A method of laying an optical fiber comprises providing a continuous optical fiber, a first segment of optical-electrical hybrid cable having a first fiber receiving tube, and a second segment of optical-electrical hybrid cable having a second fiber receiving tube. The optical fiber is laid into the first fiber receiving tube using an air-blowing device. A leading end of the optical fiber is fixed in a transfer apparatus after the leading end passes through an outlet of the first fiber receiving tube. A portion of the optical fiber which has passed through the first segment is wound in the transfer apparatus until the optical fiber is completely laid in the first segment. The leading end of the optical fiber is detached from the transfer apparatus. The portion of the optical fiber which has passed through the first segment is laid into the second fiber receiving tube using the air-blowing device.

A method of laying an optical fiber comprises providing a continuous optical fiber, a first segment of optical-electrical hybrid cable having a first fiber receiving tube, and a second segment of optical-electrical hybrid cable having a second fiber receiving tube. The optical fiber is laid into the first fiber receiving tube using an air-blowing device. A leading end of the optical fiber is fixed in a transfer apparatus after the leading end passes through an outlet of the first fiber receiving tube. A portion of the optical fiber which has passed through the first segment is wound in the transfer apparatus until the optical fiber is completely laid in the first segment. The leading end of the optical fiber is detached from the transfer apparatus. The portion of the optical fiber which has passed through the first segment is laid into the second fiber receiving tube using the air-blowing device.

A composite cable connector for terminating a cable segment is provided having at least one fiber optic element and at least one conductor element is provided. The composite cable connector has a connector housing, receiving at a first end, the at least one fiber optic element and at least one conductor element. A ferrule at a second end of the connector housing presents the at least one fiber optic element. At least one crimp on element is positioned at a back end of the connector housing for crimping onto the connector housing and couples with the at least one conductor element. At least one conductive pathway, from the crimp on element to a front end of the connector housing, proximate the ferrule, presenting at least one conductive pathway at a front face of the connector housing.

A composite cable connector for terminating a cable segment is provided having at least one fiber optic element and at least one conductor element is provided. The composite cable connector has a connector housing, receiving at a first end, the at least one fiber optic element and at least one conductor element. A ferrule at a second end of the connector housing presents the at least one fiber optic element. At least one crimp on element is positioned at a back end of the connector housing for crimping onto the connector housing and couples with the at least one conductor element. At least one conductive pathway, from the crimp on element to a front end of the connector housing, proximate the ferrule, presenting at least one conductive pathway at a front face of the connector housing.

A method and apparatus for contactless installation of an optical fiber internet connection at a customer premises is provided, wherein the customer is provided with an interior installation kit and is guided by an installation technician. The customer remains inside the premises, selects an entry point for the fiber, and indicates the entry point to the technician using a remote detection target. The technician locates the detection target, bores a hole into the premises, passes an optical fiber in to the customer, and the customer secures an attachment mount to the interior wall of the premises to receive the optical fiber and upon which to connect and mount an optical network terminal. After the optical fiber has been connected, the customer network is activated, and the technician seals the external hole.

A method and apparatus for contactless installation of an optical fiber internet connection at a customer premises is provided, wherein the customer is provided with an interior installation kit and is guided by an installation technician. The customer remains inside the premises, selects an entry point for the fiber, and indicates the entry point to the technician using a remote detection target. The technician locates the detection target, bores a hole into the premises, passes an optical fiber in to the customer, and the customer secures an attachment mount to the interior wall of the premises to receive the optical fiber and upon which to connect and mount an optical network terminal. After the optical fiber has been connected, the customer network is activated, and the technician seals the external hole.

A non-metallic layer stranded optical cable with a reversal point capable of being positioned and a detection method thereof, which solves the problems of determining a reversal point of a cable core and performing an operation of drawing out an optical fiber from the optical cable. The present invention relates to a non-metallic layer stranded optical cable, and the key points of the technical solution thereof includes a cable core and a metal film provided at each reversal point of the cable core, and an outer sheath is provided on the cable core.

A power and optical fiber interface system includes a housing having an interior. A cable inlet is configured to receive a hybrid cable having an electrical conductor and an optical fiber. An insulation displacement connector (IDC) is situated in the interior of the housing configured to electrically terminate the conductor, and a cable outlet is configured to receive an output cable that is connectable to the IDC and configured to output signals received via the optical fiber.

A hybrid cable includes a central strength member, residing in a center of the cable. At least two insulated conductors are abutting the central strength member. One or more buffer tubes are included in the cable, each with at least one optical fiber. One or more filler rods are optionally included in the cable. A shielding layer and jacket surround the elements. In one embodiment, four large insulated conductors and two filler rods abut the central strength member. A first water-blocking tape surrounds the four large insulated conductors, filler rods and central strength member to form an inner core. A concentric core surrounds the central core. The concentric core includes two insulated conductors, plural buffer tubes and a second water-blocking tape surrounding the two insulated conductors and the plural buffer tubes. The shielding layer surrounds the concentric core, and the jacket surrounds the shielding layer. A toning signal carrying medium may also exist outside of the shielding layer.

A hybrid cable includes a central strength member, residing in a center of the cable. At least two insulated conductors are abutting the central strength member. One or more buffer tubes are included in the cable, each with at least one optical fiber. One or more filler rods are optionally included in the cable. A shielding layer and jacket surround the elements. In one embodiment, four large insulated conductors and two filler rods abut the central strength member. A first water-blocking tape surrounds the four large insulated conductors, filler rods and central strength member to form an inner core. A concentric core surrounds the central core. The concentric core includes two insulated conductors, plural buffer tubes and a second water-blocking tape surrounding the two insulated conductors and the plural buffer tubes. The shielding layer surrounds the concentric core, and the jacket surrounds the shielding layer. A toning signal carrying medium may also exist outside of the shielding layer.