Patent Grant
7253362
Closure housings have been used in the telecommunications industry and electrical utilities industry for the purpose of protecting cables from outside environmental elements. Such closure housings can be installed above-ground as aerial closures, buried underground, placed in hand-holes, or mounted on poles. The outer perimeter of the closure housing provides mechanical protection from environmental elements such as rains, floods, winds, and snow, and other water or dirt particles that may harm the splice or connector.
Embodiments of the invention, for example, can advantageously include an apparatus including several housings. At least one of the housings can include a concave housing with an open face. One or more elastomeric films can surround one or more cables to seal the cables from environmental conditions, the combination defining one or more wrapped cables. A portion of each of the wrapped cables can be adapted to be interposed between the housings.
Also, for example, embodiments of the invention can advantageously include an alternative apparatus including several housings. At least one of the housings can include a concave housing with an open face. One or more conformable sealants can surround one or more cables to seal the cables from environmental conditions. One or more flexible layers can surround each of the cables and conformable sealants (the conformable sealant configured to be positioned between the cable and the flexible layer), the combination defining one or more wrapped cables. A portion of each of the wrapped cables can be adapted to be interposed between the housings.
Also, for example, embodiments of the invention can advantageously include an alternative apparatus including several housings. At least one of the housings can include a concave housing with an open face. One or more flexible layers and elastomeric films can wrap around a portion of one or more cables to seal the cable from environmental conditions (the elastomeric film configured to be positioned between the cable and the flexible layer), the combination defining one or more wrapped cables. A portion of each of the wrapped cables can be adapted to be interposed between the housings. One or more endseals of elastomeric material can be wrapped around a portion of the wrapped cables to further seal the cables from environmental conditions. The endseal of elastomeric material can be configured to align with a circumferential perimeter portion of the open face of each of the concave housings. The endseals can be adapted to be interposed between the housings.
Also, for example, embodiments of the invention can advantageously include an alternative apparatus including several housings. At least one of the housings can include a concave housing with an open face. One or more flexible layers can surround each of the cables to seal the cable from environmental conditions, the combination defining one or more wrapped cables. A portion of each of the wrapped cables can be adapted to be interposed between the housings.
In operation, the invention advantageously provides improved protection and watertight sealing of one or more cables and/or joining components from harmful environmental conditions in the communications industry (such as telecommunications industry), utilities industry (such as electrical utilities industry), or other industries involving the distribution of cables and/or the transmission of optical light or electricity, seeking improved solutions regarding sealing solutions, re-enterability solutions, pressure condition solutions, space condition solutions, and weight condition solutions advantageously provided by the invention.
In one aspect of the invention, the inclusion of the elastomeric film, flexible layer, and/or conformable sealant, in combination with the hollow nature of the concave housing, advantageously provides a solution for a closure housing that offers improved sealing, while at the same time providing a closure housing that is re-enterable to an extent not provided in existing closure housings.
Further, in another aspect, the invention advantageously provides improved mechanical cable stress and strain relief based on pressure changes during periods of operation. The relatively soft surface of the layers surrounding the cables can deform to accommodate pressure changes, without placing undue stress on the outer perimeter of the housings. The compliance of the deformable layers surrounding the cables allows for significant changes in the shape of the closure while maintaining a watertight seal. Because the volume protected from water is only marginally larger than the volume of the splice, and generally significantly smaller than the entire volume of the interior of the closure housing, the influence of pressure changes are advantageously minimized, as compared to rendering the entire volume of the closure housing watertight.
Further, the hollow nature of the concave housing advantageously provides increased room or space for the displacement of large cables inside the closure housing. Further, the hollow nature of the concave housing advantageously provides a lightweight solution for a closure housing, and the decrease in weight importantly allows for easier installation and transport, as well as a reduction in cost associated with the manufacture of such a closure housing.
In the past, closure housings have demonstrated problems that have not as yet been overcome in the art. Prior closure housings, and the sealing mechanism thereof, have demonstrated significant changes in shape with changing temperatures. Such changes in shape have caused loss of the seal and failure of the water and dirt particle barrier properties important to the sealing function. Prior closure housings also have presented the problem of not being easily re-enterable, which is significant in cases where cable repair or splice repair is necessary. The excess materials and heavier weight associated with prior closure housings contributed to increased waste and more difficult transport.
a is an isometric view of a housing in an open position, showing the hollow concave interior of the housing.
b is an isometric view of a housing in an open position, showing gas bladders filling the concave interior of the housing.
a is an isometric view of removable walls having arcuate channels according to an embodiment of the invention.
b is an isometric view of a housing prior to installation of the removable walls of
c is an isometric view of a housing after installation of the removable walls of
As shown in the Figures, the invention includes a plurality of housings 12, at least one of which comprises a concave housing 12 with an open face. Embodiments of the invention can include, for example, facing mated housings 12, where two or more of the plurality of housings 12 are concave housings 12 with an open face, and where the open face of one of the concave housings 12 faces and mates with the open face of an adjacent housing 12. Embodiments can also include one or more hinges, such as a living hinge, or other fasteners positioned at circumferential perimeter 15 portions of each of the housings 12 to join each housing 12 with an adjacent housing 12. Also, for example, embodiments can include clips, bolts, or other fasteners used to maintain the entire closure housing 10 in the closed position.
The housings 12 can be made by various processes, for example, injection molding, blow molding, spin molding, extrusion molding, vacuum molding, rotational molding, and thermal forming. Embodiments of the housings 12 can be made from various materials, for example, aluminum, steel, metal alloys, and plastics, particularly injection molded thermoplastics, such as polyolefins, polyamides, polycarbonates, polyesters, polyvinyls, and other polymeric materials. The plastic housing 12 embodiments can use a metal reinforcing strip for increased stability and strength.
As shown in
Alternatively, as shown in
Also, as shown in
A portion of each of the wrapped cables can be interposed between the housings 12. As shown in
Also, for example, as shown in
Also, for example, the cable 30 can be wrapped with two flexible layers and an elastomeric film mounted thereon. One example of such an embodiment provides a first flexible layer in the form of a woven or non-woven web of strands surrounding the cable. The elastomeric film covers the first flexible layer while at the same time co-continuously interpenetrating with the first flexible layer web of strands. Finally, a second flexible layer in the form of a rubber material surrounds the collective first flexible layer and elastomeric film.
Also, for example, the cable 30 can be wrapped with two flexible layers and a conformable sealant mounted thereon. One example of such an embodiment provides a first flexible layer in the form of a porous substrate surrounding the cable. The conformable sealant covers the first flexible layer while at the same time co-continuously interpenetrating with the first flexible layer porous substrate. Finally, a second flexible layer in the form of a rubber material surrounds the collective first flexible layer and conformable sealant.
Also, for example, the housing 12 can include one elastomeric film layer mounted thereon across the open face on the circumferential perimeter 15 of the housing 12, while at the same time featuring a cable pre-wrapped with a separate elastomeric film layer 20 that is housed within the housing 12. This embodiment offers the advantages of having multiple points of sealing. The elastomeric film layer 20 that wraps the cable acts as a first point of sealing, and the elastomeric film layer that is mounted to the housing acts as a second point of sealing.
In accordance with the invention, the flexible layer can be any layer that is flexible, the elastomeric film can be any layer exhibiting elastomeric properties, and the conformable sealant can be any material capable of conforming itself to an adjacent structure. For example, a rubber material can be both a flexible layer and an elastomeric film. Also, for example, a polymeric gel material can be a flexible layer, an elastomeric film, and a conformable sealant as well. Also, for example, a grease material can be a conformable sealant.
The elastomeric film 20 typically includes at least a polymer and an oil portion. Embodiments of the elastomeric film 20 can include, for example, a polymeric thermoplastic hydrophobic gel sealant including at least a portion of oil.
The properties of the polymer which make it most suited for this application are good compatibility with the oil, and rubber-like morphology, meaning flexible chains with some significant molecular flexibility between cross-linking sites. Examples of polymers that are useful can include oil-filled silicones, polyurethanes, polyesters, polyepoxys, polyacrylates, polyolefins, polysiloxanes, polybutadienes (including polyisoprenes), and hydrogenated polybutadienes and polyisoprenes, as well as copolymers, including block copolymers and graft copolymers. The blocks of the block copolymers may include the above polymers and poly(monoalkenylarenes) including polystyrene. Examples of these bock copolymers can include particularly SEBS (Styrene, ethylene-butylene, Styrene), SEPS (Styrene, ethylene-propylene, Styrene), similar Styrene-rubber-Styrene polymers, di-block, tri-block, graft- and star-block copolymers, and block copolymers with blocks which are non-homogeneous. Closed-cell foamed materials, and those incorporating microbubbles or other soft (or hard) fillers can also be included.
Embodiments of the invention can feature the elastomeric film 20 as a thermoplastic or alternatively as being cured in place. In the form of thermal cures, room temperature vulcanizable cures (RTV cures), UV-initiated cures, e-beam cures, radiation initiated cures, and cures from exposure to air and/or moisture. The elastomeric film 20 typically has greater cohesion than adhesion.
The portion of oil in the elastomeric film 20 can be, for example, in the range of about 50% to about 98% of the elastomeric film 20, or more particularly, in the range of about 85% to about 98% of the elastomeric film 20. Also, for example, embodiments of the elastomeric film 20 can include filler particles, such as polymeric spheres or glass microspheres. One example of such filler particles is deformable bubbles, where the elastomeric film 20 is formed by foaming and adding discrete bubbles. The added bubbles can be polymeric or glass microbubbles. Addition of such filler particles or bubbles allows the elastomeric film 20 to demonstrate volume compliance which will further allow conformity of the elastomeric film 20 in operation.
Embodiments of the oil can include, for example, an extender such as synthetic oils, vegetable oils, silicones, esters, hydrocarbon oils, including particularly naphthinic oils and paraffinic oils and blends, and also possibly some small percentage of aromatic oils. Some compositions within the elastomeric film 20 are intermediate between the polymer and the oil. For example, the elastomeric film 20 can include a liquid rubber which may not become part of the gel-forming polymer network. Examples of such a liquid rubber can include polybutene of moderate molecular weight, and low molecular weight EPR (Ethylene Propylene Rubber). Adding a liquid rubber to the polymer and oil can tailor the characteristics of the sealant by increasing the tack, for example. Takifiers, antioxidants, colorants, UV stabilizers, and others can be added.
Typically, the oil is advantageously hydrophobic to keep water out. Also, typically, the oil advantageously reduces the amount of chain entanglements and the number of crosslinks per volume, thereby making the material softer in the gel form. Also, typically, the oil advantageously reduces the viscosity of either the precursor (before curing) or the melted thermoplastic. Also, typically, the oil is relatively inexpensive thereby reducing the cost of the total formulation.
As mentioned previously, a conformable sealant 20 can be used with the housing 12 in various embodiments. Embodiments of the conformable sealant 20 provide the required mechanical properties of low shear yield point, and higher adhesion than cohesion. Embodiments of the conformable sealant 20 can include, for example, a thickener cooperating with at least a portion of oil.
The thickener can include, for example, an organic polymeric composition. The organic polymeric composition can include, for example, polymers including polyurethanes, polyesters, polyepoxys, polyacrylates, polyolefins, polysiloxanes, polybutadienes (including polyisoprenes) and hydrogenated polybutadienes and polyisoprenes, as well as block copolymers. The blocks of the block copolymers can include, for example, the above polymers and poly(monoalkenylarenes) including polystyrene. These bock copolymers can include particularly SEB (Styrene, ethylene-butylene), SEP (Styrene, ethylene-propylene), SEBS (Styrene, ethylene-butylene, Styrene), SEPS (Styrene, ethylene-propylene, Styrene), similar Styrene-rubber polymers, di-block, graft- and star-block copolymers, and block copolymers with blocks which are non-homogeneous.
Also, for example, the thickener can include an inorganic sol composition. The inorganic sol composition can include, for example, alumina, silica, or clay. Also, for example, the thickener can include a soap composition. The soap composition can include, for example, metal complex soaps, aluminum complex soaps, lithium complex soaps, or calcium complex soaps. Also, for example, the thickener can be a greases, waxes (including polyethylene and polypropylene waxes), or viscoelastic polymeric hydrophobic composition including at least a portion of oil. The conformable sealant 20 can also be prepared from shearing gels, for example, as understood by those skilled in the art.
The portion of oil in the conformable sealant 20 can be, for example, in the range of about 50% to about 98% of the conformable sealant 20, or more particularly, in the range of about 70% to about 98% of the conformable sealant 20. For example, the oil can be a hydrocarbon oil, including particularly naphthinic oils and paraffinic oils and blends, and also possibly aromatic oils. Also, for example, embodiments of the conformable sealant 20 can include filler particles, such as polymeric spheres or glass microspheres. One example of such filler particles is deformable bubbles, where the conformable sealant 20 is formed by foaming or by adding discrete bubbles. The added bubbles can be polymeric or glass microbubbles. Addition of such filler particles or bubbles allows the conformable sealant 20 to demonstrate volume compliance which will further allow conformity of the conformable sealant 20 in operation.
As mentioned previously, a flexible layer 22 can be used with the housing 12 in various embodiments. The flexible layer 22 can include, for example, a rubber, elastomer, or other elastic material. The flexible layer 22 can be used alone by itself, or alternatively the flexible layer 22 can be used in cooperation with the elastomeric film 20 and/or conformable sealant 20. An adhesive may be applied between the flexible layer 22 and the elastomeric film 20 or conformable sealant 20 in those cases in which multiple layers are utilized with the housing 12. Additionally, the flexible layer 22 can include, for example, a woven web of strands or a non-woven web of strands, capable of co-continuously interpenetrating with the elastomeric film 20. The flexible layer 22 can also include, for example, a porous substrate capable of co-continuously interpenetrating with the conformable sealant 20. The flexible layer 22 can also include, for example, open-cell foams and open geometry webs. The flexible layer 22 can be capable of deforming to seal a solid object such as a cable 30.
As shown in
As shown in
The housing 12 can advantageously operate to seal a single cable 30 or a series of cables 30 from water, particles, or other environmental elements. Embodiments can include, for example, a cable 30 or series of cables 30 joined to another cable 30 or series of cables 30 within the closure via a joining component 35, or a single cable 30 run all the way through the closure as a single unit, or, for example, both can occur within a single closure. Each of the cables 30 passing inside or through the closure is configured along a direction substantially parallel to the plane of the open face of the concave housing 12. The circumferential perimeter portions are joined by one or more fasteners at opposite sides of the open face to retain the closure housing 10 in the closed or shut position with the cables 30 sealed therein.
In some embodiments that do not include a joining component 35 joining two or more cables 30, a single cable 30 running through the closure may need to be sealed from water or other environmental elements after a cable repair material is applied for repair or maintenance of the cable 30. In such a case where a cable repair material surrounds one or more cables 30 within the closure, the worn or torn portion of the cable 30 that contains the cable repair material interfaces a portion of at least one of the elastomeric films 20, for example, after being interposed between the facing housings 12 of the closure. Embodiments of the cable repair material applied to the cable 30 can include, for example, tapes, mastics, foams, epoxys, encapsulants, shield bond connectors, braid, #6 ground wire, and other types of cable repair materials.
If a joining component 35 is used to join two or more cables 30, the housing 12 advantageously operates to seal not only each cable 30 run inside or through the closure, but also to seal the joining component 35 inside the closure from water or other environmental elements. Embodiments of the joining component 35 can include, for example, a splice or other joining component 35 having connectors therein (including discrete connectors, modular connectors, tap connectors, preterminated connector, or other connectors). Also, for example, in some applications the joining component 35 can include a termination, where the cable 30 is joined with a terminal piece of electrical or fiber optic equipment.
The joining component 35 can interface a portion of the innermost layer surrounding or wrapped around the cables 30 and the joining component 35, and thereafter the wrapped joining component can be interposed between the housings 12.
Embodiments including any or all of the flexible layer 22, elastomeric film 20, and/or conformable sealant 20 advantageously operate to prevent external particles and fluids from accessing the portion of the one or more cables 30 wrapped by the flexible layers 22, elastomeric films 20, and/or conformable sealants 20.
In some embodiments, if desirable, the housing 12 can be designed to better interface or seal a particular diameter of cable 30. For example, concave housings 12 of
Also, for example, as shown in
As shown in the exemplary embodiments of
As shown in
The endseal 40 material, as understood by those skilled in the art, includes polymers and formulations including, for example, oils, plasticizers, and other polymeric materials, rubber tape with or without adhesive, vinyl tape, as well as materials that would be considered mastic. The endseal 40 material can also be the same material as used in the aforementioned elastomeric film 20.
In operation, the invention advantageously provides improved protection and watertight sealing of one or more cables 30 and/or joining components 35 from harmful environmental conditions in the communications industry (such as telecommunications industry), utilities industry (such as electrical utilities industry), or other industry involving the distribution of cables 30 and/or the transmission of optical light or electricity, seeking improved solutions regarding sealing solutions, re-enterability solutions, pressure condition solutions, space condition solutions, and weight condition solutions advantageously provided by the invention.
The inclusion of the elastomeric film 20, flexible layer 22, and/or conformable sealant 20, in combination with the hollow nature of the concave housing 12, advantageously provides a solution for a closure housing 10 that offers exceptional sealing, while at the same time providing a closure housing 10 that is re-enterable to an extent not provided in previous closure housings 10.
Further, the invention advantageously provides improved mechanical cable 30 stress and strain relief based on inevitable pressure changes during periods of operation. The relatively soft surface of the layers mounted to the housings 12 can deform to accommodate pressure changes, without putting undue stress on the outer perimeter of the housings 12. The compliance of the deformable layers mounted to the housings 12 allows for significant changes in the shape of the closure while maintaining a watertight seal. Because the volume protected from water is only marginally larger than the volume of the splice, and generally significantly smaller than the entire volume of the interior of the closure housing 10, the influence of pressure changes due to immersion are advantageously minimized, as compared to rendering the entire volume of the closure housing 10 watertight.
Further, the hollow nature of the concave housing 12 advantageously provides increased room or space for the displacement of large cables 30 inside the closure housing 10. Further, the hollow nature of the concave housing 12 advantageously provides a lighter solution for a closure housing 10, and the decrease in weight importantly allows for easier installation and transport, as well as a reduction in cost associated with the manufacture of such a closure housing 10.
Although the aforementioned detailed description contains many specific details for purposes of illustration, anyone of ordinary skill in the art will appreciate that many variations, changes, substitutions, and alterations to the details are within the scope of the invention as claimed. Accordingly, the invention described in the detailed description is set forth without imposing any limitations on the claimed invention. The proper scope of the invention should be determined by the following claims and their appropriate legal equivalents.
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