An antenna housing that is generally ovular such that a sidewall of the housing has two curved surfaces (e.g., rounded ends) on opposing ends of the housing. The ovular shape of the housing allows a center of curvature of each rounded end to be disposed within an interior of an antenna bay(s) within the housing. In such an arrangement, the placement of the centers of curvature within the antenna bays allows for pivotally mounting individual antennas at or near the center of curvature. This allows pivoting the antennas within the antenna bay while maintaining a normal vector (e.g., extending normal to an emitting surface of the antenna) nearly perpendicular with an inside surface of shroud surrounding the antenna housing thereby reducing RF reflection and/or scatter.

Access points can be mounted in a variety of locations or orientations and can support multiple communications protocols. In some embodiments, an access point includes a main housing and a front housing. The main and front housing are connected by a hinge. A Wi-Fi antenna is included in the front housing in some embodiments. The access point is configured for use in either an open or closed position. When mounted in a vertical position, the front housing can be lowered into a horizontal position, which facilitates a preferred orientation of an antenna with respect to the ground. A first set of cooling fins serves to maintain components of the access point offset from a wall to which the access point is mounted. This facilitates airflow. Additional fins act as a spacer between the main housing and the front housing when the access point is used in a closed position. This facilitates air flow around both sides of the main housing.

An antenna housing configured to house a wireless antenna unit. The antenna housing defines an interior space sized to receive a plurality of wireless radios and/or transceivers. Inlet and outlet ducting extends through the interior of the housing from an inlet manifold to an outlet manifold to individually cool each radio. In an arrangement, the inlet manifold draws air from outside the housing and the outlet manifold exhausts air outside of the manifold.

A device for mounting a cross beam in a base station antenna is provided. The device comprises a first knob formed on a first wall of the device, the first knob comprising a first shaft portion and a first head portion. The device further comprises a second knob formed on a second wall of the device, the second wall is arranged adjacent to the first wall. the second knob comprising a second shaft portion and a second head portion. The first shaft portion of the first knob is adapted to be received in a keyhole defined in the cross beam of base station antenna. The second shaft portion of the second knob in adapted to be received in a first slot defined in a reflector of base station antenna. The device eliminates requirement of hardware elements such as bolts, washers etc to mount cross beam in base station antenna.

A low-PIM dual pipe clamp and associated mounting bracket for securing a first pipe transverse to a second pipe at a cellular base station antenna site. The dual pipe clamp accommodates a range of pipe diameters with lower PIM generation, cost, and weight characteristics compared to conventional dual pipe clamps traditionally used at cell sites. The low-PIM dual pipe clamp minimizes the number of parts to upper and lower mounting brackets connected by linear threaded rod connectors, such as bolts, avoiding the use of U-bolts known to create PIM interference in conventional designs. The dual pipe clamp secures first and second pipes against each other in transverse orientations (e.g., horizontal and vertical), as typically utilized to mount antennas at cellular base stations. Each mounting bracket includes first and second pipe restrainers that bias the first and second pipes against each other as the threaded rod connectors are tightened.

A mounting base (14) is fixed to an antenna (13) or an antenna bracket (15) for supporting the antenna (13). A baseband unit (11) and an RF unit (12) are fixed to the mounting base (14). The baseband unit (11) fixed to the mounting base (14) is disposed to face a back part (132) of the antenna (13) and to form a space between the back part (132) and the first enclosure (111). The RF unit (12) fixed to the mounting base (14) is disposed in the space formed between the back part (132) of the antenna (13) and the baseband unit (11) and is coupled to a waveguide flange (132) of the antenna (13). Thus, for example, in a configuration of a point-to-point wireless apparatus in which an RF unit and a baseband unit are separated, restrictions on installation space of the apparatus can be facilitated.

The present disclosure describes monopole platform assembly. The platform assembly includes a frame, the frame including an elongate, hollow main support member of rectangular cross-section, and a plurality of elongate, hollow auxiliary support members of rectangular cross-section attached orthogonally to the main support member; a mounting plate coupled to an end of the main support member; at least two grating edge members coupled to the auxiliary support members; and a grating, the grating being supported by the two grating edge members, the auxiliary support members, and the main support member. The opposing ends of each auxiliary support member extend a distance outwardly passed the grating edge members such that the extended ends of the auxiliary support members are positioned to support a horizontal pipe member. The extended ends of the auxiliary support members each include a feature configured to enable fixing of the horizontal pipe member thereto. Additional platform assemblies are described herein.

The present disclosure describes an antenna mount. The antenna mount may include a base plate having a plurality of mounting apertures configured to secure an antenna thereto, wherein the base plate includes a plurality of arm sections extending radially outwardly therefrom, each arm section comprising an elongated slot, a plurality of fasteners, each fastener configured to slide within a respective slot, and a plurality of brackets, each bracket secured to the base plate by a respective fastener extending through each slot, wherein the position of the brackets are adjustable relative to the base plate by sliding the fasteners within each slot, thereby allowing the antenna mount to be secured to different diameter mounting structures. Antenna mount assemblies are also described herein.

The present invention relates to a heat dissipation device for an electronic element, the heat dissipation device including a first chamber in which a printed circuit board having heating elements mounted thereon is disposed, a second chamber configured to exchange heat with heat transferred from the first chamber and configured such that an injection part configured to inject a refrigerant and a refrigerant supply part configured to supply the refrigerant to the injection part are disposed in the second chamber, a heat transfer part disposed between the first chamber and the second chamber and configured to receive heat from the heating elements of the first chamber and supply the heat to the second chamber, and a condensing part configured to condense the refrigerant injected into the second chamber, in which a plurality of evaporation-inducing ribs is provided on a surface of the heat transfer part exposed to the second chamber and allows the liquid refrigerant injected by the injection part to be adsorbed and then flow downward along wave-pattern flow paths having zigzag shapes, thereby providing an advantage of improving heat dissipation performance without increasing a size thereof.

A mounting assembly for a base station antenna includes a pair of clamp brackets, a mounting bracket configured to be connected to the base station antenna and a lead screw sub-assembly. The lead screw sub-assembly is adapted to pivotably couple the mounting bracket to the pair of clamp brackets. The lead screw sub-assembly comprising a lead screw engaged with at least one clamp bracket of pair of clamp brackets and an adjustment bracket coupled at a first end of lead screw. The adjustment bracket is configured to allow a pivotal movement of mounting bracket with respect to pair of clamp brackets. The lead screw is rotatable within the at least one clamp bracket for adjusting a tilt angle of the base station antenna. The antenna utilizes a single mounting assembly to facilitate mounting of the antenna to the support structure.