Optical waveguides – Optical transmission cable – Ribbon cable
Reexamination Certificate
1998-08-05
2001-10-09
Jagannathan, Vasu (Department: 1714)
Optical waveguides
Optical transmission cable
Ribbon cable
C385S123000, C523S160000, C428S378000
Reexamination Certificate
active
06301415
ABSTRACT:
FIELD OF THE INVENTION
The invention relates to optical glass fiber ribbon assemblies. The invention also relates to radiation-curable compositions. The radiation-curable compositions are suitable for formulating radiation-curable ink coating compositions, radiation-curable colored outer primary coating compositions, and radiation-curable matrix forming compositions.
BACKGROUND OF THE INVENTION
Optical glass fibers are generally coated with two superposed radiation-cured coatings, which together form a primary coating. The coating which is in direct contact with the glass is called the inner primary coating and the overlaying coating(s) is called the outer primary coating.
The inner primary coating is usually a relatively soft coating providing environmental protection to the glass fiber and resistance, inter alia, to the well-known phenomenon of microbending. Microbending in the coated fiber can lead to attenuation of the signal transmission capability of the coated fiber and is therefore undesirable. The outer primary coating(s), which is on the exposed surface of the coated fiber, is typically a relatively harder coating designed to provide a desired resistance to physical handling forces, such as those encountered when the fiber is cabled.
For the purpose of multi-channel transmission, optical glass fiber assemblies containing a plurality of coated optical fibers have been used. Examples of optical glass fiber assemblies include ribbon assemblies and cables. A typical ribbon assembly is made by bonding together a plurality of parallel oriented, individually coated optical glass fibers with a matrix material. The matrix material has the function of holding the individual optical glass fibers in alignment and protecting the same during handling and the installation environment. Often, the fibers are arranged in “tape-like” ribbon structures, having a generally flat, strand like structure containing generally from about 2 to 24 fibers. Depending upon the application, a plurality of resulting ribbon assemblies can be combined into a cable which has from several up to about one thousand individually coated optical glass fibers. An example of a ribbon assembly is described in published European patent application No. 194891. In general, a plurality of ribbon assemblies may then be combined together in a cable, as disclosed in U.S. Pat. No. 4,906,067.
The term “ribbon assembly” as used herein includes the tape-like ribbon assembly described above, as well as optical glass fiber bundles. Optical glass fiber bundles can be, for example, a substantially circular array having at least one central fiber surrounded by a plurality of further optical glass fibers. Alternatively, the bundle may have other appropriate cross-sectional shapes such as square, trapezoid, etc.
Coated optical glass fibers for use in optical glass fiber assemblies are usually coated with an outer colored layer, called an ink coating, or alternatively a colorant is added to the outer primary coating to facilitate identification of the individual coated optical glass fibers. Thus, the matrix material which binds the coated optical glass fibers together contacts the outer ink layer if present, or the colored outer primary coating.
Ink coatings usually have a thickness of about 3 to about 10 microns and are formed from a pigment dispersed within a UV curable carrier system. The UV curable carrier system contains a UV curable oligomer or monomer that is liquid before curing to facilitate application of the ink composition to the optical glass fiber, and then a solid after being exposed to UV radiation. In this manner, the UV curable ink composition can be applied to a coated optical glass fiber in the same manner as the inner primary and outer primary coatings are applied.
It is commonly required that, in use, branching fiber connections must be made at a location intermediate to the respective termini of a given length of the ribbon assembly. Accessing the individual fibers in this manner is commonly referred to as “mid-span access” and presents special problems. Normal methods and tools for accessing the end or terminus of the ribbon assembly are generally not well adapted or are inoperable for providing midspan access.
There have been many attempts to provide a ribbon unit in which the matrix material is easily separated from the colored coating present on optical glass fibers at any location on the ribbon unit without removal of the colored coating from the coated optical glass fibers. However, if the separation of the matrix material also removes the colored coating from the fibers, the purpose of individual fiber identification will be negated.
One common method for providing mid-span access is to contact the matrix material with a solvent, such as ethanol or isopropyl alcohol. Such a solvent must have the ability of swelling or softening the matrix material. At the same time, the solvent should be selected so as not to swell the coatings on the individual optical glass fibers. The swelling of the matrix material weakens that matrix material so that it can then be mechanically removed by mild scrubbing or similar mechanical means to remove the matrix material and thereby provide access to the individual, but still coated and color-identifiable, optical glass fibers. An example of this solvent stripping method is described in the AT&T brochure “D-182355 Accuribbon™ Single Fiber Access” (Mar. 3, 1991).
Published European application number 0614099A2 discloses an optical fiber ribbon unit in which the bonding between the coloring layer of the individual optical glass fibers and the matrix layer is suppressed by adding 5% by weight or less of a release agent to each of the layers. The purpose of adding the release agent is to prevent the coloring layer from being peeled off when the matrix material is separated from the optical glass fibers. Examples of such release agents include a silicone release agent or a fluorine-base release layer.
Published Japanese Patent Application No. 64-22976 discloses radiation-curable ink compositions containing specific radiation-curable oligomers. The ink composition provides an ink coating having adhesion to the outer primary coating which is separable from the matrix material in a ribbon assembly.
Published Japanese Patent Application No. H1-152405 discloses a radiation-curable ink composition containing an organic polysiloxane compound. The polysiloxane compound provides the ink coating with the ability to separate more easily from the matrix material in a ribbon assembly.
U.S. Pat. No. 4,900,126 (Jackson) discloses an optical glass fiber ribbon unit in which each of the individually coated optical glass fibers has a colored outer layer. Each of the optical glass fibers is further coated with a release agent which has a low affinity for the bonding material or the colorant material. An example of the release agent is teflon. The release agent creates a weak boundary layer at the interface of the colorant material and the matrix material whereby the matrix can be separated from the optical glass fibers without removing the colored layer on the individual optical glass fibers.
U.S. Pat. No. 4,953,945 discloses using a peelable cured coating layer between an outer colored layer of optical glass fibers and the matrix material whereby the matrix material can be stripped from the optical glass fibers without removing the colored layer of the optical glass fibers.
U.S. Pat. No. 5,524,164 discloses a cable assembly comprising a plurality of ribbon assemblies. The common coating material that bind the ribbon assemblies together contains a component having poor compatibility with the main component in the common coating. Examples of such poor compatibility components include hydrocarbons having from 10 to 20 carbon atoms, silicone oils and fluorine oils. The poor compatibility component reduces the friction between the ribbon assemblies to prevent damage to the fibers when the cable is bent. The poor compatibility component provides a discontinuous layer on the common coating, in the form
Murphy Edward J.
Szum David M.
Zahora Edward P.
DSM N.V
Jagannathan Vasu
Manelli Denison & Selter PLLC
Melcher Jeffrey S.
Shosho Callie E.
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