A device for applying a distribution cabling tape system includes a distribution cabling tape having an adhesive capable of adhering to a concrete or asphalt substrate and a distribution cable. The device includes an endoscope camera, wherein movement of the device in one direction simultaneously applies both the distribution cable and the distribution cabling tape at a location on the substrate viewable by the endoscope camera. A method for registering a cable and a cabling tape into a channel in a concrete or asphalt substrate includes using an endoscope to view the location at which the cable and cabling tape are applied.

A device for applying a distribution cabling tape system includes a distribution cabling tape having an adhesive capable of adhering to a concrete or asphalt substrate and a distribution cable. The device includes an endoscope camera, wherein movement of the device in one direction simultaneously applies both the distribution cable and the distribution cabling tape at a location on the substrate viewable by the endoscope camera. A method for registering a cable and a cabling tape into a conduit in a concrete or asphalt substrate includes using an endoscope to view the location at which the cable and cabling tape are applied.

A node pedestal includes a box configured to house communication system components, a housing configured to be removably coupled with the box and having opposite end walls, a pair of supports extending from the box at opposite ends of the box, and a locking mechanism configured to latch the housing with the box. The locking mechanism includes a latch rotatingly mounted to a first one of the end walls and a catch extending from a first one of the supports in a direction toward a second one of the supports, and the latch is configured to engage the catch to secure the housing to the box.

A method for adhering a tubular body onto a surface that includes smoothing a portion of the surface to create a smoothed segment of the surface and applying a tubular body directly onto the smoothed segment of the surface after the smoothing of the portion of the surface. The surface at the smoothed segment is smoother than the remainder of the surface. The method further includes applying an uncured protectant onto the tubular body while the tubular body is on the smoothed segment of the surface and curing the uncured protectant into a cured protectant while the uncured protectant is on the tubular body on the smoothed segment of the surface. The cured protectant protectively encases and adheres the tubular body to the surface.

A method of cutting a microtrech in which the buried utility is exposed by opening an access hole in a roadway above the buried utility using a roadway access hole drill that rotates and vibrates the drill bit. A roadway access hole drill having a down-the-hole jack-hammer drill bit and a motor to rotate the down-the-hole jack-hammer drill.

The disclosed systems for laying underground fiber optic cable may include a drive body, at least one rotational motor, a forward auger element rotatably coupled to the drive body and positioned to be rotated by the at least one rotational motor in a first rotational direction, and a rear auger element rotatably coupled to the drive body and positioned to be rotated by the at least one rotational motor in a second, opposite rotational direction. Various other systems, methods, and devices are also disclosed.

An optical fiber tape includes a matrix and at least one optical fiber connected to the matrix in an undulating manner. The undulations of the optical fiber are generally sinusoidal, semicircular, or elliptic, and are of amplitude and wavelength such that the minimum bend radius of each undulation is not less than a minimum bend radius specified by a manufacturer of the optical fiber. A road having an upper surface has a pathway indented into the upper surface to less than full depth of the road and has the optical fiber tape laid in the pathway so that the optical fiber tape does not protrude above the upper surface of the road.

The disclosed systems for laying underground fiber optic cable may include a drive body, at least one rotational motor, a forward auger element rotatably coupled to the drive body and positioned to be rotated by the at least one rotational motor in a first rotational direction, and a rear auger element rotatably coupled to the drive body and positioned to be rotated by the at least one rotational motor in a second, opposite rotational direction. Various other systems, methods, and devices are also disclosed.

A system and method for increasing friction between cables and surrounding soil is disclosed. In particular, a cable apparatus for use in a sub-surface protective network of intertwined cables is provided which comprises an elongate reinforced polymer cable body having a length. The cable apparatus also includes a plurality of elongate barbs provided along the length of the cable body. The barbs extend from the cable body to a respective free end in both a lengthwise direction and radially. Additionally, the barbs are spaced apart in one or more of the lengthwise direction along the length of the cable body and circumferentially about the cable body. Moreover, according to a further aspect, a plurality of such cables can be provided underground and intertwined to define a protective network cables for protecting buried assets.

Novel tools and techniques are provided for implementing telecommunications signal relays, and, more particularly, to methods, systems, and apparatuses for implementing telecommunications signal relays using radiating closures (either aerial, below grade, and/or buried, etc.), or the like. In various embodiments, a signal distribution system, which might be disposed within a radiating closure, might receive a first communications signal. A wireless transceiver of the signal distribution system might send the first communications signal, via one or more wireless communications channels, to one or more devices that are external to the radiating closure. In some embodiments, antennaswhich might comprise first antennas disposed within the radiating closure or second antennas embedded in a housing material of the radiating closure, or bothmight direct the first communications signal that is sent from the wireless transceiver to the one or more devices. In some cases, IoT sensors may be implemented in the radiating closure.