The present disclosure describes strand mounts for small cell radios. A strand mount may include a top plate, a bottom plate, and opposing side plates that form a housing having an interior cavity dimensioned to fit around one or more small cell radios, a plurality of mounting members, each mounting member coupled to the top and bottom plates within the interior cavity and configured such that a small cell radio can be mounted thereto, and one or more mounting brackets. The strand mount has the dual-capability of being mounted either horizontally on a cable strand or vertically on a pole. Alternative strand mounts and strand mount assemblies are also provided.

A module for a base station monopole has a wall defining an interior space. The wall includes an opening configured to receive electronic equipment and a vent opening in communication with the exterior of the module. A reinforcement member is secured to the wall and is positioned opposite to the opening and adjacent the vent opening. A baffle is supported adjacent the wall where the baffle has an intake opening and an exhaust opening in communication with the vent opening. The intake opening is laterally offset from the exhaust opening.

A modular monopole for wireless communications includes: an antenna module having a floor, a ceiling and a side wall that form an antenna compartment, wherein at least one antenna resides within the antenna compartment; a radio module having a floor, a ceiling and a side wall that form a radio compartment, wherein at least one remote radio unit (RRU) resides within the radio compartment; and a base. The base, the radio module, and the antenna module are arranged in vertically stacked relationship, with the base below the radio module and the antenna module above the radio module.

The present invention relates to an installation bracket (100), comprising a top plate unit (102) configured to be positioned at the top end of a tubular element (104), and a clamping device (106) coupled to the top plate unit (102); wherein the clamping device (106) is configured to be clamped against the inner wall (108) of the tubular element (104) thereby fixing the installation bracket (100) to the tubular element (104) in its clamping state.

Various base station enclosures and systems are detailed herein. Such systems can include, a radio unit (RU) and a plurality of cellular antennas. A base station cellular enclosure is present that reduces wind drag. The enclosure can include an airfoil enclosure housing that defines a cavity for housing the plurality of antennas and is at least partially covered in dimples to reduce wind drag.

A communications system. The communications system includes a pole with an inner channel extending substantially an entire vertical height thereof, the pole being anchorable in a support surface. An antenna luminary assembly is received in the inner channel of the pole at an end thereof, the antenna luminary assembly including an antenna and a light source. The antenna luminary assembly is transitionable from an unlocked position where the antenna luminary assembly is rotatable about a central axis of the pole and a locked position where the antenna luminary assembly is non-rotatable about the central axis of the pole. A rotational position of the antenna luminary assembly relative to central axis of the pole defines a horizontal azimuth of the antenna.

A mounting assembly can include or use a pole attachment mount, first, second, and third arms, respectively including proximal ends that are respectively couplable to the pole attachment mount, the proximal end of the second arm located between the proximal ends of the first and third arms, a first face member, coupled to a distal end of the first arm and coupled to a distal end of the second arm and a second face member, coupled to a distal end of the third arm and coupled to a distal end of the second arm. Multiple mounting assemblies can he attached to a pole such as to provide a mounting surface for communications equipment and orienting the same such as to cover multiple azimuths around the pole.

A multi-antenna mounting device includes: a mounting member to which two or more antennas are fixable; and a tilt angle adjusting mechanism including an upper adjusting component and a lower adjusting component spaced apart along a length direction of the mounting member. The upper adjusting component includes a plurality of tilt angle adjusting holes arranged in a row, one end of the upper adjusting component is connectable to the mounting member, and the other end is connectable to a user's support pole with a fastening element extending through one of the tilt angle adjusting holes. When the fastening element extends through different tilt angle adjusting holes, the multi-antenna assembly has different mechanical tilt angles relative to the support pole. The lower adjusting component includes a first section and a second section. The second section has a predetermined length and the first section is pivotable relative to the second section.

The present disclosure describes a sector frame antenna mount assembly. The assembly includes an antenna mount, a sector frame, and a pair of offset extension units. The pair of offset extension units are configured to position the sector frame an increased distance from a mounting structure.

A power transmission tower comprises a tower body (100) longitudinally arranged and cross arms (120) transversely arranged on the tower body. The tower body (100) is provided with a first transverse direction (Y) and a second transverse direction (X), which are perpendicular to each other, in the horizontal direction. A supporting piece (110), which extends outwards from the tower body (100) in the first transverse direction (Y), is arranged on the power transmission tower. One end of the supporting piece (110) is fixed to the tower body (100) and the other end of the supporting piece (110) is a free end (111, 112). The cross arms (120) extend in the second transverse direction (X). One end of each cross arm (120) is connected to the free end (111, 112) and the other end of each cross arm (120) is used for arranging overhead wires. The power transmission tower reduces corridor width and occupies less area.