Abstract: A cable system and method including a cable or a microduct provided within the groove extending vertically into, but not through, a pavement. The cable has a central strength member, at least one buffer tube stranded around the central strength member, an outerjacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. Provided within the microduct is a microduct cable including at least one transmission element. A cable including a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. The cable has a longitudinal thermal expansion force due to a change in temperature from 20° C. to 70° C. of less than 305 lbs when constrained.

Abstract: An optical fiber cable including a central strength member extending longitudinally; a plurality of buffer tubes housing optical fibers and stranded around the strength member; a pair of filler elements stranded around the strength member along with the buffer tubes and arranged such that one filler element of the pair is diametrically opposite the other filler elements of the pair to protect the buffer tubes when the cable is subjected to a radially inward force; and an outer sheath surrounding the buffer tubes and filler elements

Abstract: A cable system and method including a cable or a microduct provided within the groove extending vertically into, but not through, a pavement. The cable has a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. Provided within the microduct is a microduct cable including at least one transmission element. A cable including a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. The cable has a longitudinal thermal expansion force due to a change in temperature from 20° C. to 70° C. of less than 305 lbs when constrained.

Abstract: A drop cable includes a jacket having first and second opposing sides. The first side has a concave surface. At least one strength member is disposed in the jacket. An optical transmission component is disposed within the jacket and proximate the concave surface. The optical transmission component includes a plurality of optical fibers.

Abstract: A method of installing a cable including at least one communication element, such as an optical fiber, disposed in a buffer tube and a surrounding jacket. The method includes the steps of exposing a portion of the buffer tube over a predetermined length and forming the exposed portion of the buffer tube into a coupling coil having at least one loop. The cable installation method prevents fiber retraction in cable terminations by utilizing at least one coupling coil formed from the exposed buffer tube and advantageously yields coupling coil terminations with small diameter coils, requiring less cable for more efficient installation, and further provides for the coupling coil to be located within a splice closure for more visually pleasing terminations. Preferably, coupling coils are formed at each end of the cable and located in splice enclosures.

Abstract: A cable system and method including a cable or a microduct provided within the groove extending vertically into, but not through, a pavement. The cable has a central strength member, at least one buffer tube stranded around the central strength member, an outerjacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. Provided within the microduct is a microduct cable including at least one transmission element. A cable including a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. The cable has a longitudinal thermal expansion force due to a change in temperature from 20° C. to 70° C. of less than 305 lbs when constrained.

Abstract: A cable system and method including a cable or a microduct provided within the groove extending vertically into, but not through, a pavement. The cable has a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. Provided within the microduct is a microduct cable including at least one transmission element. A cable including a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. The cable has a longitudinal thermal expansion force due to a change in temperature from 20° C. to 70° C. of less than 305 lbs when constrained.

Abstract: A cable system and method including a cable or a microduct provided within the groove extending vertically into, but not through, a pavement. The cable has a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. Provided within the microduct is a microduct cable including at least one transmission element. A cable including a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. The cable has a longitudinal thermal expansion force due to a change in temperature from 20° C. to 70° C. of less than 305 lbs when constrained.

Abstract: The present invention is an easy access tape with peelable sections to allow easy access to the internal components of the cable or tube. The tape of the present invention contains at least one removable, peelable section which can be easily positioned within the cable and can be removed easily. The removable section of the tape is separated from the remainder of the tape by a number of different methods, including the use of perforation and channels. Additionally, the removable section of the tape can have a different thickness than the remainder of the tape, can be made of different materials, or have different physical properties.

Abstract: A central tube cable, including a cable jacket defining an optical fiber cavity therein; at least one radial strength member embedded in the jacket; a plurality of optical fibers disposed within the optical fiber cavity; and a bundle support member disposed inside the optical fiber cavity to limit movement of the optical fibers with respect to the bundle support member. The optical fibers are preferably housed in buffer tubes and at least some of the buffer tubes contact the bundle support member. The buffer tubes are either helically stranded around the bundle support member or are S-Z stranded. The optical fibers may be provided in the form of optical fiber ribbons that are located in the optical fiber cavity.

Abstract: A fiber optic cable is provided with an outer jacket material having a coefficient of thermal expansion less than approximately 6E?5 in the range from 23° C. to ?50° C. By utilizing an outer jacket material having a reduced coefficient of thermal expansion, the need for rigid strength members within the outer jacket is eliminated, thereby providing a fiber optic cable having a reduced size and weight.

Abstract: A method of installing a cable including at least one communication element, such as an optical fiber, disposed in a buffer tube and a surrounding jacket. The method includes the steps of exposing a portion of the buffer tube over a predetermined length and forming the exposed portion of the buffer tube into a coupling coil having at least one loop. The cable installation method prevents fiber retraction in cable terminations by utilizing at least one coupling coil formed from the exposed buffer tube and advantageously yields coupling coil terminations with small diameter coils, requiring less cable for more efficient installation, and further provides for the coupling coil to be located within a splice closure for more visually pleasing terminations. Preferably, coupling coils are formed at each end of the cable and located in splice enclosures.

Abstract: A fiber optic cable with optical fibers stranded around a central strength member, and surrounded outer jacket made of a low coefficient of friction material and thinly constructed to show the profile of the stranded shape of the optical lines through the jacket, to thereby form a textured surface.

Abstract: A cable system and method including a cable or a microduct provided within the groove extending vertically into, but not through, a pavement. The cable has a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. Provided within the microduct is a microduct cable including at least one transmission element. A cable including a central strength member, at least one buffer tube stranded around the central strength member, an outer jacket surrounding the buffer tube and central strength member, and at least one transmission element provided within said at least one buffer tube. The cable has a longitudinal thermal expansion force due to a change in temperature from 20 ° C. to 70 ° C. of less than 305 lbs when constrained.

Abstract: A fiber optic cable is provided with an outer jacket material having a coefficient of thermal expansion less than approximately 6E-5 in the range from 23° C. to −50° C. By utilizing an outer jacket material having a reduced coefficient of thermal expansion, the need for rigid strength members within the outer jacket is eliminated, thereby providing a fiber optic cable having a reduced size and weight.

Abstract: A fiber optic cable utilizing fibers mixed within the jacket material. This design improves the properties of the jacket by decreasing the jacket's shrinkage after aging; decreasing the jacket's coefficient of thermal expansion; and increasing the jacket's surface roughness.

Abstract: A fiber optic cable with optical fibers stranded around a central strength member, and surrounded outerjacket made of a low coefficient of friction material and thinly constructed to show the profile of the stranded shape of the optical lines through the jacket, to thereby form a textured surface

Abstract: The present invention is an easy access tape with peelable sections to allow easy access to the internal components of the cable or tube. The tape of the present invention contains at least one removable, peelable section which can be easily positioned within the cable and can be removed easily. The removable section of the tape is separated from the remainder of the tape by a number of different methods, including the use of perforation and channels. Additionally, the removable section of the tape can have a different thickness than the remainder of the tape, can be made of different materials, or have different physical properties.

Abstract: A central tube cable, including a cable jacket defining an optical fiber cavity therein; at least one radial strength member embedded in the jacket; a plurality of optical fibers disposed within the optical fiber cavity; and a bundle support member disposed inside the optical fiber cavity to limit movement of the optical fibers with respect to the bundle support member. The optical fibers are preferably housed in buffer tubes and at least some of the buffer tubes contact the bundle support member. The buffer tubes are either helically stranded around the bundle support member or are S-Z stranded. The optical fibers may be provided in the form of optical fiber ribbons that are located in the optical fiber cavity.

Abstract: A seal for sealing the space between a cable and the ends of the corrugated conduit. The seal includes a seal body including a base portion, an engagement portion attached to the base portion and being insertable in the space between the cable and the conduit, and a retainer disposed on the engagement portion for engaging at least one of the corrugations of the conduit. The base portion preferably has a groove for retaining an O-ring such that the O-ring tightly circumscribes the cable to create a seal. The retainer preferably includes helical threads disposed on the outside surface of the engagement portion. Alternatively, however, the retainer can include a rib which engages a corrugation or one or more protrusions which engages a corrugation. Further, the seal body is preferably split into two halves so that it can be installed onto the cable without requiring access to the end of the cable. In addition, the seal body may include two halves interconnected by a hinge so that it is one-piece.