The present invention provides a shielding for cable components that uses a conductive or semi-conductive coating to reduce or eliminate internal and external cable crosstalk as well as other EMI/RF from sources outside of the cable. The present invention also relates to a method for applying the shielding to a substrate, such as a cable component.
A conventional communication cable typically includes a number of insulated conductors that are twisted together in pairs and surrounded by an outer jacket. Crosstalk or interference often occurs because of electromagnetic coupling between the twisted pairs within the cable or other components in the cable, thereby degrading the cable's electrical performance. Also, as networks become more complex and have a need for higher bandwidth cabling, reduction of cable-to-cable crosstalk (alien crosstalk) becomes increasingly important.
Shielding layers are often used to reduce crosstalk. Conventional shielding layers for communication cables typically include a continuous solid conductive material, such as aluminum or copper foil bonded to a plastic substrate. The substrate being provided for durability as the foil itself is not suitable for processing in a manufacturing environment. The shielding layer is wrapped around the cable's core of twisted wire pairs to isolate electromagnetic radiation from the core and also protect the core from outside interference. The conductive materials that can be used in this arrangement, however, are limited to those specific conductive foils that can be processed into a foil sheet. Other shielding applications rely on materials that highly absorb and dissipate interference. Shielding formed of such materials, however, is not advantageous in high performance communication cables, because the materials tend to attenuate the signal causing excessive power loss.
Typically in UTP (unshielded twisted pair) data communication cables, fillers made from dielectric materials are often used to provide physical separation between the pairs, effectively isolating their signals from one another. In UTP cables, the increased NEXT (near end crosstalk) performance required by 10 gigabit Ethernet applications necessitates the use of very large fillers, which in turn increases the size of the overall cable. In addition, the relatively large quantities of dielectric materials used in these large fillers often adversely affect the flame and smoke performance required to meet the plenum and riser ratings required for use in commercial installations.
Conventional STP (shielded twisted pair) and FTP (foil shielded twisted pairs) type cables often require shielding material to be placed around the individual pairs of conductors. Cable constructions of STP and FTP cables typically include pairs wrapped in foil tapes backed with polyester substrates to shield the pairs. These tapes are often rigid and do not effectively conform to the shape of the pair, thus adding extra radial dimension to the overall cable construction. The polyester backer or substrate material also adversely affects the flame and smoke performance required to meet the plenum and riser ratings needed for use in commercial installations.
Additionally, it is often advantageous to make the shield discontinuous to avoid the need for grounding. Conventional discontinuous shields, however, are difficult to manufacture and require application of separate segments onto a substrate or laser ablation to cut the shield foils to make the shield discontinuous.
Therefore, a need exists for a shielding that can be easily applied to any cable component, such as a separator, that improves both electrical and flame/smoke performance, reduces the radial size of the cable, and increases flexibility of the cable. Moreover, a need exists for easily making the shielding discontinuous.
Accordingly, the present invention provides a shielded cable component and method that comprises a main body that has an outer surface and the main body is formed of a dielectric material and a coating that is applied to the outer surface of the main body where the coating includes a conductive or semi-conductive shielding material. An outer layer is disposed on the coating that completely encapsulates the coating and the main body and the outer layer is formed of a dielectric material. In one exemplary embodiment, the cable component is a crossweb separator. In another exemplary embodiment, the coating is made of graphene.
The present invention also provides a cable that comprises a plurality of wire pairs and a separator that is disposed between the pairs. The separator includes a main body that has an outer surface and the main body is formed of a dielectric material. A coating is applied to the outer surface of the main body. The coating includes a conductive or semi-conductive shielding material. An outer layer is disposed on the coating completely encapsulating the coating and the main body. The outer layer is formed of a dielectric material. In one embodiment, the coating is discontinuous.
The present invention further provide a method for applying a shielding to a substrate the comprises the steps of providing a dielectric substrate that has a surface; coating the surface of the substrate with a conductive or semi-conductive shielding layer; and extruding a dielectric outer layer over the shielding layer such that the outer layer completely encapsulates the shielding layer and the substrate.
The present invention yet further provides a method for applying shielding to a substrate that comprises the steps of providing a substrate having a surface; applying at least one discrete amount of masking solution on the surface of the substrate; coating the surface of the substrate with a conductive or semi-conductive shielding layer such that the at least one discrete amount of masking solution is covered by at least one portion of the shielding layer; and removing the at least one discrete amount of masking solution and the at least one portion of the shielding layer from the substrate to create an electrically discontinuous shield on the surface of the substrate.
The present invention may also provide a method for applying shielding to a cable component that comprises the steps of providing a dielectric cable component and the cable component has a surface; applying at least one discrete amount of masking solution on the surface of the cable component; coating the surface of the cable component with a conductive or semi-conductive shielding layer such that the at least one discrete amount of soluble solution is covered by at least one portion of the shielding layer; and removing the at least one discrete amount of masking solution and the at least one portion of the shielding layer to create an electrically discontinuous shield on the surface of the cable component.
Other objects, advantages and salient features of the invention will become apparent from the following detailed description, which, taken in conjunction with the annexed drawings, discloses a preferred embodiment of the present invention.
A more complete appreciation of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
Referring to
A method according to an exemplary embodiment of the present invention generally includes the steps of applying a coated shielding layer 122 to a substrate, such as cable component 100, and encapsulating or completely covering the same with an outer layer 130. The outer layer 130 completely encapsulates the cable component 100 and its shielding layer 122 such that there are not openings or gaps in the outer layer 130. More specifically, the method may include the steps of: extruding the substrate or cable component 100 (
As seen in
After extruding the cable component 100, discrete amounts of the masking solution 110 may be applied to the outer surface 114 of the component 100. The discrete amounts of masking solution 110 are preferably applied as spaced apart concentric circumferential bands around the outer surface 114 of the component 100, as seen in
After application of the discrete amounts of masking solution 110, the component outer surface 114 and the bands of masking solution 110 may be coated with the conductive shielding layer 122 of the shielding 120, as seen in
Alternatively, the shielding layer 120 may be formed by conductive particles suspended in a non-conductive substrate, as disclosed in commonly owned currently pending U.S. application Ser. No. 13/246,183, filed Sep. 27, 2011 and entitled Shielding for Communication Cables Using Conductive Particles, and commonly owned currently pending U.S. application Ser. No. 13/045,000, filed Mar. 10, 2011 and entitled Cable Having Insulation With Micro Oxide Particles, the subject matter of each of which is herein incorporated by reference. For example, the conductive particles may be selected from aluminum, copper, iron oxides, silicone dioxide, nickel, zinc, silver, carbon nano fibers, graphene, or graphite, and the substrate may be an ink or adhesive.
To make the coated shielding layer 122 discontinuous, the circumferential bands of the masking solution 110 are removed, thereby taking with it any residual shielding layer 122 or portions of the shielding layer 120 covering the circumferential bands of the masking solution, as seen in
It is preferable that the segments 560 be sized relative to the lay length of the individual pairs 102 and lay length of the cable's core. This is due to the fact that the segments 560 act as antennas that retransmit electromagnetic energy. Also the gaps 550 are preferably sized to effectively block the range of frequencies most likely to impinge on the shielding 120 to accommodate any cable component design. These gaps 550 in the coating 122 provide another method to tune the shielding characteristics to the specific cable design by spacing them at intervals to avoid interference with the pair and or cable lay lengths. Although it is preferable that the shielding 120 be made discontinuous, the shielding 120 may be made continuous by eliminating the steps of applying and removing the masking solution 110 before applying the coating 122.
To protect the coated shielding layer 122, the outer layer 130 is extruded over the coated shielding layer 122, as seen in
While particular embodiments have been chosen to illustrate the invention, it will be understood by those skilled in the art that various changes and modifications can be made therein without departing from the scope of the invention as defined in the appended claims. For example, the separators of the above exemplary embodiments may have any cross-sectional shape, and is not limited to a crossweb or tube. Moreover, the shielding of the exemplary embodiments may be applied to any component of a cable and not just the separator.
This application claims the benefit of U.S. Provisional Application No. 61/505,772, filed Jul. 8, 2011 and entitled Shielding for Cable Components, and U.S. provisional application No. 61/513,220, filed Jul. 29, 2011, and entitled Method For Shielding A Substrate.
Number | Date | Country | |
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61505772 | Jul 2011 | US | |
61513220 | Jul 2011 | US |