Disclosed are example embodiments of a switching terminal that can be rotated with minimal parts. The switching terminal can include: an inner portion configured to be securely or loosely attached to an external conductor element; and an outer portion configured to be rotatably affixed to the inner portion when then inner portion is loosely attached to the external conductor and to be tightly affixed to the inner portion when then inner portion is tightly attached to the external conductor.

Disclosed are example embodiments of a switching terminal that can be rotated with minimal parts. The switching terminal can include: an inner portion configured to be securely or loosely attached to an external conductor element; and an outer portion configured to be rotatably affixed to the inner portion when then inner portion is loosely attached to the external conductor and to be tightly affixed to the inner portion when then inner portion is tightly attached to the external conductor.

A plug structure and an electronic device are provided. The plug structure includes a plug body and a plug. The plug body has an accommodating groove configured to accommodate the plug. The plug includes a rotating shaft and a plurality of pins. The rotating shaft is slidably arranged in the accommodating groove and is rotatable to at least a first position and a second position. When the rotating shaft is rotated to the first position, the plurality of pins is accommodated in the accommodating groove. When the rotating shaft is rotated from the first position to the second position, the plurality of pins protrudes out of the plug body from the accommodating groove. The plug structure and the electronic device are small in size and can be easily stored and carried around.

A floating connector includes a housing, a substantially planar surface positioned within the housing, a set of electrical contacts, and a bushing. The set of electrical contacts are arranged substantially normal to the planar surface. The bushing is cooperatively mated with the housing and the planar surface so as to permit the bushing to pivot the planar surface about one or more points. In one exemplary embodiment, the bushing defines a pair of diametrically opposite pin apertures. In such an embodiment, the floating connector may further include a pair of pivot pins, where each pivot pin passes through a respective one of the pin apertures and pivotally interconnects the bushing and the housing. Additionally, the housing may define a pair of diametrically opposite wells to receive the pivot pins. The floating connector may form part of an electronic apparatus that is mountable to a luminaire of a streetlight.

A floating connector includes a housing, a substantially planar surface positioned within the housing, a set of electrical contacts, and a bushing. The set of electrical contacts are arranged substantially normal to the planar surface. The bushing is cooperatively mated with the housing and the planar surface so as to permit the bushing to pivot the planar surface about one or more points. In one exemplary embodiment, the bushing defines a pair of diametrically opposite pin apertures. In such an embodiment, the floating connector may further include a pair of pivot pins, where each pivot pin passes through a respective one of the pin apertures and pivotally interconnects the bushing and the housing. Additionally, the housing may define a pair of diametrically opposite wells to receive the pivot pins. The floating connector may form part of an electronic apparatus that is mountable to a luminaire of a streetlight.

The present disclosure relates to a Radio Frequency (RF) connector and a terminal. The RF connector includes: a rotation shaft which includes a first connection contact and a second connection contact, the first connection contact and the second connection contact forming rotation shaft structures which are rotatable relative to each other, and the first connection contact and the second connection contact forming an electrical connection; a first connection wire, which is connected with the first connection contact; and a second connection wire, which is connected with the second connection contact. By rotationally connecting two connection wires through an RF connector, an antenna of a first part in a foldable terminal is connected to a motherboard of a second part in the foldable terminal, or the antenna of the second part in the foldable terminal is connected to the motherboard of the first part in the foldable terminal.

The present disclosure relates to a Radio Frequency (RF) connector and a terminal. The RF connector includes: a rotation shaft which includes a first connection contact and a second connection contact, the first connection contact and the second connection contact forming rotation shaft structures which are rotatable relative to each other, and the first connection contact and the second connection contact forming an electrical connection; a first connection wire, which is connected with the first connection contact; and a second connection wire, which is connected with the second connection contact. By rotationally connecting two connection wires through an RF connector, an antenna of a first part in a foldable terminal is connected to a motherboard of a second part in the foldable terminal, or the antenna of the second part in the foldable terminal is connected to the motherboard of the first part in the foldable terminal.

A rotary connector device includes a stator, a rotor and an electrical connector; the rotor including a rotor main body and a connector housing. The connector housing includes a first connector holder and a second connector holder. The second connector holder includes a second holder main body, a first wall, and a second wall. The first wall extends from the second holder main body along an axial direction parallel to the rotation axis. The second wall extends from the second holder main body along the axial direction and is coupled to the first wall.

A rotary connector device includes a stator, a rotor and an electrical connector; the rotor including a rotor main body and a connector housing. The connector housing includes a first connector holder and a second connector holder. The second connector holder includes a second holder main body, a first wall, and a second wall. The first wall extends from the second holder main body along an axial direction parallel to the rotation axis. The second wall extends from the second holder main body along the axial direction and is coupled to the first wall.

A rotary connector device includes a fixed body, a rotation body, and an inhibiting structure. The fixed body includes a first fixed body portion and a second fixed body portion disposed facing each other with a space being defined between the first fixed body portion and the second fixed body portion. The first fixed body portion and the second fixed body portion are coupled at a coupling portion. The rotation body rotatably is assembled to the fixed body. The inhibiting structure is configured to inhibit foreign matter from entering the space through the coupling portion. The coupling portion is exposed to an outer surface of the fixed body.