The present invention relates generally to fiber optic terminals, and more particularly to fiber optic terminals that have a small form factor and are variably configurable for use in a centralized or distributed split fiber optic network. The present disclosure also relates to removable modules for use in fiber optic terminals, and, more particularly, to reversible modules that can be easily installed in fiber optic terminals and oriented to provide a desired layout of input and output adapters.
Fiber optic terminals in a fiber optic network may be referred to as local convergence points (LCP), fiber distribution terminals (FDT), fiber distribution hubs (FDH), and the like. Such fiber optic terminals may be cabinets or enclosures which may house fiber connection points, splices, splitter modules, or other components. For example, the splitter modules may split an optical signal from a network operator or service provider into many optical signals for distribution to subscribers. This enables the transmission of individual optical signals to subscriber premises in the optical network. The fiber optic terminal provides a convergence point for management of the fibers and the optical signals between the network operator or service provider and the subscriber.
Referring now to
In a centralized split architecture, the local convergence point 902 or fiber distribution hub is typically designed to service from 144 to 864 customers, but can service more or less customers depending on a particular installation. Traditional fiber distribution hubs provide for the management of input and output fiber cables, mounting of splitters 906, and fixed input and distribution fields that are factory configured to accommodate the maximum number of connections. Due to the large number of customers serviced by a single fiber distribution hub, the equipment size and insulation requirements for the fiber distribution hubs in a centralized split architecture can be extensive and costly. Installation typically includes one or more steps which may include permitting with the local municipality, deployment of underground cables, placement of a splice vault in concrete pad, and securing the equipment cabinet to the pad.
To allow service providers a more modular and customizable fiber distribution architecture, many providers have moved from centralized split architectures to distributed split architectures.
Embodiments disclosed herein provide for a fiber optic terminal that has a small form factor and is customizable to accommodate changes in the bandwidth needs of a particular network. The fiber optic terminal may enable pole or wall-mounted installations, reducing installation time and costs, and customized network applications. In contrast to traditional terminals, which may be large, heavy cabinet enclosures requiring a lift truck and concert pad for installation, the fiber optic terminal of the present disclosure is small and lightweight, and, in some cases, can be installed by a single person without the use of a lift truck.
The fiber optic terminal includes module holders that accept removable, configurable modules to allow for increased customization. The removable modules include input and output adapters for feeder and distribution fiber connections. The module holders are aligned in the fiber optic terminal such that when two or more modules are positioned in the module holders, the input and distribution adapters of the modules are aligned to form input and distribution fields in the fiber optic terminal. Each removable module may include one or more of the following: a splitter, cable or fiber storage components, pass-through fiber components, connector parking components, splice components, input adapters, and distribution adapters. Each fiber optic terminal is customizable by incorporating one or more modules having the required functionality into the module holders. Each module holder need not include a module at all times.
An example fiber distribution hub may include an enclosure defining an interior space, a feeder cable port for receiving into the interior space a feeder cable having at least one optical fiber, and a distribution cable port for receiving into the interior space a distribution cable having at least one optical fiber. A user may insert feeder and distribution cables through the feeder and distribution ports, respectively. The feeder and distribution cables may each have connectors positioned outside of the enclosure, at an exterior wall of the enclosure, or within the enclosure. The polarity of the connectors of the feeder cable may be different than the polarity of the connectors of the distribution cables to allow a user to easily bypass the fiber optic terminal or to link multiple fiber optic terminals in a series.
The fiber optic terminal may also include at least one module holder positioned in the interior space. Each of the module holders is configured to receive a removable module. As discussed above, the modules may include a splitter or pass-through components. The optical fiber or fibers of the feeder cable are optically connected to one or more optical fibers of the distribution cable through the splitter or pass-through components of the module. The optical fiber or fibers of the feeder cable may be connectorized so that they are couplable to one or more input adapters on the module and the optical fiber or fibers of the distribution cable may also be connectorized so that they are couplable to one or more distribution adapters on the module.
The present disclosure also includes a method for forming a fiber optic terminal. The method may include inserting a feeder cable and a distribution cable into an enclosure defining an interior space. The feeder cable may include an optical fiber and a first connector coupled to the optical fiber, and the distribution cable may include an optical fiber and a second connector coupled to the optical fiber. One or more modules are inserted into one or more module holders of the enclosure, as discussed above. The connector or connectors of the feeder cable are then directly coupled to input adapters on the module and the connector or connectors of the distribution cable are directly coupled to distribution adapters on the module.
Embodiments disclosed herein also provide for a fiber optic module that is reversibly positionable in the module holder. The module can be positioned in a first position in the module holder, for example with an top face of the module facing upwards in the module holder, and can also be positioned in a second, opposite position in the module holder, for example with the top face of the module facing downwards in the module holder. This allows for customization of the location of the input adapters and output adapters. For example, in a fiber optic terminal having a column of vertically aligned module holders, the modules may be installed with the input adapters on a left-hand side for a particular application or on the right-hand side for another application. It is to be understood that directional terms, such as “top,” “bottom,” “upper,” “lower,” “left,” “right,” “medial,” “distal,” etc., are used for non-limiting illustrative purposes only.
The modules may also include a handle that is reversibly attachable to the module to match the orientation of the module within the module holder. The reversibility of the body and the handle provides for routing efficiency, enhanced organizational options, and ease of use for the modules within a fiber optic terminal.
An example fiber optic module may include a body defining a front side, a rear side, a first side face, a second side face, a top face, a bottom face, and an interior volume between the front side, the rear side, the first side face, the second side face, the top face and the bottom face. The fiber optic module may also include an input adapter positioned on a front side of the body and an output adapter positioned on the front side of the body. The fiber optic module may include a first arm extending from the front side of the body, a second arm extending from the front side of the body, a first flange extending from the first side face, and a second flange extending from the second side face. The first and second flanges may extend at a plane that bisects the body. The fiber optic module may also include a handle that is coupleable to the first and second arms. The handle is pivotably coupled to the first and second arms and is rotatable between a closed position and an open position. The handle is removable from the first and second arms when the handle is in the open position and the handle is not removable from the first and second arms when the handle is in the closed position.
The present disclosure also includes a method for forming a fiber optic module. The method may include incorporating a splitter into an interior space of a fiber optic module. The method may also include coupling a handle to a first arm and a second arm of the fiber optic module. The handle is rotatable with respect to the first and second arms between an open position and a closed position. The first arm may include a first protrusion and the second arm may include a second protrusion. The first protrusion mates with a first opening in the handle and the second protrusion mates with a second opening in the handle to hingedly couple the handle to the body. In addition, the first arm may include a first locking feature and the second arm may include a second locking feature. The first locking feature mates with a third opening in the handle and the second locking feature mates with a fourth opening in the handle to releaseably maintain the handle in the closed position. The first and second arms may be deflectable to release the first locking feature from the third opening and to release the second locking feature from the fourth opening. The handle is rotatable from the closed position to the open position when the first locking feature is released from the third opening and the second locking feature is released from the fourth opening.
Additional features and advantages will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art. It is to be understood that the foregoing general description, the following detailed description, and the accompanying drawings are merely exemplary and intended to provide an overview or framework to understand the nature and character of the claims.
Reference will now be made in detail to the embodiments, examples of which are illustrated in the accompanying drawings. Whenever possible, like reference numbers will be used to refer to like components or parts. One embodiment of a fiber optic terminal 10, which may also be referred to as a local convergence point (LCP), a fiber distribution hub (FDH), a fiber distribution terminal (FDT), or the like, is illustrated in
Each removable module 14 may include one or more of the following: a splitter, cable or fiber storage components, pass-through fiber components, connector parking components, splice components, input adapters, and distribution adapters. For example, in some embodiments, the modules 14 each include a 1×4 splitter, two 1×4 splitters, a 1×8 splitter, a 1×16 splitter or a 1×32 splitter. In these embodiments, the number of input adapters 16 and the number of output adapters 18 corresponds to the split ratio (i.e., a module 14 having a 1×4 splitter has one input adapter 16 and four output adapters 18 and a module 14 having a 1×8 splitter has one input adapter 16 and eight output adapters 18).
The fiber optic terminal 10 is customizable by incorporating modules 14 having the required functionality. For example, a fiber optic terminal 10 used for splitting each incoming signal into four separate signals may have one or more modules 14 having 1×4 splitters. In another example, a fiber optic terminal 10 used for splitting each incoming signal into eight separate signals may have one or more modules 14 having 1×8 splitters. In other embodiments, a fiber optic terminal 10 may have multiple uses. For example, a single fiber optic terminal 10 may be used for splitting a signal into four separate signals and for passing-through an un-split signal. Thus, the user would incorporate at least one module 14 having pass-through components and at least one module 14 having a 1×4 splitter. In other words, a single fiber optic terminal 10 may include a combination of modules 14 having different functionality (i.e., a combination of modules, where some modules have splitters, some modules have cable or fiber storage components, some modules have pass-through fiber components, some modules have splice components, and some modules have parking components). The modules 14 are interchangeable in the fiber optic terminal 10, thus eliminate the need for complex SKU management and allowing the user to assemble the desired configuration using a small set of standard parts.
The fiber optic terminal 10 may also include dedicated components, such as one or more patch panels 28 for pass-through fibers and one or more parking panels 30 for unused connectors, although these components are not required in every embodiment.
Referring again to
The enclosure 32 in
The enclosure 32 may also be made of any suitable material, such as a rigid metal or plastic material.
While not depicted, the enclosure 32 may include a cover that is affixed to the enclosure 32. The cover and the enclosure 32 serve to close off and protect the internal components of the fiber optic terminal 10 when the cover of the enclosure 32 is closed, and may include security features such as a security screw or external lock.
In some embodiments, the enclosure 32 is designed to be versatile such that it can be mounted in different environments. For example, the enclosure 32 may be configured for mounting on a strand, a floor, a wall, a conduit, a pole, a pedestal, a rack, or underground to provide compatibility with service provider's mounting preferences.
The enclosure 32 may also be provided with optional build-out features (for example, expansion rings or deep doors) to optionally increase the depth and capacity of the enclosure 32 for the purposes of adding expanded capacities at a later date. Such features may eliminate the need for civil placement costs and/or permitting as demands on the network require additional fiber placement. In other embodiments, the enclosure 32 may include external features that allow a user to attach another enclosure 32 on top of an existing enclosure 32.
The enclosure 32 may include one or more ports 36 for receiving feeder cables 24 and distribution cables 26 into the interior space 34. In some embodiments, the ports 36 are initially closed and must be opened by punching out material in the port, otherwise known as “punch-out” ports. Unused ports may remain closed and then may be “punched-out” to allow for additional feeder or distribution cables 24, 26. While the enclosure 32 of
The terms “feeder cable,” “distribution cable,” “fiber optic cables” and/or “optical fibers” include all types of single mode and multi-mode light waveguides. The waveguides may be coated, colored, buffered, ribbonized, and/or have other organizing or protective structures. The waveguides may be located in one or more tubes and the cable may also include other features, such as strength members, jackets, or the like. Suitable waveguides include optical fibers such as bend-insensitive optical fibers or any other expedient of a medium for transmitting light signals. An example of a bend-insensitive optical fiber is ClearCurve® Multimode fiber commercially available from Corning Incorporated. The term “feeder cable” as used herein should be understood to include, without limitation, transport cables, back haul cables, and the like. The term “distribution cable” as used herein should be understood to include, without limitation, branch cables, drop cables, and the like.
The fiber optic terminal 10 may be configured to accept stubbed and non-stubbed, preconnectorized or non-preconnectorized cables. As such, the ports 36 may be a pass-through type ports with standard hub and/or grommet functionality or may have a fiber optic adapter seated therein. For example, a fiber optic adapter may be seated within each port 36 and each fiber optic adapter may be configured to receive a single optical fiber connector or multiple optical fiber connectors, including, without limitation, SC, LC, MTP, OptiTap®, or OptiTip™ adapters commercialized by Corning Cable Systems LLC, Hickory, N.C.
In some embodiments, the enclosure 32 is preconfigured with one or more feeder cables 24, one or more distribution cables 26, or both feeder and distribution cables 24, 26. In some embodiments, additional feeder or distribution cables 24, 26 are included to facilitate rapid deployment of the enclosure 32.
For example, referring now to
In some embodiments, the gender of the feeder cable connector 38 (i.e., male connector or female connector) may be opposite from the gender of the distribution cable connectors 40 to allow for rapid insertion or removal of the enclosure 32 into/from a distribution network without the need for planning or modification of the fiber connections or cabling system. In addition, the opposite gender of the feeder and distribution cable connectors 38, 40 allows for serial placement of multiple enclosures 32 or rapid bypassing of an enclosure 32 to allow for expressing of un-modified or un-split fibers deeper into the network.
Referring still to
Referring again to
The module holders 12 may include one or more rail guides (see e.g., rail guide 226 in
The fiber optic terminal 10 may include any number of module holders 12. In some embodiments, for example, the fiber optic terminal 10 includes 3, 6, 9, or 12 module holders 12. For the removal of doubt, each module holder 12 need not include a module 14 at all times. Thus, the number of modules 14 positioned inside the enclosure may be less than the total number of module holders 12.
In other embodiments, the module 14 does not include input adapters 16 but rather an input fiber is spliced into the module 14. In yet other embodiments, the module 14 is configured to allow for spliced input fibers as well as connectorized input fibers. Likewise, the modules 14 may include openings for the splicing of output fibers in addition to, or in place of, the distribution adapters 18.
In some embodiments, the feeder and distribution cables 24, 26 include connectorized fibers that can be coupled directly to the input and output adapters 16, 18 of the modules 14. Thus, an optical connection may be established between the one or more optical fibers in the feeder cable 24 and the one or more optical fibers in the distribution cable 26 through the module 14 without the need to engage a separate input field or separate distribution field in the fiber optic terminal 10.
The modules 14 can be configured with any suitable adapter type. For example, in some embodiments the modules 14 include LC adapters while in other embodiments the modules 14 include SC adapters. The adapters 16, 18 may be factory installed in the modules 14 or may be installed in the field by a technician. Likewise, the modules 14 may be factory installed in the module holders 12 or may be installed in the field by field personnel as network demand increases.
As discussed above, the modules 14 may include one or more of the following: a splitter, cable or fiber storage components, pass-through fiber components, parking components, splice components, and the like. Modules 14 that include a splitter may include a number of input and distribution adapters 16, 18 corresponding to the split ratio of the splitter. For example, a module 14 that includes a 1×8 splitter may include 1 input adapter 16 and eight distribution adapters 18. Likewise, a module 14 that includes a double 1×4 splitter may include 2 input adapters 16 and eight distribution adapters 18.
Although the individual modules 14 may contain different features, such as splitters, cable or finer storage components, pass-through fiber components, parking components, splice components and the like, the modules 14 may have a uniform shape and size to allow for interchangeability of the modules 14 within standard sized module holders 12.
Referring again to
The fiber optic terminal 10 may also include a dedicated parking panel 30 including parking adapters to enable management of unused fibers until there is a need for future network expansion.
The fiber optic terminal 10 may also include dedicated fiber management features 46. The optical fibers route around the fiber management features 46 to manage the routing of the optical fibers and accommodate any slack. This allows the field technician to effectively and easily accommodate varying lengths of the optical fibers and identify the particular optical fibers. The fiber management may be accomplished in the fiber optic terminal 10 by dedicated fiber management features 46, modules 14 having fiber management components, or both dedicated fiber management features 46 and modules 14 having fiber management components.
The fiber optic terminal 10 may also include dedicated splitters (not shown) having high split ratios, such as 1×16, 1×32 or 1×64 splitters. Such splitters may have input and output pigtails and may be fixed to the fiber optic terminal 10 to accommodate various network configurations.
Referring now to
The module 14 includes a body 202, a handle 204 that is removably coupled to the body 202, and input and output adapters 16, 18 on the body 202. The module 14 is positionable in a module holder 12 of a fiber optic terminal 10, as described above. The module 14 is reversible, such that the module 14 can be positioned in a first position in which the top face 214 of the module 14 is upwards in the module holder 12, as illustrated in
The reversible nature of the module 14 allows for customization of the location of the input adapters 16 and output adapters 18 in the fiber optic terminal 10. For example, in
Referring again to
Referring again to
Referring now to
The term “splitter” as used herein should be understood to include any form of passive or active optical splitting, coupling, or wavelength managing device, including without limitation, a passive optical splitter, fused biconic taper coupler (FBT), wave length division multiplexer/demultiplexer (WDM), coarse wavelength division multiplexer/demultiplexer (CWDM), dense wave division multiplexer/demultiplexer (DWDM), and the like. The terms “cable storage components” as used herein should be understood to include any repository for holding excess cable length, including without limitation, reels, cable channels, flanges, tie-wraps, slots, hubs and the like. The term “fiber storage components” as used herein should be understood to include any repository for holding excess fiber length, including without limitation, routing rings, tie-wraps, slots, channels, storage flanges, hubs and the like. The term “pass-through fiber components” as used herein should be understood to include any feature that couples a first fiber to a second fiber without substantial modification to the signal carried by the first and second fibers. The term “parking components” as used herein should be understood to include any feature for temporarily holding a connector, or connectorized or unconnectorized fiber. The term “splice components” as used herein should be understood to include any feature for holding or protecting a permanent connection between two optical fibers, including without limitation, heat shrink splice protectors, crimp splice protectors, and the like.
Referring again to
The first and second arms 226, 228 each include a hinge protrusion 230 and a locking protrusion 236. The hinge protrusions 230 extend laterally from the first and second arms 226, 228 and provide a hinging point for the removable handle 204. The hinge protrusions 230 may be any suitable shape and size, such as, for example, a cylindrical shape. In some embodiments, the hinge protrusions 230 each include a lateral extension 234 (
The locking protrusions 236 of the first and second arms 226, 228 are positioned near a freestanding end of the first and second arms 226, 228. The locking protrusions 236 removably lock the handle 204 in the closed position. In the embodiments illustrated herein, the locking features 236 comprise a semicircular bulge on the exterior surface of the first and second arms 226, 228, but the locking features 236 may be any other physical feature that releasably locks the first and second arms 226, 228 to the handle 204 when the handle 204 is in the closed position. As described in more detail below, the locking features 236 engage second openings 288 of the handle 204 when the handle 204 is in the closed position to releasably hold the handle 204 in the closed position.
The handle 204 interacts with the first and second arms 226, 228 to manage and direct fibers and/or cables that are coupled to the adapters 16, 18. Referring specifically to
The first body portion 248 and the second body portion 250 provide surfaces against which feeder and distribution cables or fibers rest when coupled to the input and output adapters 16, 18. For example,
The first and second fiber guides 256, 258 also assist with directing the input and distribution fibers 290, 292 away from the module 14 in first and second lateral directions 302, 204. The first and second fiber guides 256, 258 have curved outer surfaces 282 to prevent the fibers 290, 292 from bending at too severe of an angle, which can damage the fiber 290, 292 or cause undesirable attenuation of the optical signal. In use, the fibers 290, 292 pass through a space 294 between the first fiber guide 256 and the second body portion 250 or the space 296 between the second fiber guide 258 and the second body portion 250.
The first and second fiber guides 256, 258 also include concave surfaces 298 configured to provide a finger hold for a user. As described in more detail below, the user places a finger on the concave surfaces 298 to apply a force to the handle 204 when moving the handle 204 between the closed and open positions.
The removal of the handle 204 from the first and second arms 226, 228 of the body 202 will now be described with reference to
The lateral extension 234 of the hinge protrusions 230 is misaligned with a keyhole 260 of the first openings 238 of the handle 204 so that the handle 204 is not removable from the first and second arms 226, 228 of the body 202. The locking protrusions 236 engage the second openings 288 of the first and second arms 226, 228 to hold the handle 204 in the closed position.
To move the handle 204 from the closed position (the closed position is shown in
The handle 204 may then be re-attached to the body 202 in the same orientation or a reversed orientation (i.e, such that the first and second fiber guides 256, 258 face the bottom surface 216 of the body, as illustrated in
The terms “left side,” “right side,” “upward,” downward,” “top,” “bottom” and similar terms are used for convenience of describing the attached figures and are not intended to limit this description. For example, the terms “left side” and “right side” are used with specific reference to the drawings are not intended to limit this description. Rather, the module 14 may be installed in other orientations in a reversible manner. For example, the module 14 may be installed in a closure such that the top surface 214 facing upward or facing downwards, to the right side, to the left side, or any other non-vertical direction.
To attach the handle 204 to the body 202, the second openings 288 of the handle 204 are placed over the hinge protrusions 230 of the first and second arms 226, 228 and the keyholes 260 (best shown in
The handle 204 may then be rotated approximately 90 degrees from the open position (
Referring again to
Referring momentarily to
In
The modules 14 are slideably received in the module holder deck 264 by sliding the first and second flanges 240, 242 in corresponding rail guides 266 of the module holders 12. In some embodiments, the railguides 266 include registration features 306 to removably hold the modules 14 on the rail guides 266. The registration features 306 interact with detents 246 (
In some embodiments, the modules 402 are shaped to fit snugly within the slots 404 so that the outer permimeter of the module 402 corresponds to the shape of the inner surfaces 406A, 406B of the closure 400. Thus, space is not wasted behind or around the modules 402 when installed in the closure 400.
In some embodiments, the slots 404 of the closure 400 are positioned adjacent to each other to allow for adjacent positioning of the removable modules 402 when the modules 402 are placed within the closure 400. All of the slots 404 need not include a module 402 and the modules 402 may be added or removed from the closure 400 as needed.
In use, the required modules 402 slide into the slots 404 in the closure 400. For example,
It is to be understood that the disclosure is not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. It is intended that the present disclosure cover the modifications and variations of this disclosure provided they come within the scope of the appended claims and their equivalents. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
This application claims the benefit of priority of U.S. Provisional Patent Application Ser. No. 62/331,040, filed May 3, 2016, U.S. Provisional Patent Application Ser. No. 62/351,493, filed Jun. 17, 2016, U.S. Provisional Patent Application Ser. No. 62/373,549, filed Aug. 11, 2016, and U.S. Provisional Patent Application Ser. No. 62/382,590, filed Sep. 1, 2016, the content of each of which is relied upon and incorporated herein by reference in its entirety.
Number | Date | Country | |
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62382590 | Sep 2016 | US | |
62351493 | Jun 2016 | US | |
62373549 | Aug 2016 | US | |
62331040 | May 2016 | US |