ERL of the ribbon in the cable, and roughly differs from the introduction length of the ERL into the optical fiber for wiring using the index tube as described above. The minimum bend radius of the distribution cable 110 is about 125 millimeters, which allows the cable to be coiled in a relatively small diameter so that the cable can be stored in a slack state. Of course, distribution cables with other suitable fiber / ribbon counts may have other ERL values and / or cable dimensions. As an example, a cable similar to the distribution cable 110 may have four ribbons with various numbers of cores, for example: (1) for a total of 48 optical fibers, no more than about 12 millimeters 12 core optical fiber ribbons with a major cable dimension W of (2) If there are a total of 144 optical fibers, a 36 core optical fiber ribbon with a major cable dimension W of about 18 millimeters or less, or (3) an optical fiber A total of 260 have 48-fiber ribbons with a major cable dimension W of about 21 millimeters or less.

  In addition, the cavity 111 has a cavity height CH and a cavity width CW suitable for the desired arrangement of optical fibers, ribbons, and the like. As an example, each ribbon 113 has a height of about 0.3 millimeters when the total height of the ribbon is about 1.2 millimeters (4 times 0.3 millimeters), and the cavity height CH is the cavity height CH 110 is about 5.5 millimeters. The cavity width CW is generally determined by the ribbon width intended for the cable (or by the number of optical fiber cores) and is about 7.5 millimeters for 24 fiber ribbons. In this embodiment, the water-swellable components 116 each have an uncompressed height of about 1.8 millimeters, although other suitable uncompressed heights are possible. The degree of compression of the water-swellable component 116 in the cable is the local maximum compression of this water-swellable component, generally when the cable has a positive ERL (ie, the ribbon is undulating in the cavity). Case), which occurs when having maximum displacement from the neutral axis.

  By way of example, the illustrative embodiment has an overall height of about 4.8 millimeters for the uncompressed absorbent expandable component 116 and ribbon 113, which is greater than the cavity height CH of 5.5 millimeters. short. As a result, the standardized ribbon pulling force is generally caused by the undulating ribbon stack causing local maximum compression of the water-swellable component 116 due to ERL and / or friction. As an example, proper bonding of a ribbon stack (or ribbon or optical fiber) is, for example, two 1 millimeters when the uncompressed height of the dry insert is about 40% or more of the cavity height CH. This can be achieved by using the water-swellable component 116 in a cavity having a cavity height CH of about 5 millimeters. Of course, other suitable ratios are possible as long as the optical performance is maintained. In the illustrated embodiment, the total uncompressed height of the water-swellable component 116 (twice 1.8 millimeters equals 3.6 millimeters) is about 65 of the cavity height CH (5.5 millimeters). %, Which is greater than 50% of the cavity height CH. Of course, the cavities, ribbons and / or water-swellable components 116 may have other suitable dimensions as long as they still provide adequate performance. For example, thinner ribbons and / or water-swellable components can be used. Although the cavity 111 is shown as being rectangular, it may be difficult to fabricate the rectangular cavity as shown, ie, the extrusion process forms a cavity with a somewhat irregular rectangular shape. There is a case. Similarly, the cavities may generally have other suitable shapes besides rectangles, for example, oval, round, etc., and such shapes are generally between dry inserts, ribbons and / or cavities. The relationship (alignment) may be changed.

  Generally speaking, positioning the water-swellable components 116 at opposite ends of a ribbon stack (or a single ribbon or loose optical fiber) is generally associated with the distribution cable 110 under various conditions. Affects the uniform ERL distribution as well as helps maintain it, thereby helping to maintain optical performance. In addition, ribbon and cable coupling is advantageous, for example, during bending, to affect a relatively uniform ERL distribution along the cable, which generally allows for a small cable bend radius. Other factors, such as the size of the cavity and / or the compression of the dry insert, may also affect the distribution of ERL / EFL along the cable.

  Another feature related to the optical performance of a distribution cable having a generally flat profile with a non-strand ribbon stack is the total amount of ERL required to obtain adequate cable performance. The amount of ERL to obtain reasonable cable performance is generally determined by the cable design, eg, the number of ribbons. Generally speaking, the minimum ERL for a cable with a single ribbon is determined by the desired allowable fiber strain level at the rated cable load, whereas the minimum ERL for a cable with multiple ribbons is generally of bending performance. to be influenced. Specifically, when choosing a minimum ERL for the cable design, the tensile member geometry and material (ie, cross-sectional area) to calculate the desired fiber strain level at the cable design's rated tensile load. And Young's modulus) should be considered. In addition, the amount of ERL required for bending generally increases as the number of ribbons in the stack increases. This is because the outer ribbon of the ribbon stack is located far from the cable neutral axis. However, there is a limit to the upper limit of ERL for obtaining appropriate optical performance (that is, if ERL is too much, optical performance may deteriorate). Furthermore, distribution cables with relatively high levels, eg 0.6% to 1.5% ERL, may be suitable for self-supporting erection, eg NESC heavy load, but for a given design Certain ERLs should have the desired cable performance. On the other hand, a distribution cable similar to distribution cable 110 having loose optical fibers should have a small value of excess fiber length (EFL), for example, an EFL of about 0.2%. This is because all optical fibers are placed near the neutral axis of the cable.

  Returning to the description of the cable assembly 100, FIGS. 12-16 are perspective views showing portions of the distribution cable 110 in various constituent stages (i.e., subassemblies) to illustrate a method of manufacturing the cable assembly 100. FIG. FIG. FIG. 12 shows that the access location AL is formed in the protective covering material 118, the optical fiber 115 for wiring is cut in the distribution cable 110, and the cap 120 and the transition tube 130 are attached and passed through the opening in the access location AL. Thereby, the distribution cable 110 is shown after the subassembly 102 of the cable assembly 100 is formed. From the subassembly 102, various distribution cables can be constructed, for example, the cable assembly 100 shown in FIGS. 7 and 8, or the cable assembly 200 as shown in FIGS. Further, the subassembly 102 or other subassembly structure is suitable for field deployment. Briefly, the optical fiber for wiring of the subassembly 102 is led out of the wiring cable so that it can be used by a technician in the field. When used in this manner, tape or other dressing may be placed around the wiring optical fiber and / or access location to protect them until access is required in the field.

  Subassembly 102 is formed as follows. First, the protective covering 118 of the distribution cable 110 around the access location AL is roughened by performing scalloping (cut into a corrugated pattern) and / or flame brushing as shown. By roughening the protective covering material 118, the tightness of the sealing portion 190 is improved, and this roughening operation is easy and safe to perform before opening the protective covering material 118. Thereafter, the opening 118 a of the access location AL is formed in the protective covering material 118. The opening 118a may be of any suitable length, in this case about 25 millimeters long. Any suitable cable entry tool, such as a utility knife, can be used to open the protective covering 118. After opening the protective covering 118, a portion of the top water-swellable component 116 of the distribution cable 110 is exposed at the access location AL. The exposed portion of the water-swellable component 116 is removed, for example, by cutting with scissors, thereby allowing easy access to the optical fiber in the distribution cable 110. Thereafter, a desired optical fiber for wiring is selected for cutting in the distribution cable, and a dedicated tool such as a dividing tool is preferably used. In this example, fewer than the total number of optical fibers in the top ribbon are selected for wiring, so the top ribbon has splits S between the optical fibers as shown in FIG. 6f. Specifically, the four optical fibers of the top ribbon are selected to be optical fibers for wiring at the access location AL. Of course, optical fibers for wiring may be selected from other ribbons in the stack. In addition, if a ribbon located above the ribbon being accessed is already in use, the used ribbon may be removed for access to the desired optical fiber for wiring. The technician makes the split S of the top ribbon by using a suitable tool and / or his finger. Thereafter, the cutting element 58 of the tool 50 is positioned around the split S as shown in FIG. 6f. Next, the cutting element 58 is loosened and the tool 50 is slid into the cavity 111 of the distribution cable 110 so that when the tool 50 is moved into position, the ribbon is lighted along its longitudinal length. Split between fibers. After positioning the tool 50 at the cutting location CL in the distribution cable 110, the cutting element 58 is pulled with sufficient force to cut the distribution optical fiber 115 in the distribution cable 110. In this case, the tool 50 is inserted and the optical fiber 115 for wiring is cut about 175 millimeters downstream from the access location AL. As a result, the optical fiber length DOFL for wiring is about 7 times longer than the access length AL. After the tool 50 is taken out from the wiring cable 110, the wiring optical fiber 115 is pulled out from the cavity 111 and positioned outside the protective covering material 118. Next, the cap 120 (which is similar to the cap 64) and the transition tube 130 (which is similar to the transition tube 62) dimensioned and shaped to the distribution cable 110 at its access location AL. ) As shown in FIG. 6e. Specifically, the transition tube 130 has a length of about 65 millimeters and a generally rectangular shape so that it can slide along an optical fiber split from the optical fiber ribbon 113; The cap 120 is generally flat and has a length slightly longer than the access location AL, so that a part can fit into the cavity 111 of the distribution cable 110. The transition tube 130 is slid along the optical fiber 115 for wiring so that about 35 millimeters can be received in the cavity 111 of the distribution cable 110. Next, the exposed end of the transition tube 130 is passed through the opening 120 a of the cap 120 and the cap 120 is positioned so that a portion of this is tucked into the cavity 111 of the distribution cable 110. As before, the cap 120 closes the access location AL and the transition tube 130 protects the wiring optical fiber when the wiring optical fiber 115 is pulled out of the wiring cable 110. Thereafter, a material such as hot melt adhesive (not shown) is applied over cap 120 and around transition tube 130, and cap 120 and transition tube 130 are opened in the access location as shown in FIG. 6f. Secure at the part.

  FIG. 13 is a perspective view of another subassembly 104 of the cable assembly 100 for explaining the manufacturing method. More specifically, FIG. 13 shows the subassembly 102 of FIG. 12 after splicing the wiring optical fiber 115 with the wiring optical fiber pigtail 115 ′ and protecting the splice location with the splice protector 170. ing. With respect to this embodiment and access location of the cable assembly 100, the routing optical fiber pigtail 115 'is a four-core optical fiber ribbon that is fused together to the routing optical fiber 115 split from the top ribbon. In other words, the wiring optical fiber pigtail 115 ′ is in optical communication with the wiring optical fiber 115 and is a part of the wiring optical fiber. Furthermore, this step increases the length of the wiring optical fiber based on the desired connectivity configuration, such as the length of the tether tube or other configuration. The splice protector 170 is used to protect and immobilize the splice (not visible), pushing the splice protector onto the wiring fiber pigtail 115 'prior to splicing, and then forming the splice. It may be positioned later on the splice. Similarly, other components may be slid along the optical fiber pigtail 115 'for wiring, depending on the form of the embodiment. As with subassembly 102, various distribution cables may be constructed from subassembly 104 or other similar subassemblies. The cable assembly 100 has a tether tube 140 with an optical fiber stub for wiring (second end of the optical fiber pigtail 115 'for wiring) for optical connectivity, but other configurations are possible. . For example, one or more ferrules may be attached to the second end of the fiber optic pigtail 115 'for wiring, the ferrule being a receptacle for plug and play connectivity. It may be a part of a plug or the like. As an example, FIG. 19 shows a second end of a tether tube 140 'having a wiring optical fiber attached to a ferrule that is part of a plug 195, as is known in the art. Of course, the second end of the tether tube 140 'was provided with any suitable form to obtain connectivity, such as an optical fiber, a connector or ferrule, a multiport, etc., ready for splicing. It may have a receptacle, which provides flexibility for the technician in making the downstream connection. As an example, FIG. 19 a shows a wiring optical fiber pigtail 115 ′ attached to a ferrule 196. The ferrule 196 is a multi-core ferrule, but a single-core ferrule may be attached to one or more wiring optical fibers. FIG. 19 b shows a multiport 198 having a plurality of receptacles 198 a attached to the end of the tether tube 140. Similarly, FIG. 19 c shows another multi-port 199 having a plurality of receptacles 199 a attached to the end of the tether tube 140. Figures 19d and 19e show tether tube branches using branch legs to provide plug and play connectivity. More specifically, FIG. 19d shows an assembly 193 having a plurality of plugs 193a provided at the end of a plurality of branch legs 193b, and FIG. 19e shows the end of the plurality of branch legs 194b. An assembly 194 is shown having a plurality of receptacles 194a provided on the device. Of course, other types and / or structures for optical connectivity, such as a single receptacle, can be used. As will be described below, the cable assembly 100 protects the splice and uses a splice provided in the cavity of the index tube 140 as described below to place the ERL or EFL into the wiring optical fiber. Have.

  As best shown in FIG. 10 a, the splice connecting index tube 150 is slid along and along a portion of the wiring optical fiber 115 and a portion of the transition tube 130. As a result, the splice protector 170 is located within the cavity 150 a of the index tube 150 and the fiber pigtail 115 ′ extends from the second end of the index tube 150. In addition, the splice 170 may include an optional cushioning element (not shown), such as foam tape provided around the splice. For example, the foam may be positioned around the splice 170, for example, the index tube 150 may be folded over the splice before sliding along the splice. As further illustrated, the index tube plug 160 is then pushed into the upstream end of the index tube 150. Index tube plug 160 is used to prevent sealing portion 190 from being injected into index tube 150 in the next manufacturing process. The index tube plug 160 can be made of any suitable material, such as foam, soft polymer, etc., and the index tube plug can be placed in the cavity of the index tube 150 with the transition tube 130 in a light friction fit. Dimensioned to fit into Next, if desired, the indexing tube 150 may be taped or secured to the distribution cable 110 to hold the indexing tube in place at an appropriate position. In this embodiment, the index tube 150 is part of a distribution cable 110 having an empty cavity as best shown in FIG. In other words, the index tube 150 is part of the distribution cable 110, and the ribbon 113 and the water-swellable component 116 have been removed from the cavity 111 (ie, only the protective covering 118 with the tensile member 114 embedded therein). Is). Of course, other suitable indexing tubes such as other dimensions and / or shapes, such as round, square, etc. are possible.

  FIG. 14 is a perspective view of the subassembly 106 of the cable assembly 100 provided within the mold 190 shown in phantom lines prior to injection of the curable material to form the sealed portion 190. The subassembly 106 further includes applying a material 106a, such as a hot melt adhesive, to seal and / or fix the components of the assembly together and fix the position of the transition tube 130, for example. Applying material 106a prevents injected material from entering the access site opening and / or prevents indexing tube 150 from moving the part during the composite molding process, thereby reducing optical performance. Performance is maintained. In addition, it may be advantageous to heat a portion of subassembly 106 immediately prior to forming sealing portion 190 around a portion of subassembly 106 to facilitate coupling of sealing portion 190 and subassembly 106. is there. Thereafter, the subassembly 106 is placed in the mold 192 as shown in FIG. 14, and the sealing portion 190 is formed by injecting the sealing material into the mold under pressure. Sealing portion 190 provides a means of protection from the surrounding environment of access location AL and can provide structural integrity. In this embodiment, the sealing portion 190 is a two-component material of isocyanate resin and polyol hardner available from Loctite, but other suitable materials may be used. In this embodiment, the sealing portion 190 has a generally uniform minimum wall thickness of about 3 to 5 millimeters, although other dimensions can be used. Other methods and / or materials for making the sealing portion 190 are possible as long as they meet the requirements of the desired application. The sealing portion 190 can be formed by a technique other than the technique of injecting a curable material into the mold or a manufacturing method. For example, a preformed shell 190 'is shown, which covers the subassembly 106 and then heats to form and / or partially melt or partially melt it. (Or other reaction) is added, thereby sealing the access location. More specifically, the sealing portion 190 ′ has a hinge line 192 ′ that allows the sealing portion to be folded around the subassembly 106. In other embodiments, the sealing portion 190 'can be two or more separate portions. A sealing portion, such as sealing portion 190 ', can be used with any suitable distribution cable. As an example, FIGS. 20a-20c illustrate a method of forming a cable assembly 100 ′ using another sealed portion 190 ″ with a circular cross-sectional distribution cable 110 ′ and tether tube 140 ′. In yet another embodiment, a hardened tube (not shown) may be placed around the access location and then injected with a suitable material to seal the end or the entire hardened tube. If the application allows, the sealing portion 190 can also be formed using heat shrink tubing disposed around the access location.

  FIG. 15 is a perspective view of the subassembly 108 of the cable assembly 100 before indexing the tether tube 140 relative to the index tube 150. More specifically, by indexing the tether tube 140 into and against the index tube 150, a predetermined amount of ERL is placed in the routing optical fiber 115 and / or the routing optical fiber pigtail 115 '. Can be put. As a result, the ERL or EFL of the wiring optical fiber prevents forces from being applied to the wiring optical fiber that may cause problems with reliability and / or optical attenuation. As best shown in FIG. 10, the cavity 150a of the indexing tube 150 is sized so that the tether tube 140 fits within this cavity. In FIG. 9, the tether tube 140 has a plurality of tension members 142 provided on opposite sides of the cavity 141, and a part of the wiring optical fiber 115 is accommodated in the cavity 141. Is shown. The tether tube 140 has a generally flat shape, but other dimensions and / or shapes can be used for the tether tube within the scope of the inventive concept. FIG. 15 shows the tether tube 140 housed within a portion of the index tube 150 and pulled taut to remove excess ribbon length as represented by the symbol M1. Thereafter, the tether tube 140 is pushed into the indexing tube 150 for a predetermined distance D represented by the symbol M2 (that is, indexed). In this cable assembly, the distance D is about 5 millimeters, and thus about 5 millimeters of ERL is generally introduced into the wiring optical fiber that is stored in the index tube 150. Of course, other suitable distances D can be used to enter the desired ERL or EFL. After indexing occurs, the tether tube 140 must be fixed in place to maintain ERL or EFL. As shown in FIG. 7, the heat shrinkable tube 180 is fitted to a part of the tether tube 140 and a part of the indexing tube 150 to maintain the relative position, but other methods for maintaining the relative position, such as composite molding Etc. can be used. In addition, it should be understood that a method of indexing the first tube with the second tube to provide ERL or EFL may be used, in which case the distribution optical fiber is routed within the distribution cable. The cutting step is not performed. Of course, other variations of the cable assembly 100 can be envisaged. As an example, FIG. 16 has an optional cable seam 196 that secures the distribution cable 110 and the sealing portion 190 near the downstream end, thereby preventing the generation of separation forces between the two. A cable assembly 100 is shown.

  As described above, the subassembly of the present invention can be configured in other cable assembly configurations. As an example, FIGS. 17 and 18 show a cable assembly 200 having a subassembly 102 to which a fiber optic pigtail 115 ′ for wiring is spliced, and the fiber optic pigtail 115 ′ for wiring includes a splice protector. Protected by H.270. As best shown in FIG. 18, a ferrule (not visible) is attached to the optical fiber pigtail 115 'for wiring. In this embodiment, the ferrule is a multi-fiber optic ferrule. Furthermore, the ferrule is part of the connector body 220, thereby providing plug and play optical connectivity at the access location rather than at the end of the tether tube.

  Naturally, the cable assemblies 100 and 200 are examples of many wiring cables configured in accordance with the technical idea of the present invention. As noted above, other assemblies may use other cable cross sections, or may have fewer or more and / or different components than the examples described above. As an example, the sealing portion 190 of the distribution cable 100 may have a segmented end 190a as shown in phantom in FIG. The segmented end 190a allows some distortion removal for the leading end of the wiring location. In addition, the cable assembly of the present invention may include other components that assist in housing the cable assembly in a duct, for example. To give an example, FIG. 21 shows a distribution cable 300 with a safety pulling or traction device 302 provided in front of the access location as shown. Specifically, the safety pull device 302 allows a technician to detect blockages and / or constrictions in the duct, so that the technician can route the wiring cable without damaging the access location. Efforts are made to pull beyond the occlusion or stenosis. In this embodiment, the safety tensioning device is dimensioned for being slightly larger than the sealing portion 190 so that the technician can increase the force and / or the safety tensioning device 302 before reaching the access location. Damage can be detected. Of course, the safety tensioning device may have approximately the same or the same size and / or shape as the sealing portion. As a result, the technician can pull the distribution cable out of the duct before damaging the distribution cable and repair the duct or remove anything in the duct before trying to store the distribution cable again. . In other embodiments, the safety tensioning device may be shaped to facilitate twisting or alignment of the wiring cable to fit over the obstruction or constriction.

  It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. For example, the technical idea described in the present specification can be applied to an optical fiber cable having any appropriate design. Similarly, the fiber optic cable can have other suitable cable components, such as lip cords, or other components for optical coupling. Thus, the present invention includes modifications and variations of the present invention so long as they fall within the scope of the present invention as set forth in the appended claims and equivalents thereof.

1 is a perspective view of a conventional method for opening a fiber optic cable over a relatively long length to access the fiber for proper length fiber optic wiring. FIG. FIG. 5 is a perspective view of another conventional method of opening a fiber optic cable at two locations to access the fiber for proper length fiber optic wiring. FIG. 3 is a perspective view of a superordinate optical fiber distribution cable, wherein a wiring optical fiber protruding from a first access location of the optical fiber distribution cable after being cut at a cut location in the optical fiber distribution cable according to the present invention; FIG. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. FIG. 4 is a cross-sectional view of an exemplary optical fiber distribution cable represented by the superordinate optical fiber distribution cable of FIG. 3. 4 is a flowchart illustrating various steps of a method of manufacturing the optical fiber distribution cable of FIG. 3 in accordance with the present invention. 1 is a perspective view of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. FIG. 6 is a perspective view of a variation of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. 6 is a perspective view of a variation of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. 6 is a perspective view of a variation of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. 6 is a perspective view of a variation of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. 6 is a perspective view of a variation of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. 6 is a perspective view of a variation of an exemplary tool for cutting an optical fiber in an optical fiber distribution cable of the present invention. FIG. 6 is a diagram showing the tool of FIG. 5, in which the cutting element is in a loop shape around a plurality of wiring optical fibers of the optical fiber wiring cable of FIG. 3 before cutting. FIG. 6 is a diagram illustrating the tool of FIG. 5 inserted into the optical fiber wiring cable of FIG. 3 in order to cut the optical fiber for wiring at a cutting location in the optical fiber wiring cable. It is a figure which shows the optical fiber wiring cable of FIG. 3 with the exploded assembly figure of the component kit of this invention. 6c is a cross-sectional view of the cap of FIG. 6c. FIG. FIG. 6 is a perspective view of the optical fiber distribution cable of FIG. 3 with the component kit of FIG. 6c assembled on the optical fiber distribution cable according to the present invention. FIG. 6e shows the assembly of FIG. 6e after the cap has been secured with a suitable material. FIG. 6 shows the tool of FIG. 5 positioned around a portion of the optical fiber ribbon to divide the optical fiber ribbon along its length before cutting the wiring optical fiber at the cutting site. It is a perspective view of the optical fiber wiring cable of FIG. 3 provided with the cap of another structure of this invention. It is a figure which shows another optical fiber wiring cable which has the segment point provided around the optical fiber for wiring of this invention. It is a side view of the optical fiber wiring cable assembly of the present invention. FIG. 8 is an exploded view of the optical fiber wiring cable assembly of FIG. 7 of the present invention. FIG. 9 is a cross-sectional view of the optical fiber distribution cable assembly of FIG. 7 taken along line 9-9. FIG. 10 is another cross-sectional view of the fiber optic wiring cable assembly of FIG. 7 taken along line 10-10. It is a figure which shows a part of cross section of FIG. FIG. 11 is another cross-sectional view of the fiber optic wiring cable assembly of FIG. 7 taken along line 11-11. It is a perspective view which shows several parts of the distribution cable assembly of FIG. 7 in one structure step. FIG. 8 is a perspective view showing several parts of the distribution cable assembly of FIG. 7 in another configuration stage. FIG. 8 is a perspective view showing several parts of the distribution cable assembly of FIG. 7 in another configuration stage. FIG. 8 is a perspective view showing several parts of the distribution cable assembly of FIG. 7 in another configuration stage. FIG. 8 is a perspective view showing several parts of the distribution cable assembly of FIG. 7 in another configuration stage. It is a perspective view of another optical fiber wiring cable which has the ferrule of this invention. It is a perspective view of the wiring cable of FIG. 17, and is a figure shown in a state where it is removed for easy understanding of a part of the overmold. 1 is a perspective view of a tether tube to which a plug that has been pre-connected to provide plug and play connectivity according to the present invention is attached. FIG. It is a perspective view of the ferrule attached to the optical fiber for wiring of this invention. It is a perspective view of the assembly for obtaining the plug and play connectivity of the present invention. It is a perspective view of the assembly for obtaining the plug and play connectivity of the present invention. It is a perspective view of the assembly for obtaining the plug and play connectivity of the present invention. It is a perspective view of the assembly for obtaining the plug and play connectivity of the present invention. It is a perspective view of another sealing part of this invention. It is a perspective view of another optical fiber wiring cable of the present invention. It is a perspective view of another optical fiber wiring cable of the present invention. It is a perspective view of another optical fiber wiring cable of the present invention. It is a side view of the optical fiber wiring cable which has the safety traction apparatus of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Optical fiber cable 30 Optical fiber distribution cable 32 Optical fiber for wiring 38,118 Protective coating material 50 Tool 52 Tool main body 54,55 Cable end part 56 Opening part 58 Cutting element 60 Parts kit 62 Transition tube 64 Cap 100 Optical fiber cable assembly Solid 110 Wiring cable 111 Cavity 102, 104, 106 Subassembly 115 ′ Optical fiber pigtail 116 Water-absorbing swellable component 140 Tether tube 150 Index tube 160 Index tube plug 170 Splice protector 180 Heat shrink tube 190 Sealing part 192 Mold 196 Ferrule 198 , 199 Multi-port 200,300 Cable assembly 220 Connector body

Claims (10)

A kit of parts for deriving at least one optical fiber for wiring from an optical fiber cable,
At least one cap having an opening or notch provided therethrough;
A transition tube dimensioned to fit in the opening of the cap or the notch,
Kit characterized by that. The at least one cap is contoured to the fiber optic cable such that the at least one cap fits into an opening in the access location;
The kit according to claim 1. Further having a plug,
The kit according to claim 1. A tether tube and a plug, the plug being dimensioned to fit within the end of the tether tube with the wiring optical fiber inserted;
The kit according to claim 1. Further comprising an index tube and a heat shrink tube,
The kit according to claim 1. A sealing portion for providing an environmental seal at the wiring location;
The kit according to claim 1. Further comprising a ferrule attached to at least one optical fiber;
The kit according to claim 1. Further comprising a multi-fiber optic ferrule attached to a plurality of optical fibers;
The kit according to claim 1. A connector body;
The kit according to claim 1. A tool capable of cutting one or more optical fibers from within the optical fiber cable;
The kit according to claim 1.

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