Abstract: A central office surge protector having at least one gas tube and at least one varistor. The at least one varistor interacts with the at least one gas tube to lower the impulse breakdown voltage of the gas tube. The at least one gas tube may be a two or a three element gas tube. Alternative embodiments of the surge protector further include at least one sneak current protection element.
Abstract: A surge protector having a failsafe mechanism including at least one overvoltage protection element, at least one arm assembly, at least one ground element, at least one resilient member, and at least one protrusion. The at least one resilient member is electrically connected to the at least one ground element and the at least one protrusion is generally positioned between the at least one resilient member and the at least one arm assembly. The at least one protrusion is in thermal contact with the at least one resilient member, prevents the at least one resilient member from electrically contacting the at least one arm assembly during normal operation, and is spaced away from the at least one arm assembly.
Type:
Grant
Filed:
November 30, 2001
Date of Patent:
December 30, 2003
Assignee:
Corning Cable Systems LLC
Inventors:
Robert J. Bennett, Gustavo A. Gonzalez, Jr., Casimir Z. Cwirzen
Abstract: Fiber optic cables, and methods of manufacturing the same, include a plurality of carriers having at least one optical fiber therein. In one embodiment, the carriers are arranged in two layers within the cable and are generally disposed about a center area of the cable. Each layer has a respective helix-plus-EFL value. A difference between the respective helix-plus-EFL values of the layers defines a differential range being, preferably, about 1% or less. Additionally, the fiber optic cables can be used in fiber optic cable systems such as dispersion managed cable systems (DMCS).
Abstract: A fiber optic cable having at least one interface being formed by a plurality of adjacent support members. Adjacent the interface is at least one retention area having an optical fiber component disposed therein. The retention area is disposed generally longitudinally and non-helically relative to an axis of the cable. The cable can also include a cable jacket substantially surrounding the support members, a cushioning zone adjacent the optical fiber component, a water-blocking component and/or an interfacial layer at least partially disposed between an outer surface of the support members and the cable jacket.
Abstract: A fiber optic cable having at least two interfaces being formed by first and second members. Between the interfaces is at least one retention area having an optical fiber component disposed therein. The retention area is disposed generally longitudinally and non-helically relative to an axis of the cable. The cable may also include a cable jacket substantially surrounding the members, a cushioning zone adjacent the optical fiber component, a water-blocking component and/or an interfacial layer. In another embodiment, a fiber optic cable includes a strength group having at least one strength member and an optical fiber being proof-tested to 125 KPSI or greater.
Abstract: A fiber optic cable and method of manufacturing the same having at least one optical fiber component, at least one strength member and at least one ultra-low shrinking filament. The at least one ultra-low shrinking filament having a shrinkage of about 0.2% or less when heated and held at about 85° C. for about seven days. At least one strength member and at least one ultra-low shrinking filament being disposed generally between the at least one optical fiber component and a cable jacket. The jacket generally surrounding the at least one optical fiber component, the at least one strength member and the ultra-low shrinking filament. The cable can include an interfacial layer interposed between said at least one optical fiber component and the jacket. Additionally, the cable can be riser or plenum rated.
Abstract: A fiber optic cable including at least one tube assembly therein. The tube assembly includes an optical fiber ribbon stack in a tube. The optical fiber ribbon stack comprises optical fiber ribbons arranged at least partially in a gradually decreasing optical fiber count profile. A diagonal free space of the tube assembly being about 0.5 mm to about 5 mm. The diagonal free space is defined as the tube inner diameter minus the maximum diagonal length of the ribbon stack. The maximum diagonal length of the ribbon stack being the greater of either a diagonal measurement across lateral subgroups of the ribbon stack or a diagonal measurement across a major dimension of a medial subgroup of the ribbon stack.
Type:
Grant
Filed:
August 15, 2001
Date of Patent:
February 11, 2003
Assignee:
Corning Cable Systems LLC
Inventors:
Patrick K. Strong, Michael L. Elmore, Jason C. Lail, Douglas S. Hedrick, Eddie H. Hudson
Abstract: A fiber optic cable and method of manufacturing the same include at least one optical fiber component and at least one strength member disposed adjacent to said at least one optical fiber component. The at least one strength member includes a yarn and a jacket generally surrounding said at least one optical fiber component and said at least one strength member. The yarn includes a coating system having a percentage by weight, based on the dry weight of said yarn, of about 2.0% or less. Other embodiments can include a delta attenuation of about 0.3 dB or less over the range of about 0% to about 1.0% of optical fiber strain, a peak cable core pull-out force of about 1 newton or less, or a space disposed between a cable core and the jacket.