The present invention relates to the storage, installation, and protection of runs of optical fibers and jumpers.
When running and storing fiber optic cabling, a number of problems exist that must be addressed. Optic fibers often are run along side copper and other cabling, which can subject the optic fibers to damage, along with the risk of damage from other factors such as seismic activity. Subjecting the fibers physical forces can compromise the signal transmission properties of fiber optical conductors. In order to create a separate fiber level to shield the fibers from damage, it is necessary to design and implement additional supports, bracing, and ironwork infrastructure. These extra ironwork levels can result in a huge capital investment, especially for long runs of cabling.
Systems and methods in accordance with embodiments of the present invention can overcome deficiencies in existing approaches by changing the way in which fiber optic cables and/or jumpers (simplex, duplex and assemblies variants) are contained. A racksaver device in accordance with one embodiment, as shown in
The product is manufactured using several variants for ease of installation. While the “house” or “modified pentagon” version is shown in the drawings, the product could also be configured as a cross-section of a circle, oval, triangle, square/rectangle “box”, pentagon, hexagon, heptagon, octahedral, octagonal, or decagon. Preferably, the designs would include internal cross supports to handle both static and dynamic stress.
These devices will come in two primary formats. First, individual straight and flexible curved components will be provided that can be assembled by attaching one to another. As an alternative, the product could be sold in long lengths which are wound on large spools that can be unspooled and straightened at the work site to form the protection component. The spooled version will require some form of stiffener to make the product more rigid after being unspooled. In a preferred embodiment, splines will be provided along the length of the structure that will permit the ability to place strengthener rods throughout the length. The rods will give the product the ability to become freestanding between supports for ranges up to 15 feet. Also, the spooled version can have predesignated cut points along its length that will permit the attachment (when separated) to connect with fixed racksaver components and different products from other manufacturers.
Different racksavers with different sized openings can be used for fiber cabling and fiber jumpers, since minimizing the opening size can help to prevent damage to the cabling/jumpers and improve the strength of the racksaver. Fiber cable and fiber jumper assemblies also can be separated into separate rack enclosures, such that fiber cable and jumpers are not be secured to each other in any enclosure. A separate type of racksaver for fiber optic jumpers can be manufactured for use in controlled environment areas such as central offices, IT computer/data centers, remote terminals, and at customer premises.
A racksaver can include a number of components. A standard straight component 2a as shown in
An interoperable transition component 2c as shown in
Fiber optical cables and conductors can be routed on or in dedicated raceways to minimize the potential for installed cables being subjected to physical forces that may compromise the signal transmission properties of fiber optical conductors. Optical conductors are susceptible to light transmission degradation if the fibers are subjected to tight bends over time and momentary heavy forces at concentrated points, sometimes referred to as micro bends. Accordingly, most optical cable manufacturers include minimum bending radius recommendations or requirements in their product documentation. The minimum-bending radius for cables commonly used within network equipment environments is 1.5″. Commercially available fiber protection raceway systems are constructed using the 1.5″ bending radius standard.
Routing fiber optic interconnect cables with copper network cable would subject the cables to potentially extremely heavy vertical loads, which would tend to force fiber optic cables to conform to the irregularities formed within copper cable bundles. This also would probably be less than the minimum bending radius requirements and recommendations of cable manufacturers. Installing fiber optic cable with copper cable would also subject the relatively more fragile fiber cables to potentially damaging forces during copper cable mining activities as well.
Outside plant (OSP) fiber cables that are routed interior to network equipment areas for any distance are generally placed on or in dedicated raceways primarily to protect them from cable “chum” that occurs throughout the life of a building. Generally, once placed, OSP cables are there forever, whereas cable within network equipment areas is subject to removal as equipment technologies are replaced over time. OSP cables are therefore kept separate from other communications cables, when possible, to avoid being disturbed and needlessly handled during the cable mining activities of other communications cable. Mining cable from raceways often involves the use of wooden wedges forced into cable bundles to obtain physical access to cables that are no longer being used. A fiber optic racksaver can perform this protective and routing function without the need for additional ironwork placements.
A fiber optic racksaver can be placed within the standard ironwork rack system, preferably to one side in various embodiments, as shown in
The open access point can be no larger than one inch for fiber cable and is no larger than ½ inch for jumpers in one embodiment. The open access point can run the length of rigid fixed component structures 2a. On the flexible component structure there may be no open access, such that the jumpers/cable must be threaded thru the curved areas and flexible components.
Securing bolts can be placed through the ends of two adjoining component panels to lock the panels together. As seen in
The racksaver is installed in one of two methods. In the first using the fixed components, the products are placed into the copper metal overhead or underfloor super structure racking and then assembled to one another to make a extended length product. Flexible racksaver turns will be used to reroute the racksaver product to match the superstructure and building systems. Each racksaver component will then be connected with each other and then the racksaver product will be secured to the superstructure ironwork.
Using the spooled racksaver version, the product will be unrolled from a 20 to 500 foot roll. One end will be placed in the superstructure ironwork and pulled throughout the route in the same manner that copper cable is placed in this ironwork superstructure. Where there are sharp turns, a support cast will be attached to the interior bend to protect the bend radius. This support cast will attach to the exterior of the racksaver using strengthener rod grommet attachments on the exterior of the product. This can be rapidly deployed using tie wraps or equivalent materials. Once the racksaver is in its final placement location, the strengthener rods are placed at such bridge points where there is a gap in the overhead or underfloor ironwork superstructure of 4 feet or more. The ends of the racksaver are cut at the premarked cut point and then subsequently attached to other fixed or other manufacturer products through the use of the flexible racksaver component. The product is then secured in the same manner to the ironwork superstructure.
On one side of the angled roof of a racksaver can be an opening running the length of the component panels. The cable version of the panels can use a ½ inch high opening, while the jumper assemblies can use a ¼ inch version. At reinforcement points, there can be a latch that helps to perform the function of weight support on that side. If for any reason the latches are not engaged properly, the opening can close due to the weight, with the upper portion of the opening seating with the lower lip of the opening. The roof could be lifted at any point using a grappling tool to gain access in an unusual condition.
Latches can be placed at each reinforced superstructure at the open access point on the panels. As seen in
An interoperable component 2c, as shown in
A downspout 2d, as seen in
A grappling tool 2f, as seen in
A flexible component can use three rigid structures attached with accordion-like flexible plastic materials that permit a flex in any one of 360 degrees of direction, up to 90 degrees in any one-direction. A flexible component can be designed to not bend with a radius less than two inches in any one direction.
Each component panel can have a wider attachment wall on the right end and a tighter on the left. Such design permits the interconnection of the ends of a wider section to a narrower section using a secure bolt.
Jumpers can be scooped up and, using a 1.5″ bend radius, be lifted over the edge and straight down.
As seen in
It should be recognized that a number of variations of the above-identified embodiments will be obvious to one of ordinary skill in the art in view of the foregoing description. Accordingly, the invention is not to be limited by those specific embodiments and methods of the present invention shown and described herein. Rather, the scope of the invention is to be defined by the following claims and their equivalents.
This application is a divisional application of U.S. patent application Ser. No. 11/341,837 filed Jan. 27, 2006, now abandoned which in turn claimed priority to U.S. Provisional Application Ser. No. 60/649,187, filed Feb. 2, 2005, which is incorporated herein by reference.
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6535683 | Johnson et al. | Mar 2003 | B1 |
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Number | Date | Country | |
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20080089655 A1 | Apr 2008 | US |
Number | Date | Country | |
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60649187 | Feb 2005 | US |
Number | Date | Country | |
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Parent | 11341837 | Jan 2006 | US |
Child | 11980249 | US |