An antenna device for a vehicle includes a base plate, an expansion element formed by a first expansion element part and a second expansion element part mated with the first expansion element part, and an actuating element cooperating with the base plate and the expansion element. Each of the first expansion element part and the second expansion element part has a flat area, a side arm protruding at an angle from the flat area, and a laterally open breakthrough in the flat area. The laterally open breakthrough of each of the first expansion element part and the second expansion element part when mated forms a single passage opening for the actuating element.

A radio antenna interface for a portable radio is provided comprising a radio housing having a control top with a circular walled control top opening for receiving an antenna, the circular walled control top opening having an interior surface with a protruding bumper feature formed thereon. An antenna having has a base portion for insertion into the circular walled control top opening, the base portion has a ring feature forming a full circumference bump around the base portion. Once the antenna is assembled with the portable radio, the ring feature is located beneath and abuts with the protruding bumper to form the radio antenna interface. The radio antenna interface provides increased friction to minimize loosening of the antenna under extreme usage conditions.

A radio antenna interface for a portable radio is provided comprising a radio housing having a control top with a circular walled control top opening for receiving an antenna, the circular walled control top opening having an interior surface with a protruding bumper feature formed thereon. An antenna having has a base portion for insertion into the circular walled control top opening, the base portion has a ring feature forming a full circumference bump around the base portion. Once the antenna is assembled with the portable radio, the ring feature is located beneath and abuts with the protruding bumper to form the radio antenna interface. The radio antenna interface provides increased friction to minimize loosening of the antenna under extreme usage conditions.

In one embodiment, a method for maintaining a coupling gap between a coupling element and a radiating element using an antenna carrier includes: applying, by one or more springs disposed on an inner surface of the antenna carrier, a first lateral force on the antenna carrier; causing, by the first lateral force, the antenna carrier to translate outwardly toward an edge of a mounting surface, the antenna carrier slidably coupled to the mounting surface; receiving, by one or more standoffs disposed on an outer surface of the antenna carrier, a second lateral force from an inside surface of a device cover; causing, by the second lateral force, the antenna carrier to translate inwardly away from the edge of the mounting surface; and causing, by the first lateral force and the second lateral force, the standoffs to maintain the coupling gap between the coupling element and the radiating element.

The present disclosure describes a telecommunications equipment mount. The telecommunications equipment mount includes a stabilization frame having a plurality of lower rails, a plurality of vertical rails, and a plurality of upper rails, the lower, vertical, and upper rails forming a top, a bottom, and at least sides of the stabilization frame to define an open interior cavity; at least one mounting member extending outwardly from, and perpendicular to, one of the sides of the stabilization frame a distance; at least one brace member coupled to the stabilization frame and configured to support the at least one mounting member; and at least one mounting pipe secured to the at least one mounting member. The stabilization frame is configured to ballast the mount on a mounting structure when telecommunications equipment is secured to the at least one mounting pipe. Telecommunications equipment mount assemblies are also described herein.

The present disclosure describes a telecommunications equipment mount. The telecommunications equipment mount includes a stabilization frame having a plurality of lower rails, a plurality of vertical rails, and a plurality of upper rails, the lower, vertical, and upper rails forming a top, a bottom, and at least sides of the stabilization frame to define an open interior cavity; at least one mounting member extending outwardly from, and perpendicular to, one of the sides of the stabilization frame a distance; at least one brace member coupled to the stabilization frame and configured to support the at least one mounting member; and at least one mounting pipe secured to the at least one mounting member. The stabilization frame is configured to ballast the mount on a mounting structure when telecommunications equipment is secured to the at least one mounting pipe. Telecommunications equipment mount assemblies are also described herein.

The combined antenna for satellite and terrestrial radio communications includes: a support structure (1); a “crossed dipole” compact broadband satellite antenna (10), in turn including a pair of dipoles (11,12), which extend from the support structure (1), and which are substantially perpendicular to each other and connected so as to be electrically out of phase. A broadband “monopole” antenna (50) for terrestrial communications is included, having a plurality of linear electric mass elements (52) extending radially from the support structure (1) to provide an electric mass surface (53), and a radiating arm (55) is also included extending from the support structure (1) away from the electric mass surface (53). The radiating arm (55) is arranged around the central column (2) and includes thread-like radiating elements (56); and the dipoles (11,12) further include one or more thread-like dipole elements (111,112), arranged to define a flattened configuration of the respective dipole (11,12).

The combined antenna for satellite and terrestrial radio communications includes: a support structure (1); a “crossed dipole” compact broadband satellite antenna (10), in turn including a pair of dipoles (11,12), which extend from the support structure (1), and which are substantially perpendicular to each other and connected so as to be electrically out of phase. A broadband “monopole” antenna (50) for terrestrial communications is included, having a plurality of linear electric mass elements (52) extending radially from the support structure (1) to provide an electric mass surface (53), and a radiating arm (55) is also included extending from the support structure (1) away from the electric mass surface (53). The radiating arm (55) is arranged around the central column (2) and includes thread-like radiating elements (56); and the dipoles (11,12) further include one or more thread-like dipole elements (111,112), arranged to define a flattened configuration of the respective dipole (11,12).

A support piece comprises: a first support section configured in the shape of a plate, and a plurality of second support sections; every second support section in the plurality of second support sections is set on the outside of the first support section and is bent relative to the first support section; every second support section comprises at least one support structure. At least a portion of the support structure of the at least one support structure is configured to support a first dipole arm, and at least a portion of the support structure of the at least one support structure is configured to support a second dipole arm; a second arm section on the outside of the first dipole arm is bent relative to the first arm section on the inside toward a first side of the first support section to support the dipole arm; a second arm section on the outside of the second dipole arm is bent relative to the first arm section on the inside toward a second side of the first support section opposite to the first side.

An antenna mast structure for a haul truck may include a buttressed frame having a support column and a raised frontal support point. The antenna mast structure may also include a propping element extending from the raised frontal support point and a top frame pivotally secured to the support column and supported at a front side by the propping element.