Abstract: Methods for manufacturing cables and cables assemblies include providing powder particles within a tube extruded about optical fiber. The particles may be accelerated so that as they strike the tube and mechanically attach to the tube.

Abstract: Methods for manufacturing cables and cables assemblies include providing powder particles within a tube extruded about optical fiber. The particles may be accelerated so that as they strike the tube and mechanically attach to the tube.

Abstract: Methods for manufacturing cables and cables assemblies include providing powder particles within a tube extruded about optical fiber. The particles may be accelerated so that as they strike the tube and mechanically attach to the tube.

Abstract: Methods for manufacturing cables and cables assemblies include providing powder particles within a tube extruded about optical fiber. The particles may be accelerated so that as they strike the tube and mechanically attach to the tube.

Abstract: A fiber optic cable includes a jacket, an element of the cable interior to the jacket, and first and second powders. The element includes a first surface and a second surface. The cable further includes a third surface interior to the jacket and facing the first surface at a first interface and a fourth surface interior to the jacket and facing the second surface at a second interface. At least one of the third and fourth surfaces is spaced apart from the jacket. The first powder is integrated with at least one of the first and third surfaces at the first interface and the second powder integrated with at least one of the second and fourth surfaces at the second interface. The first interface has greater coupling than the second interface at least in part due to differences in the first and second powders.

Abstract: Methods for manufacturing cables and cables assemblies include providing powder particles within a tube extruded about optical fiber. The particles may be accelerated so that as they strike the tube and mechanically attach to the tube.

Abstract: A fiber optic cable includes a jacket, an element of the cable interior to the jacket, and first and second powders. The element includes a first surface and a second surface. The cable further includes a third surface interior to the jacket and facing the first surface at a first interface and a fourth surface interior to the jacket and facing the second surface at a second interface. At least one of the third and fourth surfaces is spaced apart from the jacket. The first powder is integrated with at least one of the first and third surfaces at the first interface and the second powder integrated with at least one of the second and fourth surfaces at the second interface. The first interface has greater coupling than the second interface at least in part due to differences in the first and second powders.

Abstract: An optical communication cable includes a central strength member, at least one optical fiber, a buffer tube surrounding the at least one optical fiber; and at least one non-solid filler tube defining a cavity, wherein the cavity contains a water-blocking component and no optical fibers, and wherein the buffer tube and the filler tube are stranded about the central strength member.

Abstract: A fiber optic cable includes a jacket, an element of the cable interior to the jacket, and first and second powders. The element includes a first surface and a second surface. The cable further includes a third surface interior to the jacket and facing the first surface at a first interface and a fourth surface interior to the jacket and facing the second surface at a second interface. At least one of the third and fourth surfaces is spaced apart from the jacket. The first powder is integrated with at least one of the first and third surfaces at the first interface and the second powder integrated with at least one of the second and fourth surfaces at the second interface. The first interface has greater coupling than the second interface at least in part due to differences in the first and second powders.

Abstract: A fiber optic cable includes one or more optical fibers, a jacket, strength members, and water-swellable powder. The jacket is formed from a polymer and has a cavity defined therein. The one or more optical fibers extend through the cavity. Further, the jacket is non-round in cross-section and the strength members are encapsulated in the jacket on opposite sides of the cavity. The water-swellable powder is at least partially mechanically attached to an inner surface of the cavity, where the mechanical attachment of the water-swellable powder allows a portion of particles of the water-swellable powder to protrude beyond the surface and not be completely embedded therein.

Abstract: A fiber optic cable includes one or more optical fibers, a jacket, strength members, and water-swellable powder. The jacket is formed from a polymer and has a cavity defined therein. The one or more optical fibers extend through the cavity. Further, the jacket is non-round in cross-section and the strength members are encapsulated in the jacket on opposite sides of the cavity. The water-swellable powder is at least partially mechanically attached to an inner surface of the cavity, where the mechanical attachment of the water-swellable powder allows a portion of particles of the water-swellable powder to protrude beyond the surface and not be completely embedded therein.

Abstract: A fiber optic cable includes a jacket, an element of the cable interior to the jacket, and first and second powders. The element includes a first surface and a second surface. The cable further includes a third surface interior to the jacket and facing the first surface at a first interface and a fourth surface interior to the jacket and facing the second surface at a second interface. At least one of the third and fourth surfaces is spaced apart from the jacket. The first powder is integrated with at least one of the first and third surfaces at the first interface and the second powder integrated with at least one of the second and fourth surfaces at the second interface. The first interface has greater coupling than the second interface at least in part due to differences in the first and second powders.

Abstract: A fiber optic cable includes a tube formed from a flame-retardant material, an optical fiber disposed in a cavity of the tube, and powder comprising flame-retardant particles. At least a portion of the powder is mechanically attached to a surface of the cavity, where the mechanical attachment of the powder allows a portion of flame-retardant particles of the powder to protrude beyond the surface and not be completely embedded therein.

Abstract: A fiber optic cable includes a tube formed from a flame-retardant material, an optical fiber disposed in a cavity of the tube, and powder comprising flame-retardant particles. At least a portion of the powder is mechanically attached to a surface of the cavity, where the mechanical attachment of the powder allows a portion of flame-retardant particles of the powder to protrude beyond the surface and not be completely embedded therein.